Population Genetics of Neisseria gonorrhoeae in a High-Prevalence Community Using a Hypervariable Outer Membrane porB and 13 Slowly Evolving Housekeeping Genes

doi:10.1093/molbev/msi184

MBE Advance Access originally published online on June 8, 2005
Molecular Biology and Evolution 2005 22(9):1887-1902; doi:10.1093/molbev/msi184

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Research Article

Population Genetics of Neisseria gonorrhoeae in a High-Prevalence Community Using a Hypervariable Outer Membrane porB and 13 Slowly Evolving Housekeeping Genes

Marcos Pérez-Losada^*, Raphael P. Viscidi, James C. Demma, Jonathan Zenilman and Keith A. Crandall^*^,

^* Department of Integrative Biology, Brigham Young University; Department of Pediatrics, Johns Hopkins University School of Medicine; Division of Infectious Diseases, Johns Hopkins University School of Medicine; and Department of Microbiology and Molecular Biology, Brigham Young University

E-mail: keith_crandall{at}byu.edu.

Baltimore, Md., is an urban community with a high prevalenceof Neisseria gonorrhoeae. Due to partially protective immuneresponses, introduction of new strains from other host populations,and exposure of N. gonorrhoeae to antibiotics, the phenotypicand genotypic characteristics of the circulating strains canfluctuate over time. Understanding the overall genetic diversityand population structure of N. gonorrhoeae is essential forinforming public health interventions to eliminate this pathogen.We studied gonococci population genetics in Baltimore by analyzinga hypervariable and strongly selected outer membrane porB geneand 13 slowly evolving and presumably neutral housekeeping genes(abcZ, adk, aroE, fumC, gdh, glnA, gnd, pdhC, pgm, pilA, ppk,pyrD, and serC) in 204 isolates collected in 1991, 1996, and2001 from male and female patients of two public sexually transmitteddiseases clinics. Genetic diversity ( ${theta}$ ), recombination (C), growth(g), population structure, and adaptive selection under codon-substitutionand amino acid property models were estimated and compared betweenthese two gene classes. Estimates of the F_ST fixation indexand the ${chi}$ ² test of sequence absolute frequencies revealed significanttemporal substructuring for both gene types. Baltimore's N.gonorrhoeae populations have increased since 1991 as indicatedby consistent positive values of g. Female patients showed similaror lower levels of ${theta}$ and C than male patients. Within the MLSThousekeeping genes, levels of ${theta}$ and C ranged from 0.001–0.013and 0.000–0.018, respectively. Overall recombination seemsto be the dominant force driving evolution in these populations.All loci showed amino acid sites and physicochemical propertiesunder adaptive (or positive-destabilizing) selection, rejectingthe generally assumed hypothesis of stabilizing selection forthese MLST genes. Within the porB gene, protein I B showed higher ${theta}$ and C values than protein I A. Directional positive selectionpossibly mediated by the immune system operates to a significantextent in the protein I sequences, as indicated by the distributionof the positively selected sites in the surface-exposed loops.Thirteen amino acid physicochemical properties seem to driveprotein evolution of the PI porins in N. gonorrhoeae.

Key Words: Baltimore • housekeeping genes • MLST • Neisseria gonorrhoeae • population genetics • porB

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