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EP2254993A1 - Nanosupports de protéine, leur procédé d'obtention et applications - Google Patents

Nanosupports de protéine, leur procédé d'obtention et applications

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Publication number
EP2254993A1
EP2254993A1 EP09712586A EP09712586A EP2254993A1 EP 2254993 A1 EP2254993 A1 EP 2254993A1 EP 09712586 A EP09712586 A EP 09712586A EP 09712586 A EP09712586 A EP 09712586A EP 2254993 A1 EP2254993 A1 EP 2254993A1
Authority
EP
European Patent Office
Prior art keywords
fusion protein
peptide
bap
ligand
protein
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP09712586A
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German (de)
English (en)
Inventor
José Francisco Rodríguez Aguirre
Ana María OÑA BLANCO
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Kapsid Link SL
Original Assignee
Kapsid Link SL
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Filing date
Publication date
Application filed by Kapsid Link SL filed Critical Kapsid Link SL
Priority to EP09712586A priority Critical patent/EP2254993A1/fr
Publication of EP2254993A1 publication Critical patent/EP2254993A1/fr
Withdrawn legal-status Critical Current

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    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12NMICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
    • C12N7/00Viruses; Bacteriophages; Compositions thereof; Preparation or purification thereof
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K14/00Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
    • C07K14/005Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from viruses
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K2039/51Medicinal preparations containing antigens or antibodies comprising whole cells, viruses or DNA/RNA
    • A61K2039/525Virus
    • A61K2039/5258Virus-like particles
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K2319/00Fusion polypeptide
    • C07K2319/20Fusion polypeptide containing a tag with affinity for a non-protein ligand
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K2319/00Fusion polypeptide
    • C07K2319/33Fusion polypeptide fusions for targeting to specific cell types, e.g. tissue specific targeting, targeting of a bacterial subspecies
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K2319/00Fusion polypeptide
    • C07K2319/70Fusion polypeptide containing domain for protein-protein interaction
    • C07K2319/735Fusion polypeptide containing domain for protein-protein interaction containing a domain for self-assembly, e.g. a viral coat protein (includes phage display)
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K2319/00Fusion polypeptide
    • C07K2319/70Fusion polypeptide containing domain for protein-protein interaction
    • C07K2319/74Fusion polypeptide containing domain for protein-protein interaction containing a fusion for binding to a cell surface receptor
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K2319/00Fusion polypeptide
    • C07K2319/90Fusion polypeptide containing a motif for post-translational modification
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12NMICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
    • C12N2720/00MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA dsRNA viruses
    • C12N2720/00011Details
    • C12N2720/10011Birnaviridae
    • C12N2720/10022New viral proteins or individual genes, new structural or functional aspects of known viral proteins or genes
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12NMICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
    • C12N2720/00MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA dsRNA viruses
    • C12N2720/00011Details
    • C12N2720/10011Birnaviridae
    • C12N2720/10023Virus like particles [VLP]

Definitions

  • the invention relates to a system for the transport and presentation of products of interest based on nanocarriers (NCs) formed by protein assemblies, obtained by means of the assembly of a genetically modified self assembly protein in order to couple products of interest bound to a ligand.
  • NCs nanocarriers
  • the invention also related to processes for producing them and applications.
  • VLPs virus like particles
  • VLPs obtained by means of expressing a large number of viral proteins in the development of non- infective vaccines (subunit) against various diseases (Yao et al., 2003; Maclean et al . , 2005; Hammonds et al . , 2007) .
  • the genetic modification of some of these proteins has allowed obtaining chimeric VLPs characterized by the insertion of heterologous amino acid regions corresponding to immunogenically relevant proteins of different origin (Niikura et al . , 2002; Varsani et al . , 2003) .
  • Chimeric VLPs have essentially been used for the development of subunit vaccines which can induce a specific response against heterologous epitopes introduced in the protein which can self assemble (Xu et al . , 2006; Mejia et al . , 2006) .
  • the viability of these types of vaccines is conditioned by the technical difficulty required for introducing a repertoire of epitopes that is wide enough so as to assure the induction of an immune response against a sufficient number of antigenic determinants of the pathogen of interest.
  • EP1849799 describes VLPs based on SV40 protein Vl in which different epitopes are inserted in an internal region of said protein, including the myc, FLAG, HA, Tat-PTD, hexahistidine, RGD epitopes, etc., as well as VLPs formed by the assembly of said protein and conjugates formed by VLPs containing the FLAG epitope and anti-FLAG antibodies.
  • TMV coat protein Ul in which epitopes have been introduced in an internal region of said protein forming an exposed loop in the VLP.
  • Said epitopes include the V5 epitope, the HA epitope and the myc epitope, as well as the formation of complexes between the VLP and a ligand that specifically recognizes the epitope inserted in the protein Ul .
  • US2006/0121468 describes VLPs based on infectious pancreatic necrosis virus (IPNV) proteins VP2 and VP3 containing HIV-I epitopes in an internal region of said sequences resulting in their presentation in a loop exposed to the solvent.
  • IPNV infectious pancreatic necrosis virus
  • VLPs based on bovine papillomavirus type 1 (BPV-I) protein Ll comprising the sequence of an extracellular CCR5 loop wherein said region is inserted in an internal region of protein Ll .
  • BBV-I bovine papillomavirus type 1
  • WO0069907 describes oligomers formed from subunit cpnlO of chaperonin (GroES and protein Gp31 of phage T4) in which an antigenic epitope is inserted in an internal region of said sequence (the so-called mobile loop) such that after the oligomer is assembled, the antigenic epitope is exposed to the exterior; conjugates formed by VLPs based on Gp31 with an antibody are furthermore described.
  • BL encoded by Escherichia coli gene BirA (Barker et al . , 1981) .
  • BirA Barker et al . , 1981
  • This approach has allowed developing systems for purifying soluble proteins and protein complexes (Nesbeth et al . , 2006; Barat and Wu, 2007) .
  • Figure 1 schematically shows the production of nanocarriers (NCs) loaded with recombinant proteins.
  • the strategy briefly consists of: on one hand, (1) expressing a genetically modified self assembly protein (gray lines) by means of introducing a peptide insert or heterologous sequence (black) comprising a specific binding domain (black) in an exposed region of the protein assembly (2) ; on the other hand, constructing vectors for expressing bipartite recombinant proteins (3) comprising a region (dotted) with the capacity to interact with the exposed specific binding domain in the NCs and a region comprising a protein of interest (white) ; and, finally, (4) the interaction between the NCs and the recombinant proteins leads to the formation of stable complexes wherein the recombinant proteins coat the surface of the NC.
  • FIG. 2 shows the experimental design for constructing the self assembly fusion protein SAP_BAP (SEQ ID NO: 4) .
  • the self assembly protein (SAP) is the protein identified as IBDV pVP2 452 [protein comprising amino acids 1- 452 of infectious bursal disease virus (IBDV) protein VP2] and the BAP peptide is a biotin acceptor peptide having the amino acid sequence shown in SEQ ID NO: 3.
  • Figure 2A schematically shows the position of the flexible loop P H i inside the primary sequence of said SAP as well as its position (marked in a box) inside the atomic structure of the latter (lower part of the panel); the corresponding image was generated by using the Chimera computer program with the access code of the Protein Data Base PDB: 2GSY, corresponding to pVP2_452 (Garriga et al . , 2006) .
  • the amino acid sequence of loop P H i as well as the numbers corresponding to the initial and terminal residues of said loop P HI in the sequence of the SAP (pVP2_452) are shown.
  • the different domains, protuberant (P) , capsid (S), base (B) , of said BAP peptide are also indicated.
  • FIG. 2B schematically shows the position of the BAP peptide inside the flexible loop P H i in fusion protein SAP_BAP.
  • the amino acid sequence of the modified loop P H i as well as the numbers corresponding to the initial and terminal residues of the mentioned loop in the sequence of fusion protein SAP BAP are shown .
  • FIG. 3 shows the expression of self assembly fusion protein SAP_BAP (SEQ ID NO: 4) [Example 1.2] .
  • SAP_BAP self assembly fusion protein
  • FIG. 3 shows the expression of self assembly fusion protein SAP_BAP (SEQ ID NO: 4) [Example 1.2] .
  • an extract of a culture of insect cells infected with the recombinant baculovirus rBV/FB SAP BAP was analyzed by means of SDS-PAGE and immunoblotting using a specific serum against the SAP (IBDV anti-pVP2_452) .
  • the positions of the band recognized by the anti-serum (SAP_BAP) corresponding to fusion protein SAP_BAP and the positions of the bands corresponding to the pre- stained molecular weight (MW) markers used in the assay are indicates.
  • the molecular mass of the markers is indicated in kDa.
  • the SAP is IBDV pVP2_452 and the BAP peptide has the amino acid sequence shown in SEQ ID NO: 3.
  • Figure 4 shows the purification and structural characterization of NCs produced by means of the expression of fusion protein SAP_BAP (SEQ ID NO: 4) .
  • An extract of a culture of insect cells infected with the recombinant baculovirus rBV/FB SAP BAP was used to purify the NCs produced by means of centrifuging in sucrose gradients.
  • Figure 4A shows the results of the analysis by means of SDS-PAGE and immunoblotting of the fractions collected from a 20-50% sucrose gradient.
  • the positions of the bands recognized by the anti-serum (IBDV anti- pVP2_452) corresponding to fusion protein SAP_BAP and the positions of the bands corresponding to the pre-stained molecular weight (MW) markers used in the assay are indicated.
  • the molecular mass of the markers is indicated in kDa.
  • the positions of the samples corresponding to the upper and lower areas of the gradient are indicated with the words top and bottom, respectively.
  • the box indicates the fractions used for the subsequent structural characterization of the purified NCs.
  • the fractions corresponding to the area of the gradient with a higher content of fusion protein SAP_BAP were mixed and analyzed by means of electronic microscopy.
  • Figure 4B is a micrograph corresponding to a samples subjected to negative staining with uranyl acetate.
  • the bar indicates 100 A.
  • the SAP is IBDV pVP2 452 and the BAP peptide has the amino acid sequence shown in SEQ ID NO: 3.
  • Figure 5 shows the characterization of the biotinylation of NCs produced by means of the expression of fusion protein SAP_BAP (SEQ ID NO: 4) .
  • samples containing purified NCs from insect cells infected with the recombinant baculovirus rBV/FB SAP BAP were incubated with biotin in the presence (+) or absence (-) of the commercial biotin ligase (BL) enzyme. After the incubation, the samples were subjected to SDS-PAGE. The corresponding gels were stained with Coomassie blue ( Figure 5A) , or transferred to nitrocellulose membranes.
  • Figure 5A Coomassie blue
  • NC_SAP recombinant baculovirus rBV/FB_SAP
  • SAP recombinant baculovirus rBV/FB_SAP
  • the SAP is IBDV pVP2_452 and the BAP peptide has the amino acid sequence shown in SEQ ID NO: 3.
  • Figure 6 shows the characterization of NCs by the assembly of fusion protein SAP_BAP (SEQ ID NO: 4) produced in the presence of the biotin ligase (BL) enzyme.
  • FIG. 6B shows a second membrane corresponding to peroxidase-conjugated streptavidin (Figure 6B) and subsequently developed by means of incubation with l-chloro-4-naphthol .
  • the position of the molecular weight markers (in kDa) used in the assay is indicated.
  • Figure 6C shows a micrograph corresponding to purified NCs from cultures infected with rBV_FB_SAP_BAP_BirA subjected to negative staining with uranyl acetate and displayed by means of electronic microscopy. The bar indicates 100 A.
  • the SAP is IBDV pVP2_452 and the BAP peptide has the amino acid sequence shown in the SEQ ID NO: 3.
  • Figure 7 is a schematic diagram of chimeric gene mAV_NANP. Said diagram shows the essential elements of chimeric gene mAV_NANP (SEQ ID NO: 20) synthesized in vitro and subsequently cloned into vector pFastBacl . The region encoding a mutant form of avidin (mAV) of G. gallus, the region corresponding to the sequence encoding 6 consecutive repetitions of the NANP peptide (6xNANP) followed by a stop codon (TAA) and by the region corresponding to a multiple cloning site (MCS) are indicated.
  • mAV avidin
  • TAA stop codon
  • MCS multiple cloning site
  • Figure 8 shows the characterization of the interaction between protein mAV_NANP (SEQ ID NO: 23) and biotinylated NCs in vitro. Briefly, supernatants of cultures of insect cells that are not infected (SN-) or infected with the recombinant baculovirus rBV/ FB_mAV_NANP (SN+) were incubated with biotinylated NCs (NC-biot) , or with non-biotinylated NCs (NC-) or with buffer lacking NCs (-) . Total samples of SN- and SN+ not subjected to ultracentrifugation were analyzed as controls.
  • the samples were deposited on a 20% sucrose cushion and subjected to ultracentrifugation .
  • the sediments obtained were resuspended in loading buffer and subjected to SDS-PAGE and immunoblotting.
  • the resulting nitrocellulose membranes were divided into two halves. The upper half of the membranes (A) was incubated with rabbit anti-SAP serum and the lower half (B) with rabbit anti-avidin serum. Finally, the membranes were incubated with goat IgG anti- rabbit IgG peroxidase-conjugate and subsequently developed by means of incubation with l-chloro-4-naphthol .
  • SAP_BAP SEQ ID NO: 4
  • mAV_NANP SEQ ID NO: 23
  • the SAP is protein IBDV VP2 452 and the BAP peptide has the amino acid sequence shown in SEQ ID NO: 3.
  • Figure 9 shows the characterization of the interaction between protein mAV_NANP (SEQ ID NO: 23) and biotinylated NCs in vivo.
  • supernatants of cultures of insect cells that are not infected (SN-) or infected with the recombinant baculovirus rBV/FB_mAV_NANP (SN+) were incubated with biotinylated NCs in vivo (NC-Biot) .
  • a corresponding sample of SN+ incubated in the absence of NCs (-) was analyzed as a control.
  • the samples were deposited on a 20% sucrose cushion and subjected to ultracentrifugation.
  • the sediments obtained were resuspended in loading buffer and subjected to SDS-PAGE and immunoblotting.
  • the resulting nitrocellulose membranes were divided into two halves. The upper half of the membranes (A) was incubated with rabbit anti-SAP serum and the lower half (B) with rabbit anti-avidin serum. Finally, the membranes were incubated with goat IgG anti-rabbit IgG peroxidase-conjugate and subsequently developed by means of incubation with l-chloro-4-naphthol.
  • the invention generally relates to a nanocarrier (NC) which can be obtained by the assembly of fusion proteins comprising (i) a self assembly protein and (ii) a heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand.
  • N nanocarrier
  • heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand
  • SAP self assembly protein
  • said NC further comprises a product of interest.
  • Said product of interest forms part of a conjugate comprising, in addition to the product of interest, a ligand with the capacity to bind to said peptide insert present in the NC (as a result of the assembly of the fusion proteins forming said NC) .
  • the binding of said product of interest to said NC is carried out through said ligand by means of the specific interaction between the specific binding domain present in the peptide insert of the NC and the region of interaction with said specific binding domain present in the peptide insert, contained in the ligand which is present in the conjugate comprising the product of interest.
  • the binding of said ligand to said peptide insert can be carried out either directly or indirectly through a connector.
  • the different components of said NC will be described in detail below.
  • the invention relates to a fusion protein
  • fusion protein (I) of the invention comprising (i) a self assembly protein (occasionally identified in this description as "SAP") , and
  • a heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand (occasionally identified in this description as "peptide insert") .
