Evaluation of IFN-γ polymorphism +874 T/A in patients with recurrent tonsillitis by PCR Real Time Mismatch Amplification Mutation Assay (MAMA Real Time PCR)

Interferon gamma (IFN-γ) is an important cytokine that plays a crucial role in the balance between normal and pathological immune response. Defect of IFN-γ can give a predisposition to infectious disease, autoimmune pathologies and tumours. Different polymorphisms in this gene have been described, in particular the single nucleotide polymorphism (SNP) + 874 1 T/A that may affect IFN-γ gene expression. Several techniques can be used for the detection of SNPs. In this work two PCR Real Time assays were developed, an Amplification Refractory Mutation System (ARMS) and a Mismatch Amplification Mutation Assay (MAMA). Twenty-seven samples from patients (tonsillectomy) and 85 from donor’s blood bank were considered. As a result, 78/85 controls (91.7%) and 25/27 patients (92.6%) were heterozygosis, considering the ARMS-PCR; 55/85 (64.7%) and 14/27 (51.9%) were heterozygosis using MAMA-PCR assay. Fourteen of 85 (16.5%) and 8/27 (29.6%) were homozygosis A, 16/85 (18.8%) and 5/27 (18.5%) presented homozygosis T, taking into account the MAMA-PCR. There are statistically difference between the two assay with p < 0.0001 at Chi-square test. Our preliminary data suggest that tonsillectomy patients had a statistical trend to possess the low IFN-γ polymorphism when compared with control subject (p = 0.3) but is not statistically significant. In conclusion the Real time MAMA-PCR assay has several advantages over other SNP identification techniques such as rapidity, reliability, easily to perform in one working day and applicable in clinical molecular diagnostic laboratories, although sequencing remains the gold standard.     

Comparison between two standardized cultural methods and 24 hour duplex SYBR green real-time PCR assay for Salmonella detectionin meat samples

Food-borne diseases caused by Salmonella represent a worldwide public health problem. Salmonella must be absent in an established amount depending on the kind of the product and usually cultural methods have to be applied to evaluate the compliance of the products. ISO 6579:2002 in Europe and FSIS MLG 4.04.:2008 in the USA have usually been employed to detect Salmonella in meat, poultry and egg products. A Real Time PCR method using probes has recently been validated against the NMKL (Nordic Committee on Food Analysis) standard method. This method has been modified using the less expensive Sybr Green Real Time PCR approach and applied directly in the 18 hours preenrichment broth for the purpose of detecting Salmonella in meat products in less than 24 hours. The purpose of this study was to: - compare the effectiveness of ISO and FSIS cultural methods; - develop a new 24 hour duplex Sybr Green Real Time PCR-melting curve analysis; - evaluate the performance of Salmonella, Standard Method, Rapid Method, SYBR Green Real Time PCR. The equivalence between ISO and FSIS methods was demonstrated and the use of SYBR Green Real Time PCR as a screening tool for negative results seems appealing especially to evaluate compliance with the HACCP systems.     

Direct haplotype determination by double ARMS: specificity, sensitivity and genetic applications.

We have developed a novel double Amplification Refractory Mutation System (double ARMS) using a highly polymorphic region 5' to the human delta-globin gene as a model system. The double ARMS approach involves using two allele-specific ARMS primers simultaneously during DNA amplification by the polymerase chain reaction (PCR). The resulting system is highly sensitive and more specific than single ARMS. In addition, this approach enables the elucidation of the relationship of polymorphic sites on the same chromosome and thus allows the direct determination of haplotypes. We have also demonstrated that this system can be used in conjunction with inverse PCR, the resulting double ARMS inverse PCR (DARMSI-PCR) may allow haplotype determination on polymorphic sites which are separated further apart than the length limit imposed by PCR. The double ARMS approach has numerous other applications in molecular biology including HLA typing, virology, forensic pathology and the investigation of the phenomenon of chimerism following bone marrow transplantation.     

