Classifications

• • C—CHEMISTRY; METALLURGY
  • C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
  • C12Q—MEASURING OR TESTING PROCESSES INVOLVING ENZYMES, NUCLEIC ACIDS OR MICROORGANISMS; COMPOSITIONS OR TEST PAPERS THEREFOR; PROCESSES OF PREPARING SUCH COMPOSITIONS; CONDITION-RESPONSIVE CONTROL IN MICROBIOLOGICAL OR ENZYMOLOGICAL PROCESSES
  • C12Q1/00—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions
  • C12Q1/68—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions involving nucleic acids
  • C12Q1/6804—Nucleic acid analysis using immunogens
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
  • G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
  • G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
  • G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
  • G01N33/53—Immunoassay; Biospecific binding assay; Materials therefor
  • G01N33/543—Immunoassay; Biospecific binding assay; Materials therefor with an insoluble carrier for immobilising immunochemicals
  • G01N33/54306—Solid-phase reaction mechanisms

Definitions

• the present invention provides for uses of a nanoparticle or a virus or virion, preferably a bacteriophage, for providing control in an immunoprecipitation reaction with a recognition molecule, wherein an epitope peptide is displayed on said nanoparticle or virus or virion and recognized by said recognition molecule in the immunoprecipitation reaction.
• the nanoparticle carries a nucleic acid comprising a sequence encoding said epitope.
• the immunoprecipitation is chromatin immunoprecipitation (ChIP).
• IP Immunoprecipitation
• Co-IP co-immunoprecipitation
• Conventional IP protocols start with cell lysis or tissue homogenisation under denaturing (or non-denaturing) conditions for protein extraction, continued by sample pre-cleaning to exclude non-specific interactions.
• capture of the antigen e.g. specific protein
• an insoluble resin such as agarose or magnetic beads in the form of an antibody complex in solution. This is followed by precipitation of the complex by centrifugation or magnetic field.
• Detection of the antigen is then typically achieved by Western blotting using labelled specific antibody, or an unlabelled specific antibody together with a labelled secondary antiimmunoglobulin antibody (or via detection of the enzymatic activity of the specific protein).
• Any antibody based detection method e.g. ELISA can be used, however, for analysis of the antigens.
• Chromatin immunoprecipitation is a method to study protein-DNA interactions, typically in-vivo interactions. The method is one of the most important functional genomic methods that had a significant impact on the development of the field of epigenetics.
• the sample used in ChIP is typically cell lysate. Upon sample preparation relatively small fractions of the chromatin of the cells are obtained having the chromatin associated protein binding to the chromatin DNA. Quite often the sample is fixed by using a crosslinker as fixative. In general, besides chromatin, any protein binding nucleic acid, either DNA or RNA can be studied based on the same principles.
• the purification step is carried out by using specific antibodies that recognize a specific epitope of a nucleic acid binding protein.
• the antibodies are bound to beads, e.g. beads covered by protein A or protein G or protein A/G.
• this method it is possible to purify (precipitate) complexes that contain specific nucleic acid fragments, preferably DNA fragments associated with the protein recognized by the antibody.
• the output of the procedure is the purified nucleic acid.
• the researcher analyzes the nucleic acid, e.g. DNA to identify the regions where the nucleic acid binding proteins bind.
• the nucleic acid binding proteins are chromatin-associated proteins which bind to the chromatin in vivo and these regions are to be identified.
• the sample used in ChIP is typically cell lysate, wherein nucleic acid - protein complexes as well as protein - protein complexes are cross-linked with formaldehyde as fixative.
• a result of cross-linking is that protein complexes bound to the nucleic acid are held together.
• chromatin is sheared by sonication to obtain smaller fragments which can be analysed.
• chromatin is digested by nucleases. In this latter version crosslinking is sometimes omitted (native ChIP).
• the isolated DNA or other nucleic acid should be ready for downstream analysis by methods such as PCR- or qPCR-based assays, or parallel DNA sequencing. Alternatively; protein based detection methods, applicable in traditional immunoprecipitation, e.g. ELISA are also available or can be used in parallel here.
• Negative controls like i) a lysate of cells not containing the antigen, ii) immunoprecipitation with unrelated or non-immune antibody.
• IP buffers
• a kind of positive control can be e.g. an aliquot taken from the chromatin before preclearing or antibody binding (input control). If the chromatin sample is obtained after crosslinking it is decrosslinked and DNA (or nucleic acid) is isolated. This nucleic acid (e.g. DNA) sample can be analysed. For example, if PCR is used for analysis, it should yield a PCR product with all primer sets used. Besides serving as a positive control, the data derived from the input sample can be used for data normalization [see e.g. Haring M. et a.. Chromatin immunoprecipitation: optimization, quantitative analysis and data normalization Plant Methods 2007, 3: 1 1.].. A non-immunoprecipitated chromatin control (input control) is recommended as a reference control both in case of PCR analysis and DNA sequencing analysis of the chromatin.
• input control is recommended as a reference control both in case of PCR analysis and DNA sequencing analysis of the chromatin.
• an antibody that consistently binds chromatin-associated proteins under a wide variety of cellular conditions.
• Antibodies against heterochromatin markers like H3- K9Me3 H3K4me3 (trimetylated Lys 9 and Lys 4 of histone H3) or markers which are associated with actively transcribed regions (like H3-K9Ac, ie.
• acetylated Lys 9 of H3 often associated the c-Fos gene [MAGnifyTM Chromatin Immunoprecipitation System Catalog no: 49-2024, 27 January 201 1 ; McEwen KR and Ferguson- Smith AC “Distinguishing epigenetic marks of developmental and imprinting regulation", Epigenetics & Chromatin 2010, 3:2].
• the negative control can be a chromatin sample to which non-specific control serum is added instead of a specific antibody (no antibody or ' oAb control sample, cf. e.g. Haring M. et al, 2007, infra).
• the negative control samples are treated the same way as the CMP samples.
• the QPCR signals resulting from the NoAb samples indicate the amount of background signal generated by the chromatin preparations and ChIP procedure. In case of NoAb samples theoretically the washing steps should remove non-specifically bound chromatin, resulting in an absence of signals for the NoAb samples.
• non specific antibodies like Rabbit IgG and Mouse IgG antibodies can be used in a kit for use as negative controls to measure nonspecific binding.
• the present invention relates to the Use of a nanoparticle as a control or for providing control in an imrn hpprecipitatibn reaction carried out with or utilizing a recognition molecule, said nanoparticle comprising a nucleic acid and a polypeptide carrying an epitope; wherein said nucleic acid comprises an oligonucleotide segment, wherein said epitope peptide is displayed oil the surface of the nanoparticle and recognized by said recognition molecule in the immunoprecipitation reaction.
• the nanoparticle is a virus or a virion, preferably a virion.
• the present invention also relates to the use of a virus or a corresponding virion as a control or for providing control in an immunoprecipitation reaction carried put with or Utilizing a recognition, molecule, wherein the genetic material of the virus or virion comprises an oligonucleotide segment, wherein said epitope peptide is displayed by the virion and recognized. by said recognition molecule in the immunoprecipitation reaction.
• the oligonucleotide segment is a traceable oligonucleotide! segment or region or stretch.
• the oligonucleotide in the' microparticle or in the viral genome e.g. said segment encodes said, epitope peptide.
• virus or virion is a bacteriophage.
• the immunoprecipitation reaction according to the invention is nucleic acid immunoprecipitation, preferably direct nucleic acid immunoprecipitation or a nucleic acid— protein complex immunoprecipitation, preferably chromatin'immunoprecipitation.
• the invention also provides for an immunoprecipitation kit, said kit comprising
• a positive control nanoparticle comprising a nucleic acid and a polypeptide carrying an epitope, wherein the nucleic acid comprises. an oligonucleotide segment which. is preferably traceable and/or encodes said.epitope peptide.
• the kit comprises a. recognition molecule recognizing an antigen epitope for use .in immunoprecipitation and as a positive control virus or virion, preferably a bacteriophage, comprising, an oligonucleotide segment in its genome encoding an epitope peptide, wherein said epitope, peptide is displayed by said bacteriophage and.recognized by said recognition molecule in. the immunoprecipitation reaction..
