辽宁省2006-2016年集中空调冷却水中 嗜肺军团菌毒力岛基因组携带情况

摘要:目的 了解2006?2016年辽宁地区集中空调冷却水中军团菌携带毒力岛基因情况及其致病性。方法 根据GenBank公布的嗜肺军团菌核苷酸序列设计和合成嗜肺军团菌种和毒力岛基因鉴定引物,采用PCR法对2006?2016年辽宁省各大公共场所委托及抽样检测中分离到的军团菌,进行了毒力岛基因组检测,并与血清型进行比较分析,其中嗜肺军团菌15株、非嗜肺军团菌8株。结果 标准菌株ATCC（33152）12个毒力岛基因全阳性;9株LP1型嗜肺军团菌分别检出9~11个毒力岛基因,6株LP2-14型嗜肺军团菌分别检出6~9个毒力岛基因,8株非嗜肺军团菌分别检出2~11个毒力岛基因。结论 辽宁地区军团菌广泛存在公共环境集中空调冷却系统中,以LP1型嗜肺军团菌居多,LP2-14型嗜肺军团菌与非嗜肺军团菌也普遍存在,而且所测菌株均携带毒力岛基因,是细菌感染性肺炎的重要隐患病源之一。     

嗜肺军团菌毒力基因、致病性及实验诊断研究进展

嗜肺军团菌是引起军团菌肺炎的重要病原体,关于军团菌感染的致病机制目前尚不十分清楚。近来研究发现,军团菌的致病性与其毒力因子和铁代谢等相关,本文对嗜肺军团菌的毒力因子及其作用。致病机制和实验室诊断方法研究进展作一综述。     

一个细菌的致命之旅——嗜肺军团菌分泌系统及效应蛋白的研究进展

嗜肺军团菌是引起军团菌肺炎以及庞蒂亚克热的革兰氏阴性胞内病原细菌,嗜肺军团菌侵染宿主的主要特点是可以通过其IVB型毒力分泌系统,向宿主细胞内分泌超过150种的底物效应蛋白。通过这些效应蛋白的作用,嗜肺军团菌能够调整宿主细胞的胞内运输途径,改变内外环境来伪装自己的吞噬泡,干扰宿主的细胞周期,抑制宿主细胞的凋亡,从而有效逃避宿主细胞的防御功能,创造出理想的胞内增殖环境。最后,效应蛋白还可以帮助军团菌从宿主细胞中逃逸。目前,嗜肺军团菌已经成为"病原菌-宿主相互作用"的重要研究模型,其毒力分泌系统及其底物效应蛋白的功能也成为细胞微生物学的研究热点。对嗜肺军团菌分泌系统及效应蛋白的研究不仅能够帮助阐明病原细菌的致病机理,还有助于推动对宿主免疫机制的更深层次的研究。文章主要针对嗜肺军团菌的毒力分泌系统,尤其是IVB型分泌系统的结构和功能,以及底物效应蛋白的研究进展进行了综述,向读者展示出一个小小的细菌所拥有的那令人惊叹的、如此狡猾的生存策略和它精致的杀伤武器。     

嗜肺军团菌效应蛋白之间的调控机制

嗜肺军团菌(Legionella pneumophila)是一种革兰氏阴性致病菌,它可以引起人类军团病。嗜肺军团菌的Dot/Icm分泌系统在其致病过程中至关重要,其向宿主细胞内转运约330种效应蛋白,通过修饰细胞调节因子、抑制细胞凋亡等一系列措施操纵宿主细胞的多种生命活动,以完成自身的增殖与侵染。为避免对宿主生理造成不必要的破坏,嗜肺军团菌已进化出复杂而精细的调控机制来平衡嗜肺军团菌毒力与宿主细胞的稳态,以确保嗜肺军团菌在宿主细胞内的生存。军团菌效应蛋白的功能及分子机制的研究近几年取得突破性进展,嗜肺军团菌效应蛋白之间的作用机理也成为我们进一步研究的热点。该文主要对嗜肺军团菌的致病机制及其效应蛋白间的调控机制进行了综述,为进一步了解嗜肺军团菌致病机制提供了一定的参考。     

