沙门菌、志贺菌、副溶血性弧菌多重PCR检测方法的研究

建立快速检测沙门菌、志贺菌和副溶血性弧菌的多重PCR方法[1-4].根据沙门菌hilA基因、志贺菌ipaH基因及副溶血性弧菌TDH基因设计特异性PCR引物[5-6],被检样品经4 h振荡培养后金属浴裂解制备DNA模板,使用全自动毛细管电泳核酸检测系统分析PCR扩增产物.在580、423和245 bp处分别出现预期的特异性DNA条带,且无非特异扩增条带出现.敏感性试验显示沙门菌在模拟标本中的检测灵敏度为101-2cfu/mL、志贺菌为101cfu/mL、副溶血性弧菌为102cfu/mL.该方法操作方便、分析时间短、特异性和灵敏度高,可用于公共卫生突发事件食源性病原菌的快速检测.     

Development of a multiplex PCR detection of Salmonella spp. and Shigella spp. in mussels

Multiplex PCR amplification of invA and virA genes was developed enabling simultaneous detection in mussels of Salmonella spp. and Shigella spp., respectively. Simultaneous amplification of products of 215 and 275 bp was obtained either by using mixtures of individual strains of Sh. dysenteriae and Salm. typhimurium or spiked contaminated mussels with both bacteria. In the case of the mussels, 10-100 cells of Salmonella spp. and Shigella per millilitre of homogenate were detected by the multiplex PCR following a pre-enrichment step to increase sensitivity and to ensure that detection was based on the presence of cultivable bacteria. Also, the sensitivity and specificity of this method was evaluated. Multiplex PCR amplification was shown to be an effective, sensitive and rapid method for the simultaneous detection of pathogens in mussels.     

Detection of Salmonella spp. in oysters by PCR.

PCR DNA amplification of a region of the himA gene of Salmonella typhimurium specifically detected Salmonella spp. In oysters, 1 to 10 cells of Salmonella spp. were rapidly detected by the PCR following a pre-enrichment step to increase sensitivity and to ensure that detection was based on the presence of viable Salmonella spp.     

Aerobactin genes in Shigella spp.

Aerobactin, a hydroxamate iron transport compound, is synthesized by some, but not all, Shigella species. Conjugation and hybridization studies indicated that the genes for the synthesis and transport of aerobactin are linked and are found on the chromosome of Shigella flexneri, S. boydii, and S. sonnei. The genes were not found in S. dysenteriae. A number of aerobactin synthesis mutants and transport mutants have been isolated. The most common mutations are deletions of the biosynthesis or biosynthesis and transport genes. The Shigella aerobactin genes share considerable homology with the E. coli ColV aerobactin genes. On the ColV plasmid and in the Shigella chromosome, the aerobactin genes are associated with a repetitive sequence which has been identified as IS1.     

Specific Oligonucleotide Primers for Detection of Lecithinase-Positive Bacillus spp. by PCR

Volume 61, no. 1, p. 100, Table 3: in columns 7 and 8, row 3, "-" should read "+." [This corrects the article on p. 98 in vol. 61.].     

志贺菌毒力检测的常用方法

志贺菌属的细菌以人类为特异性宿主,感染人类肠上皮细胞,多导致痉挛性腹痛、腹泻、发烧等症状,是细菌性痢疾最为常见的病原菌。志贺菌的致病机理主要由其Ⅲ型分泌系统调节。志贺菌侵袭力的高低及毒力强弱决定了其致病性的强弱。我们简要介绍志贺菌属细菌的毒力检测方法。     

Detection of Shigella spp. in food with a nested PCR method – sensitivity and performance compared with a conventional culture method

A nested PCR method was developed and its performance evaluated by detection of Shigella flexneri in food. The nested PCR amplifies sequences within an invasion-associated locus (ial) on the invasion plasmid specific for Shigella and enteroinvasive Eschrichia coli (EIEC). The nested PCR detected Sh. flexneri in lettuce inoculated with 2, 20 and 200 cfu g-1 after 1, 7 and 18 d of storage, respectively. In comparison, a culture method (NMKL no. 151) detected 10(5) cfu g-1 after 1 but not after 7 d of storage. The presence of inhibitors in blue cheese and shrimps reduced the sensitivity of the PCR assay. To overcome this inhibition, a sample preparation step based on buoyant density centrifugation was developed. This treatment resulted in a successful recovery of Sh. flexneri in lettuce, milk, shrimp and blue cheese inoculated with 10 cfu g-1. The proposed method, which includes a combination of enrichment, buoyant density centrifugation and a nested PCR, can be completed in less than two working days.     

