RU2631934C1 - Sorption composite membrane and bioseparating device for dna extraction - Google Patents

Abstract

FIELD: biotechnology.

SUBSTANCE: sorption composite membrane and a bioseparating device for DNA extraction have been proposed. This membrane includes a porous template and a sorption cover. The porous template is a microfiltration polymer membrane with a porosity of 0.2-0.65 mcm. The template is made of polyamide, polyethersulfone or polyvinylidenfluoride. The sorption cover of the template is made of polyaniline, and the mass fraction of the sorption cover is 10-25%. The biosepararing device is a plastic cartridge inserted in a microtube. The plastic cartridge contains the above-mentioned sorption composite membrane, rolled into a roll with a packing density of 24-48 cm²/cm³.

EFFECT: shortening the duration of DNA extraction at high efficiency.

3 cl, 1 dwg

Description

The invention relates to analytical chemistry in the field of molecular biology and pharmacological biotechnology and can be widely used in modern medical diagnostics. The effectiveness of modern methods of medical diagnostics is largely determined by the ability to quickly isolate a pure biopolymer preparation (nucleic acid or the corresponding protein marker), without violating its secondary or tertiary structure, from complex clinical samples (such as blood, plasma, urine, smear, sputum and etc.).

Typically, methods for the separation and isolation of biopolymers, in particular DNA, are based on the different solubilities of nucleic acids, proteins and polysaccharides. Despite their effectiveness, most separation methods are multi-stage, time-consuming and often accompanied by losses of the excreted component. This is a consequence of the fact that such methods are based on the concept of “capture” and “retention” of the target biopolymer by the sorbent from the mixture at the first separation stage, followed by washing from impurities and elution of the target component from the sorption material at the subsequent stages.

In practice, various microcolumn bioseparation methods are widely spread, based on the use of spin columns or cartridges, through which the mobile phase (i.e., eluent) is passed through the action of centrifugal force in a centrifuge or under pressure using various pumps. Such microcolumns contain unmodified silica, modified silica (using low molecular weight and high molecular weight modifiers), synthetic membranes, polymer monoliths, polymer or glass capillaries, etc. In contrast to traditional column chromatography, this approach allows one to purify and isolate the necessary DNA relatively quickly, using small amounts of sorption material.

A number of DNA extraction methods are based on preliminary concentration of microorganism cells from biological samples, in particular, the following methods are used: filtering the sample (Icuta, K., Maruo, S., Fujisawa, T., Yamada, A. Micro Concentrator with OptoSense Micro Reactor for Biochemical IC Chip Family - 3D Composite Structure and Experimental Verification Proc. Of 12th IEEE International Conference on Micro Electro Mechanical Systems (MEMS'99), Orlando, 1999: p. 376-381), electrokinetic focusing (CR Cabrera, P. Yager, Continuous concentration of bacteria in a microfluidic flow cell using electrokinetic techniques. Electrophoresis, 2001, v. 22, p. 355-362), microdialysis (F. Xiang, Y. Lin, J. Wen, DW Matson, RD Smith. An integrated microfabricated device for dual m icrodialysis and on-line ESI-ion trap mass spectrometry for analysis of complex biological samples. Anal Chem., 1999, v. 71, p. 1485-1490), affinity chromatography for cell concentration and subsequent solid-phase extraction of NK (C. Yu, M.H. Davey, F. Svec, J.M. Frechet, Monolithic porous polymer for on-chip solid-phase extraction and preconcentration prepared by photoinitiated in situ polymerization within a microfluidic device. Anal Chem., 2001, v. 73, p. 5088-5096).

A variety of materials from borosilicate glass, cellulose, polytetrafluoroethylene, polyvinylidene difluoride, etc., can be used as semipermeable membranes.

Most preferred are semi-permeable membranes based on polyvinylidene difluoride. Due to hydrophilicity, chemical inertness, mechanical strength, ease of processing and the absence of an inhibitory effect on the polymer chain reaction (PCR), this type of filter can be used to perform mechanical concentration and chemical lysis of cells in the form of a miniature closed device (microfluidic module).

