Conjugal transfer of the 5-nitroimidazole resistance plasmid pIP417 from Bacteroides vulgatus BV-17: characterization and nucleotide sequence analysis of the mobilization region.

Three small 5-nitroimidazole (5-Ni) resistance plasmids (pIP417, pIP419, and pIP421) from Bacteroides clinical isolates are transferable by a conjugative process during homologous or heterologous matings. The mobilization properties of pIP417 originated from strain BV-17 of Bacteroides vulgatus were studied. The plasmid was successfully introduced by in vitro conjugation into different strains of Bacteroides and Prevotella species and could be transferred back from these various strains to a plasmid-free 5-Ni-sensitive Bacteroides fragilis strain, indicating that in vivo spread of the resistance gene may occur. The transfer of plasmid pIP417 harbored by the Tc(r) strain BF-2 of B. fragilis was stimulated by low concentrations of tetracycline or chlorotetracycline. This suggests a possible role for coresident conjugative transposons in the dissemination of 5-Ni resistance among gram-negative anaerobes. The nucleotide sequence of the 2.1-kb DNA mobilization region was determined. It contains a putative origin of transfer (oriT) in an A+T-rich-region, including three inverted repeats, and two integration host factor binding sites. The two identified mobilization genes (mobA and mobB) are organized in one operon and were both required for efficient transfer. Southern blotting indicated that the mobilization region of plasmid pIP417 is closely related to that of both the erythromycin resistance plasmid pBFTM1O and the 5-Ni resistance plasmid pIP419 but not to that of the 5-Ni resistance plasmid pIP421.     

Identification and DNA sequence of the mobilization region of the 5-nitroimidazole resistance plasmid pIP421 from Bacteroides fragilis.

The nucleotide sequence of the DNA mobilization region of the 5-nitroimidazole resistance plasmid pIP421, from strain BF-F239 of Bacteroides fragilis, was determined. It contains a putative origin of transfer (oriT) including three sets of inverted repeats and two sequences reminiscent of specific integration host factor binding sites. The product of the mobilization gene mob421 (42.2 kDa) is a member of the Bacteroides mobilization protein family, which includes the MobA of pBI143, NBUs, and Tn4555. Sequence similarity suggests that it has both oriT binding and nicking activities. The transfer frequency of pIP421 in a B. fragilis donor strain possessing a Tc(r) or Tc(r) Em(r)-like conjugative transposon was significantly enhanced by tetracycline. Moreover, the mobilization region of pIP421 confers the ability to be mobilized from Escherichia coli by an IncP plasmid.     

Transferable 5-nitroimidazole resistance in the Bacteroides fragilis group

We report the characterization of a strain of Bacteroides vulgatus, BV17, that exhibits a moderate resistance to 5-nitroimidazoles and carries plasmids of 4.5, 5, 7.7, and 56 kb. A genetic determinant involved in this resistance is carried by the 7.7 +/- 0.2-kb plasmid (pIP417). This plasmid can be introduced and replicated in a sensitive strain of B. fragilis 638R by transformation or by conjugation. In the latter case, the transfer may involve mobilization by the 56-kb conjugative plasmid (pIP418) regularly found in transconjugants but not in transformants.     

类杆菌5-硝基咪唑抗性质粒pIP419的研究

5-硝基咪唑类药物广泛应用于厌氧菌感染症的临床治疗,近几年厌氧菌5-硝基咪唑抗性菌株的报道有所增加。本文介绍分离自类杆菌的编码抗5-硝基咪唑抗性质粒pIP419的研究结果。pIP419分子量为10kb,已建立了限制性内切酶物理图谱。该质粒可通过接合和转化在不同的菌种或菌株间转移。质粒上负责质粒复制和转移的基因片段已被定位和克隆。     

Antibiotic resistance patterns and plasmids of ruminal strains of Bacteroides ruminicola and Bacteroides multiacidus