嗜肺军团菌生物膜形成及其影响因素

嗜肺军团菌在自然环境和人工供水系统中普遍存在,能够在阿米巴原虫和其他原生动物体内繁殖,所引起的军团菌病主要表现为严重的呼吸系统疾病。但在自然环境中,嗜肺军团菌的生存和繁殖受到多菌种生物膜形成和繁殖的影响,一些军团菌病的暴发与生物膜的存在相关。因此,阻止自然环境和人工水系统中生物膜的形成显然已成为降低水污染的有效策略之一。根据近年来的报道分别对影响嗜肺军团菌生物膜形成的生化因子和嗜肺军团菌的毒力因子,以及其他生物物种在嗜肺军团菌生物膜形成过程中所起的不同作用等进行综述。     

用绿色荧光蛋白研究军团菌与寄主的相互关系*

原生动物作为军团菌的天然寄主,在军团菌的生存、增殖、毒力和抗逆性等方面起着重要的作用。通过多次转化筛选,获得了一种高量表达绿色荧光蛋白基因gfpmut2的自发突变质粒。该质粒在嗜肺军团菌细胞内稳定复制和表达;转化了该质粒的嗜肺军团菌在自然光下即可发出明亮的绿色荧光。以转化菌饲喂嗜热四膜虫BF1株后,在荧光显微镜下能清楚观察到细菌在细胞内的形态变化、增殖和裂解宿主细胞的过程。为研究嗜肺军团菌与原生动物寄主的相互关系提供了一种简单而直观的方法。     

用绿色荧光蛋白研究军团菌与寄主的相互关系

原生动物作为军团菌的天然寄主,在军团菌的生存、增殖、毒力和抗逆性等方面起着重要的作用。通过多次转化筛选,获得了一种高量表达绿色荧光蛋白基因gfpmut2的自发突变质粒。该质粒在嗜肺军团菌细胞内稳定复制和表达;转化了该质粒的嗜肺军团菌在自然光下即可发出明亮的绿色荧光。以转化菌饲喂嗜热四膜虫BF1株后,在荧光显微镜下能清楚观察到细菌在细胞内的形态变化、增殖和裂解宿主细胞的过程。为研究嗜肺军团菌与原生动物寄主的相互关系提供了一种简单而直观的方法。     

嗜肺军团菌效应蛋白质介导的新型泛素化过程

泛素化是真核细胞特有的蛋白质翻译后修饰方式,调节真核细胞内多种重要生理过程,例如蛋白质稳态、细胞周期、免疫反应、DNA修复以及囊泡转运等。鉴于泛素化对于生命活动的重要性,病原菌在与宿主细胞的长期进化过程中衍生出一系列针对宿主泛素化过程的效应蛋白质,调控宿主体内泛素化过程,从而构建有利于病原菌自身生长繁殖的内环境。嗜肺军团菌是一种革兰氏阴性菌,是军团菌肺炎的致病菌,能够引起发热和肺部感染,重型病死率高达15%~30%。Dot/Icm Ⅳ型分泌系统是嗜肺军团菌侵染过程中最主要的毒力系统。在侵染宿主细胞的过程中,嗜肺军团菌利用该分泌系统,分泌超过330种效应蛋白质,协助细菌在宿主胞内生存、增殖和逃逸。多种嗜肺军团菌效应蛋白质通过直接或者间接的方式对宿主泛素化过程进行调控。近年的研究发现,多种效应蛋白质可以介导不同于真核生物经典泛素化的新型泛素化过程。本文介绍了嗜肺军团菌效应蛋白质介导的新型泛素化过程的最新研究进展,为理解泛素化过程在嗜肺军团菌致病过程中的重要作用提供参考依据。     

