Genetics of Antimicrobial Resistance

Antimicrobial resistant strains of bacteria are an increasing threat to animal and human health. Resistance mechanisms to circumvent the toxic action of antimicrobials have been identified and described for all known antimicrobials currently available for clinical use in human and veterinary medicine. Acquired bacterial antibiotic resistance can result from the mutation of normal cellular genes, the acquisition of foreign resistance genes, or a combination of these two mechanisms. The most common resistance mechanisms employed by bacteria include enzymatic degradation or alteration of the antimicrobial, mutation in the antimicrobial target site, decreased cell wall permeability to antimicrobials, and active efflux of the antimicrobial across the cell membrane. The spread of mobile genetic elements such as plasmids, transposons, and integrons has greatly contributed to the rapid dissemination of antimicrobial resistance among several bacterial genera of human and veterinary importance. Antimicrobial resistance genes have been shown to accumulate on mobile elements, leading to a situation where multidrug resistance phenotypes can be transferred to a susceptible recipient via a single genetic event. The increasing prevalence of antimicrobial resistant bacterial pathogens has severe implications for the future treatment and prevention of infectious diseases in both animals and humans. The versatility with which bacteria adapt to their environment and exchange DNA between different genera highlights the need to implement effective antimicrobial stewardship and infection control programs in both human and veterinary medicine.     

细菌遗传元件水平转移与抗生素抗性研究进展

细菌可移动遗传元件包括噬菌体、质粒、转座子、插入序列、整合子、基因组岛（genomic island and genomic islet）等,其中接合性质粒、转座子、整合子及基因组岛等是与抗生素抗性有关的元件,可以在向种甚至于不同种菌株间水平转移,加速了临床上耐药及多重耐药菌株的产生。综述了细菌与抗生素抗性有关的可移动遗传元件的种类、特征及转移机制的研究进展。     

1株多重耐药肺炎克雷伯菌耐药基因和整合子、转座子遗传标记研究

目的 了解多重耐药肺炎克雷伯菌的耐药基因存在状况和遗传学背景。方法 聚合酶链反应(RCR)法对多重耐药的肺炎克雷伯菌进行β-内酰胺酶基因、氨基糖苷类修饰酶基因、质粒AmpC酶基因、qacEΔ1-sull耐消毒剂和磺胺基因、整合子遗传标记(整合酶基因)、Tn21/Tn501转座子遗传标记(汞离子还原酶基因)检测。结果 TEM、SHV型β-内酰胺酶基因, DHA型质粒AmpC酶基因,aac(6′)-1型氮基糖苷类修饰酶基因,qacEΔ1-sul1耐消毒剂和磺胺基因,整合子遗传标记(intI1整合酶基因),Tn21/Tn501转座子遗传标记(merA汞离子还原酶基因)检测阳性。结论 多重耐药肺炎克雷伯菌存在多种耐药基因和Ⅰ类整合子、Tn21/Tn501转座子。     

Detection and characterisation of integrons in Salmonella enterica serotype enteritidis

Integrons have been widely described among the Enterobacteriaceae including strains of multi-resistant Salmonella enterica serotype Typhimurium DT104; however, information with respect to the presence of integrons among S. enterica serotype Enteritidis strains is limited. Multi-resistant isolates of Enteritidis were screened for the presence of integrons using a PCR protocol. One integron was detected in all isolates that were resistant to sulfonamide and streptomycin. Characterisation of these isolates indicated an integron which ranged in size between 1000 and 2000 bp and which harboured a gene cassette encoding the ant(3")-Ia gene specifying streptomycin and spectinomycin resistance. Further studies revealed the integrons to be located on large conjugative plasmids. This appears to be the first report of plasmid-borne integrons in Enteritidis.     

