辽宁省溶藻弧菌REP-PCR和 PFGE分子分型、耐药谱的研究

目的利用PFGE和REP-PCR两种分型方法对溶藻弧菌进行分子分型和亲缘关系的研究;并将两种分型方法进行对比,并结合对抗生素耐药试验结果对其关联性进行初步探讨。方法应用脉冲场凝胶电泳(PFGE)方法对辽宁省2017年食品中分离的39株溶藻弧菌进行分型,应用BN(7.6版本)软件分析同源性。以基因外重复回文序列(REP)为引物,对40株溶藻弧菌DNA进行扩增,得到DNA指纹图谱,并利用SPSS 13.0统计软件对DNA扩增图谱进行聚类分析,同时将两种聚类分析结果进行比较,并用肉汤稀释法测定对15种抗生素的耐药性。结果 PFGE和REP-PCR两种方法的聚类分析结果均可分出两种优势带型A型和B型,且包含的菌株一致。PFGE分型方法在一些菌株中出现的DNA条带更多更复杂一些,分辨力指数(DI)为0.974,REP-PCR分型方法的DI为0.936。溶藻弧菌对头孢唑啉耐药率最高达57.5%,其次是氨苄西林(20.0%)和红霉素(12.5%),三重耐药菌比例达12.5%。结论 PFGE和REP-PCR两种方法均可以对溶藻弧菌进行分型,且均具有较好的分型能力,分辨力和再现性都很好,但PFGE分型方法的分辨力更优于REP-PCR分子分型。耐药菌株间带型具有高度同源性,优势带型菌株易耐药。综上所述,PFGE和REP-PCR两种分子分型方法对于评估溶藻弧菌流行及分布规律均是有用的,并且分型结果是一致的,都可以对菌株间亲缘关系进行有效溯源,因此在溶藻弧菌所致疾病爆发流行时,在普遍缺乏昂贵的PFGE专业设备和昂贵的配套BN软件以及专业操作人员的实验室,可以应用REP-PCR方法和SPSS统计软件代替PFGE方法和BN软件对菌株进行快速有效溯源。     

基于16S rRNA基因和细菌基因组间重复序列的DNA指纹图谱技术对肝硬化大鼠肝移植后肠道菌群多样性的研究

目的应用PCR-DGGE和rep-PCR技术对肝硬化大鼠肝移植后肠道菌群多样性进行研究,探讨肠道菌群多样性的变化,并比较这两种方法在菌群分析中的作用。方法首先建立CCL4诱导肝硬化大鼠的肝移植模型,收取对照组、肝硬化成模时、肝移植后7 d和肝移植后30 d的大鼠粪便,提取细菌基因组DNA,采用PCR-DGGE和rep-PCR[BOX-PCR,ERIC-PCR,ERIC2-PCR,(GTG)5-PCR,REP-PCR]进行DNA指纹图谱分析。结果PCR-DGGE可明确将正常大鼠、肝硬化大鼠、肝移植大鼠分为3个簇,并显示出肝硬化、肝移植大鼠肠道菌群多样性明显增多。rep-PCR技术也可将各组分开,其中ERIC-PCR、ERIC2-PCR及REP-PCR三者扩增条带各组差异有显著性,鉴别效果更好。结论应用基于16S rRNA基因和细菌基因组间重复序列的指纹图谱技术对肝硬化大鼠肝移植后肠道微生态的研究具有重要价值,可对临床肝硬化、肝移植患者肠道微生态制剂的使用起到指导作用。     

副溶血性弧菌重复序列-PCR分型研究

利用基因外重复回文序列-PCR(REP-PCR)和肠细菌基因间共有重复序列-PCR(ERIC-PCR)技术, 对副溶血性弧菌进行了分子分型研究和亲缘关系的探讨, 并使用Hunter和Gaston方法计算分辨力指数。结果显示40株副溶血性弧菌分离株均可扩增产生可重复的DNA指纹图谱, 并且不同菌株基因组DNA的扩增条带具有多态性。根据SPSS10.0软件得出的树状图结果, REP-PCR可以把40株菌分为21个型, 分辨力指数可达到0.953, 优势菌型为G1型; ERIC-PCR可将40株菌分成4个型, 分辨力指数为0.5。研究显示重复序列-PCR方法可以用于该菌分型分析, REP-PCR具有较好的分型能力。在两种PCR的DNA指纹图谱中, 血清型O1群与O3群主条带均非常相似, 表明它们之间亲缘关系密切。     