嗜肺军团菌分子检测最新进展

嗜肺军团菌是军团病最主要的致病原,在人工水体或空调冷却系统中多有存在,是影响公众健康的一大隐患。能否准确高效地检测嗜肺军团菌,对军团病的防控具有重要意义。分子生物学技术多具有快速、简便、特异、灵敏等优点,近年越来越多地应用于嗜肺军团菌的检测。本文简要综述了嗜肺军团菌分子检测的最新进展,介绍了PCR及其衍生技术、核酸等温扩增技术、基因分型、探针杂交及其相关技术,以及新一代测序在嗜肺军团菌分子检测中的应用,并简单讨论了嗜肺军团菌检测存在的问题,对嗜肺军团菌分子检测的前景进行了展望。     

PCR-酶切技术快速鉴定军团菌

[目的]建立一种新型的军团菌鉴定方法,并探讨该法在鉴定环境水源和临床标本军团菌菌株中的应用价值.[方法]根据军团菌16S rRNA基因保守序列设计引物,以分离培养得到的可疑军团菌菌株作为模板,采用PCR法对模板扩增,并用限制性内切酶对PCR产物进行酶切分析,建立一种嗜肺军团菌及非嗜肺军团菌的鉴定方法.对16株嗜肺军团菌、22株非嗜肺军团菌及12株其他细菌标准菌株进行检测,验证该方法的可靠性,最后用该法检测广州地区分离的169株可疑军团菌菌株并进行基因测序.[结果]该PCR方法检测嗜肺军团菌及非嗜肺军团菌所有标准菌株均为阳性,非军团菌检测结果均为阴性;进一步的Hinf Ⅰ酶切分析可准确的区分嗜肺军团菌标准菌株;广州地区分离的169株可疑军团菌菌株经该法检测发现160株为军团菌,其中79株为嗜肺军团菌,与基因测序检测结果一致.[结论]PCR-酶切技术可快速、特异地检测军团菌及嗜肺军团菌,适用于环境水源和临床标本可疑军团菌菌株的检测.     

A 65-kilobase pathogenicity island is unique to Philadelphia-1 strains of Legionella pneumophila

Nucleotide sequence analysis of an approximately 80-kb genomic region revealed an approximately 65-kb locus that bears hallmarks of a pathogenicity island. This locus includes homologues of a type IV secretion system, mobile genetic elements, and known virulence factors. Comparative studies with other Legionella pneumophila strains and serogroups indicated that this approximately 65-kb locus is unique to L. pneumophila serogroup 1 Philadelphia-1 strains.     

致病岛及其分泌系统

致病岛是指细菌染色体上一段具有典型结构特征的基因簇,主要编码与细菌的毒力及代谢等功能相关的产物。病原菌必须要有一套高效的分泌系统才能将致病因子分泌到细菌表面或转运出细胞,并尽可能进入宿主细胞。现在已经发现了至少5套不同的蛋白分泌系统。本文就致病岛及其分泌系统的相关研究进展作一综述。     

毒力岛与细菌致病性

毒力岛作为细菌染色体上一段具有典型结构特征的基因簇,与多种致病茵毒力因子的产生和细菌的进化有密切的关系,研究毒力岛对于认识致病细菌的变异,阐述病原菌的致病机理,预测新病原茵的出现有着十分重要的意义。     

cag pathogenicity island of Helicobacter pylori in Korean children

Background. cag pathogenicity island is reported to be a major virulence factor of Helicobacter pylori. The aim of this study was to investigate the status of cag pathogenicity island genes and gastric histology in Korean children with H. pylori gastritis. Methods. Helicobacter pylori DNA was extracted from antral biopsy specimens from 25 children with H. pylori gastritis. Specific polymerase chain reaction assays were used for four genes of cag pathogenicity island. The features of gastritis were scored in accordance with the updated Sydney System. Results. cagA was present in 23 (92%) of 25 children, and cagE in 24 (96%). Twenty‐two (88%) children were cagT positive and 19 (76%) virD4 positive. All of the selected genes of the cag pathogenicity island were present in 17 (68%) children and completely deleted in one child. There were no differences in neutrophil activity and chronic inflammation between children infected with intact cag pathogenicity island strains and those with partially or totally deleted‐cag pathogenicity island strains. Conclusion. cag pathogenicity island is not a uniform, conserved entity in Korea. Completeness of cag pathogenicity island may not be the major factor to determine the severity of H. pylori gastritis in children.     