Summary Plasmids were recovered and are described from three ruminal Bacteroides strains — 23, 223/M2/7 and 46/5(2). Although all three were originally isolated as Bacteroides ruminicola, 46/5(2) is shown here to be a strain of Bacteroides multiacidus, a species not previously described from the rumen. An 11.7 kbp plasmid present in strain 46/5(2) gave the same digestion pattern with Sal I and Sma I as a plasmid in B. multiacidus subgroup b type strain P208-58. Strains 46/5(2) and P208-58 both showed resistance to tetracycline, as did B. ruminicola strain 223/M2/7. B. multiacidus P208-58, and, to a lesser degree, B. ruminicola 23, showed resistance to ampicillin. Four other strains of B. ruminicola and one of B. multiacidus in which plasmids were not detected were sensitive to both antibiotics. It has still to be established whether these resistance traits are plasmid or chromosomally coded.     

Mobilization of Bacteroides plasmids by Bacteroides conjugal elements.

A 4.2-kilobase cryptic Bacteroides plasmid, pB8-51, is found in several colonic Bacteroides species. To determine whether pB8-51 is mobilized by any of the known Bacteroides conjugal elements, we constructed an Escherichia coli-Bacteroides shuttle vector, pVAL-1, which contains pB8-51. We constructed Bacteroides uniformis 0061 derivatives which carry pVAL-1 and various Bacteroides conjugal elements. The Bacteroides conjugal elements tested were six conjugal tetracycline resistance (Tcr) elements (which appear to be chromosomal), i.e., Tcr ERL, Tcr V479, Tcr Emr ERL, Tcr Emr 12256, Tcr Emr DOT, and Tcr Emr CEST, and the conjugal erythromycin resistance (Emr) plasmid pBF4. These Tcr conjugal elements have not been extensively characterized, except for Tcr ERL. All six Tcr elements tested mobilized pVAL-1 at high frequency (10(-3) to 10(-5)) from one Bacteroides strain to another or from a Bacteroides strain to E. coli. Pregrowth of the donors (containing one of the Tcr elements and pVAL-1) in 1 microgram of tetracycline per ml enhanced the transfer of pVAL-1 by 20- to 10,000-fold, depending on which Tcr element was present in the donor. An Ems derivative of pBF4 (pBF4 delta E2) mobilized pVAL-1 from one Bacteroides strain to another at a frequency of 10(-4) but did not mobilize pVAL-1 from a Bacteroides strain to E. coli as efficiently. Thus the Tcr conjugal elements and pBF4 recognize a mobilization region on pB8-51.     

Epidemiology,molecular characterization,and drug resistance of IncHI5 plasmids from Enterobacteriaceae

International Microbiology - The increasingly frequent occurence of IncHI5 plasmids has attracted worldwide attention. The aim of this study was to perform an in-depth bioinformatics analysis to...     

Characterization and mobilization of nonconjugative plasmids encoding resistance to streptomycin and sulfanilamide

Most of nonconjugative streptomycin (Sm)- and sulfanilamide (Su)- resistance of clinical isolates belonging to various species of Enterobacteriaceae and Pseudomonas were encoded by an Inc Q plasmid, molecular size of which was 5.5 Md. The SmSu plasmids were efficiently mobilized by Inc P plasmids between E. coli strains. Inc I group and Inc F group plasmids could mobilize the Inc Q plasmids at lower efficiencies. The Inc Q plasmid was also mobilized to various species of Enterobacteriaceae at high frequencies without accompanying the conjugative Inc P plasmid; as a result, most of the SmSu-resistant transconjugants were nontransferable. The above results may explain the wide distribution of nonconjugative SmSu strains among clinical isolates.     

Genetic and molecular analysis of tomato Cf genes for resistance to Cladosporium fulvum.

