副溶血性弧菌肠细菌基因间共有重复序列-PCR分子分型和耐药性、血清型研究

目的对副溶血性弧菌进行ERIC-PCR分子分型、耐药性和血清型相关性研究。方法肠细菌基因间共有重复序列（ERIC）为引物,对40株菌株基因组DNA进行扩增,得到DNA指纹图谱,并利用SPSS13.0统计软件对DNA扩增图谱进行分析,做出聚类图从而分型,并与菌株血清型、耐药性比较分析。结果40株菌用ERIC-PCR分为5个型,分辨力指数为（DI）为0.5;血清分型分为4个型;对8种抗生素中的萘啶酸、头孢噻亏、头孢西丁出现了不同程度的耐药。耐药菌株均出现在ERIC-PCR方法分型A型和血清分型O3型中。结论研究显示ERIC-PCR方法可以用于该菌分型分析,具有较好的分型能力。血清分型与ERIC-PCR方法分型一致。通过ERIC-PCR分型的树状图和血清分型结果推断,血清型O3群菌株很可能起源于血清型O1群菌株,血清型O3群和O1群密切相关。     

三种DNA指纹图谱技术在菌株分型中的应用

旨在通过ERIC-PCR、BOX-PCR、RAPD等技术对4株地芽孢杆菌属菌株进行DNA指纹图谱分析,找到一种适合于地芽孢杆菌属尤其是嗜热脂肪地芽孢杆菌的菌株分型方法。4株地芽孢杆菌属菌株呈现出4种不同的指纹图谱,其中ERIC-PCR的方法获得的条带较为清晰,实验方法较为简便快捷,且能相对较好地区分不同株系;BOX-PCR的方法得到的条带相对较少,不能很好地区分同一种菌的不同株系;RAPD的方法获得的条带相对较多,区分性更高,但同时也增加了一部分工作量和成本。3种菌株分型技术均能有效的区分地芽孢杆菌属菌株,其中ERIC-PCR是一种最有效最便捷区分嗜热脂肪地芽孢杆菌不同株系的方法。     

利用ERIC-PCR对苏云金芽胞杆菌与蜡状芽胞杆菌进行鉴定的研究

为了探索ERIC-PCR技术在苏云金芽胞杆菌和蜡状芽胞杆菌的鉴定及分型中的应用价值,本研究采用PCR方法初步检测苏云金芽胞杆菌杀虫晶体蛋白基因的组成,并对苏云金芽胞杆菌和蜡状芽胞杆菌的总DNA进行ERIC-PCR扩增,分析ERIC-PCR指纹图谱的特点并采用NTSYS2.10软件对其进行聚类。结果显示,各菌株的ERIC指纹图谱表现出不同程度的多态性,但图谱与菌株所含cry基因的类型存在一定的相关性。聚类分析结果显示,含有相同或相近cry基因类型的Bt菌株在进化树上趋向聚为一类,而不含cry基因的蜡状芽胞杆菌趋向于与不含cry基因的Bt菌株聚为一类或单独聚类。若在多种模式菌株的参考下,该方法可用于苏云金芽胞杆菌的初步鉴定和分型。     

ERIC-PCR技术在李斯特氏菌种、菌株鉴定中的应用

应用肠杆菌基因间重复一致序列聚合酶链反应技术（ERIC-PCR）对李斯特氏菌基因组DNA进行分析,结果显示,李斯特氏菌种间DNA指纹图谱带型差异较大;单核细胞增生性李斯特氏菌株间及相同血清型不同来源的菌株,其DNA指纹图谱带型也有明显差异。在单核细胞增生性李斯特氏菌各株的DNA指纹图谱中发现1600bp的种专一性扩增带。结果表明,ERIC-PCR技术可用于李斯特氏菌种、菌株的鉴定及进一步分型研究。 Abstract:Enterobacteia repetitive intergenic consensus sequences-based PCR(ERIC-PCR) was used to generate DNA fingerprints for Listeria spp.We got the specific profiles with ERIC-PCR technique that enables to identify Listeria species and the L.monocytogenes strains of different sterotype,and the same sterotype of L.monocytogenes from different sources also could be identified.Moreover,the species-spcific 1600bp DNA fragment was obtained from the fingerprint of L.monocytogenes.The study indicates that ERIC-PCR technique can be used in the identification of Listeria species and strains and its further typing,which is simple and quickly.     