副溶血性弧菌重复序列-PCR分型研究

利用基因外重复回文序列-PCR(REP-PCR)和肠细菌基因间共有重复序列-PCR(ERIC-PCR)技术,对副溶血性弧菌进行了分子分型研究和亲缘关系的探讨,并使用Hunter和Gaston方法计算分辨力指数.结果显示40株副溶血性弧茵分离株均可扩增产生可重复的DNA指纹图谱,并且不同菌株基因组DNA的扩增条带具有多态性.根据SPSS10.0软件得出的树状图结果,REP-PCR可以把40株茵分为21个型,分辨力指数可达到0.953,优势菌型为G1型;ERIC-PCR可将40株菌分成4个型,分辨力指数为0.5.研究显示重复序列-PCR方法可以用于该菌分型分析,REP-PCR具有较好的分型能力.在两种PCR的DNA指纹图谱中,血清型O1群与O3群主条带均非常相似,表明它们之间亲缘关系密切.     

应用DNA指纹图谱技术鉴定整肠生菌株BL63516的研究

目的建立应用DNA指纹图谱技术鉴定微生态制剂——整肠生菌株BL63516的方法,提高菌种鉴别水平。方法应用RAPD（随机扩增多态性）方法,采用50条随机引物对7株地衣芽胞杆菌进行基因组DNA指纹图谱分析,选择多态性好、重复性好、稳定性强的随机引物,对BL63516与其他地衣芽胞杆菌进行区分。结果发现选用引物$87或$88分别对7株地衣芽胞杆菌进行基因组DNA指纹图谱分析,BL63516菌株扩增的DNA片段的大小、数量均与其他地衣芽胞杆菌有明显差异。结论此方法具有可重复性,方便、快速和准确的优势,可用于微生态制剂整肠生菌株的鉴别。     

用ISSR分子标记鉴别东北地区黑木耳生产菌株的研究

利用ISSR分子标记对东北地区黑木耳生产菌株进行了分子鉴别,结果表明在选用的20个UBC-ISSR引物中,有10个引物能对供试的27个黑木耳菌株基因组DNA进行扩增,获得的指纹图谱清晰稳定、多态性强。用NTSYS软件进行聚类分析,相似水平在0.75时,可将27个供试黑木耳菌株分为3个组群。研究结果说明ISSR分子标记,可以有效地用于黑木耳生产菌株快速准确鉴别,是黑木耳指纹图谱分析的理想手段。     

用ISSR分子标记鉴别东北地区黑木耳生产菌株的研究

利用ISSR分子标记对东北地区黑木耳生产菌株进行了分子鉴别,结果表明在选用的20个UBC-ISSR引物中,有10个引物能对供试的27个黑木耳菌株基因组DNA进行扩增,获得的指纹图谱清晰稳定、多态性强。用NTSYS软件进行聚类分析,相似水平在0.75时,可将27个供试黑木耳菌株分为3个组群。研究结果说明ISSR分子标记,可以有效地用于黑木耳生产菌株快速准确鉴别,是黑木耳指纹图谱分析的理想手段。     

副溶血性弧菌重复序列-PCR分型研究

目的利用REP—PCR技术对副溶血性弧菌进行分子分型研究和亲缘关系的探讨。方法以基因外重复回文序列（REP）为引物,对20株副溶血性弧菌基因组DNA进行扩增,得到DNA指纹图谱,并利用SPSS11．5统计软件对DNA扩增图谱进行分析,做出聚类图,并与血清型进行比较分析。结果REP-PCR可以把20株菌分为7个型,优势菌型为A型和B型,分辨力指数为0．932。结论REP．PCR方法可以用于副溶血性弧菌分型分析,具有较好的分型能力,如果能将分子分型和血清分型两种方法联用,分辨率会更高。研究推断血清型01群与03群菌株之间亲缘关系密切。     