耶尔森菌强毒力岛*

近年来,人们发现了耶尔森菌强毒力岛,并对其结构与功能进行了大量研究。同时,在一些研究中,发现它也广泛存在于其它几种肠道致病菌中。就耶尔森菌毒力岛HPI结构与功能及它在其它肠道致病菌分布的研究现状作一综述。     

Genetic approaches to study Legionella pneumophila pathogenicity

Abstract: Legionella pneumophila is an intracellular pathogen replicating in human macrophages during the course of infection of the lungs, infection by legionellae often leads to severe pneumonia, termed Legionnaires' disease. Genetic approaches to identify the factors responsible for L. pneumophila pathogenicity started with the construction of genomic libraries in Escherichia coli. Various L. pneumophila -specific genes were cloned in E. coli K-12 by identifaction using functional assays, antibody screening and hybridization ('reverse genetics'). By disrupting the genes via allelic exchange, mutants have been created to assess the influence of the factors on pathogenicity. Among the cloned genes, only for the gene product of the mip gene, encoding a 24-kDa surface-associated protein (macrophage infectivity potentiator) unequivocal evidence for its contribution to pathogenicity could be provided. Two hemolytic factors that have been cloned do not seem to play a role in L. pneumophila pathogenicity. Genetic systems for transposon mutagenesis of the L. pneumophila genome (Tn5, Tn903dlIlacZ, MudphoA), including TnphoA shuttle mutagenesis, have been established and specifically adapted to identify mutants which displayed an impaired capability to multiply inside macrophages and with a reduced in vivo virulence. Furthermore, by complementation of avirulent mutants, genetic loci could be identified which restored the virulence.     

A Markov Chain Model for Newcastle Disease and its Relevance to the Intracerebral Pathogenicity Index

By modelling the progression of the avian disease caused by Newcastle disease virus (NDV) as a one‐step, time homogeneous Markov Chain (MC) it is possible to set the intracerebral pathogenicity index (ICPI) in a statistical context. Previous assessments of ICPI values for different viruses ignore the fact that the same ICPI value may occur via different sequences of disease status. However, the MC model approach takes into account the state transitions by which an animal came to obtain its particular contribution to the ICPI value. Because the probability that an animal remains normal approaches zero as time increases, the MC model suggests a pathogenicity index based on the multiplying factor that determines this probability's approach to zero. Numerical examples are given with data from NDV pathogenicity trials.     

Population structure and recombination in environmental isolates of Legionella pneumophila

Legionella pneumophila is a water-borne bacteria responsible for most cases of legionellosis, an emerging disease with an increasing incidence in industrialized countries. Although early analysis based on multilocus enzyme electrophoresis (MLEE) described the population structure of this species as clonal, more recent reports have suggested that recombination also contributes to shaping variation across its genome. We report here the results of analysing the nucleotide sequences of 19 loci in 31 environmental samples of L. pneumophila from a small Spanish region (near Alcoi, province of Alicante) where legionellosis has become almost endemic. We analysed the six loci currently incorporated to the sequence-based typing scheme developed by European Working Group for Legionella Infections (EWGLI) for L. pneumophila and 13 intergenic regions, for which we developed primers anchored in flanking, conserved genes. Our results show that recombination among natural isolates of this species is a common phenomenon, as 20 of the 31 isolates contained at least one locus in which recombination was revealed by at least three different methods. The mapping of the recombination events on the maximum likelihood tree of the concatenate sequence of the 19 loci indicated that at least nine independent recombination events might explain the observed distribution of recombinant loci among isolates. In consequence, we have shown that recombination in L. pneumophila is much more frequent than previously considered and that it does not seem to be restricted to already described pathogenicity islands or other genome constituents which provide it with a high plasticity.