FR2822477A1 - Rapid phenotyping of nucleic acid, useful e.g. for detecting risk of restenosis, where nucleic acid is isolated without chemical extraction or protease treatment - Google Patents

Abstract

Genotyping of nucleic acid (NA) without chemical extraction or addition of protease comprising treating a cell preparation with a lytic surfactant, heating then centrifuging the treated cells, and recovering the supernatant which contains NA for genotyping, is new.

Description

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 The invention relates to a rapid genotyping method, without prior chemical extraction of DNA.

 The genotyping of individuals consists of the analysis of their genotype, and notably includes the determination of polymorphisms. Today, numerous DNA polymorphisms, distributed throughout the genome, have been identified. These mutations, functional or not, reflecting the diversity of each individual, are listed in accessible databases, for example from the National Center for Biotechnology Information, and from which geneticists draw to locate disease genes. They are most frequently nucleotide polymorphisms (single nucleotide polymorphisms, SNP). These genotypic analyzes can be used to assess the risk that an individual develops a disease (Lathrop et al, 2000) or to adapt therapeutic protocols to the genotypic profile of a patient (Amouyel, 2000).

 Genotyping studies are generally carried out on genomic DNA extracted, for example from blood leukocytes, by conventional methods of DNA extraction. The article Amant et ai, 1997, which reports on an analysis of the polymorphisms of the ACE gene (angiotensin converting enzyme), thus refers to protocols for routine DNA preparation (Marcadet et al, 1987).

 These nucleic acid extraction methods, however, have the disadvantage of being relatively long to perform (generally between 24 and 48 hours).

 In addition, they generally use proteases, the cost of which is not negligible.

 However, it would be advantageous if genotyping results could be obtained very quickly, and at a reasonable cost, for example for diagnostic purposes or to adapt the treatment to the patient whose genotype has been identified.

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 The authors of the present invention have now developed a genotyping method which solves this problem simply.

In accordance with the invention, the nucleic acid which serves to identify the genotype has not undergone chemical extraction. In particular, no extraction with phenol, chloroform, ether or isobutanol is carried out. By chemical extraction is meant any step based on the use of the differential solubility of molecules (nucleic acid and contaminants) between two immiscible phases, or on the use of the differential reactivity of these molecules with respect to an agent chemical. Within the meaning of the invention, the term extraction therefore includes the conventional precipitation of nucleic acids in the presence of a precipitation agent of ethanol or isopropanol type for example.

 In fact, the authors of the invention have eliminated these usual extraction steps, and replaced them by simple heating followed by centrifugation.

 The subject of the present invention is therefore a method of genotyping a nucleic acid without a chemical extraction step, comprising: placing a cell preparation in the presence of a detergent agent, which allows the lysis of cells; heating the preparation obtained, then centrifuging it; the recovered supernatant, which comprises nucleic acids, being finally subjected to genotypic analysis.

 No chemical extraction, chromatography or other processing of the cell preparations is necessary.

 Significantly, and unlike most conventional extraction methods, the method of the invention does not require the addition of proteases, which makes it possible to further reduce the time for preparing DNA and reduces the overall cost of the method.

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 The cell preparation serving as starting material may for example be a whole blood sample, or a preparation of blood leukocytes. It can also be tissues, such as tissue biopsies but also smears, in particular endo-buccal.

 The detergent agents which can be used are well known to those skilled in the art. Examples include SDS (Sodium Dodecyl Sulfate) or sarcosyl.

 In accordance with the present invention, the nucleic acid preparation is incubated at a temperature of about 70 to 100oC, preferably 85-95OC, more preferably 90OC.

 An incubation time of the order of 30 minutes to 1 hour is suitable, for example around 40 minutes.

 Advantageously, the preparation can be incubated at 90 ° C. for 40 minutes.

 The conditions of the following centrifugation are adapted to precipitate the contaminants (such as cellular debris) in the form of a pellet and leave the nucleic acid in the supernatant. Centrifugation on the order of 5 to 15 minutes (preferably 10 minutes) between approximately 4000 and 7000g (preferably approximately 5600g) is particularly suitable.

 The recovered supernatant, which includes the nucleic acids, can be directly analyzed. These nucleic acids are essentially formed by genomic DNA.

 Genotypic analysis is carried out according to methods known to those skilled in the art.

 A determination of alleles can for example be carried out after amplification (preferably of the PCR type, chain amplification by a polymerase) of the DNA region in which there is a polymorphism of interest. For this, it is possible to create in a PCR primer a cleavage site for a restriction enzyme, which does not exist in individuals carrying one of the alleles. It is also possible to use a hybridization technique using allele-specific oligonucleotide probes. Amplification products

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 can then be separated in a matrix, for example by electrophoresis on an agarose gel, the polymorphism of interest being then easily detected according to standard techniques.

 Genotypic analysis of SNPs by mass spectrometry can also be performed (Sauer et al, 2000). It is based on the primer extension method which generates products with a specific mass for each allele. The alleles are distinguished by their difference in mass, which is easy to interpret automatically by computer.

 Genotypic analysis can also be carried out by implementing sequencing, preferably automatic.

 The method of the invention is not only very fast, but is also very sensitive. It is therefore particularly suitable for any clinical application which would require the rapid and reliable determination of the genotype of a patient. The method of the invention can, for example, be used to identify the D alleles of the ACE gene, in relation to a risk of restenosis after the installation of a stent.

