禽致病性大肠杆菌（CVCC1565）中耶尔森菌强毒力岛核心区的检测

采用PCR法,检测了大肠杆菌（CVCC1565）中耶尔森菌强毒力岛（high pathogenicity island,HPI）核心区的irp1、irp2、irp3、irp4、irp5及fyuA基因片段,并与小肠结肠炎耶尔森菌毒力岛的类似基因进行同源性比较。结果显示,E.coliCVCC1565菌株irp1、irp2、irp3、irp4、irp5及fyuA基因大小分别为799bp、414bp、798bp、504bp、758bp、948bp,与GenBank中公布的小肠结肠炎耶尔森菌（Yersinia enterocoliticaO：8 WA）HPI的irp1、irp2、irp3、irp4、irp5及fyuA基因同源性分别达到98%、98%、98%、95%、98%、98%。研究结果表明禽致病性大肠杆菌标准株（CVCC1565）携带耶尔森菌强毒力岛基因,这几个毒力岛基因在小肠结肠炎耶尔森菌和禽致病性大肠杆菌之间可能存在水平性转移。     

rmlA 基因缺失影响禽致病性大肠杆菌的生物被膜形成

【目的】构建禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)rmlA基因缺失株,研究该缺失株的生物学特性。【方法】利用Red重组系统构建rmlA缺失株;比较野生株与缺失株在生长特性、运动性和生物被膜形成能力等方面的差异;运用Real-time PCR技术,比较野生株与rmlA缺失株对APEC部分毒力基因转录的影响。【结果】rmlA缺失株,不影响APEC的生长和运动特性,但生物被膜形成能力显著增强,且使luxS、irp2基因转录水平分别上调2倍、1.8倍,iucD、fyuA则下调25倍。【结论】APEC的rmlA基因可以影响禽致病性大肠杆菌的生物被膜形成能力及部分毒力基因的转录水平;而对APEC的生长、运动特性没有影响。     

断奶仔猪源大肠杆菌LEE及HPI毒力岛的检测

应用Duplex_PCR方法,对240株断奶仔猪源大肠杆菌分离株的LEE毒力岛的eaeA基因和耶尔森菌强毒力岛核心区的irp2基因进行了检测,并对HPI毒力岛的fyuA基因及其在大肠杆菌染色体中的插入位置进行了分析,以及随机选取部分PCR产物进行了克隆和序列分析。结果表明:其中29株(12.08%)为LEE HPI ,39株(16.25%)为LEE ,11株(4.58%)为HPI ;另外还发现:不同病例来源的分离株之间,两种毒力岛的携带率不同;在断奶仔猪腹泻源分离株中,29株(20.71%)为LEE HPI ,22株(15.71%)为LEE ,9株(6.43%)为HPI ;断奶仔猪水肿病源分离株中,仅5株(6.58%)为LEE ,2株(2.63%)为HPI ,未发现LEE HPI 菌株;断奶仔猪水肿病并发腹泻源分离株中,仅12株(50%)为LEE ,未发现HPI 及LEE HPI 菌株。本实验克隆的eaeA(425bp)与已发表序列完全一致,irp2(280bp)f、yuA(948bp)、asn_tRNA_intB(1391bp)均与已发表的序列高度同源,同源性分别在98.2%、98.3%、95.8%以上;40株LEE HPI 或HPI 分离株中,29株(72.5%)为fyuA ,且其HPI毒力岛位于大肠杆菌染色体asn_tRNA位点。     