Application of real time PCR in post transplant monitoring of cytomegalovirus infection: comparison with other diagnostic approaches

Immunosuppressive status in solid organ transplant recipients is often related to the reactivation of Human Cytomegalovirus (HCMV) infection that remains one of the major causes of morbidity and mortality. Therefore, the early detection of HCMV followed by infection monitoring is important to institute prompt and appropriate treatment. In recent years good results have been obtained by HCMV DNA amplification methods; qualitative and quantitative approaches have shown good sensitivity and specificity, but they often require post-PCR manipulation that adds time to the analysis and may lead to contamination problems. Recently, Real Time PCR (RT-PCR) has been proposed in HCMV DNA analysis as a valid method for its good sensitivity and rapidity. In the present study, twenty-five solid organ transplant recipients were analyzed for HCMV diagnosis; 60 peripheral blood leukocytes and 120 plasma samples were tested by RT-PCR and the results compared to those obtained by a qualitative Nested PCR and a quantitative DNA enzyme immunoassay.     

Analysis of any point mutation in DNA. The amplification refractory mutation system (ARMS).

We have improved the "polymerase chain reaction" (PCR) to permit rapid analysis of any known mutation in genomic DNA. We demonstrate a system, ARMS (Amplification Refractory Mutation System), that allows genotyping solely by inspection of reaction mixtures after agarose gel electrophoresis. The system is simple, reliable and non-isotopic. It will clearly distinguish heterozygotes at a locus from homozygotes for either allele. The system requires neither restriction enzyme digestion, allele-specific oligonucleotides as conventionally applied, nor the sequence analysis of PCR products. The basis of the invention is that unexpectedly, oligonucleotides with a mismatched 3'-residue will not function as primers in the PCR under appropriate conditions. We have analysed DNA from patients with alpha 1-antitrypsin (AAT) deficiency, from carriers of the disease and from normal individuals. Our findings are in complete agreement with allele assignments derived by direct sequencing of PCR products.     

G-quadruplex-generating polymerase chain reaction for visual colorimetric detection of amplicons

We have developed a self-reporting polymerase chain reaction (PCR) system for visual colorimetric gene detection and distinction of single nucleotide polymorphisms (SNPs). Amplification is performed using target-specific primers modified with a 5′-end tail that is complementary to a G-quadruplex deoxyribozyme-forming sequence. At end-point, G-quadruplexes are forced to fold from PCR-generated duplex DNA and then are used to colorimetrically report the successful occurrence of PCR by assaying their peroxidase activity using a chromogenic substrate. Furthermore, primer design considerations for the G-quadruplex-generating PCR system have allowed us to visually distinguish SNPs associated with Mycobacterium tuberculosis drug resistance alleles.     

Melt analysis of mismatch amplification mutation assays (Melt-MAMA): a functional study of a cost-effective SNP genotyping assay in bacterial models

Single nucleotide polymorphisms (SNPs) are abundant in genomes of all species and biologically informative markers extensively used across broad scientific disciplines. Newly identified SNP markers are publicly available at an ever-increasing rate due to advancements in sequencing technologies. Efficient, cost-effective SNP genotyping methods to screen sample populations are in great demand in well-equipped laboratories, but also in developing world situations. Dual Probe TaqMan assays are robust but can be cost-prohibitive and require specialized equipment. The Mismatch Amplification Mutation Assay, coupled with melt analysis (Melt-MAMA), is flexible, efficient and cost-effective. However, Melt-MAMA traditionally suffers from high rates of assay design failures and knowledge gaps on assay robustness and sensitivity. In this study, we identified strategies that improved the success of Melt-MAMA. We examined the performance of 185 Melt-MAMAs across eight different pathogens using various optimization parameters. We evaluated the effects of genome size and %GC content on assay development. When used collectively, specific strategies markedly improved the rate of successful assays at the first design attempt from ~50% to ~80%. We observed that Melt-MAMA accurately genotypes across a broad DNA range (~100 ng to ~0.1 pg). Genomic size and %GC content influence the rate of successful assay design in an independent manner. Finally, we demonstrated the versatility of these assays by the creation of a duplex Melt-MAMA real-time PCR (two SNPs) and conversion to a size-based genotyping system, which uses agarose gel electrophoresis. Melt-MAMA is comparable to Dual Probe TaqMan assays in terms of design success rate and accuracy. Although sensitivity is less robust than Dual Probe TaqMan assays, Melt-MAMA is superior in terms of cost-effectiveness, speed of development and versatility. We detail the parameters most important for the successful application of Melt-MAMA, which should prove useful to the wider scientific community.     