用ISSR分子标记鉴别东北地区黑木耳生产菌株的研究

利用ISSR分子标记对东北地区黑木耳生产菌株进行了分子鉴别,结果表明在选用的20个UBC-ISSR引物中,有10个引物能对供试的27个黑木耳菌株基因组DNA进行扩增,获得的指纹图谱清晰稳定、多态性强。用NTSYS软件进行聚类分析,相似水平在0.75时,可将27个供试黑木耳菌株分为3个组群。研究结果说明ISSR分子标记,可以有效地用于黑木耳生产菌株快速准确鉴别,是黑木耳指纹图谱分析的理想手段。     

应用RAPD技术鉴别微生态菌种

目的：建立应用RAPD技术鉴别微生态菌种的方法,提高菌种鉴别水平。方法：应用RAPD（随机扩增多态性）方法,选用5条随机引物,利用PCR方法,对3株长双歧杆菌,3株嗜酸乳杆菌,3株粪肠球菌进行基因组DNA指纹图谱分析。结果：发现不同菌株扩增的DNA片段的大小、数量是有差异的。结论：此方法具有可重复性,方便、快速和准确的优势,可用于微生态制剂生产用菌株的鉴别。     

用rep—PCR技术研究中国花生根瘤菌的多样性

采用细菌基因组重复序列ＰＣＲ技术（简称ｒｅｐＰＣＲ）中常用的ＲＥＰＰＣＲ和ＥＲＩＣＰＣＲ,对从中国１１个省、市的２３个点、２４个花生品种采集的根瘤中分离的５９株花生根瘤菌Ｂｒａｄｙｒｈｉｚｏｂｉｕｍｓｐ．（Ａｒａｃｈｉｓ）进行多样性研究,同时对来自国外的６株花生根瘤菌及１４株参比慢生根瘤菌也进行了比较。得到的低相似性结果表明中国花生根瘤菌基因组存在显著的多样性。ＲＥＰＰＣＲ揭示,在相似性５０％上分为１１个群,而ＥＲＩＣＰＣＲ却得到２４个分群。这两种结果对菌株的分群有差异,暗示这两种短重复序列在慢生根瘤菌基因组中的分布的不同。没有发现菌株间基因组的多样性分布与花生品种、地理来源之间的必然联系。将两者电泳图谱结合并分析,得到介于上述两者间的结果。此结果进一步反映了菌株基因组间存在的多样性。同时还表明ｒｅｐＰＣＲ不仅是研究生物多样性的快速简便方法,还可应用于菌株的鉴别和生态学研究。     

Intraspecies variability of Desulfovibrio desulfuricans strains determined by the genetic profiles

Fifteen (soil and intestinal) strains of Desulfovibrio desulfuricans species were typed by PCR method with the use of primers specific for repetitive extragenic palindromic (REP) and enterobacterial repetitive intergenic consensus (ERIC) sequences. As a result, characteristic DNA fingerprints for the strains were obtained. Moreover, the genetic profiles were found to be useful for typing and distinguishing the strains of D. desulfuricans. According to cluster analysis, PCR with primers complementary to the sequences REP appeared to be slightly more discriminatory than PCR with ERIC primers for the investigated strains. Distinct fingerprint patterns of two isolates derived from the same patient pointed to the different origin of both strains.     

Characterization of Pseudoalteromonas citrea and P. nigrifaciens isolated from different ecological habitats based on REP-PCR genomic fingerprints

DNA primers corresponding to conserved repetitive interspersed genomic motifs and PCR were used to show that REP, ERIC and BOX-like DNA sequences are present in marine, oxidative, gram-negative Pseudoalteromonas strains. REP, ERIC and BOX-PCR were used for rapid molecular characterization of both the type species of the genus and environmental strains isolated from samples collected in different geographical areas. PCR-generated genomic fingerprint patterns were found to be both complex and strain specific. Analysis of the genotypic structure of phenotypically diverse P. citrea revealed a geographic clustering of Far Eastern brown-pigmented, agar-digesting strains of this species. Marine isolates of P. nigrifaciens with 67-70% DNA relatedness generated genomic patterns different from those of the type strain and formed a separate cluster. It is concluded that REP, ERIC and BOX-PCR are effective in generating strain specific patterns that can be used to elucidate geographic distribution, with these genomic patterns providing a valuable biogeographic criterion.     