禽致病性大肠杆菌脂多糖核心型分布与毒力基因的相关性分析

【目的】大肠杆菌脂多糖(LPS)核心型根据其化学结构的不同分为5种,即R1、R2、R3、R4和K12。通过对禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)安徽、江苏、上海和河南等省市分离株的脂多糖核心型分布情况的研究,分析其与大肠杆菌主要毒力基因之间的潜在联系,以期为APEC的研究和防治提供参考。【方法】对分离到的76株APEC,利用PCR方法开展对LPS核心型分型鉴定和毒力基因检测;分析LPS核心型的分布和毒力基因、致病性之间的相关性。【结果】在76株APEC分离株中,68.4% (52株)为R1核心型,15.8% (12株)为R3型,11.8% (9株)为R4型,3.9% (3株)为R2型,未检测到K12核心型。毒力基因鉴定结果中yijp、mat、fimC、ibeB和ompA的检验阳性率均达到90%以上,可作为APEC的保守基因。其中LPS核心型R1与neuC、cva/cvi、irp2均具有显著正相关性(P<0.05),R3与iroN、irp2均具有显著负相关性(P<0.05),R4核心型与aatA显著正相关(P<0.05)。【结论】APEC的LPS核心型主要为R1。LPS核心型对部分毒力基因分布具有显著影响。     

禽致病性大肠杆菌gspL基因缺失株构建及生物学特性

【目的】研究gsp L基因缺失对禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)生物学特性的影响。【方法】利用Red重组方法构建禽致病性大肠杆菌DE17株的gsp L缺失株;分析野生株与缺失株的生长特性、黏附和入侵DF1细胞的差异;采用荧光定量PCR的方法比较野生株和缺失株毒力基因转录水平的变化;比较野生株与缺失株的半数致死量(LD50)差异。【结果】gsp L缺失不影响DE17的生长特性,但其黏附和入侵DF1细胞能力显著下调。荧光定量PCR检测结果表明,缺失株毒力基因lux S,pfs,fyu A和iss转录水平明显上调,tsh的转录水平明显下调,而vat,ibe A,stx2f和omp A的转录水平无显著变化;LD50检测结果表明,缺失株比野生株毒力增强了12倍。【结论】gsp L基因的缺失不影响禽致病性大肠杆菌的生长特性,但能减弱其黏附和入侵能力,且可以正调控禽致病性大肠杆菌部分毒力基因的转录水平,推测gsp L基因可能与APEC对宿主的致病性有关。     

禽致病性大肠杆菌毒力基因多重PCR方法的建立和应用

【目的】建立禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)黏附相关基因、侵袭及毒素相关基因、抗血清存活相关基因及铁转运相关基因的多重PCR方法,实现禽致病性大肠杆菌毒力基因的简便、快速检测。【方法】根据GenBank公布的基因序列,设计合成18对特异性引物,通过条件优化,建立四组多重PCR体系,并通过模板倍比稀释检测各组多重PCR的灵敏性。利用多重PCR检测100株APEC毒力基因的分布,验证多重PCR方法的可行性。【结果】根据PCR扩增片段大小判定,上述四组多重PCR体系均能同时扩增出该组中的各个毒力基因,且灵敏度分别为:103CFU、103CFU、105CFU、105CFU细菌和1ng、1ng、10ng、10ng DNA。100株APEC的毒力因子检测结果显示,多重PCR和单基因PCR结果一致。【结论】建立的四组多重PCR方法能够简便、快速地检测禽致病性大肠杆菌的毒力基因,可用于毒力基因的鉴定以及流行病学调查。     

禽源多重耐药金黄色葡萄球菌耐药基因检测及分子分型

【背景】金黄色葡萄球菌是革兰氏阳性菌,在动物和人身上能引起一系列疾病。【目的】了解安徽省不同地区禽源多重耐药金黄色葡萄球菌耐药性的情况及基因分型特征。【方法】以安徽不同地区的病禽肝脏作为标本,分离鉴定得到103株多重耐药金黄色葡萄球菌,并进行耐药基因型检测和ERIC-PCR分子分型。【结果】耐药菌株从三重到八重耐药均有分布,主要集中在五重(43/103)、四重(21/103)和六重耐药(22/103)。药敏结果显示,β-内酰胺类的耐药率最高(79.6%),氨基糖苷类次之(71.8%)。耐药基因检出率由高到低分别为mec A(92.2%)、aac(6′)/aph(2″)(76.7%)、ermC(37.9%)、ermA(13.6%)和fem A(3.9%)。ERIC-PCR分子分型获得6种不同类群,优势流行菌群为类群Ⅱ(38/103)。【结论】安徽地区金黄色葡萄球菌存在较严重的耐药性,氨基糖苷类、β-内酰胺类和大环内酯类抗生素的耐药基因携带率较高。分型结果表明安徽部分区域耐药金黄色葡萄球菌具有遗传多样性,但耐药谱与ERIC-PCR分子分型无明显关联。     