Detection of Mycobacterium tuberculosis complex with Real Time PCR: comparison of different primer-probe sets based on the IS6110 element

The sensitivity and specificity to detect Mycobacterium tuberculosis complex of four Real Time PCR primer-probe sets was compared. Three sets targeted nearly the same location on the IS6110 sequence and set 4 targeted a location 200 bp downstream on IS6110. Real Time PCR's with sets 1, 2 and 3 were carried out with co-amplification of a modified target as an internal amplification control. By testing identical DNA samples it was shown that small changes in primer and probe sequences result in differences in the performance of the assays, regarding analytical sensitivity and specificity.     

Techniques de recherche des polymorphismes génétiques

Sequencing the human genome has allowed the discovery of millions of DNA sequence variants. Sequence variations in human DNA are mainly present asSingle Nucleotide Polymorphisms (SNPs); this common form of variation is found about once every 1,000 bases in the human genome and 1.8 million SNPs have now been identified and located. The accessibility of databases of SNPs opens the possibility of studying the influence of these polymorphisms on disease risks as well as on drug responses. Numerous approaches have been set up for the identification of SNPs. In this review we describe the main techniques used for the identification of these polymorphisms. They rely on two major consequences of sequence variations: the apparition or the disappearance of restriction enzyme sites or the alteration of DNA strand hybridization due to the presence of a mismatch. Southern blotting and restriction endonucleases have allowed the development of the technique ofrestriction fragment length polymorphisms (RFLPs), now performed on PCR products. Several other approaches such as denaturing high-performance liquid chromatography or real-time PCR can detect allele differences upon re-hybridization and heteroduplex formation. However, DNA sequencing remains the obligate step for the positive identification of known or unknown SNPs. At last, the development of high-throughput methods allows a large increase in the rate of discovery of SNPs likely.     

Sensitive Melting Analysis after Real Time- Methylation Specific PCR (SMART-MSP): high-throughput and probe-free quantitative DNA methylation detection

DNA methylation changes that are recurrent in cancer have generated great interest as potential biomarkers for the early detection and monitoring of cancer. In such situations, essential information is missed if the methylation detection is purely qualitative. We describe a new probe-free quantitative methylation-specific PCR (MSP) assay that incorporates evaluation of the amplicon by high-resolution melting (HRM) analysis. Depending on amplicon design, different types of information can be obtained from the HRM analysis. Much of this information cannot be obtained by electrophoretic analysis. In particular, identification of false positives due to incomplete bisulphite conversion or false priming is possible. Heterogeneous methylation can also be distinguished from homogeneous methylation. As proof of principle, we have developed assays for the promoter regions of the CDH1, DAPK1, CDKN2A (p16^INK4a) and RARB genes. We show that highly accurate quantification is possible in the range from 100% to 0.1% methylated template when 25 ng of bisulphite-modified DNA is used as a template for PCR. We have named this new approach to quantitative methylation detection, Sensitive Melting Analysis after Real Time (SMART)-MSP.     

Strategies for signal amplification in nucleic acid detection

Many aspects of molecular genetics necessitate the detection of nucleic acid sequences. Current approaches involving target amplification (in situ PCR, Primed in situ Labeling, Self-Sustained Sequence Replication, Strand Displacement Amplification), probe amplification (Ligase Chain Reaction, Padlock Probes, Rolling Circle Amplification) and signal amplification (Tyramide Signal Amplification, Branched DNA Amplification) are summarized in the present review, together with their advantages and limitations.     

Somatic Mutation Allelic Ratio Test Using ddPCR (SMART-ddPCR): An Accurate Method for Assessment of Preferential Allelic Imbalance in Tumor DNA

