Quantitative Deep Sequencing Reveals Dynamic HIV-1 Escape and Large Population Shifts During CCR5 Antagonist Therapy in Vivo

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2009 May 30

PMID 19479085

Citations 133

Authors

Athe M N Tsibris

Bette Korber

Ramy Arnaout

Carsten Russ

Chien-Chi Lo

Thomas Leitner

Brian Gaschen

James Theiler

Roger Paredes

Zhaohui Su

Michael D Hughes

Roy M Gulick

Wayne Greaves

Eoin Coakley

Charles Flexner

Chad Nusbaum

Daniel R Kuritzkes

Affiliations

Soon will be listed here.

Abstract

High-throughput sequencing platforms provide an approach for detecting rare HIV-1 variants and documenting more fully quasispecies diversity. We applied this technology to the V3 loop-coding region of env in samples collected from 4 chronically HIV-infected subjects in whom CCR5 antagonist (vicriviroc [VVC]) therapy failed. Between 25,000-140,000 amplified sequences were obtained per sample. Profound baseline V3 loop sequence heterogeneity existed; predicted CXCR4-using populations were identified in a largely CCR5-using population. The V3 loop forms associated with subsequent virologic failure, either through CXCR4 use or the emergence of high-level VVC resistance, were present as minor variants at 0.8-2.8% of baseline samples. Extreme, rapid shifts in population frequencies toward these forms occurred, and deep sequencing provided a detailed view of the rapid evolutionary impact of VVC selection. Greater V3 diversity was observed post-selection. This previously unreported degree of V3 loop sequence diversity has implications for viral pathogenesis, vaccine design, and the optimal use of HIV-1 CCR5 antagonists.

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