Spread and evolution of natural plasmids harboring transposon Tn5

Abstract: The presence of transposon Tn 5 was studied in 730 Enterobacteriaceae strains from clinical and sewage origin. From these strains, twenty-five conjugative plasmids harboring transposon Tn 5 were isolated. These plasmids were compared with pJR67 and pRYC119, the only previously studied plasmids harboring Tn 5 . A phylogenetic tree of the evolution of all different plasmids was proposed. Irrespective of their bacterial host and geographical place of isolation, some of the plasmids were shown to be identical. All of them can be included in only eight different prototypical plasmid species. Twenty-two plasmids (88%) carried an IncI1 incompatibility determinant as judged form DNA hybridization experiments. The presence of some other common resistance genes suggested that these plasmids are descendants of a common ancestor. These IncI1 plasmids could be grouped in six prototypical species. The results presented here suggest that Tn 5 spread in nature may be dependent on the conjugative ability of the IncI plasmids harboring the transposon, rather than on the efficiency of Tn 5 transposition between different replicons.     

水平基因转移介导抗菌素耐药性传播机制的研究进展

近几十年来,病原菌耐药性的出现和蔓延已上升为严峻的公共卫生问题。越来越多研究表明,抗菌素抗性基因(antibiotic resistance genes,ARGs)不仅仅见于临床所分离的病原体,而是包括所有的致病菌、共生菌以及环境中的细菌,它们都能在可移动遗传元件和噬菌体的作用下,通过水平基因转移(horizontal gene transfer,HGT)途径获得耐药性,进而形成抗菌素耐药基因簇(耐药基因组)。HGT可导致抗菌素的耐药性在环境共生菌和病原菌之间传播扩散,这可通过临床上一些重要的抗菌素耐药基因的传播证实。传统观念认为HGT的三种机制中,接合对ARGs的传播影响最大,最近研究表明转化和转导对ARGs播散起到不可忽视的作用。通过深入了解耐药基因组的传播及其在动员病原菌耐药中发挥的作用,对于控制这些基因的播散是至关重要的。将讨论耐药基因组的概念,提供临床相关的抗菌素抗性基因水平基因转移的例子,对当前已研究的促使抗菌素耐药性传播的各种HGT机制进行回顾。     

一株猪源鼠伤寒沙门氏菌的耐药性鉴定及其消除

猪源鼠伤寒沙门氏菌临床分离株17Y,检测其对19种抗生素的耐药性,结果耐14种抗生素。用高温及高浓度SDS处理后,获得对11种抗生素的敏感性,该菌株命名为17S1。PCR检测证明,大部分耐药基因存在于质粒上,包括I型整合子携带耐药基因,且随着质粒的消除而被消除。所鉴定的耐药基因有blaTEM、blaOXA-1、cat1、tet(B)、aacC2、aadA8b、dhfrXⅡ和sul1等。喹诺酮类药物的靶基因gyrA与parC位于染色体上。GyrA在耐药决定区第87位氨基酸突变(N78D),导致了喹诺酮类药物的耐药性逆转。敏感菌中扩增不到质粒毒力基因spv与rck。耐药性消除后的菌株17S1对小鼠的毒力降低(LD50增加10倍),在小鼠体内的增长与散速度也显著降低(P<0.05)。以上证据表明,鼠伤寒沙门氏菌的多重耐药性主要由质粒决定,研究开发新型质粒消除剂将对克服鼠伤寒沙门氏菌多重耐药性具有重要意义。     

Proton Motive Force Disruptors Block Bacterial Competence and Horizontal Gene Transfer

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Horizontal Gene Transfer and the History of Life

Microbes acquire DNA from a variety of sources. The last decades, which have seen the development of genome sequencing, have revealed that horizontal gene transfer has been a major evolutionary force that has constantly reshaped genomes throughout evolution. However, because the history of life must ultimately be deduced from gene phylogenies, the lack of methods to account for horizontal gene transfer has thrown into confusion the very concept of the tree of life. As a result, many questions remain open, but emerging methodological developments promise to use information conveyed by horizontal gene transfer that remains unexploited today.The discovery of the existence of prokaryotic microbes dates back more than 300 years. Since then, our picture of our distant microscopic relatives has undergone several revolutions: from being the living “proofs” of the existence of spontaneous generation, they became later the “archaic” representatives of our distant ancestors, to finally be legitimately recognized as exceptionally diverse organisms, keystone to any ecosystem, including the most familiar and the most hostile environments on Earth. Similarly, although they were first seen as elementary and unbreakable bricks of life, they are now seen as genetically composite bodies, heavyweight champions of “gene robbery.” The most recent of these revolutions has indeed been the realization of their unparalleled ability to integrate genetic material coming from more or less evolutionarily distant organisms. This mechanism is called “horizontal gene transfer” as opposed to vertical transmission from mother to daughter cell.     