The extent to which heritable genetic variants can affect tumor development has yet to be fully elucidated. Tumor selection of single nucleotide polymorphism (SNP) risk alleles, a phenomenon called preferential allelic imbalance (PAI), has been demonstrated in some cancer types. We developed a novel application of digital PCR termed Somatic Mutation Allelic Ratio Test using Droplet Digital PCR (SMART-ddPCR) for accurate assessment of tumor PAI, and have applied this method to test the hypothesis that heritable SNPs associated with childhood acute lymphoblastic leukemia (ALL) may demonstrate tumor PAI. These SNPs are located at CDKN2A (rs3731217) and IKZF1 (rs4132601), genes frequently lost in ALL, and at CEBPE (rs2239633), ARID5B (rs7089424), PIP4K2A (rs10764338), and GATA3 (rs3824662), genes located on chromosomes gained in high-hyperdiploid ALL. We established thresholds of AI using constitutional DNA from SNP heterozygotes, and subsequently measured allelic copy number in tumor DNA from 19–142 heterozygote samples per SNP locus. We did not find significant tumor PAI at these loci, though CDKN2A and IKZF1 SNPs showed a trend towards preferential selection of the risk allele (p = 0.17 and p = 0.23, respectively). Using a genomic copy number control ddPCR assay, we investigated somatic copy number alterations (SCNA) underlying AI at CDKN2A and IKZF1, revealing a complex range of alterations including homozygous and hemizygous deletions and copy-neutral loss of heterozygosity, with varying degrees of clonality. Copy number estimates from ddPCR showed high agreement with those from multiplex ligation-dependent probe amplification (MLPA) assays. We demonstrate that SMART-ddPCR is a highly accurate method for investigation of tumor PAI and for assessment of the somatic alterations underlying AI. Furthermore, analysis of publicly available data from The Cancer Genome Atlas identified 16 recurrent SCNA loci that contain heritable cancer risk SNPs associated with a matching tumor type, and which represent candidate PAI regions warranting further investigation.     

A novel Real Time micro PCR based Point-of-Care device for Salmonella detection in human clinical samples

Our POC (Point of Care) device is intended to be a diagnostic tool for routine use in the clinical sector. The validation of the whole procedure, including bacterial genomic DNA isolation and the Real Time detection of Salmonella spp., was conducted on 29 clinical stool samples that had been diagnosed with Salmonella spp. by a routine culture technique. The entire process was achieved in a single microfluidic chip within 35 min. In comparison to the culture reference method that is used in the clinical laboratories, this new device performed well in regards to the analytical parameters of sensitivity, specificity and accuracy. Therefore, the POC device reported in this study proved to be very appropriate for the fully integrated analysis system. To the best of our knowledge, this is the first work to report the sample preparation and followed by Real Time PCR (Polymerase Chain Reaction) on a single 2.5 μl chamber chip for the detection of Salmonella spp. bacteria in stool samples.     

Ultrasensitive cDNA detection of dengue virus RNA using electrochemical nanoporous membrane-based biosensor

A nanoporous alumina membrane-based ultrasensitive DNA biosensor is constructed using 5'-aminated DNA probes immobilized onto the alumina channel walls. Alumina nanoporous membrane-like structure is carved over platinum wire electrode of 76 μm diameter dimension by electrochemical anodization. The hybridization of complementary target DNA with probe DNA molecules attached inside the pores influences the pore size and ionic conductivity. The biosensor demonstrates linear range over 6 order of magnitude with ultrasensitive detection limit of 9.55×10(-12) M for the quantification of ss-31 mer DNA sequence. Its applicability is challenged against real time cDNA PCR sample of dengue virus serotype1 derived from asymmetric PCR. Excellent specificity down to one nucleotide mismatch in target DNA sample of DENV3 is also demonstrated.     

Enumeration of 16S rDNA of Desulfotomaculum lineage 1 in rice field soil by real-time PCR with SybrGreen detection

Real-time PCR is a new and highly sensitive method for the quantification of microbial organisms in environmental samples. This work was conducted to evaluate real-time PCR with SybrGreen (SG) detection as quantification method for Desulfotomaculum lineage 1 organisms in samples of rice field soil. The method was optimized in several parameters like SG concentration. These allowed quantitative PCR with different primer combinations yielding PCR products with lengths up to 1066 bp and with sensitivities of 10(2) targets for all assays. The detection limit in environmental DNA extracts (rice bulk soil and rice roots) was 10(6) targets per gram dry weight according to the dilution of the DNA extracts necessary to overcome PCR inhibition of humic substances. A verification, that the fluorescence increase was due to specific PCR products, was done by agarose gel electrophoresis since melting curve analysis of the PCR products did not show a distinct peak in the first derivative, when the environmental DNA extracts were used in PCR. Amplification with a primer combination specific for Desulfotomaculum lineage 1 organisms showed an abundance of this group of approximately 2% and 0.5% of the eubacterial 16S rDNA targets in rice bulk soil and rice root samples, respectively. Approximately half of this number was obtained in both habitats with a PCR assay specific for a Desulfotomaculum sequence cluster obtained previously from rice field soil.     

