Analysis of the genetic differences between Neisseria meningitidis and Neisseria gonorrhoeae: two closely related bacteria expressing two different pathogenicities

PCR-based subtractive hybridization and differences in gene content among strains of Helicobacter pylori

Genes that are characteristic of only certain strains of a bacterial species can be of great biologic interest. Here we describe a PCR-based subtractive hybridization method for efficiently detecting such DNAs and apply it to the gastric pathogen Helicobacter pylori. Eighteen DNAs specific to a monkey-colonizing strain (J166) were obtained by subtractive hybridization against an unrelated strain whose genome has been fully sequenced (26695). Seven J166-specific clones had no DNA sequence match to the 26695 genome, and 11 other clones were mixed, with adjacent patches that did and did not match any sequences in 26695. At the protein level, seven clones had homology to putative DNA restriction-modification enzymes, and two had homology to putative metabolic enzymes. Nine others had no database match with proteins of assigned function. PCR tests of 13 unrelated H. pylori strains by using primers specific for 12 subtracted clones and complementary Southern blot hybridizations indicated that these DNAs are highly polymorphic in the H. pylori population, with each strain yielding a different pattern of gene-specific PCR amplification. The search for polymorphic DNAs, as described here, should help identify previously unknown virulence genes in pathogens and provide new insights into microbial genetic diversity and evolution.

Structure and function of repetitive sequence elements associated with a highly polymorphic domain of the Neisseria meningitidis PilQ protein

Secretins are a large family of proteins associated with membrane translocation of macromolecular complexes, and a subset of this family, termed PilQ proteins, is required for type IV pilus biogenesis. We analysed the status of PlIQ expression in Neisseria meningitidis (Mc) and found that PlIQ mutants were non-piliated and deficient in the expression of pilus-associated phenotypes. Sequence analysis of the 5' portion of the pilQ ORF of the serogroup B Mc strain 44/76 showed the presence of seven copies of a repetitive sequence element, in contrast to the situation in N. gonorrhoeae (Gc) strains, which carry either two or three copies of the repeat. The derived amino acid sequence of the consensus nucleotide repeat was an octapeptide PAKQQAAA, designated as the small basic repeat (SBR). This gene segment was studied in more detail in a collection of 52 Mc strains of diverse origin by screening for variability in the size of the PCR-generated DNA fragments spanning the SBRs. These strains were found to harbour from four to seven copies of the repetitive element. No association between the number of copies and the serogroup, geographic origin or multilocus genotype of the strains was evident. The presence of polymorphic repeat elements in Mc PilQ is unprecedented within the secretin family. To address the potential function of the repeat containing domain, Mc strains were constructed so as to express chimeric PilQ molecules in which the number of SBR repeats was increased or in which the repeat containing domain was replaced in toto by the corresponding region of the Pseudomonas aeruginosa (Pa) PilQ protein. Although the strain expressing PilQ with an increased number of SBRs was identical to the parent strain in pilus phenotypes, a strain expressing PilQ with the equivalent Pa domain had an eightfold reduction in pilus expression level. The findings suggest that the repeat containing domain of PilQ influences Mc pilus expression quantitatively but not qualitatively.

Short-sequence DNA repeats in prokaryotic genomes

Short-sequence DNA repeat (SSR) loci can be identified in all eukaryotic and many prokaryotic genomes. These loci harbor short or long stretches of repeated nucleotide sequence motifs. DNA sequence motifs in a single locus can be identical and/or heterogeneous. SSRs are encountered in many different branches of the prokaryote kingdom. They are found in genes encoding products as diverse as microbial surface components recognizing adhesive matrix molecules and specific bacterial virulence factors such as lipopolysaccharide-modifying enzymes or adhesins. SSRs enable genetic and consequently phenotypic flexibility. SSRs function at various levels of gene expression regulation. Variations in the number of repeat units per locus or changes in the nature of the individual repeat sequences may result from recombination processes or polymerase inadequacy such as slipped-strand mispairing (SSM), either alone or in combination with DNA repair deficiencies. These rather complex phenomena can occur with relative ease, with SSM approaching a frequency of 10(-4) per bacterial cell division and allowing high-frequency genetic switching. Bacteria use this random strategy to adapt their genetic repertoire in response to selective environmental pressure. SSR-mediated variation has important implications for bacterial pathogenesis and evolutionary fitness. Molecular analysis of changes in SSRs allows epidemiological studies on the spread of pathogenic bacteria. The occurrence, evolution and function of SSRs, and the molecular methods used to analyze them are discussed in the context of responsiveness to environmental factors, bacterial pathogenicity, epidemiology, and the availability of full-genome sequences for increasing numbers of microorganisms, especially those that are medically relevant.