Genetic characterization of Escherichia coli populations from host sources of fecal pollution by using DNA fingerprinting

Escherichia coli isolates were obtained from common host sources of fecal pollution and characterized by using repetitive extragenic palindromic (REP) PCR fingerprinting. The genetic relationship of strains within each host group was assessed as was the relationship of strains among different host groups. Multiple isolates from a single host animal (gull, human, or dog) were found to be identical; however, in some of the animals, additional strains occurred at a lower frequency. REP PCR fingerprint patterns of isolates from sewage (n = 180), gulls (n = 133), and dairy cattle (n = 121) were diverse; within a host group, pairwise comparison similarity indices ranged from 98% to as low as 15%. A composite dendrogram of E. coli fingerprint patterns did not cluster the isolates into distinct host groups but rather produced numerous subclusters (approximately >80% similarity scores calculated with the cosine coefficient) that were nearly exclusive for a host group. Approximately 65% of the isolates analyzed were arranged into host-specific groups. Comparable results were obtained by using enterobacterial repetitive intergenic consensus PCR and pulsed-field gel electrophoresis (PFGE), where PFGE gave a higher differentiation of closely related strains than both PCR techniques. These results demonstrate that environmental studies with genetic comparisons to detect sources of E. coli contamination will require extensive isolation of strains to encompass E. coli strain diversity found in host sources of contamination. These findings will assist in the development of approaches to determine sources of fecal pollution, an effort important for protecting water resources and public health.     

Distribution of repetitive DNA sequences in eubacteria and application to fingerprinting of bacterial genomes.

Dispersed repetitive DNA sequences have been described recently in eubacteria. To assess the distribution and evolutionary conservation of two distinct prokaryotic repetitive elements, consensus oligonucleotides were used in polymerase chain reaction [PCR] amplification and slot blot hybridization experiments with genomic DNA from diverse eubacterial species. Oligonucleotides matching Repetitive Extragenic Palindromic [REP] elements and Enterobacterial Repetitive Intergenic Consensus [ERIC] sequences were synthesized and tested as opposing PCR primers in the amplification of eubacterial genomic DNA. REP and ERIC consensus oligonucleotides produced clearly resolvable bands by agarose gel electrophoresis following PCR amplification. These band patterns provided unambiguous DNA fingerprints of different eubacterial species and strains. Both REP and ERIC probes hybridized preferentially to genomic DNA from Gram-negative enteric bacteria and related species. Widespread distribution of these repetitive DNA elements in the genomes of various microorganisms should enable rapid identification of bacterial species and strains, and be useful for the analysis of prokaryotic genomes.     

细菌基因组重复序列PCR技术及其应用

细菌中散在分布的DNA重复序列近年来不断被报道,基因外重复回文序列和肠细菌基因间共有重复序列是两个典型的原核细胞基因组散在重复序列。重复序列在染色体上的分布和拷贝数具种间特异性,用它们的互补序列作为引物,以细菌基因组DNA为模板进行PCR扩增反应,反应产物的琼脂糖电泳可以提供非常清晰的DNA指纹图谱,使用此图谱既可对各种微生物进行快速分型及鉴定,又可对它们进行DNA水平上的遗传多样性分析。细菌基因组重复序列PCR技术具有简捷、快速、结果稳定等特点,可对细菌进行分子标记,用于菌株分型、分类鉴定和亲缘关系等方面的研究。     

Genetic Characterization of Escherichia coli Populations from Host Sources of Fecal Pollution by Using DNA Fingerprinting

