The genome of the bacterium Borrelia burgdorferi B31, the aetiologic agent of Lyme disease, contains a linear chromosome of 910,725 base pairs and at least 17 linear and circular plasmids with a combined size of more than 533,000 base pairs. The chromosome contains 853 genes encoding a basic set of proteins for DNA replication, transcription, translation, solute transport and energy metabolism, but, like Mycoplasma genitalium, it contains no genes for cellular biosynthetic reactions. Because B. burgdorferi and M. genitalium are distantly related eubacteria, we suggest that their limited metabolic capacities reflect convergent evolution by gene loss from more metabolically competent progenitors. Of 430 genes on 11 plasmids, most have no known biological function; 39% of plasmid genes are paralogues that form 47 gene families. The biological significance of the multiple plasmid-encoded genes is not clear, although they may be involved in antigenic variation or immune evasion.
We have determined that Borrelia burgdorferi strain B31 MI carries 21 extrachromosomal DNA elements, the largest number known for any bacterium. Among these are 12 linear and nine circular plasmids, whose sequences total 610 694 bp. We report here the nucleotide sequence of three linear and seven circular plasmids (comprising 290 546 bp) in this infectious isolate. This completes the genome sequencing project for this organism; its genome size is 1 521 419 bp (plus about 2000 bp of undetermined telomeric sequences). Analysis of the sequence implies that there has been extensive and sometimes rather recent DNA rearrangement among a number of the linear plasmids. Many of these events appear to have been mediated by recombinational processes that formed duplications. These many regions of similarity are reflected in the fact that most plasmid genes are members of one of the genome's 161 paralogous gene families; 107 of these gene families, which vary in size from two to 41 members, contain at least one plasmid gene. These rearrangements appear to have contributed to a surprisingly large number of apparently non‐functional pseudogenes, a very unusual feature for a prokaryotic genome. The presence of these damaged genes suggests that some of the plasmids may be in a period of rapid evolution. The sequence predicts 535 plasmid genes ≥300 bp in length that may be intact and 167 apparently mutationally damaged and/or unexpressed genes (pseudogenes). The large majority, over 90%, of genes on these plasmids have no convincing similarity to genes outside Borrelia, suggesting that they perform specialized functions.
The emergence of multidrug-resistant strains ofMycobacterium tuberculosis has resulted in increased interest in the fluoroquinolones (FQs) as antituberculosis agents. To investigate the frequency and mechanisms of FQ resistance in M. tuberculosis, we cloned and sequenced the wild-type gyrA and gyrB genes, which encode the A and B subunits of the DNA gyrase, respectively; DNA gyrase is the main target of the FQs. On the basis of the sequence information, we performed DNA amplification for sequencing and single-strand conformation polymorphism analysis to examine the presumed quinolone resistance regions ofgyrA and gyrB from reference strains (n = 4) and clinical isolates (n = 55). Mutations in codons ofgyrA analogous to those described in other FQ-resistant bacteria were identified in all isolates (n = 14) for which the ciprofloxacin MIC was >2 ,ug/ml. In addition, we selected ciprofloxacin-resistant mutants of Mycobacterium bovis BCG and M. tuberculosis Erdman and H37ra. Spontaneously resistant mutants developed at a frequency of 1 in 107 to 108 at ciprofloxacin concentrations of 2 ,ug/ml, but no primary resistant colonies were selected at higher ciprofloxacin concentrations. Replating of those first-step mutants selected for mutants with high levels of resistance which harbored gyrA mutations similar to those found among clinical FQ-resistant isolates. The gyrA and gyrB sequence information will facilitate analysis of the mechanisms of resistance to drugs which target the gyrase and the implementation of rapid strategies for the estimation of FQ susceptibility in clinical M. tuberculosis isolates.The resurgence of tuberculosis and its incidence in human immunodeficiency virus-positive populations in both developing countries and the industrialized world have been accompanied by the alarming emergence of virulent multidrugresistant tuberculosis (MDR-TB) strains in North American cities (7). Many of these strains have acquired resistance to almost all first-and second-line antituberculosis agents. For this reason, there is an increasing interest in the antimycobacterial actions of the fluoroquinolones (FQs). Against Mycobacterium tuberculosis, the FQs show moderate in vitro activity (4), with sparfloxacin (MIC, 0.25 to 0.5 ,ug/ml) perhaps being the most effective compound (17). The principal target of the quinolones is the DNA gyrase, a type II DNA topoisomerase that is composed of two A and two B subunits (30) encoded by gyrA and gyrB, respectively. Mutations in the putative FQbinding region of the A subunit have been found to confer high-level FQ resistance in several bacterial species (8,19,22,31,33). Other mutations that confer resistance to quinolones have been found in gyrB, in genes that lower the intracellular concentration of the drug (although these tend to confer lower-level resistance than do the gyrA mutations [32,34]), or