Identification of a truncated, but functionally active tet(H) tetracycline resistance gene in Pasteurella aerogenes and Pasteurella multocida

Molecular analysis of Pasteurella isolates of animal origin for plasmid-encoded tetracycline resistance genes identified a common tet(H)-carrying plasmid of 5.5 kbp in a single isolate of Pasteurella aerogenes and six isolates of Pasteurella multocida. This plasmid carried a truncated Tn5706 element in which one of the IS elements, IS1596, was lost completely and of the other, IS1597, only a relic of 84 bp was left. Sequencing of the resistance gene region and the flanking areas revealed the presence of a deletion in the 3' end of the tet(H) gene which shortened the tet(H) reading frame by 24 bp. The amino acid sequence of the respective TetH protein comprised only 392 amino acids. Despite this deletion, the tet(H) gene conferred high level tetracycline resistance not only to the original Pasteurella isolates but also to the respective Escherichia coli JM107 and C600 transformants as confirmed by MIC determination. The deletion was probably the result from recombinational events. Two possible recombination sites involved in the deletion of tet(H) and that of IS1597 were identified. Macrorestriction analysis of the Pasteurella isolates carrying plasmid pPAT1 confirmed horizontal and vertical transfer of this plasmid.     

Horizontal Gene Transfer,Fitness Costs and Mobility Shape the Spread of Antibiotic Resistance Genes into Experimental Populations of Acinetobacter Baylyi

Horizontal gene transfer (HGT) is important for microbial evolution, but how evolutionary forces shape the frequencies of horizontally transferred genetic variants in the absence of strong selection remains an open question. In this study, we evolve laboratory populations of Acinetobacter baylyi (ADP1) with HGT from two clinically relevant strains of multidrug-resistant Acinetobacter baumannii (AB5075 and A9844). We find that DNA can cross the species barrier, even without strong selection, and despite substantial DNA sequence divergence between the two species. Our results confirm previous findings that HGT can drive the spread of antibiotic resistance genes (ARGs) without selection for that antibiotic, but not for all of the resistance genes present in the donor genome. We quantify the costs and benefits of horizontally transferred variants and use whole population sequencing to track the spread of ARGs from HGT donors into antibiotic-sensitive recipients. We find that even though most ARGs are taken up by populations of A. baylyi, the long-term fate of an individual gene depends both on its fitness cost and on the type of genetic element that carries the gene. Interestingly, we also found that an integron, but not its host plasmid, is able to spread in A. baylyi populations despite its strong deleterious effect. Altogether, our results show how HGT provides an evolutionary advantage to evolving populations by facilitating the spread of non-selected genetic variation including costly ARGs.     

Cloning and nucleotide sequence of a gene upstream of the eaeA gene of enterohemorrhagic Escherichia coli O157:H7

Abstract Conjugative, thermosensitive shuttle plasmids capable of transfer from Escherichia coli to Mycobacterium smegmatis were constructed. They contain both an E. coli replicon and a thermosensitive derivative of the pALS000 mycobacterial replicon. Using a temperature shift protocol, the conjugative plasmid, pJAZll was used to deliver the transposon Tn 611 from E. coli into the chromosome of M. smegmatis . Analysis of transconjugants revealed the random insertion of the transposon.     

Family 6 Glycosyltransferases in Vertebrates and Bacteria: Inactivation and Horizontal Gene Transfer May Enhance Mutualism between Vertebrates and Bacteria

Glycosyltransferases (GTs) control the synthesis and structures of glycans. Inactivation and intense allelic variation in members of the GT6 family generate species-specific and individual variations in carbohydrate structures, including histo-blood group oligosaccharides, resulting in anti-glycan antibodies that target glycan-decorated pathogens. GT6 genes are ubiquitous in vertebrates but are otherwise rare, existing in a few bacteria, one protozoan, and cyanophages, suggesting lateral gene transfer. Prokaryotic GT6 genes correspond to one exon of vertebrate genes, yet their translated protein sequences are strikingly similar. Bacterial and phage GT6 genes influence the surface chemistry of bacteria, affecting their interactions, including those with vertebrate hosts.     