It is important to note that all of the materials listed are used specifically as filters that mechanically retain the target biopolymer when passing through the sample membrane. The main disadvantage of such methods of lysis of cells and viral particles is that as a result of this procedure, along with the target nucleic acids, a filter retains many substances that can inhibit PCR. In some cases, the process of DNA isolation and purification is based on the ability of DNA to be reversibly adsorbed on the membrane surface. In this case, it is necessary to additionally wash the adsorbed DNA from impurities and subsequent elution of the target product with a suitable buffer solution, which leads to significant losses of the released component of the biological mixture.

Therefore, from a practical point of view, a one-stage scheme for isolating the target product seems more attractive. In this case, the biopolymer emitted (and at the same time purified) after contact of the mixture with the sorbent remains in an unbound form, while undesirable impurities are retained by the sorbent. It turned out that for some polymeric materials, in particular, for polyanilines and fluoropolymers, this approach is implemented in a single-stage separation of nucleic acids from proteins. Moreover, the components of the nucleic acid fraction (single-stranded and double-stranded DNA, RNA) are not retained or are weakly retained by the surface of the sorbent, while proteins are reversibly sorbed. At the same time, it remains possible to sequentially desorb the components of the retained protein fraction depending on the charge of the protein macromolecule.

Obtaining such sorbents requires the use of a complex labor-intensive washing procedure; in addition, they do not always prove to be effective in the isolation and purification of nucleic acids from some “complex” biological samples, such as blood, plant tissues, etc., containing powerful inhibitors along with proteins PCR, such as heme and chlorophyll, or for the separation of DNA and RNA, single-stranded DNA from double-stranded DNA, etc.

On the contrary, the use of polymer membranes as substrates in the synthesis of composite polyaniline-containing sorbents allows several advantages over the technologies for producing composite dispersed carriers to be realized: first, in the present invention, the polymer membrane is used specifically as a carrier having the required chemical structure of the surface layer necessary for the formation of a uniformly distributed polyaniline coating in the composition of the sorption composite membrane, as a result ate which manage to pull more manufacturable method of producing a composite sorbent (compared with access to disperse or capillary sorbents); secondly, the membrane modified with a polyaniline coating is used as a selective sorbent in the composition of the bioseparating element, but not as a filter.

Known three-layer membrane-sorption element according to the patent of the Russian Federation No. 2239490, publ. in 2004, intended for the treatment of liquid media for the purpose of filtration, detoxification, etc. In accordance with the stated solution, the membrane-sorption element consists of two microfiltration membranes, between which there is a layer of a sorption membrane having a frame with cells filled with sorbent material of various nature.

A significant drawback of this membrane-sorption element is the technological complexity of its manufacture, associated with the formation of an internal sorption layer from a granular sorbent and a membrane structure, as well as the need for hermetically sealed external membranes. In addition, a serious drawback of the known solution is the high duration of isolation and purification of biological fluids during its use.

The closest technical solution to the proposed invention in relation to the sorption composite membrane is a composite membrane with a fixed thickness of the polyaniline layer, which has high electrical conductivity and selectivity (RF Patent 2481885 publ. In 2013). The disadvantage that impedes the achievement of the technical result indicated below is the presence in the composite of ether groups and residual sulfo groups, due to the method of obtaining the above membrane, which significantly reduces the effectiveness of the possible use of the obtained membranes in the isolation of nucleic acids, because the presence of ether groups determines the growth of non-specific sorption of nucleic acids (E. Yu. Yagudaeva, D.-J. Liaw, AA Ischenko, VN Bagratashvili, VP Zubov, AI Prostyakova, D.Yu. Ryazantsev, AP Sviridov, DV Kapustin. New polyamide- containing sorbents for one-step isolation of DNA. J Mater Sci (2014) 49: 3491-3496), and the presence of residual sulfo groups can cause nucleic acids to lose their native properties upon contact with the surface of such a membrane due to apurinization (Kapustin D., Prostyakova A ., Bryk Ya., Yagudaeva E., Zubov V. New Composite Materials Modified with Nano-Layers of Functionalized Polymers for Bioanalysis and Medical Diagnostics. In: Nanocomposites and polymers with analytical methods. In: Nanocomposites and polymers with analytical methods / Cuppoletti J. (Ed.) - Croatia: Intech, 2011. ISBN: 978-953-307-352-1, p.p. 83-106).