pagP基因对禽致病性大肠杆菌抗菌肽抗性和致病性的影响

【目的】禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)不仅严重影响全球的养禽业,对人类公共健康也造成巨大的潜在威胁。pag P基因在细菌的抗菌肽抗性和致病性方面发挥重要作用,但关于pag P基因在APEC中的功能尚不清楚。本文构建禽致病性大肠杆菌pag P基因缺失株,对缺失株的抗菌肽抗性和致病性进行研究。【方法】利用Red重组系统构建APEC的pag P基因缺失株,然后利用回复质粒构建回复株。研究pag P基因对细胞黏附与入侵、生物被膜形成能力、外膜渗透性、抗菌肽敏感性、致病性等方面的影响。【结果】成功构建pag P基因缺失株和回复株,抗菌肽抗性试验发现pag P基因缺失株对多粘菌素B、鸡β-防御素2(AVBD2)的敏感性显著增加(P0.01),致病性试验结果表明pag P基因缺失株的毒力显著降低(P0.01)。【结论】APEC的pag P基因对AVBD2的敏感性和APEC的致病性密切相关,为深入研究pag P基因的功能及调控作用奠定了基础。     

禽致病性大肠杆菌IMT5155 疑似毒力基因在人源及动物源大肠杆菌中的分布

[目的]检测禽致病性大肠杆菌IMT5155自分泌黏附素基因等具有代表性的疑似毒力基因在不同来源大肠杆菌中的分布,为进一步研究其致病机理提供依据.[方法]采用PCR和Dot blot,检测疑似毒力基因在不同地区(101株大肠杆菌中国分离株和121株大肠杆菌德国分离株)、不同来源(人源、禽源及猪源)大肠杆菌中的分布,并分析其和大肠杆菌系统进化分群的关系.[结果]自分泌黏附素基因B11等11个疑似毒力基因在禽致病性大肠杆菌中分布率较高,阳性率分别为:A1 36.4%(32/88)、A8 53.4%(47/88)、A1063.6%(56/88)、B1137.5%(33/88)、F3 59.1%(52/88)等,且疑似毒力基因主要存在于大肠杆菌B2进化群中.值得注意的是,D1、E9和F11基因片段在新生儿脑膜炎大肠杆菌中有较高的分布率,分别为60%(6/10)、80%(8/10)和90%(9/10),而在新生儿脑膜炎大肠杆菌中未检测到B11基因.[结论]自分泌黏附素B11等疑似毒力基因与禽致病性大肠杆菌关系密切,但疑似毒力基因D1、E9和F11与新生儿脑膜炎大肠杆菌密切相关,提示禽致病性大肠杆菌可能是新生儿脑膜炎大肠杆菌的毒力基因储库.     

致犊牛脑膜炎大肠杆菌新疆分离株ibeB基因的特性分析北大核心CSCD

【目的】分析致犊牛脑膜炎大肠杆菌分离株ibeB基因的分子生物学信息。【方法】以自脑炎死亡犊牛脑组织、肝组织分离鉴定的O161-K99-STa致病性大肠杆菌牛-EN株和牛-EG分离株为材料。根据GenBank中公布的脑膜炎大肠杆菌K1株RS218 ibeB基因序列设计1对引物,采用PCR方法,从分离株中成功克隆ibe B基因,比较分离株ibeB基因与不同来源大肠杆菌ibeB基因的部分生物信息学特性。【结果】分离株ibeB基因序列全长1500 bp,包含1371 bp开放阅读框,共编码457个氨基酸;生物信息学分析显示,牛-EN株与致人脑膜炎大肠杆菌K1 RS218的核苷酸和氨基酸同源性分别为90.5%和96.9%,牛-EG株与大肠杆菌K12的核苷酸和氨基酸同源性分别为99.4%和100.0%;ibeB蛋白为亲水性蛋白,分子质量为50.26 kDa,理论等电点为6.05;该蛋白无跨膜区,但具有信号肽序列;亚细胞定位显示,分泌信号通路位点(SP)占比例为0.939,说明该蛋白属于分泌型蛋白。【结论】从致脑膜炎大肠杆菌分离株中成功克隆ibeB基因,该基因与致人脑膜炎大肠杆菌K1 RS218 ibeB基因有较高的同源性,均有相似的生物学特性,属肠外致病性大肠杆菌。     