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.     

副溶血性弧菌CRISPR的检测及其结构分析

【目的】检测副溶血性弧菌(Vibrio parahaemolyticus,简称VP)中规律成簇间隔的短回文序列(Clustered regularly interspaced short palindromic repeats,CRISPR),并对不同来源的VP中CRISPR位点的结构多样性进行分析。【方法】根据CRISPR DB数据库中公布的VP中确定的CRISPR结构序列CRISPR-1及文献中新发现的疑似CRISPR结构序列CRISPR-2设计引物,对不同来源的79株VP进行PCR扩增。利用CRISPR Finder分析CRISPR结构,采用生物信息学方法对不同来源VP的CRISPR位点结构多样性进行比较分析。【结果】79株VP中CRISPR-1的检出率为92.41%,CRISPR-2的检出率为96.20%,同时具有这2个位点的菌株占总数的89.87%,只有1株菌被检出不含有任何位点。分别比较不同来源的菌株CRISPR-1、CRISPR-2位点的重复序列发现不存在序列差异,而临床菌株的这2个CRISPR位点在间隔序列上比环境分离菌株存在更多的变异。2个CRISPR位点根据间隔序列的不同在VP中一共组成8种CRISPR谱型(编号A-H),除F谱型外,A-E、G谱型均只在临床分离菌株中发现,而在环境分离菌中还发现不含任何位点的H型。【结论】CRISPR在VP中普遍存在。环境分离菌株与临床分离菌株中CRISPR的结构存在差异。     

污染土壤中有机磷农药降解菌的分离及其多样性

采用添加有机磷农药的选择性培养基,在长期受有机磷农药污染的土壤中分离到7株有机磷农药降解菌,经生理生化鉴定和系统发育分析,菌株mp-1鉴定为Pseudaminobactersp.,菌株mp-2为Alcaligenessp.,菌株mp-7为Brucellasp.,其他菌株为Ochrobactrumsp.。16SrDNA序列同源性比较、系统发育分析和染色体ERIC-PCR指纹图谱扩增表明有机磷农药长期污染的土壤中有机磷农药降解菌具有丰富的多样性。     

分子分型技术用于流脑疫情的同源性分析

目的应用多位点序列分型(Multilocus sequence typing,MLST)技术和脉冲场凝胶电泳(pulsed-field gel electrophoresis,PFGE)技术对大连市2014年4月同一工地两起流脑疫情得到的脑膜炎奈瑟氏菌株进行分子分型图谱分析,了解各菌株之间的亲缘关系。方法对病例的脑脊液标本进行脑膜炎奈瑟菌PCR分群,对另一病例和所有密切接触者分离菌株进行多位点序列分型(MLST)试验和脉冲场凝胶电泳(PFGE)鉴定实验。结果疑似病例标本PCR结果为脑膜炎奈瑟氏菌A群阳性,另一病例和所有密切接触者分离到的菌株PFGE图谱基本相同,表明来自同一克隆系。多位点序列分析结果为ST7。结论两起疫情分离到的菌株型别之间具有高度的同源性,该病原菌类型为ST7的A群脑膜炎奈瑟氏菌。     

家庭内红色毛癣菌病患者间菌株差异性分析

目的用PCR技术比较分离自同一家庭红色毛癣菌病患者的菌株差异性,分析家庭内多发的红色毛癣菌病的致病菌株是家内相互感染,还是家外感染。方法以家庭内多发的皮肤癣菌病患者为研究对象,分离致病菌株并以传统方法鉴定菌种。再分别用随机扩增多态性DNA(RAPD)和巢式PCR特异扩增红色毛癣菌的串联重复亚元件(TRSS:TRS-1/TRS-2)产生的指纹图谱分析种内株间有无差异性。结果纳入实验的16株菌分离自8个家庭,用形态学等方法及种特异引物均鉴定为红色毛癣菌。RAPD显示4个家庭内的菌株间有差异性,TRS-1区PCR指纹图谱显示5个家庭内菌株有株间差异,TRS-2区能鉴定出2个家庭内菌株间有差异。综合各方法共区分出6个家庭内的菌株间有带型差异。结论该研究提示家庭内多发红色毛癣菌病从家外途径感染率高于家内感染。TRS-1区PCR指纹图谱对红色毛癣菌的菌株区分度高于RAPD,更适于红色毛癣菌株间分型。结合多种分子分型方法可最大限度发现不同菌株间的差异。     

