Multiplex Genotyping of Allelic Variants of Genes Involved in Metabolizing Antileukemic Drugs

A biochip, primer set, and genotyping protocol were developed to simultaneously address 16 single nucleotide polymorphisms in antileukemic drug metabolism genes, including TPMT, ITPA, MTHFR, SLCO1B1, SLC19A1, NR3C1, GRIA1, ASNS, MTRR, and ABCB1. The genotyping procedure included a one-round multiplex polymerase chain reaction (PCR) with simultaneous incorporation of a fluorescent label into the PCR product and subsequent hybridization on a biochip with immobilized probes. The method was used to test 65 DNA samples of leukemia patients. Fluorescence signal intensity ratios in pairs of wildtype and respective mutant sequence probes were analyzed for all polymorphic markers and demonstrated high accuracy of genotyping. The reliability of genotype determination using the biochip was confirmed by direct Sanger sequencing.     

HLA-DQA1, AB0, and AMEL genotyping of biological material with biochips

A method for genotyping of biological material for AB0, HLA-DQA1, and AMEL loci is described. The method utilizes allele-specific SNP typing with th e help of hydrogel biochip technology. Amplified fluorescentlylabeled fragments of genes were hybridized with SNP-specific DNA probes immobilized on a biochip. The alleles of the gene in a sample were determined according to the distribution of the fluorescent signal. The minimal amount of biological material required for the assay is 100 pg of DNA. The biochip assay was used to analyze 442 DNA specimens of the Eastern Slavic population of Russia and to determine the allelic frequencies of AB0 and HLA-DQA1 loci. The feasibility of genotyping the biological traces of investigative value, such as cigarette butts, sweat traces on paper, and swabs of the lip of the glass, was demonstrated. This assay is applicable in forensic studies. The significance of identification for the used loci is 99.6%.     

Investigation of frequency of occurrence of core Y haplogroups in residents of Moscow and St. Petersburg

The collection of DNA from 239 Moscow residents and 62 St. Petersburg residents has been investigated by means of a biochip for genotyping haplogroup markers of the Y chromosome, including M130 (C), M145 (DE), P257 (G), M69 (II), U179 (I), M304 (J), M185 (L), M231 (N), M175 (O), P224 (R), L146 (R1a), and M343 (R1b). The distribution of haplogroup frequency in populations native to Moscow and St. Petersburg has been obtained. Three subsamples that vary in the duration of residence (one, two, or three generations) were compared. The increase in J, G, and R1b frequencies may be related to immigration from the Caucasus and other regions.     

Biophysical methods for biochip analysis. Use of wide field digital fluorescent microscopy

This paper discusses an issue on the development of biophysical methods for biochip analysis. A scheme and construction of a biochip analyzer based on wide-field digital fluorescence microscopy are described. The analyzer is designed to register images of biological microchips labeled with fluorescent dyes. The device developed is useful for high-sensitive throughput recording analyses by biochips after interaction of immobilized probes with fluorescently labeled sample molecules as well as it provides the higher rate of the analysis compared to laser scanning devices. With this analyzer a scope where biological microchips can be applied becomes wider, the development of new protocols of the analyses is possible and standard analyses run faster with the use of biochips, the expenses for the analysis performance can be reduced.     

Plant microsatellite genotyping with 4-color fluorescent detection using multiple-tailed primers

We extended the concept of fluorescent microsatellite genotyping with a single-universal tailed primer to the simultaneous use of three different tailed primers to allow multiplexed 4-color detection for medium throughput genotyping of plant species. The method was tested on Eucalyptus DNA samples using three forward primer sequences of human microsatellite markers labeled with different fluorescent dyes. The robustness of the method was tested for the simultaneous detection and genetic analysis of microsatellites in a genetic mapping experiment. This method allows reliable and cost-effective genotyping with the same level of multiplexing attained in regular microsatellite fluorescent detection assays. Besides the enhanced quality of the genotypic data provided by the fluorescent detection method when compared to colorimetric ones, the economy brought about by this method becomes greater with an increasing number of microsatellite markers. This method has been particularly useful for genotyping populations of several tropical tree species addressing community-wide population genetics and conservation questions.     