NBS1基因SNPs与中国汉族人群原发性肝癌的遗传易感性

为分析DNA损伤修复相关基因NBS1单核苷酸多态性(SNPs)与原发性肝癌遗传易感性的关系,并对高分辨率单链构象多态性(SSCP)检测技术在SNPs分型中的适用性进行评估,本研究对来自中国汉族人群的327例原发性肝癌以及295例阴性对照中NBS1基因常见SNPs的稀有等位基因频率进行检测和分析．此外,对NBS1基因6个常见SNPs分别选择部分样本同时进行直接序列测定,以比较2种方法的检测效果．119例原发性肝癌以及95例肝硬化/慢性肝炎组织标本的SSCP分析结果表明,6个常见NBS1基因SNPs位点(102G>A, 320+208G/A, 553G>C, 1197T>C, 2016A>G和2071-30A>T)中,SNP 1197T>C的稀有等位基因频率为68.1%,显著高于肝硬化/慢性肝炎对照的57.9% (P = 0.0298)．对该SNP位点另外采用208份肝细胞癌和200份健康人群血液标本进一步分析, 肝细胞癌SNP 1197T>C的稀有等位基因频率为66.8%,显著高于健康人群对照的58.8% (P = 0.0170)．其他5个SNPs的稀有等位基因频率在原发性肝癌与肝硬化/慢性肝炎之间均无显著性差异．高分辨率SSCP分析法与直接序列测定法对所选样本的SNPs基因分型结果完全一致,而且直接测序法对PCR扩增产物质量的要求相对高分辨率SSCP分析更高．研究表明,中国汉族人群NBS1基因SNP 1197T>C可能与原发性肝癌的发生相关,高分辨率SSCP技术准确度与直接测序法相当,且操作更加简便易行,非常适用于大量样本多个已知SNPs的基因分型．     

An atypical strain associated with congenital toxoplasmosis in Tunisia

We report the identification and typing of a congenital toxoplasmosis case in a diabetic pregnant young woman living in Tunis. The Toxoplasma DNA extracted from amniotic fluid was detected by Real Time PCR and subjected to a multilocus genetic characterisation of the strain at markers: 3'SAG2, 5'SAG2, New SAG2, SAG3, GRA6, BTUB, APICO, PK1, KT850 and UPRT1. An atypical genotype of T.gondii with unusual genetic composition was revealed. It is the first time that an atypical strain has been associated with congenital toxoplasmosis in Africa. Atypical strains are associated with severe clinical manifestations so systematic genotyping should be investigated with the amniocentesis.     

Discrimination of gamma-irradiated and nonirradiated Vibrio vulnificus by using real-time polymerase chain reaction

Aims: To develop a PCR strategy for Vibrio vulnificus in irradiated foods. Methods and Results: Real‐time PCR was used to discriminate between DNA from γ‐irradiated and nonirradiated cells. γ‐Irradiation at 1·08 KGy and above of cell suspensions containing 1 × 10⁶ CFU ml^?1 resulted in 0 CFU ml^?1. Real‐time PCR was able to detect 86·6% destruction by 1·08 KGy, while ethidium bromide monoazide (EMA) real‐time PCR was able to detect 93·2% destruction at this dose. With 3·0 and 5·0 KGy, EMA real‐time PCR was able to detect 99·3% and 100% destruction, respectively. Conclusions: The inability to detect via PCR extensively degraded DNA resulting from γ‐irradiation can be taken as evidence of cell death. The increased ability of EMA to further reduce the detectable number of target sequences via PCR, with DNA from cells exposed to increased doses of γ‐irradiation, can be considered to reflect the accompanying increase in membrane damage which allows EMA to penetrate the cells. Significance and impact of the study: This is the first study that has made use of the PCR to discriminate between γ‐irradiated and nonirradiated bacterial cells and has led to insights regarding the ability of the PCR to discriminate between nonirradiated and γ‐irradiation destroyed cells.