Octaplex PCR and fluorescence-based capillary electrophoresis for identification of human diarrheagenic Escherichia coli and Shigella spp

A multiplex PCR assay, amplifying seven specific virulence genes and one internal control gene in a single reaction, was developed to identify the five main pathotypes of diarrheagenic Escherichia coli and Shigella spp. The virulence genes selected for each category were Stx1, Stx2, and eaeA for enterohemorrhagic E. coli (EHEC), eaeA for enteropathogenic E. coli (EPEC), STIb and LTI for enterotoxigenic E. coli (ETEC), ipaH for enteroinvasive E. coli (EIEC) and Shigella spp., and aggR for enteroaggregative E. coli (EAEC). Each forward primer was labelled with a fluorochrome and the PCR products were separated by multicolour capillary electrophoresis on an ABI PRISM310 Genetic Analyzer (Applied Biosystems). If present, several gene variants of each virulence gene were identified. The internal control gene rrs, encoding 16S rRNA, was amplified in all 110 clinical strains analyzed. Virulence genes were demonstrated in 103 (94%) of these strains. In the majority of the cases (98/103, 95%), classification obtained by the novel multiplex PCR assay was in agreement with that previously determined by phenotypic assays combined with other molecular genetic approaches. Numerous multiplex PCR assays have been published, but only a few of them detect all five E. coli pathotypes within a single reaction, and none of them has used multicolour capillary electrophoresis to separate the PCR products. The octaplex PCR assay followed by capillary electrophoresis presented in the present paper provides a simple, reliable, and rapid procedure that in a single reaction identifies the five main pathotypes of E. coli, and Shigella spp. This assay will replace the previous molecular genetic methods used in our laboratory and work as an important supplement to the more time-consuming phenotypic assays.     

Laboratory-Based Prospective Surveillance for Community Outbreaks of Shigella spp. in Argentina

Background

To implement effective control measures, timely outbreak detection is essential. Shigella is the most common cause of bacterial diarrhea in Argentina. Highly resistant clones of Shigella have emerged, and outbreaks have been recognized in closed settings and in whole communities. We hereby report our experience with an evolving, integrated, laboratory-based, near real-time surveillance system operating in six contiguous provinces of Argentina during April 2009 to March 2012.

Methodology

To detect localized shigellosis outbreaks timely, we used the prospective space-time permutation scan statistic algorithm of SaTScan, embedded in WHONET software. Twenty three laboratories sent updated Shigella data on a weekly basis to the National Reference Laboratory. Cluster detection analysis was performed at several taxonomic levels: for all Shigella spp., for serotypes within species and for antimicrobial resistance phenotypes within species. Shigella isolates associated with statistically significant signals (clusters in time/space with recurrence interval ≥365 days) were subtyped by pulsed field gel electrophoresis (PFGE) using PulseNet protocols.

Principal Findings

In three years of active surveillance, our system detected 32 statistically significant events, 26 of them identified before hospital staff was aware of any unexpected increase in the number of Shigella isolates. Twenty-six signals were investigated by PFGE, which confirmed a close relationship among the isolates for 22 events (84.6%). Seven events were investigated epidemiologically, which revealed links among the patients. Seventeen events were found at the resistance profile level. The system detected events of public health importance: infrequent resistance profiles, long-lasting and/or re-emergent clusters and events important for their duration or size, which were reported to local public health authorities.

Conclusions/Significance

The WHONET-SaTScan system may serve as a model for surveillance and can be applied to other pathogens, implemented by other networks, and scaled up to national and international levels for early detection and control of outbreaks.     

A Duplex PCR Assay for the Detection of Ralstonia solanacearum Phylotype II Strains in Musa spp.