Escherichia coli isolates were obtained from common host sources of fecal pollution and characterized by using repetitive extragenic palindromic (REP) PCR fingerprinting. The genetic relationship of strains within each host group was assessed as was the relationship of strains among different host groups. Multiple isolates from a single host animal (gull, human, or dog) were found to be identical; however, in some of the animals, additional strains occurred at a lower frequency. REP PCR fingerprint patterns of isolates from sewage (n = 180), gulls (n = 133), and dairy cattle (n = 121) were diverse; within a host group, pairwise comparison similarity indices ranged from 98% to as low as 15%. A composite dendrogram of E. coli fingerprint patterns did not cluster the isolates into distinct host groups but rather produced numerous subclusters (approximately >80% similarity scores calculated with the cosine coefficient) that were nearly exclusive for a host group. Approximately 65% of the isolates analyzed were arranged into host-specific groups. Comparable results were obtained by using enterobacterial repetitive intergenic consensus PCR and pulsed-field gel electrophoresis (PFGE), where PFGE gave a higher differentiation of closely related strains than both PCR techniques. These results demonstrate that environmental studies with genetic comparisons to detect sources of E. coli contamination will require extensive isolation of strains to encompass E. coli strain diversity found in host sources of contamination. These findings will assist in the development of approaches to determine sources of fecal pollution, an effort important for protecting water resources and public health.     

新疆土著大豆根瘤菌种群遗传结构的初步分析

应用重复序列REP（repetitive extragenic palindromic,重复基因外回）和ERIC（ente-robaterial repetitive intergenic consensus,肠细菌重复基因间共有序列）结合聚合酶链式反应（ERP－PCR和ERIC－PCR）对从新疆有集的27株土大豆根瘤菌染色体进行指纹分析,发现在相似水平0.5时可基本分为两大聚类群,一个类群主要包括慢生型根瘤菌,另一类群为快生型根瘤菌,来自同一地区的根瘤菌具有较高的遗传相似性,以上结果表明该技术中对大豆根瘤菌进行种群结构和遗传多样性分析的有效手段。     

Genetic relationships among strains of Xanthomonas fragariae based on random amplified polymorphic DNA PCR, repetitive extragenic palindromic PCR, and enterobacterial repetitive intergenic consensus PCR data and generation of multiplexed PCR primers useful for the identification of this phytopathogen.

Genetic relationships among 25 isolates of Xanthomonas fragariae from diverse geographic regions were determined by three PCR methods that rely on different amplification priming strategies: random amplified polymorphic DNA (RAPD) PCR, repetitive extragenic palindromic (REP) PCR, and enterobacterial repetitive intergenic consensus (ERIC) PCR. The results of these assays are mutually consistent and indicate that pathogenic strains are very closely related to each other. RAPD, ERIC, and REP PCR assays identified nine, four, and two genotypes, respectively, within X. fragariae isolates. A single nonpathogenic isolate of X. fragariae was not distinguishable by these methods. The results of the PCR assays were also fully confirmed by physiological tests. There was no correlation between DNA amplification product patterns and geographic sites of isolation, suggesting that this bacterium has spread largely through exchange of infected plant germ plasm. Sequences identified through the RAPD assays were used to develop three primer pairs for standard PCR assays to identify X. fragariae. In addition, we developed a stringent multiplexed PCR assay to identify X. fragariae by simultaneously using the three independently derived sets of primers specific for pathogenic strains of the bacteria.     

Use of repetitive DNA sequences and the PCR To differentiate Escherichia coli isolates from human and animal sources

The rep-PCR DNA fingerprint technique, which uses repetitive intergenic DNA sequences, was investigated as a way to differentiate between human and animal sources of fecal pollution. BOX and REP primers were used to generate DNA fingerprints from Escherichia coli strains isolated from human and animal sources (geese, ducks, cows, pigs, chickens, and sheep). Our initial studies revealed that the DNA fingerprints obtained with the BOX primer were more effective for grouping E. coli strains than the DNA fingerprints obtained with REP primers. The BOX primer DNA fingerprints of 154 E. coli isolates were analyzed by using the Jaccard band-matching algorithm. Jackknife analysis of the resulting similarity coefficients revealed that 100% of the chicken and cow isolates and between 78 and 90% of the human, goose, duck, pig, and sheep isolates were assigned to the correct source groups. A dendrogram constructed by using Jaccard similarity coefficients almost completely separated the human isolates from the nonhuman isolates. Multivariate analysis of variance, a form of discriminant analysis, successfully differentiated the isolates and placed them in the appropriate source groups. Taken together, our results indicate that rep-PCR performed with the BOX A1R primer may be a useful and effective tool for rapidly determining sources of fecal pollution.