  • said peptide insert is inserted inside the amino acid sequence of said self assembly protein (SAP) , whereas in another particular embodiment, said peptide insert is bound to the amino or carboxyl terminal end of said SAP.
  • SAP self assembly protein
  • self assembly protein includes any protein with self assembly capacity and the capacity to form macromolecular structures, for example, capsids, tubular assemblies (tubules), rings, ("donuts") , chaperone complexes, caveolin complexes, etc.
  • SAP self assembly protein
  • any prokaryotic or eukaryotic protein with self-assembly capacity can be used in the present invention, for example, viral proteins, chaperones, caveolins, etc., as well as functional variants thereof, i.e.
  • viral proteins useful as self assembly proteins include viral structural proteins, such as proteins forming the capsids of different viruses, etc., for example, SV40 protein Vl, tobacco mosaic virus (TMV) coat protein Ul, bovine papillomavirus type 1 (BPV-I) protein Ll, birnavirus structural proteins (e.g. infectious bursal disease virus (IBDV) protein VP2 (pVP2), infectious pancreatic necrosis virus (IPNV) proteins VP2 and VP3, etc.), etc.
  • viral structural proteins such as proteins forming the capsids of different viruses, etc., for example, SV40 protein Vl, tobacco mosaic virus (TMV) coat protein Ul, bovine papillomavirus type 1 (BPV-I) protein Ll, birnavirus structural proteins (e.g. infectious bursal disease virus (IBDV) protein VP2 (pVP2), infectious pancreatic necrosis virus (IPNV) proteins VP2 and VP3, etc.), etc.
  • said self assembly protein comprises IBDV protein VP2 or a functional variant thereof.
  • IBDV protein VP2 (or pVP2 )
  • the term "IBDV protein VP2 (or pVP2 )" generally relates to a protein the amino acid sequence of which comprises or is formed by the amino acid sequence of the IBDV pVP2 of any IBDV strain belonging to any of the known serotypes (1 or 2) [by way of illustration see the review by van den Berg TP et al . (2000) ] and includes any of the different forms of proteins pVP2 representative of any IBDV strain, according to the definition made by Sanchez and Rodriguez (1999) as well as to proteins that are substantially homologous to said IBDV proteins pVP2, i.e.
  • IBDV protein pVP2 is the Soroa strain IBDV protein pVP2 the amino acid sequence of which, complete length, is deposited in the NCBI with accession number AAD30136.
  • said self assembly protein comprises a 1-n fragment of IBDV pVP2, wherein "n” is an integer comprised between 441 and 512.
  • the term "1-n fragment of the/said IBDV pVP2, wherein "n” is an integer comprised between 441 and 512”, generally relates to a peptide the amino acid sequence of which is formed by the contiguous amino acid sequence comprised between residue 1 and residue "n" of IBDV protein pVP2, wherein "n” is a integer comprised between 441 and 512.
  • said 1- n fragment of IBDV pVP2 has an amino acid sequence formed by or comprising between 441 and 512 contiguous amino acid residues, counted from the amino acid residue number 1, of a pVP2 representative of any IBDV strain, for example, of the Soroa strain IBDV pVP2 [NCBI, accession number AAD30136] .
  • Particular 1-n fragments of IBDV pVP2 are called according to the "pVP2 n" format, wherein "n" is that defined above.
  • said self assembly protein is that identified as IBDV pVP2_452, the amino acid sequence of which is shown in SEQ ID NO: 1, and is formed by the amino acid sequence comprised between residue 1 and residue 452 of IBDV pVP2.
  • Said protein contains loop P HI in which the peptide insert can be inserted, if desired.
  • the assembly of the proteins identified as pVP2_441, pVP2_452, pVP2_456 and pVP2-466 gives rise to NCs, whereas the assembly of proteins pVP2_476, pVP2_487, pVP2_494 and pVP2_501 form tubular structures or tubules.
  • chaperones useful as self assembly proteins include proteins Hsp ⁇ O (GroEL/GroES complex in E. col ⁇ ) , Hsp70 (DnaK in E. col ⁇ ) , Hsp90 (HtpG in E. col ⁇ ) and HsplOO (CIp family (e.g. CIpA, CIpX, CIpP, etc.) in E. col ⁇ ), etc.
  • Hsp ⁇ O GroEL/GroES complex in E. col ⁇
  • Hsp70 DnaK in E. col ⁇
  • Hsp90 HtpG in E. col ⁇
  • HsplOO CIp family (e.g. CIpA, CIpX, CIpP, etc.) in E. col ⁇ )
  • caveolins useful as self assembly proteins include proteins caveolin-1, caveolin-2, caveolin-3, etc. The amino acid sequences of these proteins, as well as relevant information about them, are known and can be obtained in the corresponding database
  • the fusion protein (I) of the invention comprises, in addition to said SAP, a peptide insert or heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand (i.e. a specific binding domain) .
  • peptide insert i.e. heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand
  • peptide insert does not involve any particular size or any other technical structural characteristic other than that said peptide insert (comprising a specific binding domain) can bind to a ligand (comprising the region of interaction corresponding to said specific binding domain present in the peptide insert); nevertheless, in a particular embodiment, for its use in the present invention, said peptide insert must not adversely affect the assembly capacity of the SAP (i.e. the SAP in which said peptide insert is introduced or which it binds to must not lose its assembly capacity) .
  • the size of the peptide insert can vary within a wide range, for example, between 1 and 50 amino acid residues; advantageously, said peptide insert has less than 40 amino acid residues, preferably less than 30 amino acid residues, more preferably less than 20 amino acid residues, for example, between 1 and 15 amino acids.
  • said peptide can be a member of a specific binding pair, for example, an amino acid tag (e.g. a histidine tag (his-tag) , an arginine tag (arg-tag) , etc.) , a peptide epitope which can be recognized by an antibody (e.g. c-myc-tag, etc.) , a biotin acceptor peptide
  • BAP a linear domain of interaction with another or other protein or proteins (e.g. proteins SH3, signal transduction proteins, etc. ) , a post-translational modification sequence
  • said peptide with the capacity to bind to a ligand is a BAP;
  • BAP relates to a peptide with the capacity to bind to biotin or to an analog thereof (e.g. 2-iminobiotin, etc.) ;
  • illustrative examples of BAP are mentioned in EP 711303 (incorporated in its entirety in this description as a reference) and includes peptides comprising the following amino acid sequence (SEQ ID NO: 2) :
  • Leu Xaal Xaa2 lie Xaa3 Xaa4 Xaa5 Xaa ⁇ Lys Xaa7 Xaa8 Xaa9 XaalO
  • Xaal is any amino acid
  • Xaa2 is an amino acid other than Leu, VaI, lie, Trp, Phe, or Tyr
  • Xaa3 is Phe or Leu
  • Xaa4 is GIu or Asp
  • Xaa5 is Ala, GIy, Ser, or Thr
  • Xaa ⁇ is GIn or Met
  • Xaa7 is lie, Met, or VaI;
  • Xaa8 is GIu, Leu, VaI, Tyr, or lie
  • Xaa9 is Trp, Tyr, VaI, Phe, Leu, or lie
  • XaalO is any amino acid other than Asp or GIu.
  • said peptide with the capacity to bind to a ligand is a BAP with 15 amino acids having the amino acid sequence shown in SEQ ID NO: 3.
  • said peptide insert is inserted inside the amino acid sequence of said SAP.
  • the invention provides a fusion protein (I) of the invention comprising, in addition to said SAP, a peptide insert
  • peptide insert (heterologous peptide) inserted inside the amino acid sequence of said SAP, said peptide insert comprising an amino acid sequence with the capacity to bind to a ligand (i.e. a specific binding domain) .
  • Said peptide insert is introduced in said SAP such that the assembly capacity of said SAP is not substantially altered; and said peptide insert must furthermore be located in a region of said self assembly protein accessible for the solvent in the macromolecular structures formed after the self- assembly of the fusion protein (I) of the invention.
  • the fusion protein (I) of the invention maintains the amino and carboxyl terminal ends of said SAP and the peptide insert is included inside the amino acid sequence of said SAP, for example, between two contiguous amino acids of said SAP or, alternatively, substituting one or more amino acids of said SAP.
  • said peptide insert is located between 2 contiguous amino acids of the SAP, i.e. between residue "x" and residue "x+1" of the amino acid sequence of said SAP; whereas in another particular embodiment, due to the strategy followed to introduce the peptide insert, one or more residues located in the regions adjacent to the insertion point may be lost.
  • the peptide insert must be located in a region of said SAP accessible for the solvent in the macromolecular structures formed after the assembly of the fusion protein (I) of the invention, the peptide insert must be inserted in a suitable region.
  • Particularly suitable regions of the SAP for introducing the peptide insert are the loops present in said self assembly proteins (SAPs) , particularly those loops which, in the macromolecular structures that they form, are exposed to the solvent.
  • SAPs self assembly proteins
  • Illustrative examples of loops present in SAPs which can be used to implement the present invention include the IBDV pVP2 loop P H i, the human papilloma virus capsid protein loops (Bishop et al .
  • the atomic structure of the SAP can be determined by means of using X-ray diffraction.
  • suitable computer programs such as for example the UCSF Chimera program (http://www.cgl.ucsf.edu/chimera/) allows locating the regions of the protein being studied which can potentially be genetically modified. These merely theoretical predictions are initially useful for: i) discarding regions that are not exposed to the solvent; and ii) identifying regions the modification of which could cause a serious alteration in the secondary structure of the protein.
  • a strategy can be designed to incorporate the peptide insert in the suitable site, for example, in a loop of said SAP which is exposed to the solvent when said SAP self-assembles and forms the macromolecular structure.
  • said SAP is IBDV pVP2, or a functional variant thereof, such as the protein identified as IBDV pVP2_452 (SEQ ID NO: 1) .
  • IBDV pVP2_452 SEQ ID NO: 1
  • an in-depth study was conducted of the already described atomic structure of said IBDV pVP2_452, (Garriga et al . , 2006) (Protein Data Bank accession no. 2GSY) , by means of using the UCSF Chimera computer program
  • the SAP is IBDV pVP2, or a functional variant thereof, such as the protein identified as IBDV pVP2_452 (SEQ ID NO: 1) , and said peptide insert is located inside loop P H i of said IBDV pVP2 or functional variant thereof (IBDV pVP2_452) either between 2 contiguous amino acids or substituting one or more of the amino acids of said loop P H i .
  • the SAP is IBDV pVP2, or a functional variant thereof, such as the protein identified as IBDV pVP2_452 (SEQ ID NO: 1) , and said peptide insert comprises the amino acid sequence of a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ I D NO : 3 .
  • the SAP is IBDV pVP2, or a functional variant thereof, such as the protein identified as
  • IBDV pVP2_452 (SEQ ID NO: 1) , said peptide insert comprises the amino acid sequence of a BAP and said peptide insert is located inside loop P H i of said IBDV pVP2 or functional variant thereof
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3 and the insertion of said peptide insert in said SAP (IBDV pVP2, or a functional variant thereof, such as the protein identified as IBDV pVP2 452) is carried out between residues 319 and 321 of the amino acid sequence of said SAP, which involves eliminating residue 320 (GIn) [ Figure 2] .
  • the fusion protein (I) of the invention comprises a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said SAP is IBDV pVP2, or a functional variant thereof.
  • said functional variant of IBDV pVP2 is the protein identified as IBDV pVP2_452 (SEQ ID NO: 1) .
  • said peptide insert comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • the fusion protein (I) of the invention comprises a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said peptide insert comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • said SAP is IBDV pVP2, or a functional variant thereof, such as IBDV pVP2_452.
  • the fusion protein (I) of the invention comprises a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said SAP is IBDV pVP2, or a functional variant thereof, in which said peptide insert is located inside loop P H i of said IBDV pVP2 or functional variant thereof (IBDV pVP2_452), either between 2 contiguous amino acids or substituting one or more amino acids of said loop P H i .
  • said peptide insert comprises a BAP; in an even more specific embodiment, said peptide insert comprises a BAP comprising the amino acid sequence shown in SEQ ID NO: 3 and the insertion of said peptide insert in said SAP (IBDV pVP2, or a functional variant thereof, such as the protein identified as IBDV pVP2 452 of) is located in loop P HI of said SAP.
  • the fusion protein (I) of the invention comprises a SAP and a heterologous peptide inserted inside the amino acid sequence of said SAP comprising an amino acid sequence with the capacity to bind to a ligand, in which said heterologous peptide comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • said SAP is an IBDV pVP2, or a functional variant thereof, such as IBDV pVP2_452.
  • said BAP is located inside loop P H i of said IBDV pVP2 or functional variant thereof (IBDV pVP2_452) either between 2 contiguous amino acids or substituting one or more amino acids of said loop P H i .
  • said peptide insert is bound to the amino- or carboxyl-terminal end of said SAP. Therefore, in a particular embodiment, said peptide insert is bound to the amino-terminal end of said SAP, whereas, in another particular embodiment, said peptide insert is bound to the carboxyl-terminal end of said SAP.
  • the fusion protein (I) of the invention comprises two peptide inserts bound to a SAP, wherein each of said peptide inserts is bound to each of the amino- and carboxyl-terminal ends of said SAP.
  • the invention provides a fusion protein (I) of the invention comprising, in addition to said SAP, a peptide insert (heterologous peptide) bound to the amino- or carboxyl- terminal end of said SAP, or, alternatively, to both ends, said peptide insert comprising an amino acid sequence with the capacity to bind to a ligand.
  • Said peptide insert is bound to said SAP such that the assembly capacity of said SAP is not substantially altered; and said peptide insert must furthermore be located in a region of said SAP accessible for the solvent in the macromolecular structures formed after the self assembly of the fusion protein (I) of the invention.
  • the fusion protein (I) of the invention comprises a SAP and a heterologous peptide bound to the amino- or carboxyl-terminal end of said SAP comprising an amino acid sequence with the capacity to bind to a ligand, in which said heterologous peptide comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • said SAP is an IBDV pVP2, or a functional variant thereof, such as IBDV pVP2_452.
  • the fusion protein (I) of the invention can be obtained by means of the gene expression of the nucleotide sequence encoding said fusion protein (I) in suitable host cells.
  • Said suitable host cells are cells containing the nucleotide sequence encoding the fusion protein (I) of the invention, for example, cells containing a polynucleotide comprising the nucleotide sequence encoding the fusion protein (I) of the invention or which have been transformed by said polynucleotide, or cells transformed, transfected or infected with a recombinant vector comprising said polynucleotide comprising the nucleotide sequence encoding the fusion protein (I) of the invention.
  • the invention relates to a polynucleotide, hereinafter polynucleotide of the invention, comprising the nucleotide sequence encoding the fusion protein (I) of the invention.
  • the invention provides an expression cassette, hereinafter expression cassette of the invention, comprising said polynucleotide of the invention operatively bound to transcription and optionally translation control elements .
  • the transcription and optionally translation control elements present in the expression cassette of the invention include promoters, directing the transcription of the nucleotide sequence to which they are operatively linked (nucleotide sequence encoding the self assembly protein in which the nucleotide sequence encoding said peptide insert has been introduced) , and other sequences necessary or suitable for the transcription and their suitable regulation in time and place, for example, start and stop signals, cleavage sites, polyadenylation signal, replication origin, transcriptional enhancers, transcriptional silencers, etc.
  • Said elements, as well as the vectors used to construct the expression cassettes and the recombinant vectors according to the invention are generally chosen depending on the host cells which are intended to be used.