应用基因芯片快速检测分枝杆菌

目的:将临床疑似分枝杆菌感染患者的标本用基因芯片方法进行分枝杆菌菌种鉴定,并将基因芯片检测的结果与传统的抗酸染色方法进行对比。方法:采用基因芯片PCR扩增、分子杂交、微阵列芯片扫描的方法检测379例临床疑似标本。结果:基因芯片阳性检出率为16.3%(62/379),涂片抗酸染色法阳性检出率为15.3%(58/379),两者差异无统计学意义(χ2=0.16,P>0.05);62例基因芯片检测阳性患者中有52例为结核分枝杆菌,另有10例为非结核分枝杆菌(其中3例偶然分枝杆菌,1例龟/脓肿分枝杆菌,1例堪萨斯分枝杆菌,4例浅黄分枝杆菌,1例海分枝杆菌)。结论:结合临床病例分析结果显示,基因芯片检测对鉴别结核分枝杆菌和非结核分枝杆菌分型具有快速、特异性高的特点,在分枝杆菌感染的早期诊断和治疗上具有重要的临床价值,值得推广和应用。     

Biophysical methods for biochip analysis. Use of wide-field digital fluorescence microscopy

This paper discusses the development of biophysical methods for biochip analysis. A scheme and construction of a biochip analyzer based on wide-field digital fluorescence microscopy are described. The analyzer is designed to register images of biological microchips labeled with fluorescent dyes. The device developed is useful for high-sensitivity throughput recording of analyses with biochips after interaction of immobilized probes with fluorescently labeled sample molecules as well as it provides a higher rate of the analysis compared with laser scanning devices. With this analyzer, the scope where biological microchips can be applied becomes wider, development of new protocols of the analyses is possible and standard analyses run faster with the use of biochips, the expenses for performing routine analyses can be reduced.     

Immunological biochips for parallel detection of surface antigens and morphological analysis of cells

A biochip for detecting 26 cluster differentiation (CD), HLA-DR and IgM antigens on lymphocyte surface is described. The biochip, which represents a microarray of antibodies (IgG) against a panel of selected antigens immobilized on transparent plastic surfaces in 1.5-mm spots, was used for the study of normal and neoplastic lymphocytes and can also be used for determining percent of cells expressing definite surface antigens in lymphocyte suspensions. The results are consistent with data obtained by flow cytometry. The novel biochip technology entails a combination of conventional staining of cells immobilized on biochips and morphological analysis.     

Estimation of relative allele frequencies of single-nucleotide polymorphisms in different populations by microarray hybridization of pooled DNA

Single-nucleotide polymorphisms (SNPs) are considered useful polymorphic markers for genetic studies of polygenic traits. A new practical approach to high-throughput genotyping of SNPs in a large number of individuals is needed in association study and other studies on relationships between genes and diseases. We have developed an accurate and high-throughput method for determining the allele frequencies by pooling the DNA samples and applying a DNA microarray hybridization analysis. In this method, the combination of the microarray, DNA pooling, probe pair hybridization, and fluorescent ratio analysis solves the dual problems of parallel multiple sample analysis, and parallel multiplex SNP genotyping for association study. Multiple DNA samples are immobilized on a slide and a single hybridization is performed with a pool of allele-specific oligonucleotide probes. The results of this study show that hybridization of microarray from pooled DNA samples can accurately obtain estimates of absolute allele frequencies in a sample pool. This method can also be used to identify differences in allele frequencies in distinct populations. It is amenable to automation and is suitable for immediate utilization for high-throughput genotyping of SNP.     

Detection of <Emphasis Type="Italic">KRAS</Emphasis> mutations in tumor cells using biochips

Somatic mutations in the KRAS gene are important markers of some types of tumors, for example, pancreatic cancer, and may be useful in early diagnostics. A biochip has been developed which allows deter-mining most frequent mutations in 12, 13, and 61 codons of the KRAS gene. To increase the sensitivity of the method and to enable the analysis of minor fractions of tumor cells in clinical samples, the method of blocking wild type sequence PCR amplification by LNA-oligonucleotides has been used. The product of LNA-clamp PCR was further hybridized with oligonucleotide probes, immobilized on the biochip. The biochip was tested with 42 clinical DNA samples from patients with pancreatic cancer, mostly duct adenocarcinomas. As reference methods, RFLP analysis and sequencing were used. The developed approach allows detecting somatic mutations in the KRAS gene if the portion of tumor cells with mutation is at least 1% of the whole cell population.     

毛细管电泳四色荧光检测法分析茶树SSR标记

将毛细管电泳四色荧光栓测技术应用于茶树SSR标记分析.该方法采用三引物PCR扩增SSR位点,三引物即在5'端加有M13尾巴序列(5'-CACGACGTTGTAAAACGAC-3')的特异正向引物、特异反向引物及带有荧光标记的通用型M13引物:为了运用四色荧光检测系统使通过一次毛细管电泳能同时检测3个以上的SSR位点,采用蓝、绿、黑3种不同颜色的荧光染料分别对3个M13引物进行标记. 应用该方法对42个茶树品种(系)的16个SSR位点进行遗传分析的结果表明:此法具有简便、可靠、低成本及高通量的优点;且随着所分析SSR位点数的增加,降低成本的效果更加显著.采用建立的方法,还筛选获得了11个多态性丰富的可应用于茶树遗传研究的SSR标记.     