The gyrA gene of Campylobacterjejuni UA580, which encodes the A subunit of DNA gyrase, was cloned and its nucleotide sequence was determined. An open reading frame of 2,589 nucleotides was identified, which could code for a polypeptide of 863 amino acids with a Mr of 97 kDa. Both the nucleotide sequence and the putative amino acid sequence show ca. 50% identity with those of other gyrA genes from gram-positive and gram-negative bacteria. Similar mutations were also identified in ciprofloxacin-resistant isolates of S. aureus (10,27).Gootz and Martin (9) demonstrated that the DNA gyrases from Nalr mutants of C. jejuni UA535 were 100-fold less susceptible than the wild-type enzyme to inhibition by quinolones in the DNA supercoiling reaction. Subunit switching experiments with purified A and B subunits from the wild type and one of the quinolone-resistant mutants indicated that an alteration in the A subunit was responsible for resistance. Here, we report the cloning and nucleotide sequence of the C. jejuni gyrA gene and the location of the gene on both C. jejuni and C. coli chromosomes. Several mutations responsible for quinolone resistance were detected in the gyrA sequence. MATERUILS AND METHODSStrains and culture conditions. The Campylobacter spp. employed in this study were C. jejuni UA67 (Nalr mutant [35]); UA536, UA543, and UA549 (Nalr clinical isolates from H. Lior); UA580 (35); UA58OR1 and UA580R3 (Nalr mutant from UA580 [this study]); and C. coli UA417 (Nalr clinical isolates [35]). E. coli DH5at (23) was also used. The plasmids and phages employed were pUC19, M13mpl8, M13mpl9 (38), pBluescript II SK (Stratagene), pK194 (16), and pT7-5 (30).Campylobacters were grown at 37°C on Mueller-Hinton agar medium containing 7% CO2. E. coli was grown in 2x YT medium or on Luria-Bertani agar (23) at 37°C. When necessary, the medium was supplemented with ampicillin (100 ,ug/ml), kanamycin (15 jig/ml), or nalidixic acid (24 ig/ml).DNA isolation, transformation, and nucleotide sequence analysis. Plasmid DNA was isolated by a modification of the alkaline lysis method of Birnboim and Doly (2) and purified by the "magic miniprep" (Promega) when used for restriction analysis and sequencing. M13 phage DNA was prepared by the method described by Sambrook et al. (23).
Lyme disease is the most common tick-borne human illness in North America. In order to understand the molecular pathogenesis, natural diversity, population structure and epizootic spread of the North American Lyme agent, Borrelia burgdorferi sensu stricto, a much better understanding of the natural diversity of its genome will be required. Towards this end we present a comparative analysis of the nucleotide sequences of the numerous plasmids of B. burgdorferi isolates B31, N40, JD1 and 297. These strains were chosen because they include the three most commonly studied laboratory strains, and because they represent different major genetic lineages and so are informative regarding the genetic diversity and evolution of this organism. A unique feature of Borrelia genomes is that they carry a large number of linear and circular plasmids, and this work shows that strains N40, JD1, 297 and B31 carry related but non-identical sets of 16, 20, 19 and 21 plasmids, respectively, that comprise 33–40% of their genomes. We deduce that there are at least 28 plasmid compatibility types among the four strains. The B. burgdorferi ∼900 Kbp linear chromosomes are evolutionarily exceptionally stable, except for a short ≤20 Kbp plasmid-like section at the right end. A few of the plasmids, including the linear lp54 and circular cp26, are also very stable. We show here that the other plasmids, especially the linear ones, are considerably more variable. Nearly all of the linear plasmids have undergone one or more substantial inter-plasmid rearrangements since their last common ancestor. In spite of these rearrangements and differences in plasmid contents, the overall gene complement of the different isolates has remained relatively constant.
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