  • the invention in another aspect, relates to a recombinant vector, hereinafter recombinant vector of the invention, comprising a polynucleotide of the invention or an expression cassette of the invention.
  • a recombinant vector hereinafter recombinant vector of the invention, comprising a polynucleotide of the invention or an expression cassette of the invention.
  • Virtually any vector can be used in the generation of the recombinant vector of the invention.
  • said suitable expression systems or vectors can be selected according to the conditions and needs of each specific case from plasmids, bacmids, yeast artificial chromosomes (YACs) , bacterial artificial chromosomes (BACs) , phage-based artificial chromosomes (PACs), such as for example, phage Pl-based PACs, cosmids, or viruses, which can further contain a heterologous replication origin, for example a bacterial or yeast replication origin so that it can be amplified in bacteria or yeasts, as well as a marker which can used to screen the transfected cells different from the gene or genes of interest.
  • YACs yeast artificial chromosomes
  • BACs bacterial artificial chromosomes
  • PACs phage-based artificial chromosomes
  • cosmids or viruses
  • viruses which can further contain a heterologous replication origin, for example a bacterial or yeast replication origin so that it can be amplified in bacteria or yeasts, as well as a marker
  • said recombinant vector is a plasmid, such as a suitable plasmid for transforming yeasts, or a virus, such as a recombinant baculovirus (rBV) expressing during its replication cycle the fusion protein (I) of the invention and which, after its assembly, forms said NCs.
  • a plasmid such as a suitable plasmid for transforming yeasts
  • a virus such as a recombinant baculovirus (rBV) expressing during its replication cycle the fusion protein (I) of the invention and which, after its assembly, forms said NCs.
  • rBV recombinant baculovirus
  • the invention provides a host cell, hereinafter host cell of the invention, comprising the polynucleotide of the invention.
  • said host cell is a cell which can be or has been transformed by a polynucleotide of the invention.
  • said host cell is a cell which can be or has been transformed, transfected or infected with a recombinant vector of the invention comprising the polynucleotide of the invention.
  • Said host cell can be a eukaryotic or prokaryotic cell.
  • Virtually any host cell which can be transformed by a polynucleotide of the invention, or which can be transformed, transfected or infected by a recombinant vector of the invention, can be used in the present invention, for example, animal cells (e.g. mammalian cells, bird cells, insect cells, etc.), yeasts, etc.; nevertheless, in a particular embodiment, said host cell is selected from yeasts and insect cells.
  • yeasts are suitable for reasons of simplicity and production cost.
  • Insect cells are suitable when the expression system comprises an rBV. The use of rBV is advantageous for biosafety issues related to the host range of baculovi ruses , which cannot replicate in cell types other than insect cell types.
  • the invention provides a host cell, such as a yeast, for example, a yeast of the Saccharomyces genus e.g. S. cerevisae , S. pombe, etc., or of the Pichia genus, e.g. P. pastoris , etc., transformed with a recombinant vector of the invention, such as a plasmid comprising the polynucleotide of the invention or an expression cassette of the invention.
  • the invention provides a host cell, such as an insect cell, infected with a recombinant vector of the invention, such as an rBV comprising a polynucleotide of the invention or an expression cassette of the invention.
  • the invention provides a process for producing the fusion protein (I) of the invention which comprises culturing a host cell of the invention, containing the nucleotide sequence encoding the fusion protein (I) of the invention, under conditions allowing the expression of said fusion protein, and, if desired, the recovery of said fusion protein (I) of the invention.
  • the expressed proteins are assembled and form the nanocarriers (NCs) .
  • the fusion protein (I) of the invention, optionally assembled forming NCs can be isolated or removed from the medium, and optionally purified.
  • Said fusion protein (I) of the invention, optionally assembled forming NCs can be isolated and purified by conventional methods, for example by means of fractionation in sucrose gradients.
  • the gene expression of the fusion protein (I) of the invention is carried out by means of using an rBV comprising the polynucleotide of the invention, which allows expressing the fusion protein (I) of the invention from said polynucleotide of the invention in insect cells. Therefore, in a particular embodiment, the invention provides a process for producing the fusion protein (I) of the invention in insect cells which comprises (i) culturing insect cells infected with an rBV comprising the polynucleotide of the invention, under conditions allowing the expression of said fusion protein, and ( ⁇ ) if desired, isolating and optionally purifying said fusion protein (I) of the invention, optionally assembled in the form of NCs.
  • the implementation of said process involves previously constructing an rBV comprising the polynucleotide of the invention or an expression cassette of the invention and infecting insect cells with said rBV.
  • An rBV comprising the polynucleotide of the invention can be constructed by a person skilled in the art based on that described herein and on the state of the art on this technology [Sambrook & Russell (2001) ; Leusch MS et al . (1995); Luckow VA et al . (1993) ] .
  • Example 1 (section 1.2) describes the result of expressing a fusion protein (I) of the invention, identified as SAP_BAP (SEQ ID NO: 4) , comprising the self assembly protein IBDV pVP2_452 (SAP) genetically modified by means of introducing a BAP (SEQ ID NO: 3) , in insect cells (Tricoplusia Ni) infected with an rBV containing a polynucleotide comprising the nucleotide sequence (SEQ ID NO: 5) encoding said IBDV pVP2_452 genetically modified by means of introducing the nucleotide sequence encoding said BAP.
  • SAP_BAP SEQ ID NO: 4
  • SAP self assembly protein IBDV pVP2_452
  • the gene expression of the fusion protein (I) of the invention is carried out in yeast cells. Therefore, in a particular embodiment, the invention provides a process for producing the fusion protein (I) of the invention in yeast cells which comprises (i) culturing yeasts transformed with a recombinant vector comprising the polynucleotide of the invention, under conditions allowing the expression of the fusion protein of the invention, and (ii) if desired, isolating and optionally purifying said fusion protein (I) of the invention, optionally assembled in the form of NCs. The implementation of said process involves previously constructing a suitable recombinant vector for transforming yeasts.
  • Yeasts transformed with a recombinant vector comprising the polynucleotide of the invention can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology [pESC epitope tagging vectors Instructions manual. Stratagene www.stratagene.com; Sambrook & Russell (2001)] .
  • the fusion protein (I) of the invention can self assemble and form nanocarriers that are generically called NC (singular) or NCs (plural) in this description, which are an additional aspect of this invention and will be described in detail below. 2. Conjugate of the invention
  • the invention in another aspect, relates to a conjugate, hereinafter conjugate of the invention, comprising (i) a region A comprising a ligand with the capacity to bind to said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, i.e. said peptide insert contained in said fusion protein (I) of the invention, bound to (ii) a region B comprising a product of interest.
  • a conjugate hereinafter conjugate of the invention, comprising (i) a region A comprising a ligand with the capacity to bind to said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, i.e. said peptide insert contained in said fusion protein (I) of the invention, bound to (ii) a region B comprising a product of interest.
  • the term "ligand” relates to a molecule which can interact specifically and bind to the peptide insert present in the fusion protein (I) of the invention, and by extension, in the NC resulting from the assembly of said fusion proteins (I) of the invention, which enables the product of interest bound to the ligand to bind to said nanocarrier.
  • the ligand can be of a peptide (protein) or non-peptide nature.
  • the expression "which can interact specifically” or “specific interaction” describes the interaction between a first species and a second species characterized in that the nature of binding is such that an antibody, a receptor or a nucleic acid binding protein binds to its corresponding binding pair but does not substantially bind to other species.
  • binding or "binding to”, as used herein, means the physical association between a first species and a second species, for example, the binding of a ligand by a receptor, the binding of an antigen by an antibody, the binding of a nucleic acid by a nucleic acid binding protein, etc.
  • ligand does not involve any particular size or any other technical structural characteristic other than that said ligand can interact and bind to the peptide insert present in said fusion protein (I) of the invention; therefore, said ligand contains a region of interaction with the specific binding domain which is present in the peptide insert contained in the fusion protein (I) of the invention and, subsequently, in the NC resulting from the assembly of said fusion protein (I) of the invention, such that the product of interest present in the conjugate of the invention is bound to said NC by means of the specific interaction between the specific binding domain present in the NC (peptide insert) and the corresponding region of interaction with said specific binding domain present in the peptide insert (NC) , contained in the ligand, which is present in the conjugate comprising the product of interest.
  • the "peptide insert"-"ligand” pair acts as a specific binding pair, e.g. of the biotin-avidin, epitope- antibody or functional fragment thereof (e.g. a Fab or F(ab'>2 fragment, an scFv (single chain antibody), a chimeric antibody, etc.) type, etc., in which each of said peptide insert and ligand are the members of said specific binding pair, each of them containing the corresponding binding domains or regions of interaction; thus, the ligand which must be present in the conjugate of the invention will be chosen depending on the peptide insert present in the fusion protein (I) of the invention, and, vice versa, the peptide insert which must be present in the fusion protein (I) of the invention will be chosen depending on the ligand present in the conjugate of the invention .
  • the ligand which must be present in the conjugate of the invention will be chosen depending on the peptide insert present in the fusion protein (I) of the invention, and
  • Said ligand can be bound to said peptide insert directly, i.e. by means of a specific direct interaction between the specific binding domain contained in the peptide insert present in the NC and the corresponding region of interaction with said binding domain present in the ligand contained in the conjugate of the invention; the product of interest thus binds to the NC through a structure of the type: peptide insert-ligand-product of interest.
  • said ligand can be bound to said peptide insert indirectly, i.e. by means of using a "connector" or molecule comprising, on one hand, a first region of interaction with the binding domain contained in the peptide insert present in the NC, and, on the other hand, a second region of interaction (binding domain) with a region of interaction present in the ligand contained in the conjugate of the invention. Therefore, in each case, the connector binds, on one hand, to the specific binding domain contained in the peptide insert present in the NC by means of a specific interaction and, on the other hand, to the product of interest by means of a specific interaction between the binding domains present in the connector and in the ligand contained in the conjugate of the invention.
  • the product of interest thus binds to the nanocarrier through a structure of the type: peptide insert-connector- ligand-product of interest.
  • the ligand is bound to the peptide insert directly.
  • a ligand with the capacity to bind to said peptide insert present in the fusion protein (I) of the invention will be used, such that said peptide insert and ligand forma specific binding pair.
  • said peptide insert comprises an amino acid tag (e.g.
  • his-tag a histidine tag
  • arg-tag an arginine tag
  • said peptide insert comprises a peptide epitope which can be recognized by an antibody (e.g. c-myc-tag, etc.), the ligand is an antibody or a functional fragment thereof; etc.
  • the ligand is bound to the peptide insert indirectly by means of using a connector.
  • a dual connector will be used having on one hand, a first binding domain for binding to said peptide insert present in the fusion protein (I) of the invention, such that said peptide insert and connector form a first specific binding pair, and on the other hand, a second binding domain for binding to said ligand present in the conjugate of the invention, such that said connector and ligand form a second specific binding pair.
  • Illustrative non- limiting examples of this embodiment include the use of biotin or an analog thereof (connector) when the peptide insert present in the NC comprises a BAP (in this case, the ligand to which the product of interest is bound would be an avidin) ; etc.
  • the term "avidin” includes any eukaryotic or prokaryotic avidin, and its variants maintaining the capacity to bind to biotin; in a particular embodiment, the ligand present in the conjugate of the invention comprises a monomeric avidin (mAV) variant.
  • the region B present in the conjugate of the invention comprises a product of interest.
  • product of interest includes any molecule with biological activity in its broadest sense, i.e., any substance which, when administered to a subject, interacts with its receptor in the action site and exerts a certain effect.
  • the product of interest can be of a peptide (protein) or non-peptide nature, for example, a protein, an antibody or a functional fragment thereof, an enzyme, a lipid, a sugar, a non-peptide drug, a nucleic acid, etc.
  • products of interest include any type of bioactive molecules such as synthetic molecules (e.g.
  • acetylsalicylic acid paracetamol, tranexamic acid, metoprolol, etc.
  • natural products e.g. taxol, taxane derivatives, paclitaxel, epibatidine, atropine, etc.
  • oligonucleotides e.g. augmerosen
  • aptamers e.g. pegaptanib
  • proteins e.g. interleukins, interferons, erythropoietins, coagulation factors, insulins, etc.
  • antibodies e.g.
  • peptides e.g. calcitonins, vasopressin analogs (e.g. arginine vasopressin, desmopressin acetate, etc.) , insulin polypeptides (e.g. humulin, insulin aspart, etc.) , growth hormones (e.g. somatotropin, sermorelin, recombinant growth factor, etc. ) , gonadotropin polypeptides (e.g.
  • urofollitropin e.g. urofollitropin, recombinant follicle stimulating hormone, etc.
  • gonadotropins e.g. chorionic gonadotropins
  • thyrotropic hormone analogs e.g. somatostatin analogs
  • parathyroid hormone polypeptides e.g. teriparatide acetate, recombinant parathyroid hormone (1-84), etc.
  • alpha- atrial natriuretic peptide e.g. nesiritide, etc.
  • thyroid hormone e.g.
  • luteinizing hormone polypeptides e.g. lutropin alpha, etc.
  • GLPl glucagon-like peptide-1 analogs
  • corticotropin polypeptides e.g. corticotropin, etc .
  • corticotropin release factor gastrin analogs
  • peptides for radiation treatment e.g. lanreotide, etc.
  • peptide vaccines e.g. malaria, cancer, HIV, HBV, multiple sclerosis, etc.
  • hormones, enzymes, lipids, sugars, nucleic acids (DNA, RNA, PNA, etc. e.g. oligonucleotides , p o lynucleotides, genes, interfering RNA, etc.
  • said product of interest is a product of interest of a peptide nature; in this case, its size can vary within a wide range, from a few amino acids up to hundreds of amino acids.
  • Said peptide product of interest can be virtually any peptide (as used herein, the term peptide includes peptides and proteins without distinction) , regardless of its origin (eukaryotic, prokaryotic, viral, etc.), which can be recombinantly expressed, for example, a peptide antigen, such as a viral, bacterial, microbial, tumor antigen, etc., against which an immune response is to be induced in a subject (such as an animal, including human beings) ; an enzyme, such as an enzyme intended to supplement a function in which the organism is deficient; a peptide drug intended to prevent or treat a pathological condition in a subject; an antibody or a functional fragment thereof; etc.
  • a peptide antigen such as a viral, bacterial, microbial, tumor antigen,
  • said peptide product of interest is a peptide useful in vaccination, therapy or diagnosis, such as an epitope or antigenic determinant which can induce an immune response in a subject (e.g. animals, including human beings) against diseases caused by viruses, bacteria, parasites or any other types of microorganisms, or against tumor diseases, or it is a peptide useful in the therapy (prevention and/or treatment) of other pathologies, for example, heparin, a cell growth factor, an interleukin, an interferon, a protein of interaction with a membrane receptor, a peptide of interaction with a specific cell marker, etc.; in a specific embodiment, said product of interest comprises the tissue factor, or a functional variant thereof, or yeast-derived microvesicles containing the tissue factor or a functional variant thereof; as is known, the lipidized tissue factor or a functional variant thereof, as well as said yeast- derived microvesicles containing the tissue factor or a functional variant thereof, are
  • said product of interest is a product of a non-peptide nature.
  • Said product of interest of a non-peptide nature can be virtually any compound of a non- peptide nature, for example, a polynucleotide, a non-peptide antigen, such as allergens, viral, bacterial, microbial, tumor antigen, etc., against which an immune response is to be induced in a subject (such as an animal, including human beings); a non- peptide drug intended to prevent or treat a pathological condition in a subject; a lipid with the capacity to interact with a molecule of interest; a sugar with the capacity to interact with a molecule of interest; etc.