In many plant-pathogen interactions resistance to disease is controlled by the interaction of plant-encoded resistance (R) genes and pathogen-encoded avirulence (Avr) genes. The interaction between tomato and the leaf mould pathogen Cladosporium fulvum is an ideal system to study the molecular basis of pathogen perception by plants. A total of four tomato genes for resistance to C. fulvum (Cf-2, Cf-4, Cf-5 and Cf-9) have been isolated from two genetically complex chromosomal loci. Their gene products recognize specific C. fulvum-encoded avirulence gene products (Avr2, Avr4, Avr5 and Avr9) by an unknown molecular mechanism. Cf genes encode extracellular membrane-anchored glycoproteins comprised predominantly of 24 amino acid leucine-rich repeats (LRRs). Cf genes from the same locus encode proteins which are more than 90% identical. Most of the amino-acid sequence differences correspond to the solvent-exposed residues within a beta-strand/beta-turn structural motif which is highly conserved in LRR proteins. Sequence variability within this motif is predicted to affect the specificity of ligand binding. Our analysis of Cf gene loci at the molecular level has shown they comprise tandemly duplicated homologous genes, and suggests a molecular mechanism for the generation of sequence diversity at these loci. Our analysis provides further insight into the molecular basis of pathogen perception by plants and the organization and evolution of R gene loci.     

Regions in Bacteroides plasmids pBFTM10 and pB8-51 that allow Escherichia coli-Bacteroides shuttle vectors to be mobilized by IncP plasmids and by a conjugative Bacteroides tetracycline resistance element.

Bacteroides-Escherichia coli shuttle vectors containing a nonmobilizable pBR322 derivative and either pBFTM10 (pDP1, pCG30) or pB8-51 (pEG920) were mobilized by IncP plasmid R751 or pRK231 (an ampicillin-sensitive derivative of RK2) between E. coli strains and from E. coli to Bacteroides recipients. IncI alpha R64 drd-ll transferred these vectors 1,000 times less efficiently than did the IncP plasmids. pDP1, pCG30, and pEG920 could be mobilized from B. uniformis donors to both E. coli and Bacteroides recipients by a conjugative Bacteroides Tcr (Tcr ERL) element which was originally found in a clinical Bacteroides fragilis strain (B. fragilis ERL). However, the shuttle vector pE5-2, which contains pB8-51 cloned in a restriction site that prevents its mobilization by IncP or IncI alpha plasmids, also was not mobilized at detectable frequencies from Bacteroides donors by the Tcr ERL element. The mobilization frequencies of pCG30, pDP1, and pEG920 by the Tcr ERL element in B. uniformis donors to E. coli recipients was about the same as those to isogenic B. uniformis recipients. Transfer of the shuttle vectors from B. uniformis donors to E. coli occurred at the same frequencies when the matings were done aerobically or anaerobically. Growth of the B. uniformis donors in tetracycline (1 microgram/ml) prior to conjugation increased the mobilization frequencies of the vectors to both E. coli and Bacteroides recipients 50 to 100 times.     

Modular evolution of disseminated Inc 7-M plasmids encoding gentamicin resistance

We have examined the relationship between Inc 7-M plasmids conferring resistance to gentamicin by synthesis of an acetylating enzyme (AAC(3)) and other plasmids of the same incompatibility group by agarose gel electrophoresis following digestion with restriction endonucleases and by nucleic acid hybridization. Although isolated from different bacterial hosts over a 6-year period of time the three plasmids mediating acetylation of gentamicin are very similar. They are related to, but distinct from the other Inc 7-M plasmids. The in vivo evolution of these plasmids appeared modular, involving sequential deletions and stepwise acquisition of transposons (Tn6, Tn7, and a Tn9-like element). These results are in favor of a plasmid epidemic and indicate a great stability of the transfer factor part of these plasmids under natural conditions.     

Genetic and molecular analysis of aflatoxin biosynthesis.

Fungal Genetics and Biology 26,99–117.     

Genetic analysis and molecular mapping of crown rust resistance in common wheat

Key Message

This is the first report on genetic analysis and genome mapping of major dominant genes for near non-host resistance to barley crown rust ( Puccinia coronata var. hordei ) in common wheat.