• the kit is for use in nucleic acid immunoprecipitation, preferably ChlP.
• the kit is a part of or is for use together with a kit for nucleic acid immunoprecipitation ⁇ preferably ChlP.
• the use of the kit according to. the invention in any type of immunoprecipitation disclosed or contemplated herein is also considered as the subject matter of the invention.
• kit according to the invention comprises
• a negative- control nanoparticle,, virus and/or virion preferably a bacteriophage, lacking said oligonucleotide and/or the epitope but preferably having; a nucleic acid and a polypeptide, preferably snowing non-specific binding to the recognition molecule
• means for detecting" the binding of said recognition molecule to said antigen epitope preferably means. for amplification of said positive control and optionally said negative. control, support or camer for binding .
• said fec.o ⁇ ition molecule preferably beads, ⁇
• the .kit-comprises as aimeans for amplification, pligonucreotide.primers, preferably
• the kit comprises means for sequencing the nucleic acid or a fragment thereof the antigen or target protein is bound to.
• the kit may comprise a plate haying containers.
• the container may comprise elements of the kit-
• a sample container is used for the analysis of the sample of interest.
• a control container is used for a control experiment.
• assample container and a control container may be identical.
• The-invention also relates to an immunoprecipitation method-said method comprising the steps of
• nahoparticle as a positive control, said nanoparticle, comprising a nucleic acid and a polypeptide carrying an epitope recognized by a recognition molecule in said immunoprecipitation reaction.
• positive control is an epitope presenting system, wherein the nucleic acid comprises an oligonucleotide segment encoding-said epitope peptide, more preferably- said positive control naiipparticle is a virus, or virioiij even.mbre preferably aibacteriophage.
• said epitppe peptide is displayed by the yirtis or " virion arid is. recognized by said recognition molecule in the immunoprecipitation reaction.
• the invention also relates to aii immunoprecipitation method said method comprising the steps of using a naiippafticle as a negative control, said nanoparticle lacking" the polypeptide carrying an epitope recognized by a recognition molecule in said irrlmunoprec pitation reaction. Otherwise the negative control nanoparticle may be identical with or may have the same features as the positive- control nanoparticle.
• the positive control nanoparticle and/or the negative control nanoparticle is/are added to one or more samples from the set of samples in the experiment, i.e. is/are used as a spike control.
• the invention also relates to an inm npprecipitation . method said method comprising the steps .of
• - providing a set of samples, i.e. a multiplicity of samples or at least one sample comprising an antigen or a target protein carrying an epitope
• a positive control, nanoparticle said nanoparticle comprising a nucleic acid and. a polypeptide carrying ' an epitope, wherein the nucleic acid comprises an oligonucleotide segment encoding said. epitope peptide, or alternatively adding a positive control virus or virion, preferably a bacteriophage to one or more samples from • the set of Samples, wherein said positive control vihis or virion, comprising an oligonucleotide' segment ;in its genome encoding an epitope peptide, wherein said epitope peptide is displayed by the virus or virion and is recognized by said recognition molecule in the immunoprecipitation reaction,
• the number of positive control nanoparticles, yifuses or virions and those bound to the recognition molecule are compared and considered as indicative of the imm hoprecipitation reaction, whereas a higher number bound to the recognition molecule indicates a better performed or higher quality of the immunoprecipitation reaction.
• the nanoparticles, viruses or virions bound to the recognition, molecule are recovered and the number of recovered nanoparticleSi viruses or virions is compared to those added previously.
• immunoprecipitation is nucleic acid immunoprecipitation said method further comprising - fragmenting the nucleic acid and/or binding the antigen and thereby those fragments bound by the antigen to the recognition molecule, wherein preferably the recognition molecule is bound to a support or carrier.
• fragmenting the nucleic acid is carried out by sonication and/or by a nucleic acid nuclease, preferably rriicrococcal nuclease.
• the immonprecipitation is nucleic acid immunoprecipitation, preferably selected from chromatin immunoprecipitation (ChlP), DNA immunoprecipitation and RNA immunoprecipitation.
• ChlP chromatin immunoprecipitation
• DNA immunoprecipitation DNA immunoprecipitation
• RNA immunoprecipitation RNA immunoprecipitation
• the nanoparticles, viruses or virions bound or recovered are analysed.
• they are * analysed by QPGR or sequencing, preferably as a part of the detection step.
• the.detection of the-binding of the recognition molecule to the displayed epitope is carried out by
• nucleic acid fragments bound by the antigen to a chip comprising a multiplicity of nucleic acid sequences wherein preferably at least one of them is complementary to a sequence of the nucleic acid, preferably to the sequence encoding the epitope region ⁇ and/or
• an immunological method e.g by-ah immunosorbent assay; e.g. by ELISA.
• the recognition molecule is in the form bound to a support or carrier.
• the recognition molecule is bound to the support or carried before binding of the recognition molecule to the antigen or target protein or thereafter or in the same step, e;g. ,simultaneous y.
• binding of a recognition molecule to the antigen epitope or target protein is also detected.
• the recognition molecule binding to the target protein and to the positive control is identical.
• the invention also relates to a ; multiplicity of rianopafticles, viruses or virions comprising aft oligonucleotide segment- in their genome said segment encoding an epitope peptide of immunogenic portion of a nucleic acid binding protein, wherein.
• said epitope peptide or inimunogenic portion is-displayed by said virions, wherein the peptide or immunogenic portion is 7-20, preferably 8 to 18 amino acids long or 5 to 22 amino acids long, preferably at least 5, 6, 7 or 8 amino acids and at most 10, 11, 12, 13, 14, 16, 18 or 20 amino acids long and -wherein said epitope peptide is capable of binding to a recognition .molecule bound to a carrier, preferably by protein A or protein G or any combination thereof bound to a-carrier:
• the nanoparticles, viruses or virions are essentially identical preferably except in that they differ only in the epitope or in the immunogenic portion and in the nucleic acid sequence encoding said epitopes. or portions.
• the nanoparticles, viruses or virions form a library.
• the library is enriched in several panning steps in members having epitppes or immunogenic portions specifically binding to a recognition ⁇ molecule.
• the invention also relates to a use of a multiplicity of virions comprising an oligonucleotide segment in their genome said segment encoding an peptide, wherein said pepticie is displayed by said virions.
• the; multiplicity of virions is used as a ' .control, in an immunoprecipitation reaction.
• the peptide is an epitope peptide or comprises an epitope or ari.iminunogenic portion.
• the peptide, the epitope or the immunogenic portion is 5-20;, preferably 7 or 8 amino acids long.
• the peptide is capable of binding, preferably via the epitope or the immunogenic portion, to a recognition molecule bound to a carrier, wherein preferably the carrier comprises protein A or protein G or any cpmbinatioh mereofiPreferably, the multiplicity of virions is used as a positive control.
• a further multiplicit o virions are used as a negative control ⁇ said irrjinunopfecipitation ; reactipn said further multiplicity of viripns>comprising an pligpnucleotide»segment in their genome said segment encoding a further peptide, said further peptide lacking said epitope or immunogenic portion.
• the -virions are bacteriophages.
• the immunoprecipitation is chromatin immunoprecipitation.
• Immunoprecipitation is a method comprising binding of an antigen, e g. a protein antigen present in a solution using;a recognition molecule or a multiplicity thereof thatspecifically bind(s) to that particular protein, wherein the recognition.molecule is coupled to a solid substrate at a point of the procedure so that thereby the particular protein, in the form of a complex formed with the recognition 'molecule becomes attached to the solid substrate, in a reaction mixture. This complex is then brought into, a form suitable to be collected from the reaction mixture (precipitation step or: event). This process can be used to isolate and concentrate the particular protein from the solution, e.g. a sample containing 1 different proteins.
• the recognition molecule is preferably an antibody or any fragment or variant thereof.