Siderophore-mediated strategies of iron acquisition by extraintestinal isolates of Enterobacter spp

A total of 89 examined Enterobacter isolates belonging to three species: E. cloaceae, E. aerogenes and E. sakazakii, produced iron chelators detected in universal CAS assay. In chemical assays the strains were shown to excrete mostly catecholate (88 strains) and hydroxamate (42 strains) type of siderophores. Forty-one strains produced both catecholate and hydroxamate siderophores whereas one isolate produced only hydroxamate. Besides, the isolates were screened for genes coding for another siderophore: yersiniabactin. The genes for biosynthesis and uptake of yersiniabactin are located on the high-pathogenicity island (HPI) of Yersinia spp. The presence of three marker genes irp1, irp2 and fyuA was estimated by polymerase chain reaction. Two strains: E. aerogenes and E. cloaceae possessed irp1, irp2 and fyuA genes. PCR products of irp1, irp2 and fyuA were of 240, 280 and 780 bp, respectively.     

禽源大肠杆菌的分离及其毒力因子的检测

从临床疑似大肠杆菌感染的病禽组织中分离到69株细菌(其中鹅源29株,鸡源40株);通过常规形态学、培养特性和生化特征的研究,确定为大肠杆菌。PCR检测表明,其中46株(66.7%)为F1 大肠杆菌,10株(14.5%)为F1 HPI 大肠杆菌,2株(2.9%)为HPI 大肠杆菌;通过比较还发现,F1菌毛和HPI在鹅源和鸡源大肠杆菌中以及不同脏器来源的菌株中具有相似的分子流行病学。O抗原鉴定结果表明鹅源大肠杆菌的O抗原型主要有O26、O78、O18、O117,鸡源大肠杆菌的O抗原型主要有O109、O24、O18、O139、O78。药敏试验表明,其中绝大多数菌株对先锋霉素V、呋喃妥因、庆大霉素敏感,对环丙沙星因菌株差异而不同,林可霉素、四环素、多粘菌素多不敏感。     

The Yersinia high-pathogenicity island in Escherichia coli and Klebsiella pneumoniae isolated from polymicrobial infections

We examined 12 pairs of strains of Escherichia coli and Klebsiella pneumoniae isolated from mixed infections in human for the presence of the Yersinia high-pathogenicity island (HPI). In one case both isolates carried the HPI, whereas in 11 cases one strain of the pair was HPI-positive. Although there were differences in the organization of the Yersinia HPI, all HPI-positive isolates were able to produce yersiniabactin. The presence of the Yersinia HPI may enhance the capability of strains involved in mixed infections to replicate in iron-deprived conditions in the host.     

Evidence for two evolutionary lineages of highly pathogenic Yersinia species.

