Multiplex Touchdown PCR for Rapid Typing of the Opportunistic Pathogen Propionibacterium acnes.

The opportunistic human pathogen Propionibacterium acnes is comprised of a number of distinct phylogroups, designated types IA1, IA2, IB, IC, II and III, that vary in their production of putative virulence factors, inflammatory potential, as well as biochemical, aggregative and morphological characteristics. Although Multilocus Sequence Typing (MLST) currently represents the gold standard for unambiguous phylogroup classification, and individual strain identification, it is a labour and time-consuming technique. As a consequence, we have developed a multiplex touchdown PCR assay that will, in a single reaction, confirm species identity and phylogeny of an isolate based on its pattern of reaction with six primer sets that target the 16S rRNA (all isolates), ATPase (type IA1, IA2, IC), sodA (type IA2, IB), atpD (type II) and recA (type III) housekeeping genes, as well as a Fic family toxin gene (type IC). When applied to 312 P. acnes isolates previously characterised by MLST, and representing type IA1 (n=145), IA2 (n=20), IB (n=65), IC (n=7), II (n=45) and III (n=30), the multiplex displayed 100% sensitivity and 100% specificity for the detection of isolates within each targeted phylogroup. No cross-reactivity with isolates from other bacterial species was observed. The multiplex assay will provide researchers with a rapid, high-throughput and technically undemanding typing method for epidemiological and phylogenetic investigations. It will facilitate studies investigating the association of lineages with various infections and clinical conditions, as well as a pre-screening tool to maximise the number of genetically diverse isolates selected for downstream, higher resolution sequence-based analyses.

Detección por PCR multiplex de pseudomonas aeruginosa, proteus mirabilis y malassezia SPP en caninos con otitis externa.

Tesis (Maestría en Ciencia Animal) UANL, 2011.

Otimização da RT-PCR Multiplex para detecção de vírus dengue em amostras de Aedes aegypti infectados artificialmente

A dengue é a mais importante doença viral transmitida por mosquitos, no que diz respeito à morbidade e mortalidade, que afeta os seres humanos. Este vírus é transmitido pelos vetores Aedes albopictus e Aedes aegypti, este último é o principal vetor nas Américas. O controle da doença se baseia na vigilância laboratorial e vigilância entomológica. A vigilância laboratorial visa aprimorar a capacidade do diagnóstico, detectando precocemente a circulação viral e monitorando os sorotipos circulantes. Dentro deste tipo de vigilância, a RT-PCR é um método bastante usado no diagnóstico da doença em humanos e mosquitos, porém, a má conservação do material pode comprometer a integridade do RNA e trazer resultados falso-negativos. O desenvolvimento de melhores métodos de vigilância do vírus dengue (DENV) em mosquitos é de grande valor para os programas de controle. Desta maneira, o presente projeto visou otimizar a técnica de RT-PCR Multiplex para detecção de DENV em amostras de Ae. aegypti infectadas artificialmente pelo vírus. Primers que amplificam uma região de 80 pb do gene rpL8 de mosquito foram desenhados no site Primer3 e avaliados na ferramenta online Multiple Primer Analyzer, junto com primers que amplificam os sorotipos DENV. Não houve competição de primers e foi observado bandas distintas no gel de agarose. Foi avaliado o efeito de diferentes formas de preservação do material genético das amostras (RNAlater®, freezer -80°C e nitrogênio líquido) por 7 dias, onde não houve diferenças significativas em relação à integridade do RNA. O efeito de diferentes formas de extração de RNA (Kit da QIAGEN® , TRIzol® e Chomczymski-Sacchi) também foi avaliado e o método ChomczymskiSacchi obteve o melhor desempenho. A otimização desta técnica permitirá uma maior confiabilidade nos resultados, já que além da detecção dos sorotipos, haverá uma confirmação da qualidade do RNA, aprimorando a capacidade do diagnóstico e auxiliando a prevenção e controle da transmissão da dengue.