• Nucleic acid immunoprecipitation is an immunoprecipitation method wherein in an immunoprecipitation (IP) reaction after immunoprecipitation the complex of the antigen and the recognition molecule comprises a nucleic acid.
• IP immunoprecipitation
• a nucleic acid is bound, either directly:or indirectly to the recognition.molecule.
• a direct nucleic- acid immunoprecipitation me antigen is the nucleic acid and the nucleic acid itself is recognized by the recognition molecule, e.g. antibody.
• the recognition molecule recognizes and binds a protein target which in turn binds or is bound to a nucleic acid, e.g. DNA or RNA, either double; stranded orsingle stranded (ds or ss, respecitively).
• GhIP Chromatin immunoprecipitation
• IP Chromatin immunoprecipitation
• a variant of nucleic acid immunoprecipitationis a method to study protein-nucleic acid interactions, typically in-vivo interactions.
• GhIP can be used- to- determine whether a protein interacts with a candidate target nucleic acid, wherein the complex of the recognition molecule and the target protein also comprises a nucleic acid, preferably a nucleic acid fragment bound b the target protein.
• a long nucleic acid either DNA or RNA, e.g. a genomic nucleic acid, typically a chromatin is fragmented and those fragments are obtained by the ChIP method which are bound by the target protein.
• the substrate in an IP reaction e.g. in a ChIP reaction is typically a bead, preferably a bead covered by protein G or protein A or protein A/G.
• a recognition molecule is a macromolecule capable of specific binding to a target, such as a polypeptide or protein through at least one antigen recognition site thereof located in the variable region of the recognition molecule.
• a variable region of a recognition molecule is a region forming, in the native form of the recognition molecule, a molecular surface capable of contacting and binding to the target. Within a set or group of recognition molecules the variable region preferably has a variability significantly higher than other parts of the recognition molecule, i.e. the sequence identity among these sequences within the set or group is typically low.
• the recognition molecule is a protein and the variable region comprises, consists of or essentially consists of amino acids.
• An antibody is a recognition molecule which is an immunoglobulin molecule capable of specific binding to the target through at least one antigen recognition site, located in the variable region of the immunoglobulin molecule.
• the term encompasses not only intact polyclonal or monoclonal antibodies, but also fragments or variants thereof (such as Fab, Fab', F(ab')2, Fv), single chain (ScFv), a monobody, or mutants thereof, fusion proteins comprising, an antibody portion, and any other modified configuration of the immunoglobulin molecule that comprises an antigen recognition site or artificial variants thereof.
• An antibody includes an antibody of any class, such as IgG, IgA, or IgM (or sub-class thereof), and the antibody need not be of any particular class.
• the subunit structures and three-dimensional configurations of different classes of immunoglobulins are well known in the art.
• An epitope is a patch or site on a target, such as a polypeptide or protein molecule, preferably a part of its molecular surface, to which a recognition molecule preferably an antibody or the binding region thereof can specifically bind.
• a target such as a polypeptide or protein molecule, preferably a part of its molecular surface, to which a recognition molecule preferably an antibody or the binding region thereof can specifically bind.
• an epitope according to the invention is a linear epitope consisting of 5 to 22 amino acids, preferably at least 5, 6, 7 or 8 amino acids and at most 10, 11 , 12, 13, 14, 16, 18 or 20 amino acids.
• a mimotope of an epitope is a patch or site on a target molecule, preferably a part of its molecular surface, to which the same recognition molecule or antibody or the binding region thereof can bind as to the corresponding epitope.
• a mimotope can be developed e.g. by selection from peptide libraries preferably using a display method or by protein engineering methods e.g. combined with in silico molecural design.
• a mimotope is understood herein as a kind . of epitope.
• a nanoparticle as understood herein is typically a particle having one or more dimensions of the order of 700 nm or less or 500 nm or less or 300 nm or less or 200 run or less or 100 nm or less, said nanoparticle comprising; consisting of or consisting essentially of a nucleic acid and a polypeptide carrying an epitope or a mimotope and optionally a carrier or a coat or envelope thereof.
• the polypeptide may, at least partly, sourround or cover the nucleic acid or may be stably attached thereto or both the nucleic acid and the polypeptide may be attached to the carrier or coat or envelope.
• Preferablyj but. not necessarily at least a part of the polypeptide pr protein is encoded by said nucleic acid said, part comprising the epitope.
• the nanoparticle is syntetic or artificial.
• the nanoparticle is a virus or virion.
• a virion as understood herein is a particle of an infectious agent that can replicate inside the Hying cells of an organism only, said particle consisting of or essentially consisting of or comprising nucleic acid surrounded by a protein shell or a protein coat sometimes with external envelope formed e.g. by lipids, wherein at least a part of the protein shell or coat or the envelope is encoded by said nucleic acid.
• Virions can infect various types of . ⁇ organisms, from animals and plants to bacteria and archaea.
• A. virion is preferably a nanoparticle.
• a virion is ' preferably a form of a virus capable of infecting a living cell.
• a virus- is understood herein as any form of an agent that can replicate inside one or more living cells of an organism only, either in itself or together with or by the help of a further nucleic acid within the same cell.
• a virus has a nucleic acid which can be replicated in the cell and either in itself or together with the further nucleic acid.encodesVproteins of a virion.
• A. bacteriophage is a virus of preferably a virion that infects bacteria by injecting its genetic material, which is carried enclosed in an outer protein capsid.
• the genetic material of a bacteriophage can be ssRNA, dsRNA, ssDNA, or dsDNA (wherein 'ss-' or 'ds-' prefix denotes 'single-strand or double-strand) along with either circular or linear arrangement).
• An epitope or peptide is displayed on the surface of a.molecule when it is brought, or present in a form suitable to be recognized and bound by a target molecule ⁇
• the recognition preferably the specific, recognition of a target by a recognition molecule is an event or 'series of events, where the target is contacted with the recognition molecule, and the strength of the interaction between them is higher, than that of the strength interaction, e.g. affinity or avidity, which might formed or is formed between the same recognition molecule and. at. least one - preferably more than one - different target(s) and the recognition;molecule under same or similar conditions.
• Positive control in an IP e.g. in a GhlP reaction is a control substance or agent which, when added to the reaction mixture is indicative of the actual presence of the target in, the solution or the actual occurrence of an immunoprecipitation event.
• An input control is a kind of positive control in the IP method, preferably in the ChlE reaction, comprising a broad range of target molecules, preferably obtained from the solution before carrying out the immunprecipitation step and being suitable to be analyzed e.g. for detecting the. target.
• a GhlP reaction the nucleic acid, e.g. chromatin is obtained and analyzed, for the presence of the target sequence.
• a spike control is a control added to the IP reaction, mixture before and being present during the immunoprecipitation step, wherein the, formation of a complex between the spike control as a target and the recognition molecule.can be detected.
• Negative control is a control without the presence of a target and/or without the presence of the recognition molecule thereby being: indicative of the not specific recognition and binding during an IP or ChIP method.
• the nucleic, acid in. the control, according to the invention is typically traceable- which is to be understood herein that its presence can be detected or monitored, preferably quantitatively detected or measured, by any methods
• the nucleic acid can be detected and preferably its level or quantity measured among others by PGR, sequencing methods, hybridization methods e.g. on a chip, ligation methods, fluorescent marker methods or a combination, thereof.
• PGR sequencing methods
• hybridization methods e.g. on a chip
• ligation methods e.g. on a chip
• fluorescent marker methods e.g.
• FIG. 1 HDAC l monoclonal antibody immunogen epitope peptide (P4) coding sequence and P4-M13 E phage vector construct.
• FIG. 2 Schematic structure of the theoretical P4-M13 E phage displaying the P4 peptide.
• the recombinant filamentous M13 phage was generated .in E. coli ER2738 strain via electroporation of the- double stranded M13KE vector containing the nucleotide sequence encoded for the P4 peptide subcloned in a way which. allows the N-terminal fusion of the peptide to the genelll protein (minor coat protein).