Sensitivity to Yersinia pestis bacteriocin pesticin correlates with the existence of two groups of human pathogenic yersiniae, mouse lethal and mouse nonlethal. The presence of the outer membrane pesticin receptor (FyuA) in mouse-lethal yersiniae is a prerequisite for pesticin sensitivity. Genes that code for FyuA (fyuA) were identified and sequenced from pesticin-sensitive bacteria, including Y. enterocolitica biotype 1B (serotypes O8; O13, O20, and O21), Y. pseudotuberculosis serotype O1, Y. pestis, two known pesticin-sensitive Escherichia coli isolates (E. coli Phi and E. coli CA42), and two newly discovered pesticin-sensitive isolates, E. coli K49 and K235. A 2,318-bp fyuA sequence was shown to be highly conserved in all pesticin-sensitive bacteria, including E. coli strains (DNA sequence homology was 98.5 to 99.9%). The same degree of DNA homology (97.8 to 100%) was established for the sequenced 276-bp fragment of the irp2 gene that encodes high-molecular-weight protein 2, which is also thought to be involved in the expression of virulence by Yersinia species. Highly conserved irp2 was also found in all pesticin-sensitive E. coli strains. On the basis of the fyuA and irp2 sequence homologies, two evolutionary groups of highly pathogenic Yersinia species can be established. One group includes Y. enterocolitica biotype 1B strains, while the second includes Y. pestis, Y. pseudotuberculosis serotype O1, and irp2-positive Y. pseudotuberculosis serotype O3 strains. E. coli Phi, CA42, K49, and K235 belong to the second group. The possible proximity of these two iron-regulated genes (fyuA and irp2), as well as their high levels of sequence conservation and similar G+C contents (56.2 and 59.8 mol%), leads to the assumption that these two genes may represent part of an unstable pathogenicity island that has been acquired by pesticin-sensitive bacteria as a result of a horizontal transfer.     

The Yersinia HPI is present in Serratia liquefaciens isolated from meat

AIMS: The aim of the study was to screen the Enterobacteriaceae flora of meat for the presence of bacteria harbouring the Yersinia high-pathogenicity island (HPI). METHODS AND RESULTS: Bacteria from 29 meat and 29 liver samples were isolated on violet-red bile glucose agar. A total of 197 isolates were screened for the presence of the irp2 gene, encoded within the HPI, by PCR. One isolate that was positive for irp2 gene was also positive for the fyuA, irp1, ybtP/ybtQ, ybtX/ybtS and int/asn tRNA genes by PCR. The presence of fyuA, irp1 and irp2 genes was confirmed by Southern hybridization. CONCLUSIONS: The isolate was identified as Serratia liquefaciens by sequencing of the 16S rRNA gene and by ribotyping. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first report of a Serratia harbouring the Yersinia HPI. Serratia is a frequently occurring Enterobacteriaceae genus in chill-stored meat.     

藏北地区传统发酵乳中乳杆菌的多样性分析

摘要：【目的】针对藏北地区的乳杆菌来源及种属,对其多态性进行研究。【方法】采用ERIC-PCR技术和NTSYS-pc2.1软件对从藏北地区牧民家庭制作的发酵乳制品中分离出的77株乳杆菌进行多样性分析。【结果】ERIC-PCR扩增出的条带清晰,重复性好,多态性高。聚类分析表明,在0.73的水平上,77株乳杆菌共分为4大类群：干酪乳杆菌群A1、发酵乳杆菌群A2,瑞士乳杆菌群A3和植物乳杆菌群A4。其中,干酪乳杆菌群A1和发酵乳杆菌群A2分别占供试乳杆菌的35.06%和61.04%,为优势菌群。进一步对优势菌群     

The Yersinia high-pathogenicity island is present in different members of the family Enterobacteriaceae

A pathogenicity island termed high-pathogenicity island (HPI) is present in pathogenic Yersinia. This 35 to 45 kb island carries genes involved in synthesis, regulation and transport of the siderophore yersiniabactin. Recently, the HPI was also detected in various strains of Escherichia coli. In this study, the distribution of the HPI in the family Enterobacteriaceae was investigated. Among the 67 isolates pertaining to 18 genera and 52 species tested, nine (13.4%) harbored the island. These isolates were three E. coli, one Citrobacter diversus and five Klebsiella of various species (Klebsiella pneumoniae, Klebsiella rhinoscleromatis, Klebsiella ozaenae, Klebsiella planticola, and Klebsiella oxytoca). As in Yersinia sp., all nine isolates synthesized the HPI-encoded iron-repressible proteins HMWP1 and HMWP2. In the K. oxytoca strain, the right-end portion of the HPI was deleted, whereas the entire core region of the island was present in the eight other enterobacteria strains analyzed. In most of these isolates, the HPI was bordered by an asn tRNA locus, as in Yersinia sp. This report thus demonstrates the spread of the HPI among various members of the family Enterobacteriaceae.