A disposable multiplex polymerase chain reaction (PCR) chip and device

Malaysian patent application number PCT/MY2008/000190 Australian application number : 2009203047

Diferenciação das espécies Cryptococcus neoformans e Cryptococcus gattii utilizando a metodologia de PCR multiplex e determinação do perfil epidemiológico de pacientes com meningite criptocócica

Cryptococcus neoformans é uma levedura oportunista que pode se alojar no sistema nervoso central causando meningite, meningoencefalite e encefalite principalmente em indivíduos com algum comprometimento do sistema imune. É responsável por 4,5% das infecções oportunistas que acometem pacientes portadores do Vírus da Imunodeficiência Humana (HIV-positivos). Cryptococcus gattii é um patógeno primário responsável por uma alta incidência de criptococomas no pulmão e no cérebro e que apresenta uma alta morbidez neurológica e uma resposta retardada à terapia antifúngica. O diagnóstico da criptococose é, atualmente, baseado na detecção da levedura em amostras clínicas, no cultivo com posterior identificação bioquímica e na pesquisa de antígenos circulantes. A diferenciação entre as espécies C. neoformans e C. gattii, na maioria dos laboratórios, é realizada utilizando o meio de cultura ágar canavanina-glicina-azul de bromotimol (CGB) e demora em torno de sete dias. Neste trabalho foi padronizada uma metodologia de PCR multiplex que pode vir a substituir as provas bioquímicas utilizadas atualmente para a identificação das espécies de Cryptococcus, reduzindo em 6 dias o tempo necessário para a identificação das espécies. A metodologia também se mostrou mais específica na identificação das espécies, concordando com os resultados das sorotipagens em todos os 132 isolados de Cryptococcus testados, enquanto o resultado obtido com o cultivo em ágar CGB foi discordante em 6 dos 132 isolados, sendo 5 falso-positivos e 1 falso negativo. Foi também realizado o primeiro estudo epidemiológico do perfil de pacientes com meningite criptocócica no estado do Rio Grande de Sul notificados no Laboratório Central de Saúde Pública IPB-LACEN/RS no período de 2000 a 2005. A maioria dos pacientes é do sexo masculino (77,12%), branco (83,5%), na faixa etária entre 30 a 39 anos (46,24%) e infectados pelo HIV (95%).

Sexagem de embriões bovinos fecundados in vitro pela técnica de PCR multiplex

Neste trabalho, a técnica de PCR (polymerase chain reaction) foi utilizada para a sexagem de 92 embriões bovinos fertilizados in vitro. Os embriões originaram-se de fertilização in vitro de oócitos aspirados de ovários de fêmeas bovinas, provenientes de abatedouros comerciais. Os oócitos foram maturados, fertilizados e cultivados até o estádio de blastocisto. Os embriões foram lavados em solução de PBS, transferidos para tubos de polipropileno contendo água ultrapura, e imediatamente congelados a -196ºC. Os embriões foram descongelados sobre isopor contendo gelo picado e tratados com proteinase K. Para a reação de PCR, utilizaram-se alíquotas de 34 µl de cada tudo, onde foram acrescidos dois pares de primers, seqüência BC1.2 e seqüência satélite 1.715, desoxinucleotídeos, MgCl2, tampão PCR 10X, TaqDNA polimerase e água, em um volume final de 50 µl. As amostras foram amplificadas e a eletroforese realizada em gel de poliacrilamida a 8%. Os géis foram corados com solução de brometo de etídio e analisados em transiluminador de luz ultravioleta. Um índice de 93,47% de amplificação foi atingido, com 41 embriões (47,67%) machos e 45 (52,32%) embriões fêmeas. O uso de gel de poliacrilamida a 8% foi eficaz na separação de fragmentos de DNA muito próximos.

Comparison of fast-track diagnostics respiratory pathogens multiplex real-time RT-PCR assay with in-house singleplex assays for comprehensive detection of human respiratory viruses

Fast-track Diagnostics respiratory pathogens (FTDRP) multiplex real-time RT-PCR assay was compared with in-house singleplex real-time RT-PCR assays for detection of 16 common respiratory viruses. The FTDRP assay correctly identified 26 diverse respiratory virus strains, 35 of 41 (85%) external quality assessment samples spiked with cultured virus and 232 of 263 (88%) archived respiratory specimens that tested positive for respiratory viruses by in-house assays. Of 308 prospectively tested respiratory specimens selected from children hospitalized with acute respiratory illness, 270 (87.7%) and 265 (86%) were positive by FTDRP and in-house assays for one or more viruses, respectively, with combined test results showing good concordance (K=0.812, 95% CI = 0.786-0.838). Individual FTDRP assays for adenovirus, respiratory syncytial virus and rhinovirus showed the lowest comparative sensitivities with in-house assays, with most discrepancies occurring with specimens containing low virus loads and failed to detect some rhinovirus strains, even when abundant. The FTDRP enterovirus and human bocavirus assays appeared to be more sensitive than the in-house assays with some specimens. With the exceptions noted above, most FTDRP assays performed comparably with in-house assays for most viruses while offering enhanced throughput and easy integration by laboratories using conventional real-time PCR instrumentation. Published by Elsevier B.V.