The Efficiency of DNA Labeling with Near-Infrared Fluorescent Dyes

The efficiency of DNA labeling was assessed for 2'-deoxyuridine 5'-triphosphate (dUTP) derivatives containing the Cy7 cyanine dye as a fluorophore. Two fluorescent Cy7-labeled dUTP analogs differed in the chemical structure of the linker between the fluorophore and nucleotide moieties. The efficiency of the polymerase chain reaction (PCR) and inhibition with modified nucleotides were estimated by real-time PCR. The efficiency of labeled nucleotide incorporation in PCR products was measured by quantitative electrophoresis. The efficiency of target DNA labeling was evaluated by binding the fluorescently labeled PCR products to a microarray of oligonucleotide probes immobilized in hydrogel drops (a biochip). The near-infrared hybridization signal was detected by digital luminescence microscopy. An increase in linker length was found to provide more efficient incorporation of the labeled nucleotide. Both of the compounds provided high sensitivity and high specificity of DNA testing via allele-specific hybridization on a biochip.

     

TP-M13自动荧光检测法在高粱SSR基因型鉴定中的应用

研究利用TP-M13自动荧光检测法对48份高粱材料进行了简单序列重复(SSR)标记的基因型鉴定.在这个方法中,需要合成一个普适性的用荧光(如FAM)标记的M13引物,并把M13的正向引物和一个SSR反向引物相连(称为TP-M13引物),利用3条引物序列进行PCR扩增,其PCR产物在DNA测序仪(如ABI3700仪)上进行自动荧光检测.结果表明,这种方法和其他的传统方法相比,具有经济、灵敏、高效的优点.建议在利用数量很多的SSR标记对数量有限的基因组较小的材料进行基因型鉴定时,使用TP-M13自动荧光检测系统.     

Detection of KRAS mutations in tumor cells using biochips

Somatic mutations in the KRAS gene are important markers of some types of tumors, for example, pancreatic cancer, and may be useful in early diagnostics. A biochip has been developed which allows determining most frequent mutations in 12, 13 and 61 codons of the KRAS gene. To increase the sensitivity of the method and to make possible the analysis of minor fractions of tumor cells in clinical samples the method of blocking a wild type sequence PCR amplification by LNA-oligonucleotides has been used. The product of LNA-clamp PCR was further hybridized with oligonucleotide probes, immobilized on biochip. Biochip was tested with 42 clinical DNA samples from patients with pancreatic cancer, mostly ductal adenocarcinomas. As reference methods, the RFLP analysis and sequencing were used. The developed approach allows detecting somatic mutations in the KRAS gene if the portion of tumor cells with mutation is at least 1% of whole cell population.     

Application of an antibody biochip for p53 detection and cancer diagnosis

Detection of the p53 tumor suppressor gene is important in early cancer diagnostics because alterations in the gene have been associated with carcinogenic manifestations in several tissue types in humans. We have developed an antibody-based detection instrument, the biochip, to detect the presence of the anti-p53 antibody in human serum. The design of this highly integrated detector system is based on miniaturized phototransistors having multiple optical sensing elements, amplifiers, discriminators, and logic circuitry on an IC board. The system utilizes laser excitation and fluorescence signals to detect complex formation between the p53 monoclonal antibody and the p53 antigen. Recognition antibodies are immobilized on a nylon membrane platform and incubated in solutions containing antigens labeled with Cy5, a fluorescent cyanine dye. Subsequently, this membrane is placed on the detection platform of the biochip and fluorescence signal is induced using a 632.8-nm He-Ne laser. Using this immuno-biochip, we have been able to detect binding of the p53 monoclonal antibody to the human p53 cancer protein in biological matrices. The performance of the integrated phototransistors and amplifier circuits of the biochip, previously evaluated through measurement of the signal output response for various concentrations of fluorescein-labeled molecules, have illustrated the linearity of the microchip necessary for quantitative analysis. The design of this biochip permits sensitive, selective and direct measurements of a variety of antigen-antibody formations at very low concentrations. Furthermore, the acquisitions of the qualitative and quantitative results are accomplished rapidly, in about 15 min. These features demonstrate the potential of this antibody-based biochip for simple, rapid and early biomedical diagnostics of cancer.     

Development of a biochip with an internal calibration curve for quantitating two forms of the prostate-specific antigen

Three-dimensional gel-based biological microchips were developed for simultaneous quantitation of total (PSA_tot) and free (PSA_free) forms of the prostate-specific antigen in human serum in the “one patient, one biochip” format. A method not demanding construction of calibration curves prior to the assay was applied to quantitation of PSA_tot and PSA_free. In addition to gel elements with immobilized antibodies against PSA_tot and PSA_free, the biochip contains elements with immobilized PSA at different concentrations, forming an internal calibration curve. Data are processed and interpreted with the special-purpose ImaGelAssay program. The sensitivity of the assay is 0.3 ng/ml for PSA_tot and 0.2 ng/ml for PSA_free. The variation coefficient for measurements with one biochip series does not exceed 10%. The correlation coefficients between the estimates obtained for human sera by the biochip assay and by conventional ELISA were 0.988 for PSA_tot and 0.987 for PSA_free.     