Banana wilt outbreaks that are attributable to Moko disease-causing strains of the pathogen Ralstonia solanacearum (Rs) remain a social and economic burden for both multinational corporations and subsistence farmers. All known Moko strains belong to the phylotype II lineage, which has been previously recognized for its broad genetic basis. Moko strains are paraphyletic and are distributed among seven related but distinct phylogenetic clusters (sequevars) that are potentially major threats to Musaceae, Solanaceae, and ornamental crops in many countries. Although clustered within the Moko IIB-4 sequevar, strains of the epidemiologically variant IIB-4NPB do not cause wilt on Cavendish or plantain bananas; instead, they establish a latent infection in the vascular tissues of plantains and demonstrate an expanded host range and high aggressiveness toward Solanaceae and Cucurbitaceae. Although most molecular diagnostic methods focus on strains that wilt Solanaceae (particularly potato), no relevant protocol has been described that universally detects strains of the Musaceae-infecting Rs phylotype II. Thus, a duplex PCR assay targeting Moko and IIB-4NPB variant strains was developed, and its performance was assessed using an extensive collection of 111 strains representing the known diversity of Rs Moko-related strains and IIB-4NPB variant strains along with certain related strains and families. The proposed diagnostic protocol demonstrated both high accuracy (inclusivity and exclusivity) and high repeatability, detected targets on either pure culture or spiked plant extracts. Although they did not belong to the Moko clusters described at the time of the study, recently discovered banana-infecting strains from Brazil were also detected. According to our comprehensive evaluation, this duplex PCR assay appears suitable for both research and diagnostic laboratories and provides reliable detection of phylotype II Rs strains that infect Musaceae.     

沙门菌、大肠杆菌和金黄色葡萄球菌的多重PCR检测

根据沙门菌invA基因、大肠杆菌phoA基因和金黄色葡萄球菌nuc基因序列,设计3对特异性引物进行多重PCR并对反应条件进行优化。结果表明3对引物能特异地扩增出284bp、622bp、484bp的目的条带;最佳反应条件为沙门菌、大肠杆菌、金黄色葡萄球菌的引物浓度分别为40nmol／L、40nmol／L、80nmol／L,Mg^2＋浓度2．4mmol／L,dNTP浓度2001μmol／L,Taq DNA聚合酶1.5u,退火温度55．0℃-57．4℃之间;在此条件下多重PCR同时检测DNA的敏感性分别是10．2pg、10．2pg、102．0pg,检测时间4h。建立的多重PCR是一种敏感、特异、准确、快速的方法,为同时检测食品中沙门菌、大肠杆菌和金黄色葡萄球菌奠定了基础。     

Detection of Escherichia coli and Shigella spp. in water by using the polymerase chain reaction and gene probes for uid.

A method was developed for the detection of the fecal coliform bacterium Escherichia coli, using the polymerase chain reaction and gene probes, based on amplifying regions of the uid gene that code for beta-glucuronidase, expression of which forms the basis for fecal coliform detection by the commercially available Colilert method. Amplification and gene probe detection of four different regions of uid specifically detected E. coli and Shigella species, including beta-glucuronidase-negative strains of E. coli; no amplification was observed for other coliform and nonenteric bacteria.     

Detection of Pathogenic Vibrio spp. in Shellfish by Using Multiplex PCR and DNA Microarrays

This study describes the development of a gene-specific DNA microarray coupled with multiplex PCR for the comprehensive detection of pathogenic vibrios that are natural inhabitants of warm coastal waters and shellfish. Multiplex PCR with vvh and viuB for Vibrio vulnificus, with ompU, toxR, tcpI, and hlyA for V. cholerae, and with tlh, tdh, trh, and open reading frame 8 for V. parahaemolyticus helped to ensure that total and pathogenic strains, including subtypes of the three Vibrio spp., could be detected and discriminated. For DNA microarrays, oligonucleotide probes for these targeted genes were deposited onto epoxysilane-derivatized, 12-well, Teflon-masked slides by using a MicroGrid II arrayer. Amplified PCR products were hybridized to arrays at 50°C and detected by using tyramide signal amplification with Alexa Fluor 546 fluorescent dye. Slides were imaged by using an arrayWoRx scanner. The detection sensitivity for pure cultures without enrichment was 10² to 10³ CFU/ml, and the specificity was 100%. However, 5 h of sample enrichment followed by DNA extraction with Instagene matrix and multiplex PCR with microarray hybridization resulted in the detection of 1 CFU in 1 g of oyster tissue homogenate. Thus, enrichment of the bacterial pathogens permitted higher sensitivity in compliance with the Interstate Shellfish Sanitation Conference guideline. Application of the DNA microarray methodology to natural oysters revealed the presence of V. vulnificus (100%) and V. parahaemolyticus (83%). However, V. cholerae was not detected in natural oysters. An assay involving a combination of multiplex PCR and DNA microarray hybridization would help to ensure rapid and accurate detection of pathogenic vibrios in shellfish, thereby improving the microbiological safety of shellfish for consumers.     