Diversity, activity, and evolution of CRISPR loci in Streptococcus thermophilus

Clustered regularly interspaced short palindromic repeats (CRISPR) are hypervariable loci widely distributed in prokaryotes that provide acquired immunity against foreign genetic elements. Here, we characterize a novel Streptococcus thermophilus locus, CRISPR3, and experimentally demonstrate its ability to integrate novel spacers in response to bacteriophage. Also, we analyze CRISPR diversity and activity across three distinct CRISPR loci in several S. thermophilus strains. We show that both CRISPR repeats and cas genes are locus specific and functionally coupled. A total of 124 strains were studied, and 109 unique spacer arrangements were observed across the three CRISPR loci. Overall, 3,626 spacers were analyzed, including 2,829 for CRISPR1 (782 unique), 173 for CRISPR2 (16 unique), and 624 for CRISPR3 (154 unique). Sequence analysis of the spacers revealed homology and identity to phage sequences (77%), plasmid sequences (16%), and S. thermophilus chromosomal sequences (7%). Polymorphisms were observed for the CRISPR repeats, CRISPR spacers, cas genes, CRISPR motif, locus architecture, and specific sequence content. Interestingly, CRISPR loci evolved both via polarized addition of novel spacers after exposure to foreign genetic elements and via internal deletion of spacers. We hypothesize that the level of diversity is correlated with relative CRISPR activity and propose that the activity is highest for CRISPR1, followed by CRISPR3, while CRISPR2 may be degenerate. Globally, the dynamic nature of CRISPR loci might prove valuable for typing and comparative analyses of strains and microbial populations. Also, CRISPRs provide critical insights into the relationships between prokaryotes and their environments, notably the coevolution of host and viral genomes.     

Molecular typing of colonizing Streptococcus agalactiae strains by enterobacterial repetitive intergenic consensus PCR (ERIC-PCR) in a Chennai based hospital

Streptococcus agalactiae is reported to be an asymptomatic vaginal colonizer in Indian women, although it is considered one of the major causes of neonatal infections in many European countries. DNA based molecular typing methods are more reliable than the conventional serotyping method for identification and typing of this pathogen. In the present study, we have evaluated genetic diversity among colonizing S. agalactiae strains (n=86) by using a PCR-based genotyping method i.e. Enterobacterial Repetitive Intergenic Consensus PCR (ERIC-PCR). With ERIC-PCR fingerprinting at 60% similarity level in a dendrogram generated by UPGMA cluster analysis, 10 different ERIC groups were identified, which were subdivided into 62 distinct genotypes at ≥ 95% similarity level. Based on these findings, we demonstrate that ERIC-PCR is a simple, rapid, and inexpensive tool with sufficient discriminatory power and is applicable for characterization and genotyping of a large number of clinical isolates of S. agalactiae at molecular level.     

Corynebacterium diphtheriae spoligotyping based on combined use of two CRISPR loci

A large diphtheria epidemic in the 1990s in Russia and neighboring countries underlined the importance of permanent surveillance of the circulating and emerging clones of Corynebacterium diphtheriae, and hence there is a need for highly discriminatory, simple and portable typing methods. In the complete genome sequence of C. diphtheriae strain NCTC13129, we previously identified in silico two clustered, regularly interspaced short palindromic repeat (CRISPR) loci, and developed a macroarray-based method to study polymorphism in the larger DRB locus. We named this method spoligotyping (spacer oligonucleotide typing), analogously to a similar method of Mycobacterium tuberculosis genotyping. Here, we included in the analysis novel spacers of the other CRISPR locus in C. diphtheriae (DRA); both loci were simultaneously co-amplified and co-hybridized against the membrane with 27 different immobilized spacer-probes. The use of additional DRA spacers improved strain differentiation and discriminated within large DRB clusters. The 156 Russian strains of the epidemic clone were subdivided into 45 combined spoligotypes compared to 35 DRB-spoligotypes and only two ribotypes ('Sankt-Peterburg' and 'Rossija'). The spoligotyping method allows digital presentation of profiles and therefore it is perfectly suitable for interlaboratory comparison and database management; it may become a powerful tool for epidemiological monitoring and phylogenetic analysis of C. diphtheriae.     

