Culture-independent Sequence Analysis of Chlamydia Trachomatis in Urogenital Specimens Identifies Regions of Recombination and In-patient Sequence Mutations

Overview

Journal Microbiology (Reading)

Specialty Microbiology

Date 2013 Jul 12

PMID 23842467

Citations 23

Authors

Timothy E Putman

Robert J Suchland

John D Ivanovitch

Daniel D Rockey

Affiliations

Soon will be listed here.

Abstract

A culture-independent genome sequencing approach was developed and used to examine genomic variability in Chlamydia trachomatis-positive specimens that were collected from patients in the Seattle, WA, USA, area. The procedure is based on an immunomagnetic separation approach with chlamydial LPS-specific mAbs, followed by DNA purification and total DNA amplification, and subsequent Illumina-based sequence analysis. Quality of genome sequencing was independent of the total number of inclusion-forming units determined for the sample and the amount of non-chlamydial DNA in the Illumina libraries. A geographically and temporally linked clade of isolates was identified with evidence of several different regions of recombination and variable ompA sequence types, suggesting that recombination is common within outbreaks. Culture-independent sequence analysis revealed a linkage pattern at two nucleotide positions that was unique to the genomes of isolates from patients, but not in C. trachomatis recombinants generated in vitro. These data demonstrated that culture-independent sequence analysis can be used to rapidly and inexpensively collect genome data from patients infected by C. trachomatis, and that this approach can be used to examine genomic variation within this species.

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