  • said non-peptide product of interest is a compound useful in vaccination, therapy or diagnosis, such as a non-peptide antigenic determinant which can induce an immune response in a subject (e.g. animals, including human beings) against diseases caused by viruses, bacteria, parasites or any other type of microorganisms, or against tumor diseases, or it is a compound useful in the therapy (prevention and/or treatment) of other types of pathologies.
  • a subject e.g. animals, including human beings
  • diseases caused by viruses, bacteria, parasites or any other type of microorganisms, or against tumor diseases or it is a compound useful in the therapy (prevention and/or treatment) of other types of pathologies.
  • said region B comprises a single product of interest.
  • said region B can comprise two or more identical or different products of interest, which can form tandems.
  • the conjugate of the invention comprises a region A bound to a single region B; nevertheless, in another specific embodiment, particularly when said product of interest is a product of interest of a peptide nature, the conjugate of the invention can comprise a region A bound to two regions B.
  • the conjugate of the invention comprises a region A bound to two regions B, one of which is bound to the amino-terminal region of the ligand present in region A and the other of which is bound to the carboxyl-terminal region of the ligand present in region A.
  • Said regions B can be identical or different and each of them can contain one or more products of interest, which can be identical or different from one another.
  • the conjugate of the invention comprises a region A bound to a first region B containing a first product of interest (Bl) and a second region B containing a second product of interest (B2) .
  • Said products of interest (Bl) and (B2) can be identical or different.
  • said products of interest (Bl) and (B2) are different from one another.
  • the conjugate of the invention can be obtained by conventional methods depending on the (peptide or non-peptide) nature of the ligand and of the product of interest, and, where appropriate, of the connector. Indeed, given that both the ligand and the product of interest, and where appropriate, the connector can be of a peptide or non-peptide nature, different possibilities arise.
  • the ligand and the product of interest are of a non-peptide nature.
  • the conjugate of the invention can be obtained by conventional chemical methods known by persons skilled in the art, which will be chosen depending on the nature of the functional groups present in said compounds (ligand and product of interest) . It may occasionally be necessary to form derivatives of the product of interest (e.g. ethers, esters, etc.) that subsequently release the product of interest in the subject.
  • Information about the chemical interactions between the functional groups usually present in the ligands and in the products of interest of a non-peptide nature can be found in March's Advanced Organic Chemistry, 5th Ed. (2001) , Michael B. Smith & Jerry March, John Wiley & Sons, Inc.
  • the ligand is of a peptide nature and the product of interest is of a non-peptide nature, or, alternatively, the ligand is of a non-peptide nature and the product of interest is of a peptide nature.
  • the conjugate of the invention can be obtained by conventional chemical methods known by persons skilled in the art, which will be chosen depending on the nature of the functional groups present in said compounds (ligand and product of interest) . It may occasionally be necessary to form derivatives of the product of interest (e.g. ethers, esters, etc.) that subsequently release the product of interest in the subject.
  • the ligand and the product of interest are of a peptide nature.
  • the conjugate of the invention is a fusion protein, hereinafter "fusion protein (II)" comprising a ligand of a peptide nature (region A' ) and a product of interest of a peptide nature (region B' ) .
  • fusion protein (II) comprising a ligand of a peptide nature (region A' ) and a product of interest of a peptide nature (region B' ) .
  • the product of interest (region B') can be bound to the amino-terminal end of said ligand (region A') , or, alternatively, said product of interest (region B') can be bound to the carboxyl-terminal end of said ligand (region A' ) .
  • said region A' can be directly bound to said region B' , or, alternatively, said region A' is not directly bound to said region B' but rather it is bound through a linker peptide between said regions A' and B' .
  • said fusion protein can further contain a linker peptide located between said regions A' and B ' ; advantageously, said linker peptide is a peptide with structural flexibility.
  • said flexible peptide can contain repetitions of amino acid residues, particularly of GIy, Ser and Ala residues or any other suitable repetition of amino acid residues.
  • said region B' additionally comprises a single product of interest, whereas in another particular embodiment, said region B' comprises two or more identical or different products of interest, which can form tandems.
  • said fusion protein (II) [particular case of the conjugate of the invention in which both the ligand and the product of interest are of a peptide nature] comprises, in a particular embodiment, a region A' bound to a single region B' , or, alternatively, in another particular embodiment, it comprises a region A' bound to two regions B' , as has been previously mentioned, one of which is bound to the amino- terminal region of the ligand present in region A' and the other of which is bound to the carboxyl-terminal region of the ligand present in region A' .
  • Said regions B' can in turn be identical or different and each of them can contain one or more products of interest, which can be identical or different from one another.
  • Said fusion protein (II) can be obtained by means of the gene expression of the nucleotide sequence encoding said fusion protein (II) in suitable host cells. It can alternatively be obtained by means of fusing the members of said fusion protein (H) • 3. Nanocarriers (NCs) of the invention
  • the fusion protein (I) of the invention can self assemble and form nanocarriers that are generically called NC (singular) or NCs (plural) in this description, which are an additional aspect of this invention.
  • the invention relates to a nanocarrier (NC) , hereinafter nanocarrier (or NC) of the invention, which can be obtained by the assembly of fusion proteins (I) of the invention, comprising: (i) a self assembly protein (SAP) , and (ii) a peptide insert comprising the amino acid sequence of a peptide with the capacity to bind to a ligand, i.e. a specific binding domain.
  • NC nanocarrier
  • SAP self assembly protein
  • a peptide insert comprising the amino acid sequence of a peptide with the capacity to bind to a ligand, i.e. a specific binding domain.
  • said peptide insert is inserted inside the amino acid sequence of said self assembly protein (SAP) , whereas in another particular embodiment, said peptide insert is bound to the amino- or carboxyl-terminal end of said SAP.
  • SAP self assembly protein
  • the NC of the invention is a macromolecular structure resulting from the assembly of a certain number of fusion proteins (I) of the invention.
  • the structure of the trimer is stabilized by the presence of a calcium atom interacting with 6 Asp residues from the 3 molecules forming it.
  • the structure of said NC is stabilized by means of a wide range of non-covalent interactions established between adjacent trimers.
  • the invention provides an NC formed by the assembly of a fusion protein (I) of the invention comprising a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said SAP is IBDV pVP2 , or a functional variant thereof.
  • said functional variant of IBDV pVP2 is the protein identified as IBDV pVP2_452 (SEQ ID NO: 1) .
  • said peptide insert comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • the invention provides an NC formed by the assembly of a fusion protein (I) of the invention comprising a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said peptide insert comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • said SAP is IBDV pVP2 , or a functional variant thereof, such as IBDV pVP2_452.
  • the invention provides an NC formed by the assembly of a fusion protein (I) of the invention comprising a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said SAP is IBDV pVP2 , or a functional variant thereof, in which said peptide insert is located inside loop P H i of said IBDV pVP2 or functional variant thereof (IBDV pVP2_452) , either between 2 contiguous amino acids or substituting one or more amino acids of said loop P H i .
  • a fusion protein (I) of the invention comprising a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP, said heterologous peptide comprising an amino acid sequence with the capacity to bind to a ligand, wherein said SAP is IBDV pVP2 , or a functional variant thereof,
  • said peptide insert comprises a BAP; in an even more specific embodiment, said peptide insert comprises a BAP comprising the amino acid sequence shown in SEQ ID NO: 3 and the insertion of said peptide insert in said SAP (IBDV pVP2, or a functional variant thereof, such as the protein identified as IBDV pVP2_452) is located in loop P H i of said SAP.
  • the invention provides an NC formed by the assembly of a fusion protein (I) of the invention comprising a SAP and a peptide insert or heterologous peptide inserted inside the amino acid sequence of said SAP comprising an amino acid sequence with the capacity to bind to a ligand, in which said heterologous peptide comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • said SAP is an IBDV pVP2, or a functional variant thereof, such as IBDV pVP2_452.
  • said BAP is located inside loop P H i of said IBDV pVP2 or functional variant thereof (IBDV pVP2_452) , either between 2 contiguous amino acids or substituting one or more amino acids of said loop
  • the invention provides an NC f o rme d b y t he a s s emb l y o f a f u s i o n p r o t e i n ( I ) o f th e invention, identified as SAP_BAP , comprising the IBDV pVP2_452 and a BAP ( SEQ ID NO : 3 ) located inside loop P H i of said IBDV pVP2_452 .
  • the invention provides an NC formed by the assembly of a fusion protein (I) of the invention comprising a SAP and a peptide insert or heterologous peptide bound to the amino- or carboxyl-terminal end of said SAP, in which said heterologous peptide comprises a BAP.
  • said BAP comprises the amino acid sequence shown in SEQ ID NO: 3.
  • said SAP is an IBDV pVP2, or a functional variant thereof, such as IBDV pVP2 452.
  • the NC of the invention may or may not contain a product of interest (which is bound to a ligand forming the conjugate of the invention) bound to the peptide insert present in said NC through a ligand with the capacity to bind to said peptide insert, or alternatively, through a dual connector, i.e. with two different binding domains, one of which has the capacity to bind to said peptide insert and the other of which has the capacity to bind to said ligand to which the product of interest is bound.
  • a product of interest which is bound to a ligand forming the conjugate of the invention
  • the NC of the invention is not bound to any product of interest and has been called “unloaded NC of the invention", to emphasize that it is not bound to any product of interest, opposed to another particular embodiment of the NC of the invention comprising a product of interest and which has been called “loaded NC of the invention”.
  • the unloaded NC of the invention is a macromolecular structure resulting from the assembly of fusion proteins (I) of the invention, said fusion proteins (I) of the invention comprising: (i) a self assembly protein and (ii) a peptide insert comprising the amino acid sequence of a peptide with the capacity to bind to a ligand, i.e. a specific binding domain.
  • said peptide insert can be inserted inside the amino acid sequence of said self assembly protein (SAP) or bound to the amino- or carboxyl-terminal end of said SAP.
  • Figure 1 shows a schematic depiction of an unloaded NC of the invention [see the drawing identified as (2) in said Figure 1, showing an NC with several specific binding domains on its surface resulting from the assembly of the genetically modified self assembly protein identified as (1) in said Figure 1] .
  • the unloaded NC of the invention comprises a connector bound to the peptide insert.
  • said peptide insert is a BAP and said connector is a biotin which allows the binding of a conjugate of the invention the ligand of which is an avidin, for example, a monoavidin (mAV) .
  • said BAP has the amino acid sequence shown in SEQ ID NO: 3.
  • the unloaded NC of the invention can be obtained by conventional techniques known by persons skilled in the art, for example, by means of the gene expression of the nucleotide sequence encoding said fusion protein (I) of the invention in suitable host cells, such as the previously defined host cells of the invention containing the polynucleotide encoding the amino acid sequence of the fusion protein (I) of the invention, and the subsequent assembly of said fusion proteins (I) of the invention .
  • the invention relates to a process for producing an unloaded NC of the invention which comprises culturing a host cell of the invention (comprising the polynucleotide of the invention containing the nucleotide sequence encoding the fusion protein (I) of the invention) under conditions allowing the expression of said fusion protein and its self assembly to form NCs, and, if desired, the recovery of said NCs.
  • the expressed proteins are generally assembled and form the NCs which, if desired, can be isolated or removed from the medium, and optionally purified.
  • Said NCs can be isolated and purified by conventional methods, for example by fractionation in sucrose gradients.
  • the previously described process for obtaining it would include the step of putting the NCs formed in contact with the connector.
  • said connector is biotin and in this case, said unloaded NC of the invention comprising biotin bound to BAP (peptide insert) can be obtained by putting said NCs in which the peptide insert is a BAP in contact with biotin in the presence of biotin ligase (BL) enzyme under conditions allowing the specific interaction (binding) of biotin to BAP. Said interaction can be achieved metabolically or non-metabolically, i.e. in vitro, as will be described in detail below.
  • the production of said unloaded can be achieved metabolically or non-metabolically, i.e. in vitro, as will be described in detail below.
  • NC of the invention is carried out in insect cells infected with an rBV comprising the polynucleotide of the invention.
  • section 1.3 describes obtaining unloaded NCs of the invention formed by the self assembly of a fusion protein (I) of the invention identified as SAP_BAP (SEQ ID NO: 4) comprising the self assembly protein IBDV pVP2_452 (identified as "SAP") genetically modified by means of introducing a BAP (SEQ ID NO: 3) , in insect cells (T. Ni) infected with an rBV comprising a polynucleotide comprising the nucleotide sequence encoding said IBDV pVP2_452 genetically modified by means of introducing the nucleotide sequence encoding said BAP in loop P H i of IBDV pVP2- 452.
  • the production of said unloaded NC of the invention is carried out in yeasts comprising the polynucleotide of the invention; in this case, the polynucleotide of the invention can be contained in a recombinant vector integrated in the yeast genome, or, preferably, said recombinant vector not integrated in the yeast genome .
  • the unloaded NC of the invention can be used, among other applications, in the production of a loaded NC of the invention.
  • the NC of the invention is bound to a product of interest and has been called "loaded NC of the invention".
  • the loaded NC of the invention is a macromolecular structure resulting from the assembly of fusion proteins (I) of the invention, further comprising a product of interest, in which said fusion proteins
  • (I) of the invention comprise: (i) a self assembly protein and
  • a peptide insert comprising the amino acid sequence of a peptide with the capacity to bind to a ligand, i.e. a specific binding domain.
  • said peptide insert can be inserted inside the amino acid sequence of said self assembly protein (SAP) or bound to the amino- or carboxyl- terminal end of said SAP.
  • Figure 1 shows a schematic depiction of a particular case of a loaded NC of the invention [see the drawing identified as (4) in said Figure 1, showing an NC with several specific binding domains on its surface (resulting from the self assembly of the genetically modified self assembly protein identified as (1) in said Figure 1) , to which chimeric proteins (3) have been bound [particular case of the conjugate of the invention], which chimeric proteins comprise (i) a ligand containing a region of interaction with the binding domain present in the NC bound to (ii) a protein of interest] .
  • the product of interest forms part of a conjugate of the invention comprising, in addition to the product of interest, a ligand.
  • said ligand has the capacity to bind to said peptide insert present in the NC, i.e. it contains a region of specific interaction with the specific binding domain present in said NC (peptide insert) ; in this case, the specific interaction (binding) between the ligand and the peptide insert is carried out directly.
  • the binding of the ligand to the peptide insert can be carried out indirectly, through a connector; as has been defined previously, said connector is a dual molecule, i.e.
  • the ligand present in the conjugate of the invention has the capacity to bind to said connector, i.e. it contains a region interacting specifically with the corresponding specific binding domain present in said connector.
  • fusion protein (I) of the invention as well as those of its components (self assembly protein and peptide insert) , those of the conjugate of the invention and its components (ligand and product of interest) and those of the connector have already been defined above.
  • the loaded NCs of the invention are classified into: a) loaded NCs of the invention in which the product of interest is bound directly to the NC through the ligand; and b) loaded NCs of the invention in which the product of interest is bound indirectly to the NC through a connector.
  • the product of interest regardless of whether or not it is bound to the NC through a ligand or a connector, can alternatively be contained inside the NC of the invention, thus giving rise to an alternative embodiment of the loaded NC of the invention.