• the mature phage is assembled within the cells from the positive strand of the vector construct (single-stranded form, ssDNA, consisting of 7222 bases) and from coat proteins, that is the major gene VIII protein ( ⁇ 2700 copies), and the minor gene VI, geneVII, genelX. proteins, and the P4-geneIII fusion protein (3-5 copies).
• the recombinant P4-M13KE phage therefore displays the P4 peptide on its surface and is physically linked to its encoding DNA.
• Figure 3 Capillary sequencing of P4-M13KE clones.
• the sequence of the negative (antisense) strand of the P4-M13 phage DNA was obtained using -96 sequencing primer. Eagl site (CGG CCG); position 81-86; P4 peptide reading frame: position 88-135;
• Acc65I site (GGT ACC): 52-57; M13KE genlll start codon (CAC): 187-189.
• Figure 4 P4 Specific QPCR assay used for screening. A. Outline of the design. B. Sequences and melting temperatures.
• FIG. 7 Results of the pirosequencing on a 454 Junior system of the the phage libraries. Conservation, quality and Consensus are shown for the first 100 analysed sequences from Second round of panning with MECP2 antibody.
• FIG. 8 A. Results of the pirosequencing on a 454 Junior system of the the phage libraries. Conservation, quality and Consensus are shown for the first 100 analysed sequences from Second round of panning with p300ntibody. B. Conservation, quality and Consensus are shown for the first 100 analysed sequences from third round of panning with p300 antibody Data were analyzed with Mimox software as described in the results ' section. C. ChIP recovery of the libraries generated by three rounds of panning. Same input of one million phages were recovered as described and measured by qPCR relative quantitation method. Results from round twp and three of panning are shown for both MEGP2 and P300 antibodies.
• FIG 9 The mimotope quality scores and the ChIP recovery of the phage libraries.
• A. Quality scores for individual positions in the analyzed libraries as calculated by Mimox software.
• B. Sum of the Mimox quality scores of the two different antibody selected libraries and rounds two and three of the selection respectively.
• Figure 10 Amino Acid conservation scores for third round of phage library selection performed with MEGP2 and P300 antibodies respectively.
• FIG. 12 Mapping of histone modifications by ChIP Seq. Histone H3 K27 acetylation is mapped on technical replicates. The region of the mouse FABP4 gene is shown. ChIP Seq analysis was performed on an Illumina sequencing instrument.
• Figure 13 Fragment size distribution after incomplete sonication (partial fragmentation). If sonication is done till mononucleosomal fragments, large protein complexes might be disrupted and this is reducin significantly the efficiency of ChIP for transcription factors.
• Figure 14 DNAse based fragmentation of chromatin (A) Fragment size distribution of the Agilent Bioanalyzer size marker (B) Fragment size distribution shown on gel like representation of the Agilent Bioanalyzer results.
• First column shows the marker presented in panel A.
• Second column is the DNA isolated withour Micrococcal nuclease digestion. Columns three to 9 is showing digestion with Micrococcal nuclease in a three fold dilution curve. Digestion was performed for 15 minutes at 37 degree Celsius.
• the present inventors discovered a method that can be used to create spikes that have similar properties to the protein: DNA complex that is investigated in the chromatin immunoprecipitation method.
• The; method is based on the use of an epitope presenting system as a control.
• the epitope presenting system is useful as a positive control comprising a given epitope or a negative control lacking it.
• the epitope presenting system can be a multiplicity of nanoparticles having a polypeptide comprising and a nucleic acid encoding an epitope.
• the epitope presenting system is preferably viruses encoding and presenting an epitope, preferably bacteriophages.
• An appropriate positive control should show for the laboratory operator that the experiment performed well from technical point of view.
• a negative control defines a background for the measurement. The difference between the signal measured by the positive control assay and the negative control one should give an information about the dynamic range of the reaction.
• controls of the invention comprise both an epitope of an appropriate target and a nucleic acid, wherein the nucleic acid. is traceable.
• the control microparticle of the invention is bound to the recognition molecule, e.g. antibody of interest and precipitated; in principle the same way as the target protein or antigen itself. Therefore, for example in a ChIP experiment they work a very similar way to chromatin itself.
• This feature can be utilized at several levels of quality control including the IP reaction, itself to detection by modern techniques like QPCR, ChlP-on-a-chip (ChlP-chip) and ChlP-sequencing (ChIP Seq or ChlP-seq).
• the nucleic acid comprises a sequence encoding the epitope and therefore the epitope coding sequence itself provides a possibility to detect or trace the control, i.e. in this case a positive control or, in case of a negative control, the absence thereof.
• the present inventors have developed a positive control for the whole procedure that is able to monitor the performance of the method.
• the phage carries at its surface an epitope which is bound by the recognition molecule, preferably, same peptide that was used to generate an antibody or a mimotope thereof.
• phage display methodology is used to provide the controls of the invention.
• Peptide phage display technology involves expressing peptides in fusion with viral coat proteins, thereby displaying the peptides on the surface of the phage.
• peptide coding DNA sequence which is cloned into the phage genome, is also encapsulated in the whole phage as single stranded DNA, this allows identification of the peptide via nucleotide sequencing of the corresponding ' coding region.
• a recombinant phage displaying the epitope peptide of the monoclonal antibody used will allow ' to use such a phage as a control.
• a mixture of phages could be used to monitor the performance of the immunoprecipitation reaction.
• the phage can express the same peptide that was used to generate the antibody.
• the positive control according to the invention is useful as a spike control, i.e. the virion can be added to the immunoprecipitation reaction , mixture and be present during the immunoprecipitation experiment, thereby duly reporting on the performance thereof.
• a phage can be added to the chromatin sample as a spike and the level of the immunoprecipitated phage monitored in the purified DNA after the ChIP reaction.
• any virus capable of presenting an epitope and encoding the same epitope in its genome is suitable as a positive control in the present invention.
• a phage can be used that is not encoding the investigated peptide.
• This spike will show the non-specific binding of the phage to the plastic ware, the beads, or the antibodies used in the procedure, i.e; the background noise or signal.
• QPCR quantitative PCR
• a QPCR assay that is specific to the phage system will also provide good quantitative data about the enrichment of the phages based spikes' by immunoprecipitation.
• the epitope presenting system is a nanoparticle consisting of or essentially consisting of or comprising a nucleic acid and a polypeptide or a protein carrying an epitope and optionally a carrier, wherein at least a part of the polypeptide or protein is encoded by said nucleic acid said part comprising the epitope.
• the epitope is also coded. within the nucleic acid.
• Nanoparticles manufactured according to the art can be used, therefore, to carry a nucleic acid and, on their surface, an epitope or a polypeptide carrying said epitope.
• a liposome may comprise the nucleic acid whereas the epitope carrying polypeptide may be attached to its .membrane either covalently or through a membrane anchor, e.g. a membrane spanning polypeptide.
• both the nucleic acid and the polypeptide may be attached to a nanogold particle.
• Nucleic acids can be present in a gelatin nanoparticle capsule, e.g. in a polycation, whereas the; target polypeptide linked to the surface thereof.
• Preferred nanoparticles applicable in the present invention are disclosed e.g.a in US 2008/0160096 Al published on July 3, 2008 (Berbely J. et al., 2008).
• a virus or a virion is applied herein as control; for example, the nanoparticle of the ' invention is a virus or a virion.
• the virus can belong to the order of - any of the following: Caudovirales, Herpesvirales, MOnonegavirales, Nidovirales, Picornavirales, Tymovirales and Ligamenviralesv
• the virus or virion can be a double stranded.(ds) DNA virus or a single stranded (ss) DNA virus or RNA virus a • and may or may not use reverse transcriptase (RT).
• ssRNA viruses may be either sense (-k) or antisense (-).
• the virus may have either a linear or a circular genome.
• the virus is a DNA virus, e.g. a. dsDNA virus in case of chromatin immunoprecipitation e.g. an adenovirus, and adeno- associated virus or an RNA virus, e-g. a retrovirus i case of RNA immunoprecipitation.
• Viruses Manipulation of Viruses; in particular adenoviruses s disclosed, e.g.a in the- manual "Virus Gonstruction Kit - The Manual Fett JBioware lGEM 2010 (available e.g. at the Freivier Bioware group and its home page.