Diagnosis of rabies and eastern and western equine viral encephalitides in equids by multiplex Hemi-Nested RT-PCR technique

Financial support: CNPq and Pasteur Institute of São Paulo

A multiplex real-time PCR assay for rapid detection and differentiation of 25 bacterial and fungal pathogens from whole blood samples

Early detection of bloodstream infections (BSI) is crucial in the clinical setting. Blood culture remains the gold standard for diagnosing BSI. Molecular diagnostic tools can contribute to a more rapid diagnosis in septic patients. Here, a multiplex real-time PCR-based assay for rapid detection of 25 clinically important pathogens directly from whole blood in <6 h is presented. Minimal analytical sensitivity was determined by hit rate analysis from 20 independent experiments. At a concentration of 3 CFU/ml a hit rate of 50% was obtained for E. aerogenes and 100% for S. marcescens, E. coli, P. mirabilis, P. aeruginosa, and A. fumigatus. The hit rate for C. glabrata was 75% at 30 CFU/ml. Comparing PCR identification results with conventional microbiology for 1,548 clinical isolates yielded an overall specificity of 98.8%. The analytical specificity in 102 healthy blood donors was 100%. Although further evaluation is warranted, our assay holds promise for more rapid pathogen identification in clinical sepsis.

Comparison of multiplex ligation-dependent probe amplification and real-time PCR accuracy for gene copy number quantification using the beta-defensin locus

The reliable quantification of gene copy number variations is a precondition for future investigations regarding their functional relevance. To date, there is no generally accepted gold standard method for copy number quantification, and methods in current use have given inconsistent results in selected cohorts. In this study, we compare two methods for copy number quantification. beta-defensin gene copy numbers were determined in parallel in 80 genomic DNA samples by real-time PCR and multiplex ligation-dependent probe amplification (MLPA). The pyrosequencing-based paralog ratio test (PPRT) was used as a standard of comparison in 79 out of 80 samples. Realtime PCR and MPLA results confirmed concordant DEFB4, DEFB103A, and DEFB104A copy numbers within samples. These two methods showed identical results in 32 out of 80 samples; 29 of these 32 samples comprised four or fewer copies. The coefficient of variation of MLPA is lower compared with PCR. In addition, the consistency between MLPA and PPRT is higher than either PCR/MLPA or PCR/PPRT consistency. In summary, these results suggest that MLPA is superior to real-time PCR in beta-defensin copy number quantification.

Simultaneous A8344G heteroplasmy and mitochondrial DNA copy number quantification in Myoclonus Epilepsy and Ragged-Red Fibers (MERRF) syndrome by a multiplex Molecular Beacon based real-time fluorescence PCR

The association of a particular mitochondrial DNA (mtDNA) mutation with different clinical phenotypes is a well-known feature of mitochondrial diseases. A simple genotype–phenotype correlation has not been found between mutation load and disease expression. Tissue and intercellular mosaicism as well as mtDNA copy number are thought to be responsible for the different clinical phenotypes. As disease expression of mitochondrial tRNA mutations is mostly in postmitotic tissues, studies to elucidate disease mechanisms need to be performed on patient material. Heteroplasmy quantitation and copy number estimation using small patient biopsy samples has not been reported before, mainly due to technical restrictions. In order to resolve this problem, we have developed a robust assay that utilizes Molecular Beacons to accurately quantify heteroplasmy levels and determine mtDNA copy number in small samples carrying the A8344G tRNALys mutation. It provides the methodological basis to investigate the role of heteroplasmy and mtDNA copy number in determining the clinical phenotypes.

A Multiplex Real-Time PCR with High Resolution Melting Analysis for the Characterization of Antimicrobial Resistance in Neisseria gonorrhoeae.