Genetic advances for studying Mycobacterium tuberculosis pathogenicity

Tuberculosis remains the greatest cause of death worldwide because of a single pathogen. Despite its importance, the genetic basis of the pathogenicity of Mycobacterium tuberculosis remains poorly understood, mainly because the most productive investigative approach, molecular genetic analysis, has been severely hampered by a lack of efficient tools. However, significant advances, including the development of methods for inactivating genes and studying their expression with reporter genes, have been recently made. This progress may lead to opportunities for developing new vaccines and antituberculous drugs. The aim of this review is to examine the present state of the art in mycobacterial molecular genetics and pinpoint some expected or promising areas for future research.

Comparison of the genome organization of pathogenic neisseriae

Current efforts to completely sequence the meningococcal and gonocococcal genomes raise the question whether the lessons learned from the sequenced strains may be safely extrapolated to other members of these species, or whether, in view of the fact that Neisseriae are highly recombinogenic and exhibit a high degree of horizontal intra- and interspecies genetic transfer, only clone-specific conclusions are valid. From the known physical and genetic maps of each of two gonococcal and meningococcal strains, it would appear that both species exhibit a species-specific conservation in their genetic organization while the interspecies comparison revealed several rearrangements, although still with a high overall similarity. However, these data contrast with other evidence suggesting intra-species rearrangements, such as the nonconserved I-CeuI macrorestriction patterns of different meningococcal and other neisserial strains. Since I-CeuI cuts within the 23S-rRNA sequence, the restriction pattern should give reliable information on the distribution of rrn loci in the neisserial genomes. Further studies are warranted to answer these questions.

Differential display approach to quantitation of environmental stimuli on bacterial gene expression

The differential display of the mRNA technique for eukaryotes is fruitful in identifying genes with altered transcription rates caused by exogenous or endogenous stimuli. Prokaryotic analogues of the method using arbitrary oligonucleotides may reach a complete statistical genome coverage. Thus a genome-wide mass screening for transcriptionally regulated sequences will be possible. However, the primer sets have to be optimized for a given species to result in maximum band yields. Hence the construction of primers requires the calculation of oligonucleotide frequency distributions from known coding regions to choose sequences with frequent occurrence in the bacterial genome. After completion of many whole genome sequencing projects, differentially regulated cDNA sequences are readily identified by sequence comparisons.

Differential genome analysis of bacteria by genomic subtractive hybridization and pulsed field gel electrophoresis

A comprehensive analysis of the differences between the genomes of two closely related bacterial strains should give insight into the molecular basis of their individual phenotypic and genotypic characteristics. Here we present an integrative approach including two different strategies for the thorough investigation of genomic divergence. We have combined two techniques including genomic subtractive hybridization and comparative genome mapping by pulsed field gel electrophoresis (PFGE) techniques. The subtractive method for which a protocol is given herein results in the production of a library of specific DNA sequence tags present only in one strain, while the construction of macrorestriction maps of the bacterial chromosomes yields data about the overall genome organization and the arrangement and distance of gene loci. Comparison of the physical and genetic maps and determination of the map positions of the strain-specific DNA sequences reveals gross chromosomal modifications, insertions or deletions of additional genetic material, and transpositional events. The further investigation of the strain-specific regions yields information about the nature and origin of the acquired DNA and their influence on the evolution of the individual bacterial genome. The two methods were applied to differential genome analysis of clonal divergence in Pseudomonas aeruginosa choosing two clone C isolates from diverse habitats.