• the virus or virion is a bacteriophage.
• an M 13 phage system was used.
• the nucleotide sequence encoded for the exemplary P4 peptide was subcloned in a way which allows the N-termihal fusion of, the peptide to the genelll protein (minor coat protein).
• any other protein of the phages which has a surface portion capable of carrying an epitope may be useful according to the invention.
• a protein,selected.from the group of geneVIII protein, genelX protein, gene VI protein and gene VII protein can be used instead of ' genelll protein.
• the recombinant filamentous M13 phage was generated in E. co ' li via electroporation of the double stranded M13 vector.
• the mature phage is assembled within the cells', from the positive strand of the vector construct and from coat proteins,, that is the major geneVIII protein ( ⁇ 2700 copies), and the minor gene VI, geneVII, genelX proteins and the P4-geneIII fusion protein (3-5 copies).
• the recombinant P4-M13 phage construct therefore displays the P4 peptide on,its ; surface and is physically linked to its encoding DNA ( Figure 2).
• Both lytic phages and lysogenic phages are applicable in the present invention as this feature is not: utilized in the immunoprecipitation reaction but upon propagation of the virus only ' .
• the bacteriophage according to the invention can be for example but not limited to a phage selected from the group of phages of the following, families:' Siphoviridae, Myoviridae, Podoviridae, Lipothrixviridae; Rudiviridae, Cystoviridae, Fuselloviridae, Globuloviridae, Guttavirus, Corticoviridae; Clavaviridae, Bicaudaviridae, Bacilloviridae, Ampullaviridae, Tectiviridae, Plasmaviridae, Microviridae, Leviviridae, Inoyiridae.
• a phage selected from the group of phages of the following, families:' Siphoviridae, Myoviridae, Podoviridae, Lipothrixviridae; Rudiviridae, Cystoviridae, Fuselloviridae, Globuloviridae,
• the bacteriophage according to the invention can be for example but not limited to a lambda phage ( ⁇ phage), a T type phage, e.g. a T2 phage, a T4 phage, a T7 phage, a IT 2 phage, an R17 phage, an M type or an MS type- phage, like an M 13 phage or an MS2 phage a G type phage, .like>a G4 phage, a P type phage like a P 1 phage, a P2 phage or a.
• a lambda phage ⁇ phage
• T type phage e.g. a T2 phage, a T4 phage, a T7 phage, a IT 2 phage, an R17 phage
• an M type or an MS type- phage like an M 13 phage or an MS2 phage a G type phag
• the controls are used, in a GhIP experiment.
• the first step of a GhIP experiment is quite often the fixation of the sample, e.g. by cross-linking. In certain embodiments, however, e.g. if histone modifications or nucleosome positioning are to be determined this may not be necessary (native GhIP) [Barski A e al. Identification of transcription factor target genes by GhIP display. Methods Mol Biol 2008 ⁇ , 455: 177-190.].
• further :or alternative cross-linkers are used (e;g. ' disuccinimidyl glutarate) to preserve protein-protein complexes. Cross-linking also stabilizes the complexes during sonication of mechanical fragmentation:
• Fragmentation of the chromatin is an important issue. It is important to achieve sufficient and reproducible fragmentation. Most often the desired fragment size is about 150 to 500 bp. The fragmentation method should be reproducible, as far as possible: If subsequent detection is to be done by sequencing a 200 to 400 bp, preferably to 300 bp fragment size is preferred.
• the size of the lower limit is defined by the size of the nucleosome. This can be achieved e.g. by nuclease digestion. It is true in general that smaller fragment size and more gentle fragmentation can be achieved by digestion by nucleases, e.g. by micrococcal nucleases. As preparation of the subsequent library of fragments for sequencing requires fragment sizes of 200 to 300 bp, .digestion can be a preferred option in this case, or in case of native ChTP.
• the next step, immunoprecipitation, is crucial for a successful ChlP experiment.
• a specific recognition molecule e.g. an antibody is used to bind the protein of interest (target protein), and the complex shall become bound to a support, e.g. protein A or protein G covered beads, so that precipitation may occur.
• the beads can be e.g. magnetic or sepharose beads and can be collectedly a magnet or by centrifugation.
• the beads may also comprise label and can be sorted by used that label.
• the complex may be formed either before or after to binding of the recognition molecule to the support.
• the fragmented chromatin sample is enriched in those fragments which comprise the target protein bound to their specific site on the nucleic acid.
• the success of the ChlP experiment largely depends on the level of enrichment of the right chromatin fragments which in turn depends on the quality of the recognition molecule (or antibody).
• the recognition molecule or antibody.
• an appropriate negative controm may be a nonspecific control antibody such as anti-IgG and/or a virus or nanoparticle according to the invention without the epitope (or rriimotope) of interest.
• ChlP seq project depends crucially on strong enrichment of the chromatin specifically bound by the protein Under study. We routinely test a number of antibodies and choose the one with consistently high enrichment of DNA at a known binding site when, compared with the DNA immUnoprecipitated by a nonspecific control antibody such as anti-IgG arid ho enrichment at negative control sites.
• the sample to be analysed i.e. the sample of interest and the control sample are present in different containers or vials.
• the control of the invention either positive control or negative control are added to the control sample, i.e. to a different container or vial from that containing the sample to be analysed.
• the control is added to the same sample to be analysed or to container comprising that sample.
• the immunoprecipitation reaction is carried out both on the sample of interest and on the control not only simultaneously, but in the same reaction.
• the control should be detected besides the sample of interest from the same reaction mixture. This is possible by several detection method, for example but not limited to QPCR or Chip-chip.
• control value and the measured value obtained by the target or antigen can be obtained in a single reaction step.
• any kind of recognition molecule can be applied in the immunoprecipitation method of the present invention provided that it is or can be bound to an appropriate support, e.g. beads arid it binds the target protein with a sufficient binding strength, expressed e.g. as affinity or avidity.
• an appropriate support e.g. beads arid it binds the target protein with a sufficient binding strength, expressed e.g. as affinity or avidity.
• Such molecules capable of binding a target protein and attached to a support i.e. useful in an immunoprecipitation method; can be applied in the present invention.
• These type of recognition and binding molecules are expected to be further improved in the future and may provide even better alternatives to antibodies.
• antibodies and antibody fragments as well as modified, e.g. stabilized versions thereof are preferred according to the invention.
• Mimotopes i.e. analoges of epitopes can be prepared by various methods.
• a display method e.g. a phage display method is applied to present an peptide library to an antibody of interest.
• an unbiased peptide library is used.
• the length of the peptides is e.g. at. least 7, at least 8 or at least 9 amino acids and at most 22, almost 20, almost 18, at; most 16, at most 14 ' , at most 12 or at most 10 arhino acids. If a consensus sequence is known an fixed in the peptide library, a smaller library is sufficient. Similarly, if an N- or C-terminal segment or portion of the peptide is known, the variable region can be smaller, even as small as 1 , 2, 3, 4, 5 or 6 amino acids.
• viruses e.g. bacteriophages
• the library is then contacted in several selectiori (panning) steps against a pre-selected recognition molecule (e.g. antibody).
• the recognition molecule preferably has a know binding property and/or its target protein is known. These rounds are carried out in experiments comprising binding of the particles to the recognition- molecule and isolating the bound particles and, if necessary, analyising them or monitoring the enrichment some way ; In each panning step enrichment of shall be found. Mohitpring enrichment can be followed e.g. by capillary sequencing or by detecting the ratio of recovery of the nanoparticles (or viruses or phages). Alternatively, hybridization of the nucleic acids to a chip comprising a large number of appropriate sequences can be used. Chip-sequencing is more cumbersome but can be used, and may be advisable, when a new method is set.
• This mimotope finding method is applicable even in cases when no appropriate epitope on the target protein is known.
• viruses can be applied and propagated in each rounds of panning. Mutations in the sequences are allowed or induced during or between the panning steps and the bound viruses presenting epitope sequences of appropriate binding level are obtained. The so obtained viruses then are propagated in an appropriate host organism.