Resistance to antibiotics used against Neisseria gonorrhoeae infections is a major public health concern. Antimicrobial resistance (AMR) testing relies on time-consuming culture-based methods. Development of rapid molecular tests for detecting AMR determinants could provide valuable tools for surveillance, epidemiological studies and to inform individual case management. We developed a fast (<1.5 hrs) SYBR-green based real-time PCR method with high resolution melting (HRM) analysis. One triplex and three duplex reactions included two sequences for N. gonorrhoeae identification and seven determinants of resistance to extended-spectrum cephalosporins (ESCs), azithromycin, ciprofloxacin, and spectinomycin. The method was validated by testing 39 previously fully-characterized N. gonorrhoeae strains, 19 commensal Neisseria spp., and an additional panel of 193 gonococcal isolates. Results were compared with culture-based AMR determination. The assay correctly identified N. gonorrhoeae and the presence or absence of the seven AMR determinants. There was some cross-reactivity with non-gonococcal Neisseria species and the detection limit was 10(3)-10(4) gDNA copies/reaction. Overall, the platform accurately detected resistance to ciprofloxacin (sensitivity and specificity, 100%), ceftriaxone (sensitivity 100%, specificity 90%), cefixime (sensitivity 92%, specificity 94%), azithromycin and spectinomycin (both sensitivity and specificity, 100%). In conclusion, our methodology accurately detects mutations generating resistance to antibiotics used to treat gonorrhea. Low assay sensitivity prevents direct diagnostic testing of clinical specimens but this method can be used to screen collections of gonococcal isolates for AMR more quickly than with current culture-based AMR testing.

Prenatal diagnosis of tetrasomy 18p using multiplex fluorescent PCR and comparison with a variety of techniques

We report genetic characterization of isochromosome 18p using a combination of cytogenetic and molecular genetic methods, including multiplex fluorescent PCR. The patient was referred for chorionic villus sampling (CVS) due to advanced maternal age and maternal anxiety. The placental karyotype was 47,XX,+mar, with the marker having the appearance of a small supernumerary isochromosome. Because differentiating between isochromosomes and other structural rearrangements is normally very difficult, a variety of genetic tests including fluorescence in situ hybridization (FISH), PCR, and multiplex fluorescent PCR were undertaken to determine chromosomal origin and copy number and, thus, allow accurate diagnosis of the corresponding syndrome. FISH determined that the marker chromosome contained chromosome 18 material. PCR of a variety of short tandem repeats (STRs) confirmed that there was at least one extra copy of the maternal 18p material. However, neither FISH nor PCR could accurately determine copy number. Multiplex fluorescent PCR (MF-PCR) of STRs simultaneously determined that: (1) the marker included 18p material; (2) the marker was maternal in origin; (3) allele copy number indicated tetrasomy; and (4) contamination of the sample could be ruled out. Results were also rapid with accurate diagnosis of the syndrome tetrasomy 18p possible within 5 hours.

A sensitive, specific, and cost-effective multiplex reverse transcriptase-PCR assay for the detection of seven common respiratory viruses in respiratory samples

Cell culture and direct fluorescent antibody (DFA) assays have been traditionally used for the laboratory diagnosis of respiratory viral infections. Multiplex reverse transcriptase polymerase chain reaction (m-RT-PCR) is a sensitive, specific, and rapid method for detecting several DNIA and RNA viruses in a single specimen. We developed a m-RT-PCR assay that utilizes multiple virus-specific primer pairs in a single reaction mix combined with an enzyme-linked amplicon hybridization assay (ELAHA) using virus-specific probes targeting unique gene sequences for each virus. Using this m-RT-PCR-ELAHA, we examined the presence of seven respiratory viruses in 598 nasopharyngeal aspirate (NPA) samples from patients with suspected respiratory infection. The specificity of each assay was 100%. The sensitivity of the DFA was 79.7% and the combined DFA/culture amplified-DFA (CA-DFA) was 88.6% when compared to the m-RT-PCR-ELAHA. Of the 598 NPA specimens screened by m-RT-PCR-ELAHA, 3% were positive for adenovirus (ADM), 2% for influenza A (Flu A) virus, 0.3% for influenza B (Flu B) virus, 1% for parainfluenza type I virus (PIV1), 1% for parainfluenza type 2 virus (PIV2), 5.5% for parainfluenza type 3 virus (PIV3), and 21% for respiratory syncytial virus (RSV). The enhanced sensitivity, specificity, rapid result turnaround time and reduced expense of the m-RT-PCR-ELAHA compared to DFA and CA-DFA, suggests that this assay would be a significant improvement over traditional assays for the detection of respiratory viruses in a clinical laboratory.