Abstract

Barley crown rust, caused by Puccinia coronata var. hordei, primarily occurs on barley (Hordeum vulgare L.) in the Great Plain regions of the United States. However, a few genotypes of common wheat (Triticum aestivum L.) were susceptible to this pathogen among 750 wheat accessions evaluated. To investigate the genetics of crown rust resistance in wheat, a susceptible winter wheat accession PI 350005 was used in crosses with two resistant wheat varieties, Chinese Spring and Chris. Analysis of F₁ plants and F₂ populations from these two crosses indicated that crown rust resistance is controlled by one and two dominant genes in Chris and Chinese Spring, respectively. To determine the chromosome location of the resistance gene Cr1 in Chris, a set of 21 monosomic lines derived from Chris was used as female parents to cross with a susceptible spring type selection (SSTS35) derived from the PI 350005/Chris cross. Monosomic analysis indicated that Cr1 is located on chromosome 5D in Chris and one of the crown rust resistance genes is located on chromosome 2D in Chinese Spring. The other gene in Chinese Spring is not on 5D and thus is different from Cr1. Molecular linkage analysis and QTL mapping using a population of 136 doubled haploid lines derived from Chris/PI 350005 further positioned Cr1 between SSR markers Xwmc41-2 and Xgdm63 located on the long arm of chromosome 5D. Our study suggests that near non-host resistance to crown rust in these different common wheat genotypes is simply inherited.     

Structural basis of 5-nitroimidazole antibiotic resistance: the crystal structure of NimA from Deinococcus radiodurans

5-Nitroimidazole-based antibiotics are compounds extensively used for treating infections in humans and animals caused by several important pathogens. They are administered as prodrugs, and their activation depends upon an anaerobic 1-electron reduction of the nitro group by a reduction pathway in the cells. Bacterial resistance toward these drugs is thought to be caused by decreased drug uptake and/or an altered reduction efficiency. One class of resistant strains, identified in Bacteroides, has been shown to carry Nim genes (NimA, -B, -C, -D, and -E), which encode for reductases that convert the nitro group on the antibiotic into a non-bactericidal amine. In this paper, we have described the crystal structure of NimA from Deinococcus radiodurans (drNimA) at 1.6 A resolution. We have shown that drNimA is a homodimer in which each monomer adopts a beta-barrel fold. We have identified the catalytically important His-71 along with the cofactor pyruvate and antibiotic binding sites, all of which are found at the monomer-monomer interface. We have reported three additional crystal structures of drNimA, one in which the antibiotic metronidazole is bound to the protein, one with pyruvate covalently bound to His-71, and one with lactate covalently bound to His-71. Based on these structures, a reaction mechanism has been proposed in which the 2-electron reduction of the antibiotic prevents accumulation of the toxic nitro radical. This mechanism suggests that Nim proteins form a new class of reductases, conferring resistance against 5-nitroimidazole-based antibiotics.     

Molecular analysis of transferable tetracycline resistance plasmids from Clostridium perfringens.

Conjugative tetracycline resistance plasmids from 15 Clostridium perfringens isolates from piggeries were analyzed by restriction endonuclease digestion and agarose gel electrophoresis. Seven isolates from one farm were found to carry a 47-kilobase pair (kb) plasmid, pJIR5, which had EcoRI, XbaI, and ClaI profiles that were identical to those of a previously characterized plasmid, pCW3. An isolate from a second farm was found to carry a plasmid, pJIR6, which also was indistinguishable from pCW3. Five additional isolates from a third farm carried a 67-kb plasmid, pJIR2, which had at least 29 kb of DNA in common with pCW3. Finally, two isolates from a fourth farm were found to carry a 50-kb plasmid pJIR4, which appeared to consist of an entire pCW3 molecule with a 3-kb insertion. Comparative restriction maps of pCW3, pJIR2, and pJIR4 that identified the regions of homology among these plasmids were constructed. We suggest that many conjugative tetracycline resistance plasmids in C. perfringens may contain a pCW3-like core.