Natural Selection During Subtype C HIV-1 Transmission Public

Abstract

HIV-1, the causative agent of AIDS, kills approximately 1.6 million people per year globally. The majority of infected persons live in sub-Saharan Africa, where disease burden is greatest. A major roadblock to the development of an effective vaccine is the extraordinary genetic diversity of HIV, both around the world as well as within a single infected individual. However, during transmission of HIV between individuals, a strong genetic bottleneck occurs, wherein from a large diverse population of viruses present in a chronically infected person, only a single genetic variant establishes infection in the naïve host. Identifying the viral characteristics of these transmitted/founder (TF) variants may provide a useful common target for any future vaccine. We and others have strived to define common genetic and phenotypic characteristics of these TF virus variants, although few traits have so far been confirmed. Work from our lab established that a genetic bottleneck occurs during transmission, and confirmed that there is a transmission selection bias for consensus amino acid residues. This selection bias suggests that consensus amino acid residues lead to virus variants with increased transmission fitness. In order to further investigate the phenotypic characteristics of HIV TF variants, we have examined the populations of full-length genome HIV from six linked heterosexual transmission pairs near the time of transmission. We confirmed that TF variants had more consensus-like genomes across all viral genes. However, following the generation of full-length infectious molecular clones, we did not observe a selection for variants with increased infectivity, in vitro replicative capacity, or inherent resistance to IFNα. Our findings indicate that although selection for more consensus-like variants suggests a selection of virus with increased transmission fitness, this fitness is not associated with in vitro measurements of virus replication. Continued efforts to describe these uniquely derived full-length genome TF viruses in comparison to their non-transmitted counterparts will offer additional insight into viral requirements of transmission and may provide potential common targets for an effective vaccine.

Table of Contents

CHAPTER I : INTRODUCTION 1

CHAPTER II : PARTICLE INFECTIVITY OF HIV-1 FULL-LENGTH GENOME INFECTIOUS MOLECULAR CLONES IN A SUBTYPE C HETEROSEXUAL TRANSMISSION PAIR FOLLOWING HIGH FIDELITY AMPLIFICATION AND UNBIASED CLONING 21

ABSTRACT 22

INTRODUCTION 23

RESULTS 26

DISCUSSION 33

MATERIALS AND METHODS 36

TABLE 1 - CHARACTERISTICS OF THE SAMPLES FROM THE SUBTYPE C HIV-1 TRANSMISSION PAIR. 43

TABLE 2 - DNA PRIMERS USED IN THE STUDY. 44

FIGURE 1 - HIGHLIGHTER AND PHYLOGENETIC ANALYSIS OF HIV-1 NEAR FULL-LENGTH SINGLE GENOME AMPLICONS FROM A HETEROSEXUAL EPIDEMIOLOGICALLY-LINKED TRANSMISSION PAIR. 45

FIGURE 2 - DIAGRAM FOR THE FULL-LENGTH GENOME CLONING STRATEGY. (A) FIRST, THE LTR OF THE TF WAS AMPLIFIED FROM GENOMIC DNA AND CLONED USING THE IN-FUSION SYSTEM. 46

FIGURE 3 - PARTICLE INFECTIVITIES OF HIV FULL-LENGTH GENOME INFECTIOUS MOLECULAR CLONES FROM A LINKED HETEROSEXUAL TRANSMISSION PAIR. 48

FIGURE 4 - PARTICLE INFECTIVITIES OF TWO VIRAL VARIANTS WITH THE CHIMERIC R AND ORIGINAL AMPLICON R SEQUENCES. 49

REFERENCES 50

CHAPTER III : HETEROSEXUAL TRANSMISSION OF SUBTYPE C HIV-1 SELECTS CONSENSUS-LIKE VARIANTS WITHOUT INCREASED REPLICATIVE CAPACITY OR INTERFERON-α RESISTANCE 55

ABSTRACT 56

INTRODUCTION 58

RESULTS 61

DISCUSSION 70

MATERIALS AND METHODS 78

TABLE 1 - TRANSMISSION PAIR CHARACTERISTICS 87

FIGURE 1 - HIV-1 FULL-LENGTH GENOME PHYLOGENETIC ANALYSIS OF SIX EPIDEMIOLOGICALLY-LINKED HETEROSEXUAL TRANSMISSION PAIRS. 89

FIGURE 2 - TRANSMISSION SELECTS FOR MORE CONSENSUS-LIKE TF VARIANTS. 90

FIGURE 3 - PARTICLE INFECTIVITY OF TF AND NT INFECTIOUS MOLECULAR CLONES. 91

FIGURE 4 - TF VARIANTS ARE MORE SENSITIVE TO NEUTRALIZATION BY DONOR PLASMA THAN NT VIRUSES 92

FIGURE 5 - IN VITRO REPLICATION OF TF AND NT VIRUSES IN PBMC. 94

FIGURE 6 - INTERFERON-α RESISTANCE OF TF AND NT VIRUSES. 95

SUPPLEMENTAL FIGURE 1 - PARTICLE INFECTIVITY FROM 293T AND PBMC DERIVED VIRUS. 97

SUPPLEMENTAL FIGURE 2 - PARTICLE INFECTIVITY CORRELATES WITH REPLICATIVE CAPACITY. 98

SUPPLEMENTAL FIGURE 3 - REPLICATION OF TF AND NT VIRUSES IN MONOCYTE DERIVED DENDRITIC CELLS. 99

SUPPLEMENTAL FIGURE 4 - TF AND NT RESISTANCE TO IFN-α. 100

SUPPLEMENTAL FIGURE 5 - REPLICATION OF TF AND 6-MONTH CONSENSUS INFECTIOUS MOLECULAR CLONES. 102

REFERENCES 103

CHAPTER IV : DISCUSSION 113

REFERENCES 123

About this Dissertation

Rights statement

• Permission granted by the author to include this thesis or dissertation in this repository. All rights reserved by the author. Please contact the author for information regarding the reproduction and use of this thesis or dissertation.

School	Laney Graduate School
Department	Biological and Biomedical Sciences
Subfield / Discipline	Microbiology & Molecular Genetics
Degree	PhD
Submission	Dissertation
Language	English
Research Field	Biology, Virology
Mot-clé	HIV Transmission
Committee Chair / Thesis Advisor	Hunter, Eric, Emory University
Committee Members	Grakoui, Arash, Emory University Pulendran, Bali, Emory University Derdeyn, Cynthia, Emory University Amara, Rama Rao, Emory University

Dernière modification

Primary PDF

Thumbnail	Title	Date Uploaded	Actions
	Natural Selection During Subtype C HIV-1 Transmission ()	2018-08-28 15:19:02 -0400	Press to Select an action Download

Supplemental Files

Thumbnail	Title	Date Uploaded	Actions