Gene Descent, Duplication, and Horizontal Transfer in the Evolution of Glutamyl- and Glutaminyl-tRNA Synthetases

In translation, separate aminoacyl-tRNA synthetases attach the 20 different amino acids to their cognate tRNAs, with the exception of glutamine. Eukaryotes and some bacteria employ a specific glutaminyl-tRNA synthetase (GlnRS) which other Bacteria, the Archaea (archaebacteria), and organelles apparently lack. Instead, tRNA^Gln is initially acylated with glutamate by glutamyl-tRNA synthetase (GluRS), then the glutamate moiety is transamidated to glutamine. Lamour et al. [(1994) Proc Natl Acad Sci USA 91:8670–8674] suggested that an early duplication of the GluRS gene in eukaryotes gave rise to the gene for GlnRS—a copy of which was subsequently transferred to proteobacteria. However, questions remain about the occurrence of GlnRS genes among the Eucarya (eukaryotes) outside of the ``crown' taxa (animals, fungi, and plants), the distribution of GlnRS genes in the Bacteria, and their evolutionary relationships to genes from the Archaea. Here, we show that GlnRS occurs in the most deeply branching eukaryotes and that putative GluRS genes from the Archaea are more closely related to GlnRS and GluRS genes of the Eucarya than to those of Bacteria. There is still no evidence for the existence of GlnRS in the Archaea. We propose that the last common ancestor to contemporary cells, or cenancestor, used transamidation to synthesize Gln-tRNA^Gln and that both the Bacteria and the Archaea retained this pathway, while eukaryotes developed a specific GlnRS gene through the duplication of an existing GluRS gene. In the Bacteria, GlnRS genes have been identified in a total of 10 species from three highly diverse taxonomic groups: Thermus/Deinococcus, Proteobacteria γ/β subdivision, and Bacteroides/Cytophaga/Flexibacter. Although all bacterial GlnRS form a monophyletic group, the broad phyletic distribution of this tRNA synthetase suggests that multiple gene transfers from eukaryotes to bacteria occurred shortly after the Archaea–eukaryote divergence.     

Helicobacter pylori and Antibiotic Resistance,A Continuing and Intractable Problem

Helicobacter pylori, a human pathogen with a high global prevalence, is the causative pathogen for multiple gastrointestinal diseases, especially chronic gastritis, peptic ulcers, gastric mucosa‐associated lymphoid tissue lymphoma, and gastric malignancies. Antibiotic therapies remain the mainstay for H. pylori eradication; however, this strategy is hampered by the emergence and spread of H. pylori antibiotic resistance. Exploring the mechanistic basis of this resistance is becoming one of the major research questions in contemporary biomedical research, as such knowledge could be exploited to devise novel rational avenues for counteracting the existing resistance and devising strategies to avoid the development of a novel anti‐H. pylori medication. Encouragingly, important progress in this field has been made recently. Here, we attempt to review the current state and progress with respect to the molecular mechanism of antibiotic resistance for H. pylori. A picture is emerging in which mutations of various genes in H. pylori, resulting in decreased membrane permeability, altered oxidation–reduction potential, and a more efficient efflux pump system. The increased knowledge on these mechanisms produces hope that antibiotic resistance in H. pylori can ultimately be countered.     

环境中污染物降解基因的水平转移(HGT)及其在生物修复中的作用

水平基因转移是不同于垂直基因转移的遗传物质的交流方式.在污染环境这一特异生态环境中,降解基因的水平转移有着独特的功能与作用.研究环境中污染物降解基因在微生物间的水平转移,更深入地了解微生物种群适应污染环境的机理,对于评价污染物的环境毒理、生物可降解性以及污染环境的可修复潜力具有重要参考价值.在污染物生物修复实践中,可以通过调控降解基因的水平转移,增强污染环境中微生物的降解能力,更有效地发挥生物修复作用.文章将对环境中细菌间基因交流的机制,污染物降解基因的水平转移对微生物适应污染环境的机理、水平基因转移对代谢途径的进化及其对污染物生物修复作用的影响等方面的研究进展做一综述.     