• Epitopes as molecular surface parts of a molecule can by given and mimotopes also can be prepared e.g. as described [Goede,.Andrean et al.: BMC Bioinformatics 2005, 6:223].
• a library sufficiently enriched in appropriate epitopes can be used, or individual nanoparticles, viruses (virions) or phages having a particular epitope can be selected.
• Results of traditional immunoprecipitation experiments can be detected by an immunological method, e.g by , Western-blotting or by ELISA. These methods provide detection at the protein level.
• nucleic acid binding protein is immunoprecipitated with its cognate DNA or RNA and the presence of this binding at a specific site can be assessed at the nucleic acid level.
• a method utilizing nucleic acid modifying enzymes may also be applicable, provided that a restriction endonuclease specific to that particular modification is available.
• DNA adenine methyltransferase can be mentioned. This protein methylates adenines in the DNA.
• DAM is fused to the protein of interest, this fusion protein is expressed, methylates the adenines which are riot- covered by the target protein and those parts are identified by endonuclease mapping.
• qPCR quantitative PCR
• QPCR quantitative PCR
• a further method utilizing hybridization is ChlP-onTa-chip or ChiP-chip utilizing the. nucleic acid hybridization array technology.
• the sequences on the chip used depend on the purpose of the experiment. They may comprise a pre-defined portion of the genome (part of a chromosome or e.g. regulatory regions). While the method is relatively simple arid effective, the resolution of this method is relatively low, however, depends on the hybridization conditions.
• Sequencing methods provide a highly precision tool for ChIP detection. A sequencing experiment after QPCR is possible.
• ChlP-seq experiment is the sequencing of nucleic acid fragments that co-precipitate with the specific binding protein of interest.
• any nucleotide sequence precipitated can be sequenced and the result does not depend on prior knowledge of binding sites.
• this method is performed with high-throughput Next- Generation Sequencing (ChlP-seq) and became suitable for whole genome mapping of protein-DNA interactions [Kozarewa I et al. Amplification-free Illumina sequencing-library preparation facilitates improved mapping arid assembly of (G+C)-biased genomes. Nat Methods 2009, 6:291-295., Goren A et al: Chromatin, profiling by directly sequencing small quantities of immunoprecipitated DNA. Nat Methods 2010, 7:47-49., Barski A and Zhao K: Genomic location analysis by ChlP-Seq. J Cell.Biochem 2009, 107: 1 1 -18.]
• the present controls of the invention are suitable for sequencing experiments just as chromatin itself arid therefore provide an additional possibility to control the quality of the ChIP experiment.
• kits according to the invention may comprise the controls only indicated that it , is to be used as a control in TP experimehs. More preferably the kits comprise both positive and negative controls for a given recognition molecule validated for IP or ChIP experiment. Preferably the controls are provided in solution.
• the recognition molecule is provided in ; the kit,
• the kit also comprises a QPCR assay kit or at least primers suitable to arnplify the epitope.region. , '
• non-specific antibody control like IgG or other negative, non-specific controls are provided in the kit.
• IP buffers PCR buffers, washing solutions arid desired media, solutions and other reagents are provided in the kit.
• Peptide Phage Display Cloning Vector, M 13KE. was purchased from New England Biolabs, Ipswich, MA (NEB, Catalogue No. E8101 S). Subclonihg of the coding DNA sequence of the P4 peptide into M13KE vector and propagation of the M13KE vector and whole phage was carried out in the F+ E. coli K12 ER2738 host strain (NEB, Catalogue No. E4104S) according to the manufacturer's suggestions (Ph.D.TM Phage Display Libraries Instruction Manual, NEB, Catalogue No. E8100) with the following modifications. A single stranded oligonucleotide was . synthetised by Sigma- Aldrich, with the sequence of - 5'- CATGTTTCGGCCGACGCCAGTTTAACTTCTTCTTTAACACCTTTC
• the Phage Peptide 4 oligonucleotide (5 ug, ⁇ 180 pmol) was annealed to 3 molar excess (4,1 ug, 540 pmol) of a single stranded oligonucleotide, "Extension Primer" with the sequence of 5'-CATGCCCGGGTACCTTTCTATTCTC-3' (ST00099787, . ..Phage Extension", synthesized by Sigma- Aldrich) in 50 ul TE buffer containing 100 mM NaCl, by heating to 95 oC and cooling to 25 oC under 30 min.
• the annealed oligonucleotide pair was extended using 15 Units of lenow fragment in 200 ul NEBuffer 2 containing 10 mM dNTP. mix for 10 min, 37 oC, followed by an incubation at 65 oC for 15 min.
• the extended duplex was digested with 50 Units of EagI and 50 Units of Aec65I restriction endonucleases in 400 D l NEBuffer 3 at 37 oC for 5 h.
• the digested duplex was purified by separating on, 5% MetaPhor Agarose (Cambrex) gel electrophoresis on a Bio-Rad Mini SubCell apparatus; excising the 71 bp fragment with cohesive ends, and purifying using a High Pure PGR Cleanup Micro Kit (Roche), and DNA concentration was determined using a NanoDrop spectrophotometer (25 ng/ul).
• 4 ug of double stranded M13KE phage vector was digested with 50 Units of EagI and 50 Units of Acc65I restriction endonucleases in 50 ul NEBuffer 3 at 37 oC for 5 h.
• Linearised vector was loaded onto 1% Certified Molecular Biology Agarose (Bio-Rad) and the fragment (7202 bp) with cohesive ends was excised from the gel and purified with a GeneClean Kit (Qbiogen) and DNA • concentration was determined using a NanoDrop spectrophotometer (200 ng/ul).
• the digested duplex (100 ng) was ligated into the linearised M13KE vector (100 ng, molar ratio 10: 1, insert: vector) using 1.5 Weiss Units of T4 DNA Ligase (Promega) in 10 ul of T4 ligase buffer at 16 oC for an overnight and heat-killed at 65 oC for 15 min.
• T4 DNA Ligase Promega
• the ligation mix was electroporated into E. coli K12 strain ER2738.
• Top- Agar (10 g Bacto-Tryptone, 5 g Yeast extract, 0.5 g NaCl, 7 g Bacto-Agar per liter, Sigma) melted at 45 oC and containing 200 ul of ER2738 culture (20 mL) previously grown to OD595 0:38 in LB medium containig 20 ug/L tetracycline (37 oC, shaking at 240 RPM).
• Top-Agar mix was plated on LB-Agar plates containing 1 ml/L IPTG/Xgal stock (1.25 g -IPTG and 1 g Xgal in 25 mL DMF, Sigma) and incubated at 37 oC for an overnight.
• Single blue phage plaques arising on the plates due to IPTG induced beta-galactosidase expression from functional M13KE vector were picked with sterile tips and inoculated into early-log phase (0.1: OD 590 nm) ER2738 cultures ( lmL LB without antibiotics) and grown at 37 oC for 4.5 h with shaking (250 rpm) to amplify individual phage clones.
• Phage DNA template was prepared from 100 ul of the stock using: the High Pure PCR Template Preparation Kit (Roche) for qPCR-based clone screening specific to the P4 peptide coding insert.
• the presence and correct frame of the insert sequence in qPCR positive clones was verified by capillary nucleotide sequencing using 100 ng single stranded phage DNA as template and the Ml 3 -96 sequencing primer on an ABI 310 Avant.DNA sequencer ( Figure 3 A and 3 B).
• P4-M13KE phage clones which were foiind positive in the qPCR-based screen were amplified by adding an aliquot (5 iil) of the amplified phage' stock (see above) to an early-log phase (OD595: 0.05) ER2738 ⁇ culture (20 ml LB), and incubating at 37 ' oC for 4,5 h 'with shaking (25.0 rpm).