  • a loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand, (or indirectly through a connector which is bound to the NC on one hand and to the conjugate of the invention on the other hand) can generally be obtained by incubating an unloaded NC of the invention in the presence of the conjugate of the invention and, where appropriate, of the connector, under suitable conditions allowing the binding between the binding domains present in said unloaded NC of the invention and the regions of interaction present in the ligand contained in the conjugate of the invention, alternatively, between the binding domains present in said unloaded NC of the invention and the regions of interaction present in the connector and between the binding domains present in said connector and the regions of interaction present in the ligand contained in the conjugate of the invention.
  • the unloaded NC of the invention can be obtained according to the previously described methodology and the conjugate of the invention can be obtained by synthetic or recombinant methods, depending on the nature of its components, as has been mentioned previously.
  • the loaded NC of the invention comprises a product of interest bound directly to the NC through the ligand by means of a typical interaction of a specific binding pair, as has been mentioned previously in the section relating to the conjugate of the invention.
  • the loaded NC of the invention comprising a product of interest bound directly to NC through the ligand can be obtained by several conventional methods depending, among other issues, on the (peptide or non-peptide) nature of the ligand and of the product of interest.
  • the loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand can be obtained by incubating an unloaded NC of the invention in the presence of the conjugate of the invention under suitable conditions allowing the binding between the binding domains present in said unloaded NC of the invention and the regions of interaction present in the ligand contained in the conjugate of the invention.
  • Said loaded NC of the invention comprising a product of interest bound directly to NC through the ligand can alternatively be obtained by means of expressing both the fusion protein (I) of the invention and, where appropriate, the conjugate of the invention in a suitable expression system.
  • the invention provides a process (Process A.I) for producing a loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand which comprises putting an unloaded NC of the invention in contact with a conjugate of the invention comprising the ligand and the product of interest, under conditions allowing the binding between the specific binding domains present in the peptide inserts contained in said unloaded NC of the invention and the corresponding regions of interaction present in the ligands contained in said conjugates of the invention.
  • a process for producing a loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand which comprises putting an unloaded NC of the invention in contact with a conjugate of the invention comprising the ligand and the product of interest, under conditions allowing the binding between the specific binding domains present in the peptide inserts contained in said unloaded NC of the invention and the corresponding regions of interaction present in the ligands contained in said conjugates of the invention.
  • This process can be used to produce a loaded NC of the invention comprising a product of interest bound directly to NC through the ligand, either when the ligand and/or the product of interest are of a non-peptide nature or when the ligand and the product of interest are of a peptide nature.
  • Figure 1 schematically shows this process (Process A.I) for obtaining a loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand.
  • Said diagram shows in a simplified manner a strategy designed to obtain a loaded NC of the invention in which the product of interest bound directly to the NC through a ligand is a recombinant protein (particular case of the conjugate of the invention) , briefly consisting of: expressing a self assembly protein genetically modified by means of the introducing a peptide insert (1) to allow the presence of a specific binding domain in an exposed region of the protein assembly or NC (2) .
  • recombinant vectors are developed for expressing a conjugate of the invention, which in this case is a fusion protein (3) comprising a region A' comprising a region of interaction with the specific binding domain exposed in said NC and a region B' comprising a product of interest of a protein nature.
  • a conjugate of the invention which in this case is a fusion protein (3) comprising a region A' comprising a region of interaction with the specific binding domain exposed in said NC and a region B' comprising a product of interest of a protein nature.
  • the conjugate of the invention in which the conjugate of the invention is of a peptide nature (due to the fact that both the ligand and the product of interest are of a peptide nature) , i.e. when said conjugate of the invention is the fusion protein previously identified as "fusion protein (II)", the loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand can be obtained by means of an alternative process comprising the joint expression (co-expression) of said fusion protein (I) of the invention and of said fusion protein (II) , in one and the same expression system, under conditions allowing, on one hand, the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs and on the other hand, the expression of said fusion protein (II) , and furthermore the specific interaction (binding) between the specific binding domains present in the peptide inserts contained in said "unloaded” NCs and the corresponding regions of interaction present in the protein ligands contained in
  • the invention provides a process (Process A.2) for producing a loaded NC of the invention comprising a product of interest bound directly to the NC through the ligand which comprises culturing a host cell of the invention comprising, in addition to the polynucleotide of the invention (comprising the nucleotide sequence encoding the fusion protein (I) of the invention) , a polynucleotide, hereinafter "polynucleotide PF(II)” comprising the nucleotide sequence encoding said fusion protein (II) , under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said fusion protein (II) , and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the protein ligands present
  • a host cell of the invention so that it comprises, in addition to the polynucleotide of the invention, the nucleotide sequence encoding the fusion protein (II) , can be carried out by means of conventional methods known by persons skilled in the art [Sambrook & Russell (2001) ] .
  • the gene expression of the fusion protein (I) of the invention and the gene expression of said fusion protein (II) is carried in insect cells infected with an rBV comprising the polynucleotide of the invention and the polynucleotide identified as polynucleotide PF (II) [comprising the nucleotide sequence encoding said fusion protein (II) ] .
  • Said polynucleotides can form part of one and the same nucleic acid molecule or gene construct or they can alternatively be separated into two different constructs but contained in one and the same rBV.
  • a single rBV comprising the polynucleotide of the invention and the polynucleotide PF(II) is constructed either in a single gene construct or, alternatively, in two separate identical or different gene constructs, and an insect cell is subsequently co-infected with said rBV.
  • the gene expression of the fusion protein (I) of the invention and that of said fusion protein (II) is carried out in insect cells co-infected with 2 different rBVs, each of them containing one of said polynucleotides.
  • an rBV comprising the polynucleotide of the invention and another rBV comprising the polynucleotide PF(II) are constructed, and an insect cell is subsequently co-infected with said rBVs.
  • Some of said gene constructs comprising the polynucleotide of the invention and the polynucleotide PF(II) form part of the present invention and are additional aspects thereof.
  • Said gene constructs can be obtained by conventional methods known by persons skilled in the art in view of the fusion protein (I) of the invention and of the fusion protein (II) .
  • the expression cassettes, the recombinant vectors and the host cells containing said gene constructs comprising the polynucleotide of the invention and the polynucleotide PF(II) are additional aspects of the present invention and can be obtained by conventional methods known by persons skilled in the art in view of the information contained in this description [Sambrook & Russell (2001) ] .
  • the rBVs comprising said gene constructs comprising the polynucleotide of the invention and the polynucleotide PF(II) in a single gene construct, or comprising said polynucleotides (polynucleotide of the invention and polynucleotide PF(II) ) in separate constructs, form part of the present invention, are additional aspects thereof and can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology, as has been mentioned previously in relation to the production of the fusion protein (I) of the invention.
  • the gene expression of the fusion protein (I) of the invention and the gene expression of said fusion protein (II) are carried out in yeasts comprising the polynucleotide of the invention and the polynucleotide PF(II) .
  • Said polynucleotides can be integrated inside the yeast genome, or one of them can be integrated in the yeast genome and the other one not, which polynucleotide can be in a gene construct in the cytoplasm, or both polynucleotides can form part of one and the same nucleic acid molecule or gene construct not integrated in the yeast genome, or, alternatively, said polynucleotides can be separated into two different constructs but contained in one and the same yeast cell.
  • a single recombinant yeast comprising the polynucleotide of the invention and the polynucleotide PF(II) , either integrated inside the yeast genome, or one of them integrated in the yeast genome and the other one not, or in a single gene construct not integrated in the yeast genome, or in two different gene constructs not integrated in the yeast genome but contained in one and the same yeast cell, and said yeast is then cultured under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said fusion protein (II), and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the protein ligands present in the fusion protein (II), and, (ii) if desired, the isolation and optionally the purification of said NCs "loaded” with the product of interest.
  • the recombinant yeasts comprising the polynucleotide of the invention and the polynucleotide PF(II) , either integrated inside the yeast genome, or one of them integrated in the yeast genome and other one not, or in a single gene construct not integrated in the yeast genome, or in two different gene constructs not integrated in the yeast genome but contained in one and the same yeast cell, as well as the gene constructs and recombinant vectors necessary for obtaining said recombinant yeasts, form part of the present invention, are additional aspects thereof and can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology, as has been mentioned previously in relation to the production of the fusion protein (I) of the invention. 3.2.2 Loaded NC of the invention in which the product of interest is bound indirectly to the NC through the connector
  • the loaded NC of the invention comprises a product of interest bound indirectly to the NC through a connector which is bound, on one hand, to the peptide insert present in the NC and, on the other hand, to the ligand present in the conjugate of the invention, by means of typical interactions of respective specific binding pairs, as has been mentioned previously in the section relating to the conjugate of the invention.
  • said connector is biotin which is bound to the NC by means of a specific interaction with a specific biotin binding domain contained in the peptide insert, such as a BAP and said ligand comprises a domain of specific biotin interaction, such as an avidin; the product of interest bound to the ligand is thus bound indirectly to the NC through said connector.
  • said connector is a fusion protein comprising an SH3 domain which binds to the NC by means of a specific interaction with a protein SH3 binding domain contained in the peptide insert.
  • said connector is a peptide comprising a domain of specific interaction with a protein involved in a signaling cascade.
  • said connector is a peptide comprising a domain of specific interaction with a pos t-translational modification sequence (e.g. myristoylation, methylation, phosphorylation, etc.) .
  • said connector is a peptide comprising a domain of specific interaction with a sequence of transport to a cell compartment.
  • the loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector can be obtained by several conventional methods depending, among other issues, on the (peptide or non-peptide) nature of the ligand and on the product of interest, as well as on the connector, in a manner similar to how it has been described previously in relation to the production of loaded NCs of the invention comprising a product of interest bound directly to the NC through the ligand.
  • the loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector
  • the loaded NC of the invention can be obtained by incubating an unloaded NC of the invention with the conjugate of the invention in the presence of said connector under suitable conditions allowing the specific interaction (binding) between the specific binding domains present in said unloaded NC of the invention and the corresponding regions of interaction present in the connector, and, subsequently the specific interaction (binding) between the binding domains present in said connector bound to the NC and the regions of interaction present in the ligand contained in the conjugate of the invention.
  • Said specific interaction between the binding domains present in said unloaded NC of the invention and the corresponding regions of interaction present in the connector, as well as said specific interaction between the binding domains present in said connector bound to the NC and the regions of interaction present in the ligand (conjugate of the invention) are typical interactions of specific binding pairs, for example, of the BAP-biotin and biotin-avidin type, etc.
  • Said loaded NC of the invention comprising a product of interest bound indirectly to the NC through the ligand connector, depending on the nature of the conjugate of the invention, can alternatively be obtained by means of expressing both the fusion protein (I) of the invention and where appropriate, the conjugate of the invention in a suitable expression system.
  • the invention provides a process (Process B.I) for producing a loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector which comprises: a) putting an unloaded NC of the invention in contact with a connector, under conditions allowing the specific interaction (binding) between the binding domain present in said unloaded NC of the invention and the region of interaction corresponding to said binding domain present in the connector, to obtain an unloaded NC of the invention bound to said connector; b) putting said unloaded NC of the invention bound to a connector in contact with a conjugate of the invention comprising a ligand and a product of interest, under conditions allowing the binding between the binding domain present in said connector and the corresponding region of interaction present in said ligand, to obtain a loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector; and, if desired c) isolating and optionally purifying said loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector;
  • the connector first binds to the conjugate of the invention and the resulting complex binds to the unloaded NC of the invention; thus, in a variant of said Process B.I) , the invention provides a process for producing a loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector which comprises: a) putting said connector in contact with a conjugate of the invention comprising a ligand and a product of interest, under conditions allowing the binding between the binding domain present in said connector and the corresponding region of interaction present in said ligand, to obtain a connector-conjugate complex of the invention; b) putting an unloaded NC of the invention in contact with said connector-conjugate complex of the invention, under conditions allowing the specific interaction (binding) between the binding domain present in said unloaded NC of the invention and the region of interaction corresponding to said binding domain present in the connector, to obtain a loaded NC of the invention comprising a product of interest bound indirectly to the
  • This process in any of its 2 variants, can be used to produce a loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector when the connector and/or the ligand and/or the product of interest are of a non-peptide nature.
  • this process can also be used when the connector, the ligand and the product of interest are of a peptide nature.
  • said connector is biotin or an analog thereof
  • the peptide insert comprises a BAP
  • the ligand present in the conjugate of the invention comprises an avidin, preferably, a monomeric avidin (mAV) variant.
  • Example 1 (section 1.4) describes the results of a process for biotinylating NCs in vitro based on this process which comprises incubating (i) unloaded NCs of the invention formed by the self assembly of a fusion protein (I) of the invention, identified as SAP_BAP (SEQ ID NO: 4) comprising the self assembly protein IBDV pVP2_452 ("SAP") genetically modified by means of introducing a BAP (SEQ ID NO: 3), in insect cells (T.
  • SAP_BAP SEQ ID NO: 4
  • SAP self assembly protein IBDV pVP2_452
  • Ni) infected with an rBV comprising a polynucleotide comprising the nucleotide sequence encoding said IBDV pVP2_452 genetically modified by means of introducing the nucleotide sequence encoding said BAP (rBV/FB_SAP_BAP) , with (ii) biotin, in the presence of (iii) BirA (BL or biotin ligase enzyme) .
  • Example 3 describing the production of NCs loaded with a recombinant protein through a system (BAP-biotin-nxAV) based on using biotin as a connector, is also based on this process.
  • Said loaded NC of the invention comprising a product of interest bound indirectly to the NC through the connector, depending on the nature of the connector and of the conjugate of the invention, can alternatively be obtained by means of expressing both the fusion protein (I) of the invention and, where appropriate, the connector and the conjugate of the invention in a suitable expression system.
  • This alternative is also valid when the connector is a metabolite present in a native or recombinant manner in the expression system used to produce said NC, for example, biotin, a cofactor which is present in a native manner in multiple cells.
  • the invention provides a process (Process B.2) for producing a loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector, which comprises culturing a host cell of the invention comprising, in addition to the polynucleotide of the invention, the polynucleotide PF(II) and a polynucleotide, hereinafter "polynucleotide-c o nn e c t o r " , comprising the nucleotide sequence encoding said connector, under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said connector, the expression of said fusion protein (II), and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of
  • the expressed proteins are generally assembled and form the "unloaded” NCs, and the contact of said unloaded NCs with the connector and subsequently with the fusion protein (II) , under the aforementioned conditions, causes the binding of the product of interest to the NC by means of the connector, through a connector-ligand system, a loaded NC of the invention comprising a product of interest bound indirectly to the NC through the ligand thus being generated.
  • the connector can first be fused to the fusion protein (II) of the invention and the resulting complex can interact with the unloaded NC of the invention to produce the loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector.
  • a host cell of the invention so that it comprises, in addition to the polynucleotide of the invention, the polynucleotide PF(II) and the polynucleotide-connector, can be carried out by means of conventional methods known by the persons skilled in the art [Sambrook & Russell (2001)] .
  • the gene expression of the fusion protein (I) of the invention and the gene expression of said fusion protein (II) is carried out in insect cells infected with an rBV comprising the polynucleotide of the invention, the polynucleotide PF ( I I ) and the p o 1 ynu c 1 e o t i de-connector [comprising the nucleotide sequence encoding said connector] .
  • Said polynucleotides can form part of one and the same nucleic acid molecule or gene construct, or, alternatively, they can be separated into 2 (containing any combination of 2 of said polynucleotides) or 3 different constructs but contained in one and the same rBV.