The highly dynamic CRISPR1 system of Streptococcus agalactiae controls the diversity of its mobilome

Clustered regularly interspaced short palindromic repeats (CRISPR) confer immunity against mobile genetic elements (MGEs) in prokaryotes. Streptococcus agalactiae, a leading cause of neonatal infections contains in its genome two CRISPR/Cas systems. We show that type 1‐C CRISPR2 is present in few strains but type 2‐A CRISPR1 is ubiquitous. Comparative sequence analysis of the CRISPR1 spacer content of 351 S. agalactiae strains revealed that it is extremely diverse due to the acquisition of new spacers, spacer duplications and spacer deletions that witness the dynamics of this system. The spacer content profile mirrors the S. agalactiae population structure. Transfer of a conjugative transposon targeted by CRISPR1 selected for spacer rearrangements, suggesting that deletions and duplications pre‐exist in the population. The comparison of protospacers located within MGE or the core genome and protospacer‐associated motif‐shuffling demonstrated that the GG motif is sufficient to discriminate self and non‐self and for spacer selection and integration. Strikingly more than 40% of the 949 different CRISPR1 spacers identified target MGEs found in S. agalactiae genomes. We thus propose that the S. agalactiae type II‐A CRISPR1/Cas system modulates the cohabitation of the species with its mobilome, as such contributing to the diversity of MGEs in the population.     

Molecular typing of Salmonella weltevreden and Salmonella chincol by pulsed-field gel electrophoresis (PFGE) and enterobacterial repetitive intergenic consensus-polymerase chain reaction (ERIC-PCR)

Genomic DNA of Salmonella weltevreden (10 isolates from poultry, two isolates each from raw vegetables and river water) and S. chincol (15 isolates from poultry) were characterized by pulsed-field gel electrophoresis (PFGE) and enterobacterial repetitive intergenic consensus-polymerase chain reaction (ERIC-PCR) analysis. These isolates originated from a single location in Kajang, Selangor. The results of the PFGE and ERIC-PCR were analysed and comparisons were made using GelCompar software. ERIC-PCR with primers ERIC1R and ERIC2 discriminated the S. weltevreden into five clusters and two single isolates and S. chincol into two clusters and two single isolates at a similarity level of 80%, respectively. PFGE produced a single cluster and eight single isolates for S. weltevreden, and one cluster and 11 single isolates for S. chincol at a similarity level of 80% after digestion with the restriction enzyme XbaI, respectively. These results demonstrate that both PFGE and ERIC-PCR are suitable tools for molecular typing of the isolates examined. This revised version was published online in July 2006 with corrections to the Cover Date.     

Comparative Analysis of the Orphan CRISPR2 Locus in 242 Enterococcus faecalis Strains

Clustered, Regularly Interspaced Short Palindromic Repeats and their associated Cas proteins (CRISPR-Cas) provide prokaryotes with a mechanism for defense against mobile genetic elements (MGEs). A CRISPR locus is a molecular memory of MGE encounters. It contains an array of short sequences, called spacers, that generally have sequence identity to MGEs. Three different CRISPR loci have been identified among strains of the opportunistic pathogen Enterococcus faecalis. CRISPR1 and CRISPR3 are associated with the cas genes necessary for blocking MGEs, but these loci are present in only a subset of E. faecalis strains. The orphan CRISPR2 lacks cas genes and is ubiquitous in E. faecalis, although its spacer content varies from strain to strain. Because CRISPR2 is a variable locus occurring in all E. faecalis, comparative analysis of CRISPR2 sequences may provide information about the clonality of E. faecalis strains. We examined CRISPR2 sequences from 228 E. faecalis genomes in relationship to subspecies phylogenetic lineages (sequence types; STs) determined by multilocus sequence typing (MLST), and to a genome phylogeny generated for a representative 71 genomes. We found that specific CRISPR2 sequences are associated with specific STs and with specific branches on the genome tree. To explore possible applications of CRISPR2 analysis, we evaluated 14 E. faecalis bloodstream isolates using CRISPR2 analysis and MLST. CRISPR2 analysis identified two groups of clonal strains among the 14 isolates, an assessment that was confirmed by MLST. CRISPR2 analysis was also used to accurately predict the ST of a subset of isolates. We conclude that CRISPR2 analysis, while not a replacement for MLST, is an inexpensive method to assess clonality among E. faecalis isolates, and can be used in conjunction with MLST to identify recombination events occurring between STs.     

