R K Selander

Parallel evolution of virulence in pathogenic Escherichia coli

The mechanisms underlying the evolution and emergence of new bacterial pathogens are not well understood. To elucidate the evolution of pathogenic Escherichia coli strains, here we sequenced seven housekeeping genes to build a phylogenetic tree and trace the history of the acquisition of virulence genes. Compatibility analysis indicates that more than 70% of the informative sites agree with a single phylogeny, suggesting that recombination has not completely obscured the remnants of ancestral chromosomes. On the basis of the rate of synonymous substitution for E. coli and Salmonella enterica (4.7 × 10-9 per site per year), the radiation of clones began about 9 million years ago and the highly virulent pathogen responsible for epidemics of food poisoning, E. coli O157:H7, separated from a common ancestor of E. coli K-12 as long as 4.5 million years ago. Phylogenetic analysis reveals that old lineages of E. coli have acquired the same virulence factors in parallel, including a pathogenicity island involved in intestinal adhesion, a plasmid-borne haemolysin, and phage-encoded Shiga toxins. Such parallel evolution indicates that natural selection has favoured an ordered acquisition of genes and the progressive build-up of molecular mechanisms that increase virulence.

STREPTOCOCCUS PYOGENES CAUSING TOXIC-SHOCK-LIKE SYNDROME AND OTHER INVASIVE DISEASES : CLONAL DIVERSITY AND PYROGENIC EXOTOXIN EXPRESSION

Genetic diversity and relationships among 108 isolates of the bacterium Streptococcus pyogenes recently recovered from patients in the United States with toxic-shock-like syndrome or other invasive diseases were estimated by multilocus enzyme electrophoresis. Thirty-three electrophoretic types (ETs), representing distinctive multilocus clonal genotypes, were identified, but nearly half the disease episodes, including more than two-thirds of the cases of toxic-shock-like syndrome, were caused by strains of two related clones (ET 1 and ET 2). These two clones were also represented by recent pathogenic European isolates. A previous report of a relatively high frequency of expression of exotoxin A among isolates recovered from toxic-shock-like syndrome patients in the United States was confirmed; and the demonstration of this association both within clones and among distantly related clones supports the hypothesis that exotoxin A is a causal factor in pathogenesis of this disease. Near identity of the nucleotide sequences of the exotoxin A structural gene of six isolates of five ETs in diverse phylogenetic lineages was interpreted as evidence that the gene has been horizontally distributed among clones, presumably by bacteriophage-mediated transfer.

Evolutionary origin and radiation of the avian-adapted non-motile salmonellae

Multilocus enzyme electrophoresis was employed to estimate chromosomal genotypic diversity and relationships among 131 isolates of the non-motile Salmonella biotypes Gallinarum and Pullorum (serotype 1, 9, 12:-:-) that cause fowl typhoid and pullorum disease, respectively. Thirteen electrophoretic types (ETs), marking clones, were distinguished, and construction of a neighbour-joining phylogenetic tree revealed three lineages: one consisted of five ETs of Gallinarum, a second included seven ETs of Pullorum, and a third was represented by a single ET (Ga/Pu 1) that is intermediate between those of the other two lineages in both multilocus enzyme genotype and biochemical properties. Enzyme genotype analysis and comparative nucleotide sequencing of the phase 1 flagellin gene (fliC), the hook-associated protein 1 gene (flgK), and the 6-phosphogluconate dehydrogenase gene (gnd) identified serotype Enteritidis (1, 9, 12:g, m:-) as a close relative of the non-motile salmonellae. In most strains of biotype Gallinarum, the fliC gene is complete, intact and identical in sequence to that of Enteritidis, but isolates of three ETs had a stop codon at position 495. The fliC sequences of the ETs of Pullorum differed from that of Enteritidis in having non-synonymous changes in either two or three codons and a synonymous change in one codon. The sharing of distinctive alleles at three metabolic enzyme loci and a stop codon in flgK indicates that the non-motile salmonellae are monophyletic and that their most recent common ancestor was non-motile. Since diverging from that ancestor, the Pullorum lineage has evolved more rapidly than the Gallinarum and Ga/Pu 1 lineages.

DNA Sequence Analysis of the Genetic Structure of Populations of Salmonella Enterica and Escherichia Coli

The goal of bacterial population genetics is to understand the factors that determine genetic structure and mediate evolutionary change in natural populations. This broad objective transcends the practical needs of microbiologists for methods of species identification and strain discrimination for epidemiological and other purposes, but the findings of population genetics research have important implications for several branches of medical microbiology (Selander and Musser, 1990), as well as for bacterial systematics.

Sequence Polymorphism of dotA and mip Alleles Mediating Invasion and Intracellular Replication of Legionella pneumophila

Legionella pneumophila inhabit a variety of natural and man-made aquatic environments, where they live primarily as intracellular parasites of protozoans. Given the proper exposure, however, they can cause opportunistic pneumonic infections in humans. The products of two L. pneumophila genes, dotA and mip, are part of the mechanism mediating the initial invasion of eukaryotic cells, and subsequent intracellular survival and multiplication. In this study, DNA polymorphism of the dotA and mip genes was assessed for 17 clinical and environmental isolates by nucleotide sequencing to determine the level of sequence variation, rates of molecular evolution, and history of gene divergence. The mip gene is highly conserved, whereas dotA is extremely variable, with an average level of nucleotide diversity four times greater than that of mip. Gene trees for each locus support a division of the L. pneumophila isolates into two clonal lineages. There are several disagreements between the gene trees suggesting that although L. pneumophila has a clonal population structure, genetic exchange has contributed to genotypic variation among strains in nature.

Sulfonamide resistance in Neisseria meningitidis isolates of clones of the ET‐5 complex

A distinctive group of genetically closely related clones, as determined by multilocus enzyme electrophoresis, the ET‐5 complex, has been responsible for an epidemic of meningococcal disease in Norway since the mid‐1970′s. Most isolates of the ET‐5 complex from Norway are sulfonamide‐resistant, serogroup B, and serotype 15:P1.16. Clones of the ET‐5 complex that have been identified as the causative agents of recent outbreaks and epidemics in many other parts of the world show, outside Northern Europe, different associations of serotype protein antigens. We here report the analysis of sulfonamide susceptibility of isolates of the ET‐5 complex from various geographic sources. There was no difference in resistance according to geographic source, serogroup, or serotype of the isolates, demonstrating that, in contrast to serotype and serogroup, sulfonamide resistance is an essentially invariant property of clones of the ET‐5 complex.