  • a single rBV is constructed comprising the polynucleotide of the invention, the polynucleotide PF(II) , the polynucleotide-connector, either in a single gene construct or, alternatively, in 2 or 3 separate gene constructs, and an insect cell is subsequently co-infected with said rBV.
  • the gene expression of the fusion protein (I) of the invention and that of said fusion protein (II) is carried out in insect cells co-infected with 2 different rBVs, one of which rBVs contains any two of said polynucleotides (polynucleotide of the invention, polynucleotide PF(II) and polynucleotide-connector) and the other rBV contains the other polynucleotide.
  • an rBV compri sing any two of said polynucleotides (e.g.
  • the polynucleotide of the invention and the polynucleotide- connector) and another rBV comprising the other polynucleotide are constructed, and an insect cell is subsequently co-infected with said rBVs.
  • the gene expression of the fusion protein (I) of the invention and that of said fusion protein (II) is carried out in insect cells co-infected with 3 dif ferent rBVs , each of them containing one of said polynucleotides.
  • an rBV comprising the polynucleotide of the invention, another rBV comprising the polynucleotide-connector and another rBV comprising the polynucleotide PF(II) are constructed, and an insect cell is subsequently co-infected with said rBVs.
  • Some of said gene constructs comprising the polynucleotide of the invention, the polynucleotide-connector and the polynucleotide PF(II) form part of the present invention and are additional aspects thereof. Said gene constructs can be obtained by conventional methods known by persons skilled in the art in view of the fusion protein (I) of the invention and of the fusion protein (II) .
  • the expression cassettes, the recombinant vectors and the host cells containing said gene constructs comprising the polynucleotide of the invention, the polynucleotide-connector and the polynucleotide PF(II) , or combinations of any two of said polynucleotides are additional aspects of the present invention and can be obtained by conventional methods known by persons skilled in the art in view of the information contained in this description [Sambrook & Russell (2001) ] .
  • the rBVs comprising said gene constructs comprising the polynucleotide of the invention, the polynucleotide-connector and the polynucleotide PF(II) in a single gene construct, or comprising said polynucleotides in 2 or 3 separate constructs, form part of the present invention, are additional aspects thereof and can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology, as has been mentioned previously in relation to the production of the fusion protein
  • yeasts comprising the polynucleotide of the invention, the polynucleotide-connector and the polynucleotide PF(II) .
  • Said polynucleotides can be integrated inside the yeast genome, or one of them can be integrated in the yeast genome and the other two not, or any two of said polynucleotides can be integrated in the yeast genome and the other one not, which polynucleotide can be in a gene construct in the cytoplasm, or said polynucleotides can form part of one and same nucleic acid molecule or gene construct not integrated in the yeast genome, or, alternatively, said polynucleotides can be separated into 2 or 3 different constructs but contained in one and the same yeast cell.
  • a single recombinant yeast comprising the polynucleotide of the invention, the polynucleotide-connector and the polynucleotide PF(II) , in any of the aforementioned embodiments, and said yeast is then cultured under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said connector and the expression of said fusion protein (II), and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the connector, and the specific interaction (binding) between the specific binding domains present in said connector and the corresponding regions of interaction present in the protein ligands contained in the fusion protein (II) , and, (ii) if desired, the isolation and optionally the purification of said NCs "loaded” with the product of interest.
  • the recombinant yeasts comprising the polynucleotide of the invention, the polynucleotide-connector and the polynucleotide PF(II) , in any of the aforementioned specific embodiments, as well as the gene constructs and recombinant vectors necessary for obtaining said recombinant yeasts, form part of the present invention, are additional aspects thereof and can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology, as has been mentioned previously in relation to the production of the fusion protein (I) of the invention.
  • said loaded NC of the invention comprising a product of interest bound indirectly to the NC through the connector, depending on the nature of the connector and of the conjugate of the invention, can be obtained by means of expressing both the fusion protein (I) of the invention and the conjugate of the invention in a suitable expression system when the connector is a metabolite present in a native or recombinant manner in the expression system used to produce said NC, for example, biotin, a cofactor which is present in a native manner in multiple cells.
  • the conjugate of the invention is the fusion protein (II)
  • the conjugate of the invention is the fusion protein (II)
  • the connector is a compound which is present in the chosen expression system
  • the invention provides a process (Process B.3) for producing a loaded NC of the invention comprising a product of interest bound indirectly to the NC through a connector, which comprises culturing a host cell of the invention comprising, in addition to the polynucleotide of the invention, the polynucleotide PF(II) and the connector (which, as has been mentioned, is a product which is present in the chosen expression system, such as a metabolite, e.g.
  • the expressed proteins are generally assembled and form the "unloaded" NCs, and the contact of said unloaded NCs with the connector and subsequently with the fusion protein (II) , under the aforementioned conditions, causes the binding of the product of interest to the NC by means of the connector through a connector-ligand system, a loaded NC of the invention comprising a product of interest bound indirectly to the NC through the ligand thus being generated.
  • the chosen expression system i.e. the host cell of the invention, further expresses the compound or compounds necessary for the specific interaction (binding) between the specific binding domains present in said "unloaded" NCs and the corresponding regions of interaction present in said connector to occur or for enhancing it.
  • said compounds include enzymes, etc.
  • Said compounds can be natively expressed by said expression system; alternatively, if said expression system does not express said compound or compounds, it can then be suitably transformed by conventional methods in order to express said compound or compounds.
  • the connector can be biotin, a cofactor in the catalysis of a number of essential metabolic reactions for synthesizing fatty acids, in glyconeogenesis, in the leucine metabolism, etc.
  • Biotin is present in a native manner in a number of cells and the presence of the biotin ligase enzyme (e.g. E. coli protein BirA or any other biotin ligase) is necessary for biotin to bind to a peptide; therefore, in the event that the connector is biotin, it is necessary for the chosen expression system for producing the NCs to produce said enzyme either constitutively or by means of introducing the nucleotide sequence encoding said protein.
  • the biotin ligase enzyme e.g. E. coli protein BirA or any other biotin ligase
  • the host cell of the invention chosen for producing NCs comprises, in addition to the polynucleotide of the invention, the polynucleotide PF(II) and the connector, a polynucleotide comprising the nucleotide sequence encoding the biotin ligase enzyme (e.g. E. coli protein BirA or any other suitable biotin ligase) .
  • the biotin ligase enzyme e.g. E. coli protein BirA or any other suitable biotin ligase
  • the gene expression of the fusion protein (I) of the invention and the gene expression of said fusion protein (II) is carried out in insect cells producing said connector, infected with an rBV comprising the polynucleotide of the invention, the polynucleotide PF(II) and, optionally, in the event that said insect cell does not express the compound or compounds necessary for the connector to bind to the NC, a polynucleotide comprising the nucleotide sequence encoding said compound necessary for the connector to bind to the NC.
  • Said polynucleotides can form part of one and the same nucleic acid molecule or gene construct, or, alternatively, they can be separated into different constructs, in any combination, but contained in one and the same rBV.
  • a single rBV is constructed comprising the polynucleotide of the invention and the polynucleotide PF(II) , and, optionally, the polynucleotide comprising the nucleotide sequence encoding a compound necessary for the connector to bind to the NC, in a single gene construct or, alternatively, in 2 or 3 separate identical or different gene constructs, and an insect cell is subsequently co-infected with said rBV.
  • the gene expression of the fusion protein (I) of the invention and that of said fusion protein (II) is carried out in insect cells co-infected with 2 different rBVs, each of them containing one of said polynucleotides.
  • an rBV is constructed comprising the polynucleotide comprising the nucleotide sequence encoding a compound necessary for the connector to bind to the NC.
  • an insect cell is co-infected with said rBVs.
  • the expression cassettes, the recombinant vectors, including the generated rBVs, and the host cells containing said gene constructs are additional aspects of the present invention and can be obtained by conventional methods known by persons skilled in the art in view of the information contained in this description.
  • the gene expression of the fusion protein (I) of the invention and the gene expression of said fusion protein (II) , and, where appropriate, of the compound or compounds necessary for the connector to bind to the NC is carried out in yeasts comprising the polynucleotide of the invention and the polynucleotide PF(II) and, optionally, said polynucleotide comprising the nucleotide sequence encoding a compound necessary for the connector to bind to the NC.
  • Said polynucleotides can be integrated inside the yeast genome, or only one of them and the other or others can be in or two gene constructs in the cytoplasm, or said polynucleotides can form part of one and the same nucleic acid molecule or gene construct not integrated in the yeast genome, or, alternatively, said polynucleotides can be separated into different constructs but contained in one and the same yeast cell.
  • a single recombinant yeast comprising the polynucleotide of the invention, the polynucleotide PF(II) , and, if necessary, the polynucleotide comprising the nucleotide sequence encoding a compound necessary for the connector to bind to the NC, in any of the aforementioned embodiments, and said yeast is then cultured under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said fusion protein (II) , and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the connector and between the specific binding domains present in said connector and the corresponding regions of interaction present in the protein ligands present in the fusion protein (II) , and, (ii) if desired, the isolation and optionally the purification of said NCs "loaded” with the product of interest.
  • recombinant yeasts used to implement this alternative process as well as the gene constructs and recombinant vectors necessary to obtain said recombinant yeasts, form part of the present invention, are additional aspects thereof and can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology, as has been mentioned previously in relation to the production of the fusion protein (I) of the invention.
  • the peptide insert present in the fusion protein (I) of the invention comprises a BAP
  • the connector is biotin
  • the ligand present in the conjugate of the invention is an avidin
  • the invention provides a process (Process Cl) for producing a loaded NC of the invention comprising a product of interest bound indirectly to the NC through biotin, which comprises culturing a host cell of the invention comprising, in addition to a polynucleotide of the invention comprising the nucleotide sequence encoding a BAP (peptide insert) , a polynucleotide encoding the biotin ligase (BL) enzyme in the presence of biotin under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said BL enzyme, and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs (BAP) and the corresponding regions
  • the expressed proteins are generally assembled and form the "unloaded” NCs, and the contact of said unloaded NCs with the connector (biotin) and subsequently with the conjugate of the invention (avidin- product of interest) , under the aforementioned conditions, causes the binding of the product of interest to the NC by means of the connector (biotin) through a biotin-avidin (connector- ligand) system, a loaded NC of the invention comprising a product of interest bound indirectly to the NC through the ligand thus being generated. If the host cell of the invention does not produce biotin naturally, biotin would then have to be added to the medium.
  • the BL enzyme is E. coli protein BirA.
  • the BL enzyme can be overexpre s sed simultaneously to the expression of the fusion protein (I) of the invention, for the purpose of raising the biotinylated NC levels (see, for example, Buoncristiani et al . , 1998, J. Biol. Chem. 263, 1013-1016) .
  • the gene expression of the fusion protein (I) of the invention and the gene expression of said BL enzyme is carried out in insect cells infected with an rBV comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme, and in the event that said insect cell does not produce biotin naturally, biotin is then added to the medium.
  • Said polynucleotides can form part of one and the same nucleic acid molecule or gene construct, or, alternatively, they can be separated into different constructs, in any combination, but contained in one and the same rBV.
  • a single rBV is constructed comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme, in a single gene construct or, alternatively, in 2 separate identical or different gene constructs, and an insect cell is subsequently co-infected with said rBV.
  • an insect cell is subsequently co-infected with said rBV.
  • the gene expression of the fusion protein (I) of the invention and that of the BL enzyme is carried out in insect cells co-infected with 2 different rBVs, each of them containing one of said polynucleotides.
  • an insect cell is co- infected with said rBVs.
  • an additional rBV can containing a gene construct comprising the polynucleotide encoding said fusion protein (II) be constructed and the insect cell can furthermore be co-infected with said rBV.
  • the expression cassettes, the recombinant vectors, including the generated rBVs, and the host cells containing said gene constructs are additional aspects of the present invention and can be obtained by conventional methods known by persons skilled in the art in view of the information contained in this description.
  • the gene expression of the fusion protein (I) of the invention and the gene expression of the BL enzyme, and, where appropriate, of said fusion protein (II) is carried out in yeasts comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme, and, optionally, the polynucleotide PF(II) .
  • Said polynucleotides can be integrated inside the yeast genome, or only one of them and the other or others can be in one or two gene constructs in the cytoplasm, or said polynucleotides can form part of one and the same nucleic acid molecule or gene construct not integrated in the yeast genome, or, alternatively, said polynucleotides can be separated into different constructs but contained in one and the same yeast cell.
  • a single recombinant yeast comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme, and, optionally, the polynucleotide PF(II) , in any of the aforementioned embodiments, and said yeast is then cultured under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said BL enzyme, and, optionally, the expression of said fusion protein (II) , and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the connector (biotin) and between the specific binding domains present in said connector and the corresponding regions of interaction present in the protein ligands present in the fusion protein (II) (avidin) , and, (ii) if desired, the isolation and optionally the purification of said NCs "loaded” with the product of interest.
  • recombinant yeasts used to implement this alternative process as well as the gene constructs and recombinant vectors necessary for obtaining said recombinant yeasts form part of the present invention, are additional aspects thereof, and can be obtained by a person skilled in the art based on that described herein and on the state of the art on this technology, as has been mentioned previously in relation to the production of the fusion protein (I) of the invention.
  • the peptide insert present in the fusion protein (I) of the invention comprises a BAP
  • the connector is biotin
  • the ligand present in the conjugate of the invention is an avidin and the production of loaded NCs of the invention with a product of interest bound indirectly to the NC through biotin is carried out by means of a non-metabolic, i.e. in vitro, biotinylation process.
  • the invention provides a process (Process C.2) for producing a loaded NC of the invention comprising a product of interest bound indirectly to the NC through biotin, which comprises culturing a host cell of the invention comprising a polynucleotide of the invention comprising the nucleotide sequence encoding a BAP (peptide insert) in the presence of biotin ligase (BL) enzyme and biotin under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs (BAP) and the corresponding regions of interaction present in said connector (biotin) , and, subsequently, the specific interaction (binding) between the specific binding domains present in said connector (biotin) and the corresponding regions of interaction present in the ligand (avidin) present in the conjugate of the invention, and, if desired, the recovery of said loaded NCs.
  • the expressed proteins are generally assembled and form the "unloaded” NCs, and the contact of said unloaded NCs with the connector (biotin) in the presence of the BL enzyme, and, subsequently, with the conjugate of the invention (avidin- product of interest) , under the aforementioned conditions, causes the binding of the product of interest to the NC by means of the connector (biotin) through a biotin-avidin (connector- ligand) system, a loaded NC of the invention comprising a product of interest bound indirectly to the NC through the ligand thus being generated.
  • the host cell of the invention does not naturally produce biotin or the BL enzyme, biotin and/or BL enzyme would then have to be added to the medium.
  • the BL enzyme is E. coli protein BirA.
  • the gene expression of the fusion protein (I) of the invention is carried out in insect cells infected with an rBV comprising the polynucleotide of the invention, and in the event that said insect cell does not naturally produce biotin or BL enzyme, biotin and/or BL enzyme is then added to the medium.
  • a single rBV is constructed comprising the polynucleotide of the invention and an insect cell is subsequently infected with said rBV.
  • fusion protein (II) there may then be an additional gene construct comprising the polynucleotide encoding said fusion protein (II) forming part of said rBV either in the form of an independent gene construct or forming part of said gene construct comprising the polynucleotide of the invention. If the insect cell infected with the rBVs does not naturally produce biotin or the BL enzyme, biotin and/or BL enzyme would then have to be added to the medium.