Detection of pathogenic Vibrio spp. in shellfish by using multiplex PCR and DNA microarrays

This study describes the development of a gene-specific DNA microarray coupled with multiplex PCR for the comprehensive detection of pathogenic vibrios that are natural inhabitants of warm coastal waters and shellfish. Multiplex PCR with vvh and viuB for Vibrio vulnificus, with ompU, toxR, tcpI, and hlyA for V. cholerae, and with tlh, tdh, trh, and open reading frame 8 for V. parahaemolyticus helped to ensure that total and pathogenic strains, including subtypes of the three Vibrio spp., could be detected and discriminated. For DNA microarrays, oligonucleotide probes for these targeted genes were deposited onto epoxysilane-derivatized, 12-well, Teflon-masked slides by using a MicroGrid II arrayer. Amplified PCR products were hybridized to arrays at 50 degrees C and detected by using tyramide signal amplification with Alexa Fluor 546 fluorescent dye. Slides were imaged by using an arrayWoRx scanner. The detection sensitivity for pure cultures without enrichment was 10(2) to 10(3) CFU/ml, and the specificity was 100%. However, 5 h of sample enrichment followed by DNA extraction with Instagene matrix and multiplex PCR with microarray hybridization resulted in the detection of 1 CFU in 1 g of oyster tissue homogenate. Thus, enrichment of the bacterial pathogens permitted higher sensitivity in compliance with the Interstate Shellfish Sanitation Conference guideline. Application of the DNA microarray methodology to natural oysters revealed the presence of V. vulnificus (100%) and V. parahaemolyticus (83%). However, V. cholerae was not detected in natural oysters. An assay involving a combination of multiplex PCR and DNA microarray hybridization would help to ensure rapid and accurate detection of pathogenic vibrios in shellfish, thereby improving the microbiological safety of shellfish for consumers.     

Improved Method for Purification of Bacterial DNA from Bovine Milk for Detection of Brucella spp. by PCR

Different methods of extraction of bacterial DNA from bovine milk to improve the direct detection of Brucella by PCR were evaluated. We found that the use of a lysis buffer with high concentrations of Tris, EDTA, and NaCl, high concentrations of sodium dodecyl sulfate and proteinase K, and high temperatures of incubation was necessary for the efficient extraction of Brucella DNA. The limit of detection by PCR was 5 to 50 Brucella CFU/ml of milk.     

A versatile PCR marker for pungency in Capsicum spp.

Pungency in Capsicum spp. is an important quality trait for pepper breeding. The perception of pungency in pepper is due to the presence of a group of compounds named capsaicinoids, only found within the Capsicum genus. How pungency is controlled at genetic and molecular levels has not been completely elucidated. The use of molecular markers to assess pungency trait is required for molecular breeding, despite the difficulty of development of universal markers for this trait. In this work, a DNA sequence possibly related to pungency with a high similarity to Pun1 locus was studied, and sequence analysis of this homolog revealed a 15?bp deletion in non-pungent pepper accessions. An allele-specific pair of primers was designed and specific fragments of 479?bp from non-pungent and 494?bp from pungent accessions were obtained. Polymorphism of this marker, named MAP1, was tested in a wide range of accessions, belonging to several Capsicum species, including pungent and non-pungent accessions of C. annuum L., and pungent accessions of C. chinense, C. baccatum, C. frutescens, C. pubescens, C. galapagoense, C. eximium, C. tovarii, C. cardenasii, and C. chacoense. All these Capsicum accessions were correctly discriminated. The marker suitability to assess pungency in domesticated and wild Capsicum species was demonstrated, and therefore it will be very useful in marker assisted selection (MAS). Moreover, MAP1 was located in a saturated pepper linkage map and its possible relationship with the Pun1 locus has been discussed. Among the available markers for this complex quality trait, the marker developed in this study is the most universal so far.     

Detection of Escherichia coli and Shigella spp. in water by using the polymerase chain reaction and gene probes for uid

A method was developed for the detection of the fecal coliform bacterium Escherichia coli, using the polymerase chain reaction and gene probes, based on amplifying regions of the uid gene that code for beta-glucuronidase, expression of which forms the basis for fecal coliform detection by the commercially available Colilert method. Amplification and gene probe detection of four different regions of uid specifically detected E. coli and Shigella species, including beta-glucuronidase-negative strains of E. coli; no amplification was observed for other coliform and nonenteric bacteria.     