Cloning of the Chlorothalonil-Degrading Gene Cluster and Evidence of Its Horizontal Transfer

Strain Ochrobactrum lupine TP-D1 was found to degrade chlorothalonil (TPN) to 4-hydroxy-chlorothalonil (TPN-OH). To clone the related degrading gene, genomic library of TP-D1 was constructed using Escherichia coli DH10B and two positive clones 889 and 838 were gained. However, no plasmid was detected in clone 889. And in clone 838, a 3494 bp fragment was cloned which contains a 984 bp hydrolytic dehalogenase (chd) gene and a 1926 bp insertion element IS-Olup. The insertion element contains a transposase coding region (1026 bp), an ATP-binding protein coding region (657 bp) and flanked by 20 bp inverted repeat sequences. Further isolation provided another seven TPN-degrading strains, they belonged to the genera of Pseudomonas sp., Achromobacter sp., Ochrobactrum sp., Ralstonia sp., and Lysobacter sp. PCR strategy showed that they all contain the same structure of chd gene and the upstream IS-Olup. Our evidences collectively suggest that chd gene may be disseminated through horizontal gene transfer based on phylogenetic analysis of the cluster and their host bacterial strains. At the same time, the chd gene was amplified from genome of the positive clone 889, which also provides some potential evidence to the gene horizontal transfer.     

Distribution of Pathogenic Genes aatA, aap, aggR, among Uropathogenic Escherichia coli (UPEC) and Their Linkage with StbA Gene

Urinary tract infection (UTI) with E. coli (UPEC) is one of the most common bacterial infections among human beings. In addition to the host predisposing factors, genes are also proposed to have an important role in the occurrence of UTIs. This study investigated the distribution of three pathogenic genes including aggR, aap and aatA among UPEC infected samples and their linkage with stbA, the essential gene for maintaining of pAA plasmid. A total of 244 samples were collected from patients with UTIs through clinical laboratories located in western side of Tehran (Iran) during years 2008–2009. E. coli isolation was performed according to standard laboratory methods. DNAs were extracted from samples using Boiling method, and the presence of aap, aggR, aatA and stbA genes were investigated by PCR. No pathogenic genes (aap, aggR, aatA) were found in 104 out of 244 UPEC samples, while 14 of them were carrying stbA gene. Out of 140 UPEC samples with pathogenic genes, 94 (46.6%) were carrying aap gene, 52 (23%) aggR gene, and 80 (35.4%) aatA gene. A total of 18 samples were also carrying all pathogenic genes together. Moreover, 44 out of 144 samples were carrying stbA gene. The results obtained by this study showed that the aggR, aap and aatA pathogenic genes have different existence patterns in different E. coli strains that infect different organs. Our study also showed that these three plasmid genes in EAEC strains are able to transpose in the genome and change their level of linkage with pAA plasmid essential gene stbA. Meanwhile, this study confirmed that aggR, aap and aatA genes are not specific to only EAEC strains.     

利用发光酶基因监测根瘤菌重组质粒的转移性

经三亲本杂交,比较测定了重组大豆根瘤菌HN01DNL和TA11DNL中所含重组质粒pHN307在人工滤膜和灭菌土壤杂交条件下、向华癸中生根瘤菌7653R和荧光假单胞菌Pf.X1-5的转移频率;并初步跟踪了pHN307在根盒-土壤缩影、小区试验和环境释放中向土著细菌的转移性,为考察所构建重组根瘤菌在田间应用时的安全性提供了一定的实验依据。     

高等植物线粒体与细胞核和叶绿体之间遗传物质的水平转移

在线粒体基因组中存在着来自细胞核和叶绿体的DNA,这些外源DNA的存在增加了线粒体基因组的复杂性.概述了近年来关于线粒体与细胞核和叶绿体之间遗传物质水平转移方面的研究现状.