• the culture was then spinned at 8000 x g for 20 minutes and the supernatant was treated with 1/6 volume of 20% PEG/2.5 M NaCl. After an overnight precipitation at 4 oC, whole phages were collected and. washed by centrifugation and resuspended in TBS (50 ul) to obtain purified amplified phage clones for further experiments. Fragment preparation for chromatin immUnoprecipitation (ChIP)
• 293Tcells were grown in DMEM, 10%FBS, Pen/Strepto, Glutamine, in 5%C02, 37C, humidified environment in a T75 tissue culture;flask, in 20 ml riiedium,;in; a 'numb er of 15-20 million cells per flask;
• PBS was removed and 5 ml of fresh PBS was added. Cells were scraped in these five ml of icecold PBS. Scraped cells were transferred into a 50 ml conical centrifuge tube and supplemented to 20 ml PBS. Cells were centrifuged at 1000 g for 10' minutes at 4C. Supernatant was removed carefully, resuspended in l ml PBS and washed again with total 20 ml PBS as previously. PBS was removed carefully and pellet was resuspended in 0,5 ml of icecold PBS and transferred in 1,6 ml Low Binding Microcentrifuge tubes. Cells were centrifuged 6120 g 4G, 2 minutes.
• Buffer was. transferred into 15 ml conical polystyrol tubes (BD Falcon 352095 ) and sonicated on Bioruptor 3 l0min High.setting, 30 sec ON/30 sec OFF.
• The. Fragment analysis was done as it follows: 50 ul was completed to 200ul with Elution Buffer (freshly dissolved ⁇ , ⁇ NaHC03 and 1%SDS). 8ul of. 5M NaCl was added, 2ul of 0,5M EDTA (pH8) and was incubated overnight at 65C.
• RNAseA stock solution of lOug/ul
• 4ul 0,5 M ED TA pH8
• 8ul TrisCl 1 M, pH7
• 0,5 ul Proteinase K 18,5 mg/ml, Ferrnentas EO 0491
• Solution was incubated in a/thermomixer while shaking with lOOOrpm, for 2hours at 45C.
• Solution was purified on a Roche High Pure Template preparation PCR Kit. Columns were eluated twice with 50ul-s generating roughly lOOtil of eluate. This was quantified with Qubit High, Sensitivity Double stranded NA Kit (Invitrogen Q 32851). Concentration was in the range of 70-100 ng/ul.
• IP reaction buffer were, added and centrifuged again. Supernatant was removed as described previously. 5-28ul buffer was added to the. beads and beads were split in two equal parts. Beads were suplemented with reaction buffer to 1 ,4ml and 24ul HDAC1 antibody was added to one of the vials and 8ul of IgG (2ug/ul) to the other vial. Tubes were incubated in a rotation platform (30 rpm) at AG for two hours.
• Tubes were inserted into a Invitrogen magnetic rack and left 1 min, after which supernatant was removed. Next we added 528ul of reaction buffer to each tube and the content of the tubes was further divided into 8 Low binding tubes (Axygen MCT-150-L-C, 311-09-051) for I IDAC 1 (Diagenode Catalogue No. SN 144- 100) or IGG cprrespondigly (30ul coated beads per reaction).
• Sonicated chromatin corresponding to 500 cells in 30ul of Sonication buffer were diluted tenfold with IP Dilution buffer (and Proteinase inhibitors and final concentration of lmM DTT) up to 3 ' OOul. This was added to each bead containing 1,6 ml microcentrifuge tube. These reactions in individual tubes were spiked with the corresponding amount of phages as.it is shown in Table 1.
• Tubes were incubated overnight on a rotating platform at 4C.
• the coding sequence of the HDAC 1 monoclonal antibody immunogen epitope peptide was subcloned into the .Peptide Phage Display Cloning Vector, M 13KE purchased from.New England Biolabs to generate recombinant M13KE. phages displaying the .epitppe?peptide N-terrninally fused to genlll phage coat protein according to the manufacturer's suggestions. Sequence of the immunogen, epitope peptide used for the generation of HDAC1 monoclonal antibody (Diagenode Catalogue No. SN 144- 100) was disclosed by Diagenode SA as to be NH3+- EEKPEAKGVKEEVKLA-COO- (hereinafter also referred as P4). Coding nucleotide sequence of the P4 peptide was generated and optiinised iii silico for E. coli .K.12 codon usage using the open source Gene Design software (www.genedesign.org) as
• P4_2, 6, 11 , 12, arid- 13 was screened for the presence the P4 peptide coding insert using a qPCR-based protocol with M l 3 specific forward primer (General F or General S), P4 insert specific reverse primer (Peptide4 R or Peptide4 S), and a general VI 13 probe (General TM). All 5 clones (clone No. P4 2, 6, 11 , 12, arid 13) proved to be positive for. the presence of the,P4 peptide encoding insert in the qPCR screen.
• QPCR assays were developed in a way to allow the detection of virtually any newly cloned. Phage. One of the primers and the probe are specific to the backbone, while the other primer to the cloned fragment. Alternatively QPCR assays Were developed that are able to detect the empty phages too, namely the negative controls. See details in Figure 4.
• a qPCR assay that is recognizing the cloned phages. This assay is using a general probe and a general forward oligd that binds the backbone of the phage, while the the reverse primer is specific for the cloned insert ( Figure 4).
• Peptide4 R gCCgACgCCAgTTTAACTT
• PCR reaction 2ul of the purified DNA was used for the QPCR reaction. Each QPCR measurement was performed in triplicates ' .
• One PCR reaction- contained the following: 13, 68ul Nuclease free water, 2,2 10X PGR Buffer, 2,7 MgC12 :25mM, l ul dNTP 2,5mM each, 0,08ul Forward Primer (lOOuM) arid 0.08ul Reverse Primer (lOOuM), 0,13ul Probe (20uM), 0,13ul Taq Polimerase (5U/ul .Fermeritas EP 0402). Measurement was performed on a Roche Lightcycler 480 instrument. Second derivative max method was, used to calculate the Gp values during the analysis the results of the QPCR reaction.
• Panels A arid B of Figure 6 shows two biological replica, according to which the phage can be recovered from the CMP reaction by the HDACl antibody in three concentrations, namely 1 million, 100 thousands or 10 thousands;.
• Panels C and D shows the quantitiy of the phages added to the system (10% of the INPUT and the total quantity). P4 specific assay were used to the QPCR ⁇ measurements.
• Panel E shows that IgG control was negative . in/aJJ cases.
• Panel D shows that empty ⁇ 3 ⁇ phages are not boiiftd by the HDACl antibody:
• the ratio of the added phages (INPUT) bound by 3 ug antibody has also been studied. Our results showed that while in case of 750 thousands added phages the recovered ration was 87% (635440 phages recovered vs. 91227 non-:recovered), when 250 thousands phages were added this ratio increased to 90% (222780. phages recovered vs. 22231 non-recovered). This appears to be the evidence "for the empirical fact that in an IP reaction in case of more diluted samples enrichment level is. higher than in case of more concentrated samples.
• Monoclonal antibodies raised in mouse against the human MECP 2 and p300 proteins were used as targets in a random heptapeptide phage display library selection protocol to enrich for phage clones with heptapeptides which are capable of specifically binding to the antibodies (mimotopes), in order to generate phage clone " pools which can be used as controls in MECP2 or p300 ChIP protocols.
• a random peptide library Ph. D.-7 Phage Display Peptide Library (NEB) was utilised, which consists of recombinant M13KE phages displaying a fully randomised peptide library ⁇ terminally fused to genlll phage coat protein via a GGG linker sequence.
• the library preparation has a phage concentration of lO 13 pfu/ml with random heptapeptide library representation of 70 copies of each possible sequence (which is 1.28 x lO 9 in case of a 7-mer peptide) in a 10 ul aliquot (according to the manufacturer).
• Biopanning of the library on the antibodies was carried out in solution, starting with a phage blocking step to prevent non-specific interactions, with the antibodies, wherein, as the input, a 10 ul aliquot (in which the total number of phages were 10 ! ' pfu) was added to 1 ml.
• Tris Buffer Saline with 0.1% Tween-20 (TBST) containig 1% BSA and incubated for 60 min at room temperature with rotation.
• 10 ug of MECP2 or p300 specific antibody was added and the mixtures were incubate for 60 min at room temperature with shaking.