  • the gene expression of the fusion protein (I) of the invention and, where appropriate, of said fusion protein (II), is carried out in yeasts comprising the polynucleotide of the invention, and, optionally, the polynucleotide PF(II) .
  • Said polynucleotides can be integrated inside the yeast genome, or one of them can be integrated in said genome and the other one can be in a gene construct in the cytoplasm, or said polynucleotides can form part of one and the same nucleic acid molecule or gene construct not integrated in the yeast genome, or, alternatively, said polynucleotides can be separated into different constructs but contained in one and the same yeast cell.
  • a single recombinant yeast comprising the polynucleotide of the invention, and, optionally, the polynucleotide PF(II) , in any of the aforementioned embodiments, and said yeast is then cultured under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, and, optionally, the expression of said fusion protein (II) , in the presence of BL enzyme and biotin, and, furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the connector (biotin) and between the specific binding domains present in said connector and the corresponding regions of interaction present in the protein ligands present in the fusion protein (II) (avidin) , and, (ii) if desired, the isolation and optionally the purification of said NCs "loaded” with the product of interest.
  • the invention also provides a process for obtaining a biotinylated NC which comprises culturing a host cell of the invention comprising, in addition to a polynucleotide of the invention comprising the nucleotide sequence encoding a BAP
  • BL biotin ligase enzyme
  • the expressed proteins are generally assembled and form the "unloaded” NCs, and the contact of said unloaded NCs with the connector (biotin) , under the aforementioned conditions, causes the binding of the biotin, either because the host cell of the invention produces it naturally or because it has been added to the medium, to the NC, a biotinylated NC of the invention thus being generated.
  • the BL enzyme is E. coli protein BirA.
  • the biotinylated NC of the invention is a useful tool for binding any product of interest, both of a peptide nature and of a non-peptide nature, through an avidin ligand (e.g. monoavidin (mAV) ) .
  • the production of said biotinylated NCs is carried out in insect cells infected with an rBV comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme.
  • biotin is then added to the medium.
  • Said polynucleotides can form part of one and the same nucleic acid molecule or gene construct, or, alternatively, they can be separated into different constructs, in any combination, but contained in one and the same rBV.
  • a single rBV is constructed comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme in a single gene construct or, alternatively, in 2 separate identical or different gene constructs, and an insect cell is subsequently co-infected with said rBV.
  • the production of said biotinylated NCs of the invention is carried out in insect cells co-infected with 2 different rBVs , each of them containing one of said polynucleotides. According to this embodiment, once the necessary rBVs have been constructed, an insect cell is co- infected with said rBVs. In another particular embodiment, the production of said biotinylated NCs of the invention is carried out in yeasts comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme.
  • Said polynucleotides can be integrated inside the yeast genome, or only one of them and the other one can be in a gene construct in the cytoplasm, or said polynucleotides can form part of one and the same nucleic acid molecule or gene construct not integrated in the yeast genome, or, alternatively, said polynucleotides can be separated into different constructs but contained in one and the same yeast cell.
  • a single recombinant yeast comprising the polynucleotide of the invention and the polynucleotide encoding the BL enzyme, in any of the aforementioned embodiments, and said yeast is then cultured under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, the expression of said BL enzyme, and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the connector (biotin) , and, (ii) if desired the isolation and optionally the purification of said biotinylated NCs of the invention.
  • the yeasts used to produce the biotinylated NCs of the invention do not naturally produce biotin, biotin would then have to be added to the medium.
  • the invention also provides an alternative process for obtaining a biotinylated NC which comprises culturing a host cell of the invention comprising a polynucleotide of the invention comprising the nucleotide sequence encoding a BAP
  • the expressed proteins are generally assembled and form the "unloaded” NCs, and the contact of said unloaded NCs with the connector (biotin) in the presence of the BL enzyme, in the aforementioned conditions, causes the binding of the biotin to the NC, a biotinylated NC of the invention thus being generated.
  • the BL enzyme is E. coli protein BirA.
  • the production of said biotinylated NCs of the invention is carried out in insect cells infected with an rBV comprising the polynucleotide of the invention in a medium comprising BL and biotin.
  • a single rBV is constructed comprising the polynucleotide of the invention, and an insect cell is subsequently infected with said rBV and cultured in a medium comprising BL and biotin.
  • the production of said biotinylated NCs is carried out in yeasts comprising the polynucleotide of the invention.
  • Said polynucleotide can be integrated inside the yeast genome, or can be contained in a gene construct in the cytoplasm not integrated in the yeast genome.
  • a single recombinant yeast is produced comprising the polynucleotide of the invention and is cultured in a medium with BL and biotin under conditions allowing the expression of said fusion protein (I) of the invention and its assembly to form "unloaded” NCs, and furthermore the specific interaction (binding) between the specific binding domains present in said "unloaded” NCs and the corresponding regions of interaction present in the connector
  • the invention provides another alternative process for obtaining a biotinylated NC which comprises putting in contact an unloaded NC of the invention obtained by the assembly of a fusion protein (I) of the invention comprising a SAP and a peptide insert, said peptide insert comprising a biotin acceptor peptide (BAP) , in a medium comprising biotin ligase (BL) enzyme and biotin under conditions allowing the specific interaction between said BAP present in said NCs and biotin, and, if desired, the recovery of said biotinylated nanocarriers .
  • a fusion protein (I) of the invention comprising a SAP and a peptide insert, said peptide insert comprising a biotin acceptor peptide (BAP) , in a medium comprising biotin ligase (BL) enzyme and biotin under conditions allowing the specific interaction between said BAP present in said NCs and biotin, and, if desired, the recovery of said biotinylated
  • the NCs of the invention can be used in research; they can also be used as vectors of products of interest, i.e. as systems for delivering products of interest, such as molecules with biological activity both of a peptide nature and of a non- peptide nature, for example, drugs, peptides, proteins, antibodies, hormones, enzymes, lipids, sugars, nucleic acids (DNA, RNA, PNA, etc.) , e.g. oligonucleotides, polynucleotides, genes, interfering RNA, etc., useful in the treatment and/or prevention of diseases as well as in diagnosis.
  • products of interest such as molecules with biological activity both of a peptide nature and of a non- peptide nature, for example, drugs, peptides, proteins, antibodies, hormones, enzymes, lipids, sugars, nucleic acids (DNA, RNA, PNA, etc.) , e.g. oligonucleotides, polynucleotides
  • said products of interest are peptide antigens or inducers of immune responses in the subject to which they are administered, they can therefore be used in the preparation of (monovalent, bivalent or polyvalent) vaccines against animal and human disease caused by viruses, bacteria, parasites or any other types of microorganisms or against tumor diseases, etc.; in another particular embodiment, said product of interest is a molecule with biological activity, e.g. a drug, a peptide, an antibody or a functional fragment thereof, a hormone, an enzyme, etc.; in a particular embodiment, said product of interest comprises lipidized tissue factor or a functional variant thereof for the treatment of hemorrhages, etc.
  • the invention relates to the use of the NCs of the invention formed by the assembly of the fusion protein (I) of the invention as a carrier for products of interest or as a vector in gene therapy.
  • the NCs of the invention are formulated with pharmaceutically acceptable carriers and excipients.
  • the term "subject” relates to a member of a mammalian species and includes, but is not limited to, domestic animals, primates and humans; the subject is preferably a male or female human being of any age or race.
  • the invention relates to a pharmaceutical composition
  • a pharmaceutical composition comprising a loaded NC of the invention together with a pharmaceutically acceptable excipient.
  • said pharmaceutical composition is a
  • (mono- or polyvalent) vaccine comprising a therapeutically effective amount of loaded NCs of the invention together with, optionally, one or more pharmaceutically acceptable excipients and/or adjuvants.
  • Said vaccine can be used to protect animals
  • said pharmaceutical composition is a composition intended for its use in gene therapy.
  • the expression "therapeutically effective amount” relates to the amount of NCs of the invention, calculated to cause the desired effect and will generally be determined, among other causes, by the typical characteristics of the NCs of the invention used and the therapeutic effect to be achieved.
  • compositions provided by this invention are known by the persons skilled in the art and are usually used in the preparation of pharmaceutical compositions .
  • the pharmaceutical composition of the invention can be presented in any suitable form of administration, typically in the form of a suspension, and can be administered by any suitable method, for example, parenterally, etc., for which it will include the pharmaceutically acceptable excipients necessary for formulating the desired form of administration.
  • the formulations can be single-dose formulations and can be prepared according to classic Galenic methods.
  • the auxiliary substances, carriers and excipients used must be pharmaceutically and pharmacologically tolerable, they must be able to be combined with other components of the formulation and must not exert any adverse effect on the treated subject.
  • a review of the different dosage forms for administering medicinal products and of the excipients necessary for obtaining them can be found, for example, in "Tratado de Farmacia Galenica", C. Fauli i Trillo, 1993, Luzan 5, S. A. Ediations, Madrid.
  • said pharmaceutical composition is prepared in the form of an aqueous solution of suspension in a pharmaceutically acceptable diluent, such as saline solution, phosphate buffered saline solution (PBS) , or any other pharmaceutically acceptable diluent.
  • a pharmaceutically acceptable diluent such as saline solution, phosphate buffered saline solution (PBS) , or any other pharmaceutically acceptable diluent.
  • PBS phosphate buffered saline solution
  • the vaccine provided by this invention is administered parenterally, for example, intraperitoneally, subcutaneously, etc.
  • the dose of active ingredient (NCs of the invention) to be administered to a subject will be a therapeutically effective amount and can vary within a wide range .
  • the pharmaceutical composition provided by this invention can be administered once or more times a day for preventive or therapeutic purposes.
  • the dose of active ingredient to be administered will depend on a number of factors, including the characteristics of the product to be administered, such as for example, its activity and biological half-li f e , the concentration of the product i n the pharmaceutical composition, the clinical condition of the subject, the severity of the pathology, the chosen pharmaceutical dosage form, etc.
  • the pharmaceutical composition provided by this invention can contain either a single type of NCs of the invention or two or more different NCs of the invention together with one or more pharmaceutically acceptable excipients or carriers .
  • said pharmaceutical composition comprises a single type of NCs of the invention.
  • said pharmaceutical composition comprises two or more NCs of the invention.
  • the pharmaceutical composition provided by this invention if desired, can be used together with other drugs for the purpose of increasing the efficacy of the pharmaceutical composition provided by this invention, a combination therapy thus being generated.
  • Said additional drugs can form part of the same pharmaceutical composition or, alternatively, they can be provided as a separate pharmaceutical composition for its administration at the same time (simultaneous administration) as the pharmaceutical composition of the invention or at different times (sequential administration) with respect to the administration of the pharmaceutical composition provided by this invention.
  • the NCs of the invention can be contained in an inert medium, i.e. in a medium that does not substantially affect their stability, for example, in an aqueous medium such as saline solution, phosphate buffered saline solution (PBS) , etc. Therefore, in another aspect, the invention relates to a composition comprising an NC of the invention and an inert medium.
  • NCs nanocarriers
  • RPAs conjugates or recombinant protein adapters
  • SEQ ID NO: 1 amino acid sequence of which is formed by the contiguous amino acid sequence comprised between residue 1 and residue 452 of the IBDV protein VP2
  • SAP protein VP2_452
  • rBVs recombinant baculoviruses
  • HF HighFive
  • mice mice were maintained in TClOO medium (Gibco-BRL) supplemented with 10% fetal serum (Gibco-BRL) .
  • the cultures used for producing recombinant protein mAV_NANP were, after the infection with recombinant baculovirus rBV mAV NANP, maintained in Schneider' s medium (Sigma) without biotin and not supplemented with fetal serum.
  • S. cerevisiae strain YPH499 (Stratagene) were maintained and grown according to the previously described protocol (Garriga et al . , 2006) .
  • Plasmid pFB_SAP Plasmid pFB_SAP.
  • Gene SAP SEQ ID NO: 6
  • Bap 1 SEQ ID NO: 7
  • Bap 4 Bap 4
  • the resulting DNA product was purified from an agarose gel and subjected to digestion with enzymes Ndel and BamHI .
  • pFB_SAP plasmid
  • Plasmid pFB_SAP_BAP Chimeric gene SAP_BAP (SEQ ID NO: 5) was constructed by means of PCR using, respectively, 2 pairs of primers: Bap 1 (SEQ ID NO: 7) and Bap 2 (SEQ ID NO: 9) ; and Bap 3 (SEQ ID NO: 10) and Bap 4 (SEQ ID NO: 8) . Purified DNA corresponding to plasmid pFB_SAP was used as a template.
  • the resulting DNAs were isolated from agarose-TBE gels (TBE: 89 mM Tris, 89 mM boric acid, 2 mM EDTA (ethylenediaminetetraacetic acid) , precipitated with isopropanol in the presence of ammonium acetate and resuspended in water. Both DNA fragments were combined in a single tube and subjected to a new PCR round using the primers Bap 1 (SEQ ID NO: 7) and Bap 4 (SEQ ID NO: 8) . The resulting DNA product (685 bp) was purified from an agarose gel and subjected to digestion with enzymes Ndel and BamHI .
  • pFB_SAP_BAP SEQ ID NO: 11
  • Plasmid pFBD_BirA_SAP_BAP Plasmid pFBD_BirA_SAP_BAP .
  • the resulting DNA fragment was digested with restriction enzymes Xhol and Sphl , and cloned, under the transcriptional control of promoter plO, into plasmid pFastBacDual (Invitrogen) digested with the same enzymes.
  • the resulting plasmid, pFastBacDual_Bir A (SEQ ID NO: 15) , was purified and analyzed by means of nucleotide sequencing for the purpose of verifying the correctness of the sequence corresponding to gene BirA.
  • a DNA fragment containing the sequence corresponding to chimeric gene SAP_BAP (SEQ ID NO: 5) was then generated using primers Bap 1 (SEQ ID NO: 7) and Bap4 4
  • a 985 bp DNA fragment containing the sequence encoding gene BirA was then obtained by means of PCR, using primers BirA Lev 1 (SEQ ID NO: 17) and BirA Lev 2 (SEQ ID NO: 18), and plasmid pFBD_BirA_SAP_BAP (SEQ ID NO: 16) as a template.
  • This fragment was digested with enzymes EcoRI and BgIII and inserted in plasmid pESCURA_SAP-BAP digested with the same enzymes to generate plasmid pESCURA_BirA_SAP_BAP (SEQ ID NO: 19) .
  • Plasmid pFB_mAV_NANP Plasmid pFB_mAV_NANP .
  • Chimeric gene mAV_NANP (SEQ ID NO: 20) was synthesized by means of PCR (Genescript Co) .
  • the corresponding DNA contains unique restriction sites BgIII and Hindi I I at its 5' and 3' ends, respectively.
  • the DNA corresponding to chimeric gene mAV_NANP (SEQ ID NO: 20) was subjected to restriction with enzymes BgIII and HindIII and cloned into plasmid pFastBacl (Invitrogen) digested with enzymes BamRI and HindIII.
  • pFB_mAV_NANP The resulting plasmid, pFB_mAV_NANP (SEQ ID NO: 21) , was analyzed by means of nucleotide sequencing for the purpose of determining that the inserted sequence corresponded to the designed chimeric gene mAV_NANP (SEQ ID NO: 20) .
  • rBVs recombinant baculoviruses
  • the recombinant baculoviruses were generated according to the protocol based on the use of bacmids, Bac-to- bac (Invitrogen) .
  • the bacmids obtained were used to transfect HF cells (Invitrogen) .
  • the culture medium of the transfected cells was collected at 96 hours post-transfection and analyzed to determine the viral titer according to the instructions of Invitrogen.