Devices are known in which for the lysis and isolation of nucleic acids from the resulting lysates, one or more porous membranes are used through which a sample is automatically passed sequentially. In one such device, patented by Millipore Corporation, for the isolation of nucleic acids from cells or viral particles (Filter device for the isolation of a nucleic acid, Application EP 1873242, published in 2008) on a first porous membrane made of polysaccharide or polyethersulfone, cell lysis is performed; the resulting lysate enters a glass fiber filter for subsequent purification and elution of nucleic acids. The filtering membranes are connected by a valve system. The device can be either disposable or reusable. For the simultaneous processing of several samples, several filtering devices can be collected in a cassette. An obvious disadvantage of such a device is the need to use two different types of membranes, the nucleic acids being isolated as a result of a multistage procedure using a set of eluents.

A device for molecular separation and extraction of nucleic acids (patent US 7943393 publ. In 2005), which use spin columns, for example, in the form of a polypropylene tube with one or more layers of adsorbent such as glass fibers, glass beads, polymer granules silica particles modified with silanes or polymers, etc. In these patents, the implementation of the classical multistage principle of separation of biomolecules based on spin columns (cartridges) containing sorption material reversibly holding the target sorbate is presented.

A similar principle underlies a number of more complex technical devices for sample preparation. So, patented columns (Application KR 100286896, published in 2001) with glass microfibre and methods of purification of plasmid DNA on these columns, its isolation from agarose and polyacrylamide gels, as well as purification of RNA, isotopes, products of polymerization chain reaction (PCR) . The columns contain a layer of borosilicate glass microfiber and guanidine hydrochloride. The disintegration of the sample cells is carried out due to the guanidine hydrochloride contained in the columns, which, being a chaotropic substance, has a specific effect on living cells of microorganisms: it destroys membranes, ribosomes and other cellular structures, thereby causing cell disintegration and the transition of DNA to free form. In addition, it causes rapid denaturation of all cellular proteins, including nucleases. At the same time, high molecular weight genomic DNA is retained in the treated cells, not only available for nonspecific (such as micrococcal nuclease) and specific (restrictase) nucleases, but also capable of serving as a matrix in the polymerase chain reaction (PCR). The released DNA is sorbed onto a porous layer of borosilicate glass microfiber.

This method is a variant of the traditional method of DNA purification: disintegration of cells with chaotropic agents and adsorption of DNA on a sorbent. This method of DNA purification is quite simple, gives a good DNA yield and does not require further purification procedures. However, there are a number of disadvantages. Firstly, the degree of cell disintegration is not high enough, and this method is effective only when using a rather high initial titer of microorganisms or during preliminary concentration and lysis of cells. That is, the method is not effective enough when working with diluted samples. Secondly, the method is relatively expensive for widespread use.

The closest technical solution to the claimed in relation to a bioseparating device for the isolation of nucleic acids is a device according to international application WO / 2005/012521, publ. in 2005, Inivitrogen "Nucleic acid isolation" by Corp., USA. In accordance with the solution of the prototype, the device consists of a cartridge that includes a test tube connected to the filter element and then to a column for cleaning nucleic acids, while the filter element contains several layers of filters, and the column includes a carrier capable of binding nucleic acids, for example, a carrier with a variable charge . Sample manipulations are carried out using a syringe or pump. The disadvantage of this method is also along with cell lysis, dilution of blood serum, etc. manipulations, the need for a multistage nucleic acid extraction procedure. The reason that impedes the achievement of the technical result indicated below is the lack of a special selective sorption layer in the filter element, as well as the technological bulkiness of the claimed solution, leading to the duration of the selection of the target product.

The essence of the invention is as follows.

A single technical task of the claimed invention is the development of a sorption composite polymer membrane for DNA extraction and a device based on it, which provides the selection of the target product in one stage.