Genetics of CRISPR arrays in <Emphasis Type="Italic">Salmonella</Emphasis> Typhimurium 14028 associated with foreign DNA decay

Clustered regularly interspaced short palindromic repeats (CRISPRs) are a genetic locus of prokaryotes and contain highly conserved direct repeats, spacers, and CRISPR-associated genes. Spacers in CRISPRs are known as adaptive immune markers and reveal what types of phage or foreign DNA have been introduced in the past. The primary objective of this study was to analyze spacer sequences in CRISPR arrays of 15 Salmonella enterica subspecies and to determine if Salmonella CRISPRs are indeed involved in resistance to foreign DNAs. Using a bioinformatics algorithm, the CRISPR arrays of 15 subspecies of S. enterica were predicted. The transformation efficiencies of the wild-type and mutant strains lacking a space were determined using the plasmid harboring the same sequences with the space. Analysis of the CRISPR arrays indicated that S. Typhimurium encoded three possible CRISPR regions in the genome. Notably, 48 or 55 spacers were predicted in the genomes of S. Typhimurium 14028 and LT2 strains, respectively, and 39 were precisely identical. To confirm this prediction, the predicted CRISPR regions of S. Typhimurium 14028 were sequenced using the specific primers. Interestingly, a homology search of individual spacers found that the 2nd spacer of CRISPR 2 was nearly identical to a partial genome region of phage FSL SP-016. The mutant strain showed two to threefold increased transformation efficiency compared to that of the wild-type strain. These results demonstrate that the spacer sequence is dependent on genetic relations, especially for adaptive immunity against phage or foreign DNAs.     

Typing of clinical and environmental strains of Aeromonas spp. using two PCR based methods and whole cell protein analysis

Two PCR based typing methods i.e. random amplified polymorphic DNA analysis (RAPD) and enterobacterial repetitive intergenic consensus sequence (ERIC)-PCR were evaluated for typing of 42 Aeromonas isolates from clinical and environmental sources and whole cell protein (WCP) profiles were analyzed. Both RAPD and ERIC-PCR showed a high level of genetic diversity. Numerical index of the discriminatory (D) values were 0.94 and 0.96 (>0.90) for RAPD and ERIC-PCR, respectively. No correlation in banding pattern and evidence of genetic similarity was found between Aeromonas isolates from environmental and clinical sources. Therefore these techniques are highly reproducible and sensitive methods for typing the Aeromonas isolate from different sources. WCP profile showed two major variable regions i.e. 20 kDa to 45 kDa region and 70 kDa to 85 kDa region. Though WCP profiling had less discriminatory power, use of this method in combination with other established typing methods such as RAPD and ERIC-PCR may be helpful for reliable typing of Aeromonas isolates or to identify new proteins with pathogenic potential.     

BOX-PCR is an Adequate Tool for Typing <Emphasis Type="Italic">Aeromonas</Emphasis> spp.

PCR-based methods of fingerprinting take advantage of the presence of repetitive sequences that are interspersed throughout the genome of diverse bacterial species. They include the repetitive extragenic palindromic (REP) sequence, the enterobacterial repetitive intergenic consensus sequence (ERIC) and the 154-bp BOX element. The combination of the three methods is used for fine discrimination of strains and is designated as rep-polymerase chain reaction (PCR). REP-PCR and ERIC-PCR have been shown to be useful for typing Aeromonas strains. To our knowledge, rep-PCR fingerprinting method using the BOXA1R primer has never been tested on aeromonads. In this study, the BOX-PCR fingerprinting technique was evaluated for the discrimination of strains of some Aeromonas species. All strains were typeable and the majority showed unique banding patterns. Four strains from culture collections were used to investigate the reproducibility of the method. According to our results, BOX-PCR fingerprinting is applicable for typing of Aeromonas strains and can be considered as a useful complementary tool for epidemiological studies of members of this genus.