Implementation of alternating excitation schemes in a biochip-reader for quasi-simultaneous multi-color single-molecule detection

We report here the development of a device for single-molecule biochip readout using fast alternating excitation. The technology extends standard imaging cytometry by offering additional color channels in excitation. To enable the study of mobile objects, e.g. actively transported vesicles in living cells or freely diffusing lipids in a lipid bilayer, the frequency of the illumination pulses was chosen high enough to virtually freeze the motion of the biomolecules, as they are shifted through the illuminated area. The synchronization of sample illumination, scanning and line-camera readout yield two quasi-simultaneously recorded images covering the same sample region. Diffraction-limited resolution and high localization precision for point-light sources down to approximately 10 nm was shown by scanning immobilized 100 nm fluorescence latex beads. Ultra-sensitivity was demonstrated by imaging single fluorescent streptavidin molecules diffusing in a fluid lipid bilayer. Two-color streptavidin labeled with Cy3 and Cy5 could be easily identified in the two respective excitation channels; high accordance in the dye positions confirms the applicability for colocalization studies of moving objects. Finally, scans of antibody-receptor interactions in large populations of live cells illustrate the feasibility of this method for biochip application.     

A Biochip for Genotyping Polymorphisms Associated with Eye,Hair, Skin Color,AB0 Blood Group,Sex, Y Chromosome Core Haplogroup,and Its Application to Study the Slavic Population

Molecular Biology - This paper presents a method for genotyping a panel of 60 single nucleotide polymorphisms (SNPs) using single-stage PCR followed by hybridization on a hydrogel biochip. The pool...     

Analysis of genetic variation in the GenomEUtwin project.

Multiallelic short tandem repeat polymorphisms, or microsatellites, are useful markers in genome wide scans to identify chromosomal regions containing genes underlying disease loci. The biallelic single nucleotide polymorphism (SNP) can be used to fine map previously identified large candidate regions or to test functional candidate genes by association analysis. In the GenomEUtwin project the population based impact of susceptibility genes for six multifactorial traits will be studied. A genome wide panel of informative human microsatellite markers will be analyzed by fluorescent capillary electrophoresis in well characterized twin and population samples. Contrary to microsatellites, selection of the most informative panels of SNPs is hampered by imperfect data on the allele frequencies and population distribution of SNPs markers in the databases. Therefore, selection of SNPs requires a substantial amount of bioinformatics, and, the SNPs need to be validated experimentally in the relevant populations prior to genotyping large sample sets. In the GenomEUtwin project, large scale genotyping of SNPs will be performed using the SNPstreamUHT and MassARRAY genotyping systems that are based on the primer extension reaction principle combined with fluorescent and mass spectrometric detection, respectively. Production of the genotyping data will be a joint effort by GenomEUtwin partners at the University of Helsinki, the National Public Health Institute in Helsinki, Finland and Uppsala University, Sweden. All genotyping data will be stored in a common database established specifically for the GenomEUtwin project, from where it can be accessed by the twin research centres that provided the samples for genotyping.     

Multiplexed single nucleotide polymorphism genotyping by oligonucleotide ligation and flow cytometry

BACKGROUND: We have developed a rapid, high throughput method for single nucleotide polymorphism (SNP) genotyping that employs an oligonucleotide ligation assay (OLA) and flow cytometric analysis of fluorescent microspheres. METHODS: A fluoresceinated oligonucleotide reporter sequence is added to a "capture" probe by OLA. Capture probes are designed to hybridize both to genomic "targets" amplified by polymerase chain reaction and to a separate complementary DNA sequence that has been coupled to a microsphere. These sequences on the capture probes are called "ZipCodes". The OLA-modified capture probes are hybridized to ZipCode complement-coupled microspheres. The use of microspheres with different ratios of red and orange fluorescence makes a multiplexed format possible where many SNPs may be analyzed in a single tube. Flow cytometric analysis of the microspheres simultaneously identifies both the microsphere type and the fluorescent green signal associated with the SNP genotype. RESULTS: Application of this methodology is demonstrated by the multiplexed genotyping of seven CEPH DNA samples for nine SNP markers located near the ApoE locus on chromosome 19. The microsphere-based SNP analysis agreed with genotyping by sequencing in all cases. CONCLUSIONS: Multiplexed SNP genotyping by OLA with flow cytometric analysis of fluorescent microspheres is an accurate and rapid method for the analysis of SNPs.