A single technical result of the claimed invention is a reduction in the duration of DNA isolation with high efficiency of the used sorption composite polymer membrane and a device containing this membrane.

The technical result in relation to the claimed sorption composite membrane for DNA isolation is achieved by introducing into the structure of the sorption composite membrane a porous substrate and a sorption coating of the substrate that the porous substrate is a microfiltration polymer membrane with an average pore size of 0.2-0.65 μm made of polyamide, polyethersulfone or polyvinylidene fluoride, the sorption coating is made of polyaniline, and the mass fraction of the sorption coating of polyaniline in the composition of the sorption compo the membrane is 10–25%.

The most effective embodiment of the invention is the implementation of a sorption composite membrane for DNA isolation with an average pore size of 0.45 μm.

The technical result with respect to the bioseparating device for DNA isolation is achieved by incorporating a plastic cartridge inserted into the microtube into the device design, while the plastic cartridge contains the sorption composite membrane described above twisted into a roll with a packing density of 25-60 cm ² / cm ³ .

Additional studies conducted by the applicant showed that the inventive composite membrane acts as a selective sorbent, and DNA is not isolated by filtration, but by selective sorption of the components of the shared biological mixture, in particular DNA, flowing on the surface of the aforementioned membrane.

In addition, the achievement of the claimed technical result is due to the use of polyaniline to modify the surface of the polymer membrane due to the following factor. The advantage of polyanilines over other polymers is that the polyaniline macromolecule contains both hydrophobic sites and charged nitrogen-containing fragments. In this case, the polyaniline molecule is characterized by the presence of a polyconjugation system, which determines the pH sensitivity of polyaniline coatings. Due to this, the structure of the polyaniline molecule is subject to reversible changes depending on the pH of the medium, which makes it possible to reversibly change the sorption properties of polyaniline coatings. In particular, this property is manifested in the ability of polyaniline coatings to separate the components of mixtures of proteins and / or peptides depending on pI values of sorbates, changing the pH of the medium (eluent). The high selectivity and hydrophilicity of polyaniline coatings under conditions of separation of biopolymers at certain stages of separation allows not to use an eluent (mobile phase) for the effective separation of the components of the mixture used (i.e., for the effective separation of sufficient solvent present in the sample). As a result, the sorption properties of the membrane surface change due to the formation of a stable uniform biocompatible polymer coating on the membrane surface (including the pore surface), which provides high selectivity in the processes of nucleic acid extraction from complex biological mixtures in one stage with the simultaneous purification of nucleic acids from impurities. When a DNA-containing lysate is passed through a layer of a membrane modified by this method, the ratio of absorption intensities at 260 nm and 280 nm (A _260/280 ) of the resulting eluate from 1.7 to 1.85 is _achieved .

The invention is as follows.

To obtain a sorption composite membrane, matrix aniline oxidation polymerization is carried out on the surface of a microfiltration polymer membrane at room temperature in the presence of ammonium persulfate as an oxidizing agent. Then, the resulting sorption composite membrane is washed with alcohol, distilled water until the filtrate becomes discolored, and then with deionized water until optical absorption disappears in the filtrates in the wavelength range from 200 to 700 nm and dried in vacuum at room temperature until the weight stabilizes.

If necessary, carry out the modification (increase in the mass fraction of the sorption coating) of the microfiltration polymer membrane with polyaniline as follows. The membrane sheet is placed in a glass or plastic bath with a flat bottom and half of the aniline and oxidizer aqueous solution prepared immediately before the modification is added. The solution is prepared by selecting reagents from the manufacturer’s packaging in a glass beaker using mechanical dispensers with disposable tips. The resulting mixture was incubated for 15 minutes with constant stirring at a temperature of 25 ° C. Then, the necessary volume of ammonium persulfate prepared immediately before modification is added to the reaction mixture. Then the membrane sheet is transferred to a second bath with a solution of aniline and hydrochloric acid (the second half of the volume of the working solution). The polymerization is carried out at room temperature until the membrane becomes dark blue. Then the sheet is transferred to a clean bath with distilled water and the membrane surface is washed off from unbound particles of aniline with constant stirring with a periodic change of distilled water in the bath, controlling the degree of washing by measuring the absorption of washing water on a spectrophotometer. Washing is continued until the absorption of washing water in the UV region is absent. The washed membrane is stretched using suitable clothespins or other devices on a wooden frame and dried to constant weight at room temperature. The resulting sorption composite membrane sheet is stored in a tightly closed glass or plastic container until further use or cut into single tapes with a size of 1 × 12 cm ² .