• Protein G magnetic beads (Dynabeads) by .adding a 50 ul (1.5 ;mg) aliquot of Protein G magnetic beads (Dynabeads) prepared according to the manufacturer's instructions and incubated for 10 min at room temperature.-Beads were collected using a magnet and washed 10 times with 1 ml TBST containig 1% BSA.
• TM Phage Display Libraries Instruction Manual (New England Biolabs) to obtain the amplified phage output of the biopanning in .200 ul TBS.
• the phage concentration was determined as described above. These steps corresponded to the First Round of. Biopanning, which were repeated in two further rounds (Second and Third Rounds of Biopanning) was carried out using an aliquot of the. outputs from the preceeding rounds, containing .10 10 pfu, as the input of the biopanning rounds. Phage, amplificates were analysed by capillary sequencing as a fast monitoring of the process. Next, generation sequencing by Roche 454 Junior System was applied to characterize quality of the panning steps and enrichment, together with qPCR quantification in the ChIP protocols.
• the ChIP validated phage clones* the displayed mimotope peptide sequence of which are also confirmed 'indirectly by DNA sequencing, will comprise monoclonal mimotope controls for ChIP protocols.
• phages were isolated and DNA purified with standard column based DNA purification by using Roche PGR purification Kit according to the manufacturer's recommendations. Templates were used for PCR amplification of the desired region of the phage genome and in the same time tagging with an M13 FW and M l 3 RW tags. In the second round, of the PCR multiple identifyer indexes (MID adaptors) and 45 sequencing primers were added to the amplicohs. The generated amplicons were mixed and sequenced according to the manufacturer's recommendations.
• MID adaptors MID adaptors
• Results were translated into protein sequences and consensus sequences were investigated. Briefly, the best 100 sequences from the 454Junior sequencing. results ; were analyzed (Table 2). Sequences with insertions deletions, stop codons and those that contained unidentified nucleotide sequences were removed. Translation was performed with the Transeq tool of the EMBOSS package. Results were analyzed by Mimox ⁇ BMC Bidinformatics 2006, 7:451 doi: 10.1 186/1471-2105-7-451 ) and quality score of the consensus was extracted through JalView representation of the results. The amino aeid sequence length used in the Mimox software differs from seven as a result of the fact that amino acid sequence alignment generated by the program is not fully overlapping (see Table 2 and 3).
• the mimotope quality score reflects the fraction of recovered phages during the ChIP procedure as measured by QPCR.
• the calculation of quality scores is shown in Table.3 as well as on Figure 9 A:
• the mimotope quality score reflects the recovery in a CHIP reaction
• individual mimotope clones can be isojated, amplified to obtain monoclonal mimotope controls for ChIP protocols.
• An aliquote of the amplified phage eluate from the third (or the final of any further) round of biopanning. is. used to infect a culture of any K.coli strain which is competent to M13KE phage-infection, then plated onto LB-Agar/IPTG/X-gal plates using the top agar protocol (Ph.D.TM Phage Display Libraries Instruction Manual , ⁇ ). Blue plaques (10-100) are amplified separately to obtain single clones, and.
• amplified phages screened in a ChIP protocol for antibody binding and recovery Fjfotti the ChIP validated phage clones will represent monoclonal, single stranded phage' DNA is purified (e.g. any QNA purification kit capable of purifying single stranded DNA with a size of 7222 bases )
• a nanoparticle (or. phage, virion) based controll that is bound by the antibody used in the specific GhIP- Seq experiment, could serve as a process controll of the procedure.
• the most often applied genome sequencing method is the Illumina "Sequencing by synthesis” methodology, in which clonally amplified. DNA to.be sequenced on a solid phase is obtained by a so-called. bridge amplification [Chee-Seng, Ku et al. Next Generation Sequencing Technologies and Their Applications. In: Encyclopedia of Life Sciences (ELS). John Wiley & Sons, Ltd: Chichester. April 2010].
• the optimal DNA fragment length to the. bridge PCR. reaction is at most 300 bp. This size is appropriate for the ChTP-s ' eq methodology as it corresponds to the size of two nucleosomes. It has been found that in case of fragments longer than 300 bp transcription factors can be detected with more difficulty.
• a second approach is the application of a different fragmentation method.
• a suitable tool is the Micrococcal nuclease method.
• An advantage of this method is that it is gentle, i:e. that probably leaves, large protein complexes intact, and that replaces the expensive sonicator equipment.
• Figure 14 it is shown that DNAse based fragmentation of chromatine was successfully established.
• a part of the transcription factors is not linked with the DNA by the traditional formaldehyde based fixation method.
• the probable reason is that distances in the complex are probably longer than that can be bridged by this small molecule. Therefore disuccinimidyl glutarate (DSG) has been. used which can form even a molecular bridge of 7.7A.
• DSG disuccinimidyl glutarate
• a kit for this purpose preferably comprises DSG as a cross-linking agent
• sandwitch (capture) ELISA method was also evaluated for the quantification of phages in the ChIP output using a Phage Titration, ELISA Kit (PRPHAGE, PROGEN) by following' the manufacturer's instructions; Briefly, serial dilution of Ml 3 phage was prepared (at TO 7 , 2.5 x 10 7 , 5 x 10 7 , 10 8 .phage particles/ml final concentrations in 100 ul final assay volume, and in addition, at 10 4 , 10 5 , 10 6 phage particles/ml final concentrations, as being relevant to ChIP output phage final concentrations), added to ELISA strips (8-well) pre-coated by the capture antibody for M13 phage, and blocked.with BSA, after 1 hour incubation at room temperature, wells were washed and treated with the detection antibody.
• a mature M13KE phage preparation either displaying the specific epitope peptide for, or a mixture of phage clones selected, in . a biopanning, process on the specific antibody to be used ;in the immunoprecipitation experiment, is used as a positive control for antibody specificity and complex formation.
• the specific antibody binds to phages which either contain its specific epitope peptide, or a mixture of peptide sequences to which the antibody is capable of binding (mimotopes selected from a random peptide phage display library), the complexes are then be precipitated usind protein A or G beads, and finally, phages remaining bound after washing are detected and/or quantified by either Ml 3KE phage specific qPGR, or phage coat protein specific ELISA, or phage coat protein specific Western blotting.
• a cleared supernatant of a cell lysate or tissue homogenate e.g.
• phage quantification e.g. for SDS-PAGE and Western blotting, add equal volume of 2x Laemli buffer, boil for 5 min; store at 4 oC for ELISA or qPCR measurements).
• 1-2 ug specific antibody " is added-and rotated-at 4 °C for 2-3 hours to allow aritibody-phage comple formation to occur.
• Protein A/G Sepharose (Santa Cruz Biotech) or Protein A/G magnetic beads (DynaBeads). are prepared (e.g. washed with lysis buffer according to the manufacturer's instructions) for antibody binding (in an Fc- specific manner), arid 30-50 ul of a 30-50% slurry is added per 1 ml phage-treated aliquote and rotate at 4 o.G for 1 hour to allow precipitation of the immune complexes. Collect precipitate either by centrifugation (e.g.
• a QPCR assay sufficient for 96 QPCR reactions in 50 microliters final volume detecting the phage.
• QPCR mastermix sufficient for 96 QPCR reactions in 50 microliters final volume.
• An advantage, of the controls of the invention is that they comprise both an epitope of an appropriate target and a nucleic acid encoding it, therefore in a ChIP experiment they work a very similar way to chromatin itself.
• the system of the invention have the following features.
• Binding capacity of an antibody epitope can be precisely determined in a given experimental setup and thereby work-flow can be optimized-
• the assays of the invention can be widely used to study proteins, e.g. nucleic acid binding proteins including both histones and non-histone proteins, such as transcription factors, e.g. within the context of the cell.
• proteins e.g. nucleic acid binding proteins including both histones and non-histone proteins, such as transcription factors, e.g. within the context of the cell.

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• 2012
  • 2012-07-02 HU HU1200395A patent/HU230463B1/hu not_active IP Right Cessation
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