Mapping Sites of Positive Selection and Amino Acid Diversification in the HIV Genome: an Alternative Approach to Vaccine Design?

Overview

Journal Genetics

Publisher Oxford University Press

Specialty Genetics

Date 2004 Jul 29

PMID 15280222

Citations 26

Authors

Tulio de Oliveira

Marco Salemi

Michelle Gordon

Anne-Mieke Vandamme

Estrelita Janse van Rensburg

Susan Engelbrecht

Hoosen M Coovadia

Sharon Cassol

Affiliations

Soon will be listed here.

Abstract

A safe and effective HIV-1 vaccine is urgently needed to control the worldwide AIDS epidemic. Traditional methods of vaccine development have been frustratingly slow, and it is becoming increasingly apparent that radical new approaches may be required. Computational and mathematical approaches, combined with evolutionary reasoning, may provide new insights for the design of an efficacious AIDS vaccine. Here, we used codon-based substitution models and maximum-likelihood (ML) methods to identify positively selected sites that are likely to be involved in the immune control of HIV-1. Analysis of subtypes B and C revealed widespread adaptive evolution. Positively selected amino acids were detected in all nine HIV-1 proteins, including Env. Of particular interest was the high level of positive selection within the C-terminal regions of the immediate-early regulatory proteins, Tat and Rev. Many of the amino acid replacements were associated with the emergence of novel (or alternative) myristylation and casein kinase II (CKII) phosphorylation sites. The impact of these changes on the conformation and antigenicity of Tat and Rev remains to be established. In rhesus macaques, a single CTL-associated amino substitution in Tat has been linked to escape from acute SIV infection. Understanding the relationship between host-driven positive selection and antigenic variation may lead to the development of novel vaccine strategies that preempt the escape process.

Citing Articles

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