Clonal expansion of SIV-infected cells in macaques on antiretroviral therapy is similar to that of HIV-infected cells in humans

Ferris, Andrea L.; Wells, David W.; Guo, Shuang; Prete, Gregory Q. Del; Swanstrom, Adrienne E.; Coffin, John M.; Wu, Xiaolin; Lifson, Jeffrey D.; Hughes, Stephen H.

doi:10.1371/journal.ppat.1007869

Cited by 32 publications

(45 citation statements)

References 42 publications

(71 reference statements)

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“…We normally only map the sequence reads to the specific genome that was used in the study. Although most of our work involves HIV and the human genome, the experimental procedures and bioinformatics pipeline we describe here works for any retrovirus/host pair such as MLV in the human genome [7], HIV in the mouse genome [35,41], or HIV or SIV in the macaque genome [42], with proper viral specific primers.…”

Section: Discussionmentioning

confidence: 99%

An analytical pipeline for identifying and mapping the integration sites of HIV and other retroviruses

et al. 2020

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Background: All retroviruses, including human immunodeficiency virus (HIV), must integrate a DNA copy of their genomes into the genome of the infected host cell to replicate. Although integrated retroviral DNA, known as a provirus, can be found at many sites in the host genome, integration is not random. The adaption of linker-mediated PCR (LM-PCR) protocols for high-throughput integration site mapping, using randomly-sheared genomic DNA and Illumina paired-end sequencing, has dramatically increased the number of mapped integration sites. Analysis of samples from human donors has shown that there is clonal expansion of HIV infected cells and that clonal expansion makes an important contribution to HIV persistence. However, analysis of HIV integration sites in samples taken from patients requires extensive PCR amplification and high-throughput sequencing, which makes the methodology prone to certain specific artifacts. Results: To address the problems with artifacts, we use a comprehensive approach involving experimental procedures linked to a bioinformatics analysis pipeline. Using this combined approach, we are able to reduce the number of PCR/ sequencing artifacts that arise and identify the ones that remain. Our streamlined workflow combines random cleavage of the DNA in the samples, end repair, and linker ligation in a single step. We provide guidance on primer and linker design that reduces some of the common artifacts. We also discuss how to identify and remove some of the common artifacts, including the products of PCR mispriming and PCR recombination, that have appeared in some published studies. Our improved bioinformatics pipeline rapidly parses the sequencing data and identifies bona fide integration sites in clonally expanded cells, producing an Excel-formatted report that can be used for additional data processing. Conclusions:We provide a detailed protocol that reduces the prevalence of artifacts that arise in the analysis of retroviral integration site data generated from in vivo samples and a bioinformatics pipeline that is able to remove the artifacts that remain.

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Section: Discussionmentioning

confidence: 99%

An analytical pipeline for identifying and mapping the integration sites of HIV and other retroviruses

et al. 2020

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“…These specific sites recur across individuals not because of preferential integration, as HIV-1 integration into these sites are not enriched during in vitro infections [11]. Similar to HIV-1 integration sites, simian immunodeficiency virus (SIV) with integration into BACH2, MKL2 and STAT5B are found in SIV-infected macaques before ART [107]. Despite that the genomewide distribution of HIV-1 and SIV integration showed a high degree of overlap in vitro, it seems that more integrants are oriented in the convergent orientation of these genes in SIV-infected macaques under suppression, which is opposite from what observed from ART treated HIV-1infected individuals in vivo [11,12,107].…”

Section: Retroviral Integration Into Cancer-related Genes Promotes CLmentioning

confidence: 99%

“…Similar to HIV-1 integration sites, simian immunodeficiency virus (SIV) with integration into BACH2, MKL2 and STAT5B are found in SIV-infected macaques before ART [107]. Despite that the genomewide distribution of HIV-1 and SIV integration showed a high degree of overlap in vitro, it seems that more integrants are oriented in the convergent orientation of these genes in SIV-infected macaques under suppression, which is opposite from what observed from ART treated HIV-1infected individuals in vivo [11,12,107]. However, more SIV integration site data from long-term treated macaques are needed to determine whether there is positive selection of SIV proviruses integrated in genes associated with clonal expansion in individuals on ART.…”

