Complete Genomes of Two Clinical Staphylococcus Aureus Strains: Evidence for the Rapid Evolution of Virulence and Drug Resistance

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2004 Jun 24

PMID 15213324

Citations 428

Authors

Matthew T G Holden

Edward J Feil

Jodi A Lindsay

Sharon J Peacock

Nicholas P J Day

Mark C Enright

Tim J Foster

Catrin E Moore

Laurence Hurst

Rebecca Atkin

Andrew Barron

Nathalie Bason

Stephen D Bentley

Carol Chillingworth

Tracey Chillingworth

Carol Churcher

Louise Clark

Craig Corton

Ann Cronin

Jon Doggett

Linda Dowd

Theresa Feltwell

Zahra Hance

Barbara Harris

Heidi Hauser

Simon Holroyd

Kay Jagels

Keith D James

Nicola Lennard

Alexandra Line

Rebecca Mayes

Sharon Moule

Karen Mungall

Douglas Ormond

Michael A Quail

Ester Rabbinowitsch

Kim Rutherford

Mandy Sanders

Sarah Sharp

Mark Simmonds

Kim Stevens

Sally Whitehead

Bart G Barrell

Brian G Spratt

Julian Parkhill

Affiliations

Soon will be listed here.

Abstract

Staphylococcus aureus is an important nosocomial and community-acquired pathogen. Its genetic plasticity has facilitated the evolution of many virulent and drug-resistant strains, presenting a major and constantly changing clinical challenge. We sequenced the approximately 2.8-Mbp genomes of two disease-causing S. aureus strains isolated from distinct clinical settings: a recent hospital-acquired representative of the epidemic methicillin-resistant S. aureus EMRSA-16 clone (MRSA252), a clinically important and globally prevalent lineage; and a representative of an invasive community-acquired methicillin-susceptible S. aureus clone (MSSA476). A comparative-genomics approach was used to explore the mechanisms of evolution of clinically important S. aureus genomes and to identify regions affecting virulence and drug resistance. The genome sequences of MRSA252 and MSSA476 have a well conserved core region but differ markedly in their accessory genetic elements. MRSA252 is the most genetically diverse S. aureus strain sequenced to date: approximately 6% of the genome is novel compared with other published genomes, and it contains several unique genetic elements. MSSA476 is methicillin-susceptible, but it contains a novel Staphylococcal chromosomal cassette (SCC) mec-like element (designated SCC(476)), which is integrated at the same site on the chromosome as SCCmec elements in MRSA strains but encodes a putative fusidic acid resistance protein. The crucial role that accessory elements play in the rapid evolution of S. aureus is clearly illustrated by comparing the MSSA476 genome with that of an extremely closely related MRSA community-acquired strain; the differential distribution of large mobile elements carrying virulence and drug-resistance determinants may be responsible for the clinically important phenotypic differences in these strains.

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