Microbial genome sequencing and pathogenesis

The year 1997 saw the publication of the complete nucleotide sequence of Helicobacter pylori and Escherichia coli. It is conceivable that the complete nucleotide sequence for all the major human bacterial pathogens will be available by the end of the century. Database alignments have been used to ascribe the putative functions of open reading frames in the sequenced isolates and to define the differences between bacterial species at the nucleotide level. The most striking finding from all genome projects has been the high proportion of open reading frames that have no known function. Experimental data demonstrating the utility of the genome sequencing projects are only just beginning to emerge.

Use of representational difference analysis to identify genomic differences between pathogenic strains of Vibrio cholerae

Representational difference analysis (RDA) is a recently developed technique used for amplifying genetic differences between two closely related genomes. We compared RDA and a modified version of RDA to examine genomic differences between the two Vibrio cholerae serogroups that cause epidemic cholera, O1 and O139, and between the two biotypes of the O1 serogroup. With both techniques, we recovered several sequences known to be found only in V. cholerae O139 but absent in its presumed progenitor, V. cholerae O1 El Tor. A greater number of unique fragments were generated in comparing the two V. cholerae O1 biotypes, consistent with the probable greater genetic differences between the two biotypes.

Isolation and biochemical characterization of the PilA protein of Neisseria meningitidis

PilA is the response regulator of a two-component regulatory system that controls a number of genes in the pathogenic Neisseria. Previous work has shown that Neisseria gonorrhoeae (GC) PilA binds DNA and also hydrolyzes GTP. Here, we report the cloning, sequencing, purification, and biochemical characterization of PilA from N. meningitidis (MC) strain 8013. MC pilA is 94% identical to GC pilA at the nucleotide level. Of the 78 nucleotide changes, 52 are silent, while 26 result in a total of 20 amino acid changes. Additionally, the MC homolog has a 4-amino acid insertion between the putative DNA-binding and GTP-binding domains. Purified MC PilA binds to the same DNA fragment we have previously shown to be bound by GC PilA specifically and also hydrolyzes GTP. The K(m) of MC PilA for GTP is 8.6 microM, similar to that determined for the GC protein. However, the maximum velocity (Vmax) is approximately 35-fold greater than the GC PilA activity. Additionally, the nucleotide specificity of MC PilA differs from that of GC PilA. While GC PilA hydrolyzes only GTP, MC PilA hydrolyzes GTP and ATP equally well, and CTP and UTP also compete for this activity.

Large genome rearrangements discovered by the detailed analysis of 21 Pseudomonas aeruginosa clone C isolates found in environment and disease habitats

In order to determine primary genetic events which occur during the diversification of a Pseudomonas aeruginosa clone in natural habitats, comparative genome analysis of 21 isolates of a predominant clone, called clone C, derived mainly from patients with cystic fibrosis (CF) and the aquatic environment, was carried out. Physical chromosome maps were constructed for the restriction enzymes SpeI, PacI, SwaI and I-CeuI by one and two-dimensional pulsed-field gel electrophoresis and by comparison with the existing strain C map. The positioning of 26 genes generated the genetic maps. Chromosome size varied between 6345 and 6606 kilobase-pairs (kb). A plasmid of 95 kb was detected in the strains of non-CF origin and, in addition, was found to be integrated into the chromosome of all strains but one CF isolate. Four subgroups of clone C strains were discriminated by the acquisition and loss of large blocks of DNA that could cover more than 10% of the chromosome size. The exchange of DNA blocks which ranged in size from 1 kb to 214 kb occurred preferentially around the terminus of replication region which is poor in biosynthetic genes. Genetic material which was additionally introduced into strain C in comparison with strain PAO seems to be a target of mutational processes in clone C strains. Within and among subgroups CF isolates frequently exhibited large inversions affecting the whole chromosomal structure. We concluded that the exchange of DNA blocks by mechanisms of horizontal transfer and large chromosomal inversions are major factors leading to the divergence of a clone in the species P. aeruginosa.