Detection of Escherichia coli and Shigella spp. in Water by Using the Polymerase Chain Reaction and Gene Probes for uid

[This corrects the article on p. 1013 in vol. 57.].     

Combination of Chromogenic Differential Medium and estA-Specific PCR for Isolation and Detection of Phytopathogenic Xanthomonas spp.

A xanthomonad differential medium (designated Xan-D medium) was developed, on which streaks and colonies of xanthomonads, including 13 species of the genus Xanthomonas, turned wet-shining yellow-green and were surrounded with a smaller milky zone and a bigger clear zone in 3 to 4 days. The characteristics could easily be differentiated from those of yellow nonxanthomonads and other bacteria. The mechanism of color change and formation of a milky zone on the medium are mainly due to the Tween 80 hydrolytic capacity of xanthomonads. The gene, estA, responsible for Tween 80 hydrolysis was cloned and expressed in Escherichia coli, which acquired a capacity to hydrolyze Tween 80 and could turn green and form a milky zone on the Xan-D medium. The nucleotide sequence of estA is highly conserved in the xanthomonads, and the sequence was used to design a specific PCR primer set. The PCR amplification using the primer set amplified a 777-bp specific DNA fragment for all xanthomonad strains tested. The Xan-D medium was used to isolate and differentiate Xanthomonas campestris pv. campestris from naturally infected cabbages with black rot symptoms for a rapid diagnosis. All isolated X. campestris pv. campestris strains developed characteristic colonies and were positive in the PCR with the estA primer set. The Xan-D medium was further amended with antibiotics and successfully used for the detection of viable X. campestris pv. campestris cells from plant seeds. Although some yellow nonxanthomonads and other saprophytic bacteria from plant seeds could still grow on the medium, they did not interfere with the color development of X. campestris pv. campestris. However, Stenotrophomonas maltophilia, which is closely related to xanthomonads, existing in a seed lot could also develop yellow-green color but had different colony morphology and was negative in the PCR with the estA primer set. Accordingly, the combination of the Xan-D medium with the estA-specific PCR is a useful and reliable method for the isolation and detection of viable xanthomonad cells from plant materials.The genus Xanthomonas Dowson 1939 contains phytopathogenic bacteria that are usually yellow pigmented on medium and can cause diseases worldwide. Contaminated plant seeds are an important primary source of inoculum for the bacteria. A very low level of seed infestation (three in 10,000) can give rise to high disease incidence in the field (26). Therefore, planting seed free of bacterial contamination is an important disease management strategy. Several molecular and immunological methods, such as PCR (3, 4, 5, 13, 17, 30), enzyme-linked immunosorbent assay (1, 35), and flow cytometry (7), were developed to test seeds for the presence of these pathogens. However, these methods cannot directly distinguish dead and viable cells and may vary in specificity and sensitivity according to seed and other sample types (plant tissue, soil, and water).The most commonly used seed test method for recovery of viable bacterial cells is a seed-washing liquid-plating assay. In this assay, bacteria are first extracted from seeds, and the extract is diluted and plated onto semiselective medium. Several semiselective media are recommended in the working sheets in the ISTA Handbook on Seed Health Testing (27). They are considered to be reliable and efficient methods for routine detection (21, 24). Semiselective media permit quantification of viable cells and can be as sensitive as PCR in detecting Xanthomonas albilineans in sugarcane (10, 36) and even more sensitive than immunological techniques for detecting low numbers of bacteria (1, 36). Semiselective medium is easy to use and less costly than molecular and immunological methods and can often be readily used for diverse sample types.Although the semiselective media for xanthomonads can suppress the overgrowth of most saprophytic microorganisms, the major disadvantage of these media is the presence of yellow nonxanthomonads associated with plant tissues, which may interfere and complicate identification. Therefore, further identification and time-consuming pathogenicity tests must be completed to positively identify pathogenic xanthomonads. Accordingly, the search for a medium to differentiate xanthomonads from yellow nonxanthomonads is a critical task in the progress of isolation, detection, and identification of viable xanthomonads from plant tissues.In this report we describe a xanthomonad differential medium (called Xan-D medium) on which colonies of xanthomonads were wet-shiny (mucoid), convex, and yellow-green and could easily be differentiated from yellow nonxanthomonads and other bacteria. The medium could be used for the isolation of xanthomonads from naturally diseased plants and infested seeds. The mechanism and the gene responsible for the color development of xanthomonads were determined. The gene was also used to design a specific PCR primer set for the further identification of xanthomonads.