Section: Retroviral Integration Into Cancer-related Genes Promotes CLmentioning

confidence: 99%

The forces driving clonal expansion of the HIV-1 latent reservoir

Liu

Simonetti

2020

Virol J

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Despite antiretroviral therapy (ART) which halts HIV-1 replication and reduces plasma viral load to clinically undetectable levels, viral rebound inevitably occurs once ART is interrupted. HIV-1-infected cells can undergo clonal expansion, and these clonally expanded cells increase over time. Over 50% of latent reservoirs are maintained through clonal expansion. The clonally expanding HIV-1-infected cells, both in the blood and in the lymphoid tissues, contribute to viral rebound. The major drivers of clonal expansion of HIV-1-infected cells include antigendriven proliferation, homeostatic proliferation and HIV-1 integration site-dependent proliferation. Here, we reviewed how viral, immunologic and genomic factors contribute to clonal expansion of HIV-1-infected cells, and how clonal expansion shapes the HIV-1 latent reservoir. Antigen-specific CD4 + T cells specific for different pathogens have different clonal expansion dynamics, depending on antigen exposure, cytokine profiles and exhaustion phenotypes. Homeostatic proliferation replenishes the HIV-1 latent reservoir without inducing viral expression and immune clearance. Integration site-dependent proliferation, a mechanism also deployed by other retroviruses, leads to slow but steady increase of HIV-1-infected cells harboring HIV-1 proviruses integrated in the same orientation at specific sites of certain cancer-related genes. Targeting clonally expanding HIV-1 latent reservoir without disrupting CD4 + T cell function is a top priority for HIV-1 eradication.

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“…To extend our studies to more physiologically relevant models and provide clinical relevance, we first assembled open source, publicly available HIV integration datasets from 11 patients studies (Mack et al 2003;Han et al 2004;Ikeda et al 2007;Maldarelli et al 2014;Wagner et al 2014;Kok et al 2016;Sharaf et al 2018;Coffin et al 2019;Einkauf et al 2019;Garcia-Broncano et al 2019;McManus et al 2019) and 4 studies with primary CD4 + T cells infected ex vivo (Sherrill-Mix et al 2013;Sunshine et al 2016;Ferris et al 2019;Lucic et al 2019) ( Supplemental Table S4). We used these datasets to interrogate the epigenomic landscape of intact vs defective proviruses to provide fundamental principles of differential positioning and regulation of these two proviral classes and to compare their epigenomic landscapes to proviruses in the immortalized (Jurkat T cell) models of latency ( Fig.…”

Section: Combination Of In Vitro Hiv Integration/expression Data Withmentioning

confidence: 99%

An integrated genomics approach towards deciphering human genome codes shaping HIV-1 proviral transcription and fate

Ruess

Guzmán

et al. 2020

Preprint

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A large body of work has revealed fundamental principles of HIV-1 integration into the human genome.However, the effect of the integration site to proviral transcription activity has so far remained elusive.Here we combine open-source, large-scale datasets including epigenetics, transcriptome, and 3D genome architecture to interrogate the chromatin states, transcription activity landscape, and nuclear sub-compartments around HIV-1 integration sites in CD4 + T cells to decipher human genome codes shaping the transcription of proviral classes defined based on their position and orientation in the genome. Using a Hidden Markov Model, we describe the importance of specific chromatin states and genome architecture in the control of HIV-1 transcription activity. Additionally, implementation of a machine-learning logistic regression model reveals upstream chromatin accessibility, transcription activity, and categorical nuclear sub-compartments as optimal features predicting HIV-1 transcriptional outcomes. We finally demonstrate clinical relevance by interrogating the positions of intact proviruses persisting in patients under suppressive therapy and provide a compass compatible with clinical decision-making.

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Clonal expansion of SIV-infected cells in macaques on antiretroviral therapy is similar to that of HIV-infected cells in humans

Cited by 32 publications

References 42 publications

An analytical pipeline for identifying and mapping the integration sites of HIV and other retroviruses

An analytical pipeline for identifying and mapping the integration sites of HIV and other retroviruses

The forces driving clonal expansion of the HIV-1 latent reservoir

An integrated genomics approach towards deciphering human genome codes shaping HIV-1 proviral transcription and fate

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