To modify a segment of the membrane with an area of 100 cm ² (simultaneously on both sides) with one layer of polyaniline, 5.85 ml of 37% hydrochloric acid and 2.095 ml of aniline mixed in 210 ml of water, as well as 4.56 g of ammonium persulfate were used.

The weight gain of the sample of the modified membrane compared to the original membrane is 10 ± 0.1% (on average, 9.91%).

A single sample of the sorption composite membrane (area 12 cm ² ) is twisted and placed in a plastic cartridge. The cartridge is closed with a lid and packaged under sterile conditions in a dense plastic container. The resulting sorption composite membrane is used in the form of a rolled up roll with a packing density of 25-60 cm ² / cm ³ and placed in a plastic cartridge for one-step extraction (purification) of DNA from complex biological mixtures.

The inventive bio-separating device for DNA isolation is shown in FIG. 1 where

1 - sorption composite membrane twisted into a roll

2 - microtube

3 - plastic cartridge

The inventive bioseparating device for DNA extraction works as follows.

A DNA-containing mixture (e.g., a bacterial lysate, 50-100 μl) is placed on a twisted sorption composite membrane 1 with a packing density of 25-60 cm ² / cm ³ placed in a membrane bio-separating element, which is a plastic cartridge 2 (pre-moistened with deionized water) 6 × 25 mm) placed in a microtube 3. If necessary, excess water is removed. Then the plastic cartridge 2 is placed in a centrifuge, centrifuged for 30 s at a speed of 2000 rpm. The resulting purified DNA solution is suitable for various biotechnological applications, primarily for PCR analysis.

To implement the invention using the following substances and materials.

Microfiltration composite hydrophilic membranes made of polyamide, polyethersulfone and polyvinylidene fluoride were used as a porous substrate.

Aniline, ammonium persulfate, sodium acetate were used as reagents to obtain a sorption coating and evaluate its sorption properties; isopropyl alcohol, chloroform, sodium hydroxide, tris (hydroxymethyl) aminomethane (tris), ethylenediaminetetraacetic acid (EDTA), boric acid, agarose, ethidium bromide, orange W, glycerin, bovine serum albumin - all reagents produced by Sigma, Germany, as well as acid (GOST 3118-77) produced by Sigma Tech LLC, Russia, aqueous ammonia (GOST 24147-80) manufactured by Khimservice CJSC, Russia, 96% ethyl alcohol (GOST 5962-2013) manufactured by Medkhimprom OJSC, Russia . All reagents and materials - grade o.s.ch. or for HPLC analysis, with a purity of 96.5 to 99.5% - used without further purification.

Deionization of water was carried out using a Milli Q RG ultra pure water system (Millipore, USA).

Tests using model microorganisms or clinical samples were carried out on the basis of the Molecular Diagnostics Group of the IBCh RAS and NPF Genlab (Russia), respectively, using hardware, kits and reagents and in accordance with the laboratory protocols of these organizations.

The effectiveness of the use of a sorption composite membrane for the isolation and purification of DNA was evaluated by using model mixtures in the claimed bioseparating device in the form of a plastic cartridge inserted in a microtube receiver.

For the experiment, sorption composite membranes were used with a mass fraction of a polyaniline sorption coating of 10, 15, 25%, respectively, and with an average pore size of 0.65, respectively; 0.45 and 0.2 microns.