  • NCs derived from the expression of protein SAP_BAP SEQ ID NO: 4.
  • the purifications were carried out from cultures of HF cells infected with the recombinant baculoviruses rBV_SAP_BAP or rBV_FBD_BirA_SAP_BAP.
  • the multiplicity of infection used for all the assays was 1 plaque forming unit (PFU) of rBV_SAP_BAP per cell.
  • the infected cultures were collected at 72 hours postinfection (hpi) and subjected to the previously described purification protocol by means of ultracentrifugation in sucrose gradients (Garriga et al . , 2006) .
  • cerevisiae cult u re s t ran s fo rme d wi th p l a smi d pESCURA_BirA_SAP_BAP (SEQ ID NO: 19) were purified from cultures maintained for 24 hours at 30 0 C.
  • the corresponding samples obtained were analyzed by means of: i) immunoblotting using specific anti-SAP serum (i.e. IBDV anti-VP2 452) according to the previously described protocol (Saugar et al . , 2005); and ii) transmission electron microscopy, after they were stained with 2% diluted uranyl acetate in water.
  • specific anti-SAP serum i.e. IBDV anti-VP2 452
  • transmission electron microscopy after they were stained with 2% diluted uranyl acetate in water.
  • SEQ ID NO: 12 was determined in nitrocellulose membranes. To that end, the purified NCs were separated by means of SDS-PAGE, transferred to cellulose membranes and incubated with a 1/500 dilution of peroxidase-coupled streptavidin (Sigma) . The membranes were then developed by means of incubating with a 0.6 mg/ml solution of the chromogenic substrate l-chloro-4-naphthol diluted in phosphate buffered solution (PBS) in the presence of PBS.
  • PBS phosphate buffered solution
  • NC biotinylation assays The purified NCs were resuspended to a concentration of 5 ⁇ g/ml in Biomix-A biotinylation buffer (50 mM bicine buffer, pH 8.3; 10 mM ATP, 10 mM MgOAc, 50 ⁇ M d-biotin) (Avidity, LLC) in the presence of 50 ⁇ M of biotin and 2.5 ⁇ g of purified biotin ligase (BL) (Avidity, LLC) . The samples were incubated for 30 minutes at 30 0 C.
  • Biomix-A biotinylation buffer 50 mM bicine buffer, pH 8.3; 10 mM ATP, 10 mM MgOAc, 50 ⁇ M d-biotin
  • BL biotin ligase
  • the samples were separated by means of sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) , transferred to the cellulose membranes and incubated with a 1/500 dilution of peroxidase- coupled streptavidin (Sigma) .
  • the membranes were then developed by means of incubating with a 0.6 mg/ml solution of the chromogenic substrate l-chloro-4-naphthol diluted in phosphate buffered solution (PBS) in the presence of 0.15% H 2 O 2 .
  • PBS phosphate buffered solution
  • H5cells E. coli (strain DH5 ⁇ ) ] , grown in TClOO medium supplemented with 10% fetal serum, were washed 3 times with Schneider' s medium and infected with recombinant baculovirus rBV/FB mAV NANP. The supernatant of the cultures was collected at 72 hpi and, after eliminating the cell remains by means of centrif ugation (10, 000xg for 15 minutes) , it was used to determine the presence of protein mAV_NANP (SEQ ID NO: 23) .
  • the membranes were incubated with rabbit anti-avidin serum (Sigma) and developed by means of incubating with goat IgG anti-rabbit IgG peroxidase- conjugate (Sigma) followed by an incubation with 0.6 mg/ml 1- chloro-4-naphthol diluted in PBS in the presence of 0.15% H 2 O 2 .
  • NC Production of Nanocarriers (NC) 1.1 Genetic modification of a self assembly protein (SAP) by means of introducing the sequence corresponding to the biotin acceptor peptide (BAP)
  • SAP self assembly protein
  • SAP self assembly protein
  • the modifications introduced must meet two essential requirements: i) the introduction of the heterologous sequences should not alter the self assembly capacity of said SAP; and ii) the heterologous sequences introduced should be located in a region of said SAP accessible for the solvent in the NCs.
  • an in-depth study of the atomic structure of said previously described SAP (Garriga et al . , 2006) (Protein Data Bank accession no. 2GSY) was conducted by means of using t h e U C S F C h i m e r a c o m p u t e r p r o g r a m (http://www.cgl.ucsf.edu/chimera/) .
  • the nucleotide sequence corresponding to the BAP was inserted by means of PCR using "megaprimers” according to the methodology described in the Materials and Methods section.
  • SAP_BAP The genetically modified gene SAP, called SAP_BAP (SEQ ID NO: 5) was cloned into insertion vector pFastBacl , under the transcriptional control of promoter pPH, and analyzed by means of nucleotide sequencing to verify the correctness of the generated sequence.
  • the plasmid obtained [pFB_SAP_BAP (SEQ ID NO: H) ] was used to produce the recombinant baculovirus (rBV) called rBV/FB SAP BAP according to the protocol described in Materials and Methods.
  • chimeric protein SAP_BAP (SEQ ID NO: 4) maintains the self assembly capacity described for the parental protein SAP (SEQ ID NO: 1)
  • cultures of insect cells were infected with rBV/FB_SAP_BAP .
  • the cultures were collected at 72 hpi and subjected to the purification protocol based on ultracentri fugation in sucrose gradients for NCs described in the Materials and Methods section.
  • the samples collected during the fractionation of the gradients were analyzed by means of SDS-PAGE and immunoblotting using specific anti-SAP serum (IBDV anti-pVP2) (Martinez-Torrecuadrada et al . , (2000), Fernandez-Arias et al .
  • the antiserum used to detect the presence of a protein with an electrophoretic mobility of approximately 43 kDa the molecular mass of protein SAP_BAP is 50 kDa in the upper region (top) of the gradient, where the NCs must be located (Saugar et al . , 2005) .
  • the samples corresponding to this area of the gradient were dialyzed against a PES buffer (25 mM PIPES, pH 6.2, 150 mM NaCl, 20 mM CaCl 2 ) , deposited on grids for electron microscopy, stained with uranyl acetate and viewed by means of transmission electron microscopy.
  • the selected samples contain macromolecular assemblies with a size and morphology similar to the previously described NCs (Saugar et al . , 2005) .
  • a corollary of these results is the demonstration of the possibility of genetically modifying, by means of introducing heterologous sequences, the gene encoding protein SAP (SEQ ID NO: 1) without altering its self assembly capacity.
  • NCs were purified according to the methodology described in previous section 1.3.
  • the purified NCs from insect cells infected with recombinant baculovirus rBV/ FB_SAP_BAP were incubated with biotin in the presence ( + ) or absence (-) of purified biotin ligase (BL) enzyme [occasionally identified in this description as protein BL (biotin ligase) ] according to the protocol described in the Materials and Methods section.
  • BL biotin ligase
  • NCs obtained by means of the expression of gene SAP SEQ ID NO: 6
  • rBV_FB_SAP rBV_FB_SAP
  • Figure 5A the samples were analyzed by means of SDS-PAGE and stained with Coomassie blue
  • Figure 5B the membranes were developed by means of immunoblotting using anti-SAP serum (Martinez-Torrecuadrada et al. , (2000) , Fernandez-Arias et al . , 1998) ( Figure 5B) or incubated in the presence of peroxidase-coupled streptavidin
  • NC_SAP_BAP recombinant baculovirus rBV/FB_SAP_BAP
  • NC_SAP_BAP recombinant baculovirus rBV/FB_SAP_BAP
  • BL biotin ligase
  • Figure 5C shows that the single protein which can specifically bind the streptavidin-peroxidase complex is protein SAP_BAP (SEQ ID NO: 4) previously incubated with biotin in the presence of protein BL (lane 2) .
  • This result shows, in a conclusive manner, that the NCs produced by means of the expression of chimeric protein SAP_BAP (SEQ ID NO: 4) subjected to in vitro biotinylation by means of incubation with protein BL, can specifically interact with the streptavidin-peroxidase complex.
  • the infected cultures were collected and subjected to the purification protocol for NCs by means of ultracentrifugation in sucrose gradients (Materials and Methods) .
  • the samples from the gradients were analyzed by means of SDS-PAGE and immunoblotting using anti-SAP serum (IBDV anti-pVP2) (Martinez-Torrecuadrada et al . , (2000) , Fernandez-Arias et al . , 1998) .
  • the gradient contains a protein with the expected molecular mass, specifically recognized by the anti-SAP serum.
  • fusion protein SAP_BAP SEQ ID NO: 4
  • SEQ ID NO: 4 A sample containing a mixture of the gradient fractions with a larger content of fusion protein SAP_BAP (SEQ ID NO: 4) was subjected to SDS-PAGE and transferred to nitrocellulose. The corresponding membrane was incubated in the presence of peroxides-coupled streptavidin and developed in the presence of l-chloro-4-naphthol for the purpose of determining the capacity of fusion protein SAP_BAP (SEQ ID NO: 4) to specifically bind to streptavidin. As shown in Figure 6B, fusion protein SAP_BAP (SEQ ID NO: 4) expressed in the presence of the BL enzyme specifically binds the streptavidin-peroxidase complex.
  • RPAs recombinant proteins adapters
  • the experimental strategy for producing RPAs was based on the development of systems allowing the expression of hybrid molecules formed by the fusion of: i) a protein domain providing the capacity to bind to biotin; and ii) the amino acid sequence corresponding to the protein (or proteins) of interest which are to be coupled to the NCs.
  • a chimeric gene called mAV_NANP SEQ ID NO: 20
  • Figure 7 was designed and synthesized, formed by the region encoding a mutant form of the avidin protein (G. gallus) (Laitinen et al .
  • mAV_NANP nucleotide sequence encoding 6 consecutive repetitions of the NANP peptide (SEQ ID NO: 22) followed by a stop codon (TAA) , after which a multiple cloning site (MCS) was introduced in its terminal 3' region.
  • SEQ ID NO: 22 nucleotide sequence encoding 6 consecutive repetitions of the NANP peptide
  • TAA stop codon
  • MCS multiple cloning site
  • the synthesized chimeric gene contains unique restriction sites BgIII and HindIII in its 5' and 3' ends, respectively.
  • Plasmid pFB_mAV_NANP (SEQ ID NO: 21) , the construction of which is detailed in the Materials and Methods section, was used to generate the rBV called rBV/FB_mAV_NANP .
  • This rBV was used to infect H5 cells [E. coli (strain DH5 ⁇ ) ] .
  • the supernatant of the cultures was collected at 72 hpi and, after eliminating the cell remains, it was analyzed by means of SDS-PAGE and immunoblotting using specific anti-avidin serum.
  • the supernatant (SN) of the cultures infected with rBV/FB_mAV_NANP (SN+) contains a protein with the expected electrophoretic mobility (19.5 kDa) for the chimeric secretion protein mAV_NANP
  • pFB_mAV a universal vector universal for producing RPAs
  • pFB_mAV_NANP SEQ ID NO: 21
  • the nucleotide sequence of this new 5,228 nucleotide construct contains unique restriction targets BgIII (nucleotides 1-6) and HindIII (nucleotides 712-717) for cloning heterologous sequences into vector pFB_mAV (SEQ ID NO: 24) .
  • the NCs were incubated with the BL enzyme in the presence of absence of biotin.
  • the samples were deposited on sucrose cushions (25% in PES buffer [ (25 mM PIPES pH 6.2, 150 mM NaCl, 20 mM CaCl 2 ] ) and centrifuged (27, 000 rpm in a SW40rotor [Beckman] for 2 hours) .
  • the sediments were then collected, resuspended in PES buffer and incubated with supernatants of cultures of insect cells containing or not containing the recombinant protein mAV_NANP (SEQ ID NO: 23) .
  • the samples thus prepared were incubated at room temperature for 30 minutes. They were then subjected to centrifugation on sucrose cushions, as described above, for the purpose of eliminating the protein that is not coupled to the NCs.
  • the resulting sediments were resuspended in PES buffer and analyzed by means of SDS-PAGE and immunoblotting using specific anti-avidin and anti-SAP serums.
  • NC-biot biotinylated NCs
  • SN+ mAV_NANP
  • mAV_NANP protein mAV_NANP
  • Varsani A Williamson AL, de V Amsterdam D, Becker I, Christensen ND, Rybicki EP.
  • Chimeric human papillomavirus type 16 (HPV-I 6) Ll particles presenting the common neutralizing epitope for the L2 minor capsid protein of HPV-6 and HPV-I 6. J Virol. 2003. 77:8386-93.
  • Barker DF Campbell AM.
  • the birA gene of Escherichia coli encodes a biotin holoenzyme synthetase. J MoI Biol. 1981. 146:451-67.
  • Parrott MB Barry MA. Metabolic biotinylation of secreted and cell surface proteins from mammalian cells. Biochem Biophys Res Commun. 2001. 281:993-1000.

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Abstract

L'invention porte sur des nanosupports formés par des assemblages de protéine obtenus au moyen de l'assemblage d'une protéine d'autoassemblage modifiée génétiquement de façon à coupler des produits d'intérêt liés à un ligand. Ces nanosupports de protéine peuvent être utilisés comme système pour supporter et présenter des produits d'intérêt.
EP09712586A 2008-02-19 2009-02-19 Nanosupports de protéine, leur procédé d'obtention et applications Withdrawn EP2254993A1 (fr)

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PCT/EP2009/051951 WO2009103752A1 (fr) 2008-02-19 2009-02-19 Nanosupports de protéine, leur procédé d'obtention et applications
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JP5795319B2 (ja) * 2009-11-06 2015-10-14 チャイメラ ファーマ エス.エル.ユー.Chimera Pharma S.L.U. ヒトパピローマウイルス抗原を含むビルナウイルスのウイルスカプシドに基づく腫瘍形成を処置するためのワクチン
EP2505640A1 (fr) * 2011-03-29 2012-10-03 Neo Virnatech, S.L. Compositions de vaccins pour maladies provoquées par le birnavirus
WO2014008475A2 (fr) * 2012-07-05 2014-01-09 The Ohio State University Compositions et procédés associés à des vaccins viraux
US10086062B2 (en) 2012-07-05 2018-10-02 Ohio State Innovation Foundation Infectious pancreatic necrosis virus (IPNV) vaccine compositions
WO2014126260A1 (fr) * 2013-02-18 2014-08-21 味の素株式会社 Procédé de production d'une protéine par précipitation
KR20200108514A (ko) * 2015-09-17 2020-09-21 코다 바이오테라퓨틱스 인코포레이티드 신경 장애를 치료하기 위한 조성물 및 방법
CN108802366B (zh) * 2017-05-04 2020-01-21 中国科学院微生物研究所 一种检测待测样本中目标蛋白的含量的方法

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AU2002248297A1 (en) * 2001-01-05 2002-07-16 Children's Hospital, Inc. Aav2 vectors and methods
FR2824327B1 (fr) * 2001-05-02 2003-07-11 Agronomique Inst Nat Rech Particules pseudovirales de birnavirus
ES2310062B1 (es) * 2005-07-15 2009-11-13 Bionostra, S.L. Particulas pseudovirales vacias quimericas derivadas del virus causante de la enfermedad de la bursitis infecciosa (ibdv), procedimiento de obtencion y aplicaciones.
CA2621466A1 (fr) * 2005-09-08 2007-04-05 Kentucky Bioprocessing, Llc Particules virus mosaique du tabac modifiees utilisees comme supports pour la disposition d'antigenes proteiques pour des applications de vaccins

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