 It can also be useful for determining mutations in tumor cells, by analyzes carried out on samples of tumor cells, during a surgical intervention. The determination of these mutations can then orient the surgeon's gesture, depending on the origin of the cancer thus identified.

 The method of the invention also has an interesting practical and commercial aspect: inexpensive, it can be implemented on cell samples from subjects whose DNA does not need to be stored. Among the nonlimiting examples of applications, there may be mentioned in particular the genotyping of alleles of the APOE gene, for the purpose of prognosis of the risk of developing Alzheimer's disease (FR 2 716 894).

 The following example illustrates the invention without limiting its scope.

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EXAMPLE: ACE genotyping A genotyping for the ACE gene coding for the angiotensin converting enzyme was carried out on 345 patients having undergone coronary stent implantations, in the 12 to 24 hours preceding the analysis.

 15 u! of whole blood taken from EDTA anticoagulant were mixed, to 60 u! of 0.5% Lauryl sarcosyl in red blood cell lysis buffer (7.7 mM Tris HCl, MgC 2, 6H20 5 mM, 10 mM NaCl, pH 7.6).

 The samples were then incubated for 40 minutes at 90oC, then centrifuged for 10 minutes at 5600g.

 A fraction of 5 µl of supernatant was used for amplification and to determine the ACE genotype. This analysis was carried out according to the protocol described in the article by Amant et al, 1997.

 Briefly, the ACE fragment containing the desired polymorphism (ID) was amplified using a DNA thermocycler from PerkinElmer, using the DNA polymerase from Thermus aquaticus (Amersham). The ACE polymorphism was detected as described previously in the article by Tiret et al, 1992, with the exception of the addition of DMSO to increase the amplification of the ACE 1 allele (Fogarty et al, 1994; Shanmugam et al, 1993).

The reaction products were analyzed by electrophoresis on an agarose gel for allelic identification. Patients were also genotyped with a three-primer system (Hamon et al, 1995), for confirmation. The amplification products were deposited on electrophoresis gels (NuSieve agarose at 4% FMC Bioproducts).

 For more details concerning the technique for detecting ACE polymorphisms, a person skilled in the art can usefully refer to the description of application WO 90/0345, and more generally to the principles described in US Patents 4,683, 202 and US 4,683, 195.

 For all the patients, the results of the rapid determination of the genotype were verified using conventional techniques of DNA extraction using in particular phenol extraction and isopropanol precipitation (Amant et al, 1997, and Marcadet et al, 1987).

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 The rapid genotyping method made it possible to obtain results in only about 4 hours.

 16.5% of patients had the genotype II, 50% the genotype ID and 33.5% the genotype DD.

 Compared with the conventional genotyping method, the rapid DD carrier detection test had a sensitivity of 100%, a specificity of 98.7%, a positive predictive value of 97.4% and a negative predictive value of 100%.

 Patients with a DD genotype for CEA have a higher risk of restenosis after implantation of the stent. Quickly genotyped, these patients will be able to benefit from preventive therapy as soon as possible.

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REFERENCES BIBLIOGRAPHIQUES

Amant et al, 1997, Circulation, 96 (3), pp 56-60 Amouyel, 2000, Biofutur, no 206, pp 86-88 Fogarty et al, 1994, Lancet, no 343, p.

BIBLIOGRAPHICAL REFERENCES

Amant et al, 1997, Circulation, 96 (3), pp 56-60 Amouyel, 2000, Biofutur, no 206, pp 86-88 Fogarty et al, 1994, Lancet, no 343, p.

851 Hamon et al, 1995, Circulation, no 92, pp 296-299 Lathorp et al, 2000, Biofutur, no 206, pp 82-85 Marcadet et al, 1987, Histocompatibility Testing, New York, NY: Springer-Verlag, pp 553-560 Sauer et al, 2000, Nucleic Acids Research, 28 (5): E13 and 28 (3): E100 Shanmugam et al, 1993, Methods Appl., Vol. 3, pp 120-121 Tiret et al, 1992, Am. J. Hum. Broom. flight. 51, pp 197-205

Claims (7)

 1. A method for genotyping a nucleic acid without a chemical extraction step or the addition of proteases, comprising putting a cell preparation in the presence of a detergent agent, which allows the lysis of cells; heating the preparation obtained, then centrifuging it; the recovered supernatant, which comprises nucleic acids, being finally subjected to genotypic analysis.  2. Method according to claim 1, in which the heating of the preparation is carried out at a temperature of 70 to 100oC, preferably at about 90C.  3. Method according to claim 1 or 2, wherein the heating of the preparation is carried out for a period of 30 minutes to 1 hour, preferably for about 40 minutes.  4. Method according to one of the preceding claims, in which the centrifugation is carried out between approximately 4000 and 7000g, preferably approximately 5600g.  5. Method according to one of the preceding claims, in which the cell preparation consists of a whole blood sample. <Desc / Clms Page number 9>  6. Method according to one of the preceding claims, in which said genotypic analysis consists in determining the D alleles of the ACE gene coding for the angiotensin converting enzyme.  7. Method according to one of the preceding claims, in which said genotypic analysis comprises the amplification of a DNA region where there is a polymorphism of interest, the separation of the amplification products in a matrix, and the detection of said polymorphism.