HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1

Several recent large clinical trials evaluated HIV vaccine candidates that were based on recombinant adenovirus serotype 5 (rAd-5) vectors expressing HIV-derived antigens. These vaccines primarily elicited T-cell responses, which are known to be critical for controlling HIV infection. In the current...

Descripción completa

Detalles Bibliográficos
Autores principales: Hertz, Tomer, Ahmed, Hasan, Friedrich, David P., Casimiro, Danilo R., Self, Steven G., Corey, Lawrence, McElrath, M. Juliana, Buchbinder, Susan, Horton, Helen, Frahm, Nicole, Robertson, Michael N., Graham, Barney S., Gilbert, Peter
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2013
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3688560/
https://www.ncbi.nlm.nih.gov/pubmed/23818843
http://dx.doi.org/10.1371/journal.ppat.1003404
_version_ 1782476226194046976
author Hertz, Tomer
Ahmed, Hasan
Friedrich, David P.
Casimiro, Danilo R.
Self, Steven G.
Corey, Lawrence
McElrath, M. Juliana
Buchbinder, Susan
Horton, Helen
Frahm, Nicole
Robertson, Michael N.
Graham, Barney S.
Gilbert, Peter
author_facet Hertz, Tomer
Ahmed, Hasan
Friedrich, David P.
Casimiro, Danilo R.
Self, Steven G.
Corey, Lawrence
McElrath, M. Juliana
Buchbinder, Susan
Horton, Helen
Frahm, Nicole
Robertson, Michael N.
Graham, Barney S.
Gilbert, Peter
author_sort Hertz, Tomer
collection PubMed
description Several recent large clinical trials evaluated HIV vaccine candidates that were based on recombinant adenovirus serotype 5 (rAd-5) vectors expressing HIV-derived antigens. These vaccines primarily elicited T-cell responses, which are known to be critical for controlling HIV infection. In the current study, we present a meta-analysis of epitope mapping data from 177 participants in three clinical trials that tested two different HIV vaccines: MRKAd-5 HIV and VRC-HIVAD014-00VP. We characterized the population-level epitope responses in these trials by generating population-based epitope maps, and also designed such maps using a large cohort of 372 naturally infected individuals. We used these maps to address several questions: (1) Are vaccine-induced responses randomly distributed across vaccine inserts, or do they cluster into immunodominant epitope hotspots? (2) Are the immunodominance patterns observed for these two vaccines in three vaccine trials different from one another? (3) Do vaccine-induced hotspots overlap with epitope hotspots induced by chronic natural infection with HIV-1? (4) Do immunodominant hotspots target evolutionarily conserved regions of the HIV genome? (5) Can epitope prediction methods be used to identify these hotspots? We found that vaccine responses clustered into epitope hotspots in all three vaccine trials and some of these hotspots were not observed in chronic natural infection. We also found significant differences between the immunodominance patterns generated in each trial, even comparing two trials that tested the same vaccine in different populations. Some of the vaccine-induced immunodominant hotspots were located in highly variable regions of the HIV genome, and this was more evident for the MRKAd-5 HIV vaccine. Finally, we found that epitope prediction methods can partially predict the location of vaccine-induced epitope hotspots. Our findings have implications for vaccine design and suggest a framework by which different vaccine candidates can be compared in early phases of evaluation.
format Online
Article
Text
id pubmed-3688560
institution National Center for Biotechnology Information
language English
publishDate 2013
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-36885602013-07-01 HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1 Hertz, Tomer Ahmed, Hasan Friedrich, David P. Casimiro, Danilo R. Self, Steven G. Corey, Lawrence McElrath, M. Juliana Buchbinder, Susan Horton, Helen Frahm, Nicole Robertson, Michael N. Graham, Barney S. Gilbert, Peter PLoS Pathog Research Article Several recent large clinical trials evaluated HIV vaccine candidates that were based on recombinant adenovirus serotype 5 (rAd-5) vectors expressing HIV-derived antigens. These vaccines primarily elicited T-cell responses, which are known to be critical for controlling HIV infection. In the current study, we present a meta-analysis of epitope mapping data from 177 participants in three clinical trials that tested two different HIV vaccines: MRKAd-5 HIV and VRC-HIVAD014-00VP. We characterized the population-level epitope responses in these trials by generating population-based epitope maps, and also designed such maps using a large cohort of 372 naturally infected individuals. We used these maps to address several questions: (1) Are vaccine-induced responses randomly distributed across vaccine inserts, or do they cluster into immunodominant epitope hotspots? (2) Are the immunodominance patterns observed for these two vaccines in three vaccine trials different from one another? (3) Do vaccine-induced hotspots overlap with epitope hotspots induced by chronic natural infection with HIV-1? (4) Do immunodominant hotspots target evolutionarily conserved regions of the HIV genome? (5) Can epitope prediction methods be used to identify these hotspots? We found that vaccine responses clustered into epitope hotspots in all three vaccine trials and some of these hotspots were not observed in chronic natural infection. We also found significant differences between the immunodominance patterns generated in each trial, even comparing two trials that tested the same vaccine in different populations. Some of the vaccine-induced immunodominant hotspots were located in highly variable regions of the HIV genome, and this was more evident for the MRKAd-5 HIV vaccine. Finally, we found that epitope prediction methods can partially predict the location of vaccine-induced epitope hotspots. Our findings have implications for vaccine design and suggest a framework by which different vaccine candidates can be compared in early phases of evaluation. Public Library of Science 2013-06-20 /pmc/articles/PMC3688560/ /pubmed/23818843 http://dx.doi.org/10.1371/journal.ppat.1003404 Text en https://creativecommons.org/publicdomain/zero/1.0/ This is an open-access article distributed under the terms of the Creative Commons Public Domain declaration, which stipulates that, once placed in the public domain, this work may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose.
spellingShingle Research Article
Hertz, Tomer
Ahmed, Hasan
Friedrich, David P.
Casimiro, Danilo R.
Self, Steven G.
Corey, Lawrence
McElrath, M. Juliana
Buchbinder, Susan
Horton, Helen
Frahm, Nicole
Robertson, Michael N.
Graham, Barney S.
Gilbert, Peter
HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1
title HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1
title_full HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1
title_fullStr HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1
title_full_unstemmed HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1
title_short HIV-1 Vaccine-Induced T-Cell Reponses Cluster in Epitope Hotspots that Differ from Those Induced in Natural Infection with HIV-1
title_sort hiv-1 vaccine-induced t-cell reponses cluster in epitope hotspots that differ from those induced in natural infection with hiv-1
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3688560/
https://www.ncbi.nlm.nih.gov/pubmed/23818843
http://dx.doi.org/10.1371/journal.ppat.1003404
work_keys_str_mv AT hertztomer hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT ahmedhasan hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT friedrichdavidp hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT casimirodanilor hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT selfsteveng hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT coreylawrence hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT mcelrathmjuliana hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT buchbindersusan hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT hortonhelen hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT frahmnicole hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT robertsonmichaeln hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT grahambarneys hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1
AT gilbertpeter hiv1vaccineinducedtcellreponsesclusterinepitopehotspotsthatdifferfromthoseinducedinnaturalinfectionwithhiv1

Ejemplares similares