Cui, Yujun, Yang, Xianwei, Didelot, Xavier, Guo, Chenyi, Li, Dongfang, Yan, Yanfeng, Zhang, Yiquan, Yuan, Yanting, Yang, Huanming, Wang, Jian, Wang, Jun, Song, Yajun, Zhou, Dongsheng, Falush, Daniel and Yang, Ruifu (2015) Epidemic clones, oceanic gene pools, and eco-LD in the free living Marine pathogen vibrio parahaemolyticus. Molecular Biology and Evolution, 32 (6). pp. 1396-1410. doi:10.1093/molbev/msv009

Research output not available from this repository, contact author.

Request Changes to record.

Abstract

We investigated global patterns of variation in 157 whole-genome sequences of Vibrio parahaemolyticus, a free-living and seafood associated marine bacterium. Pandemic clones, responsible for recent outbreaks of gastroenteritis in humans, have spread globally. However, there are oceanic gene pools, one located in the oceans surrounding Asia and another in the Mexican Gulf. Frequent recombination means that most isolates have acquired the genetic profile of their current location. We investigated the genetic structure in the Asian gene pool by calculating the effective population size in two different ways. Under standard neutral models, the two estimates should give similar answers but we found a 27-fold difference. We propose that this discrepancy is caused by the subdivision of the species into a hundred or more ecotypes which are maintained stably in the population. To investigate the genetic factors involved, we used 51 unrelated isolates to conduct a genome-wide scan for epistatically interacting loci. We found a single example of strong epistasis between distant genome regions. A majority of strains had a type VI secretion system associated with bacterial killing. The remaining strains had genes associated with biofilm formation and regulated by cyclic dimeric GMP signaling. All strains had one or other of the two systems and none of isolate had complete complements of both systems, although several strains had remnants. Further “top down” analysis of patterns of linkage disequilibrium within frequently recombining species will allow a detailed understanding of how selection acts to structure the pattern of variation within natural bacterial populations.

Item Type:	Journal Article
Divisions:	Faculty of Science > Life Sciences (2010- )
Journal or Publication Title:	Molecular Biology and Evolution
Publisher:	Oxford University Press
ISSN:	0737-4038
Official Date:	1 June 2015
Dates:	Date Event 1 June 2015 Published 19 January 2015 Available
Volume:	32
Number:	6
Page Range:	pp. 1396-1410
DOI:	10.1093/molbev/msv009
Status:	Peer Reviewed
Publication Status:	Published
Access rights to Published version:	Open Access

Request changes or add full text files to a record

Repository staff actions (login required)

View Item