DNA isolation from cell cultures (E. coli) was performed as follows:

- to 50 ml of cell suspension (10 ⁹ cells / ml) was added 100 μl of buffer-1 (250 μl of 1M Tris HCl pH 8.0, 250 μl of 1M magnesium chloride, 500 μl of Triton X 100, 5.48 g of sucrose, the volume was brought up to 50 ml of deionized water) and 20 μl of a 3% aqueous solution of proteinase K (obtained using a proteinase K preparation immobilized on particles of polyethylene glycol - Maxatase), the resulting mixture was stirred on a shaker for 5-10 s and incubated at 60 ° C for 10 min;

- to the mixture was added 100 μl of buffer-2 (5 ml of 1M Tris-HCl pH 8.0, 0.5 ml of 0.5M EDTA pH 8.0, 2 ml of 5M sodium chloride, 0.1 g of sodium dodecyl sulfate and the volume was adjusted to 50 ml deionized water), stirred on a shaker for 5-10 seconds and re-incubated at 60 ° C for 10 min;

- the mixture was stirred on a shaker for 10-15 seconds and applied to the membrane surfaces previously wetted with deionized water, 50-100 μl per cartridge. For wetting, 250 μl of water was preliminarily applied to each cartridge and centrifuged for 2 min at 2000 rpm;

- cartridges were incubated for at least 2.5 minutes, then centrifuged for 30 seconds at 2000 rpm;

- the obtained eluates were analyzed spectrophotometrically and after electrophoresis in 2% agarose gel.

The ratio of absorption intensities at 260 nm and 280 nm (A _260/280 ) of the resulting eluates was 1.71; 1.85 and 1.82.

To demonstrate the effect of reversible retention of proteins, 100 μl of a BSA solution (550 μg) in a TE buffer (pH 7.2) was introduced into a bioseparating device containing a sorption composite membrane twisted into a roll with a given density. Cartridges were incubated for 2.5 minutes, then centrifuged for 30 seconds at 2000 rpm. Then, the resulting eluate was transferred to a plastic tube and analyzed spectrophotometrically, determining the protein content in the sample from the calibration curve. After that, 100 μl of diluted hydrochloric acid (pH 4.0) was applied to the bioseparating element and the resulting eluate was again transferred and analyzed spectrophotometrically.

An analysis of the obtained data indicates that the protein retained at neutral pH values is almost completely desorbed from the membrane surface with decreasing pH.

As a result of the experiments on DNA extraction, data were obtained on the yield of the target substance up to 90-95% with a duration of the entire technological cycle from 4 to 5 minutes with a duration of the centrifugation stage (actually the stage of DNA extraction) - 30 sec.

As can be seen from the above examples, the present invention can effectively isolate DNA in one stage. In this case, DNA is not retained by the surface of the created sorption composite membrane (the subsequent stage of desorption is excluded when it is isolated) and can be isolated from the surface of the same membrane by elution with a suitable buffer. The process is extremely simple and equally convenient for both manual and automatic execution.

Thus, the proposed sorption composite membrane for DNA isolation and a bioseparating device based on it is a simple, cost-effective solution that allows for the rapid isolation and purification of both nucleic acids and proteins that do not require the use of expensive materials as a carrier in the preparation of a composite sorbent .

The experimental data presented show the promise of a new material - a sorption composite membrane and a bioseparating device based on it, used for single-stage DNA extraction and purification. The obtained new membrane sorbents can be successfully used in biotechnology and medical diagnostics, in particular, with simplified sample preparation during PCR analysis.

Claims (3)

1. Sorption composite membrane for DNA isolation, comprising a porous substrate and a sorption coating, characterized in that the porous substrate is a microfiltration polymer membrane with a porosity of 0.2-0.65 μm made of polyamide, polyethersulfone or polyvinylidene fluoride, the sorption coating of the substrate is made from polyaniline, while the mass fraction of the sorption coating of polyaniline in the composition of the sorption composite membrane is 10-25%. 2. A sorption composite membrane for DNA isolation according to claim 1, characterized in that the preferred porosity is 0.45 μm. 3. A bio-separating device for DNA isolation, which is a plastic cartridge inserted into a microtube, while the plastic cartridge contains a sorption composite membrane according to claim 1, twisted into a roll with a packing density of 24-48 cm ² / cm ³ .

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