Immune-Correlates Analysis of an HIV-1 Vaccine Efficacy Trial

Barton F. Haynes; Peter B. Gilbert; M. Juliana McElrath; Susan Zolla‐Pazner; Georgia D. Tomaras; S. Munir Alam; David T. Evans; David C. Montefiori; Chitraporn Karnasuta; Ruengpueng Sutthent; Hua-Xin Liao; Anthony L. DeVico; George K. Lewis; Constance Williams; Abraham Pinter; Youyi Fong; Holly Janes; Allan C. deCamp; Yunda Huang; Mangala Rao; Erik Billings; Nicos Karasavvas; Merlin L. Robb; Viseth Ngauy; Mark de Souza; Robert Paris; Guido Ferrari; Robert T. Bailer; Kelly A. Soderberg; Charla Andrews; Phillip W. Berman; Nicole Frahm; Stephen C. De Rosa; Michael D. Alpert; Nicole L. Yates; Xiaoying Shen; Richard A. Koup; Punnee Pitisuttithum; Jaranit Kaewkungwal; Sorachai Nitayaphan; Supachai Rerks‐Ngarm; Nelson L. Michael; Jérôme H. Kim

doi:10.1056/nejmoa1113425

Immune-Correlates Analysis of an HIV-1 Vaccine Efficacy Trial

Barton F. Haynes(Duke University), Peter B. Gilbert(Fred Hutch Cancer Center), M. Juliana McElrath(Cape Town HVTN Immunology Laboratory / Hutchinson Centre Research Institute of South Africa), Susan Zolla‐Pazner(VA NY Harbor Healthcare System), Georgia D. Tomaras(Duke University), S. Munir Alam(Duke University), David T. Evans(Harvard University), David C. Montefiori(Duke University), Chitraporn Karnasuta(United States Department of the Army), Ruengpueng Sutthent(Siriraj Hospital), Hua-Xin Liao(Duke University), Anthony L. DeVico(University of Maryland, Baltimore), George K. Lewis(University of Maryland, Baltimore), Constance Williams(VA NY Harbor Healthcare System), Abraham Pinter(Rutgers New Jersey Medical School), Youyi Fong(Fred Hutch Cancer Center), Holly Janes(Fred Hutch Cancer Center), Allan C. deCamp(Fred Hutch Cancer Center), Yunda Huang(Fred Hutch Cancer Center), Mangala Rao(Walter Reed Army Institute of Research), Erik Billings(Walter Reed Army Institute of Research), Nicos Karasavvas(United States Department of the Army), Merlin L. Robb(Walter Reed Army Institute of Research), Viseth Ngauy(United States Department of the Army), Mark de Souza(United States Department of the Army), Robert Paris(Walter Reed Army Institute of Research), Guido Ferrari(Duke University), Robert T. Bailer(National Institutes of Health), Kelly A. Soderberg(Duke University), Charla Andrews(Walter Reed Army Institute of Research), Phillip W. Berman(University of California, Santa Cruz), Nicole Frahm(Cape Town HVTN Immunology Laboratory / Hutchinson Centre Research Institute of South Africa), Stephen C. De Rosa(Cape Town HVTN Immunology Laboratory / Hutchinson Centre Research Institute of South Africa), Michael D. Alpert(Harvard University), Nicole L. Yates(Duke University), Xiaoying Shen(Duke University), Richard A. Koup(National Institutes of Health), Punnee Pitisuttithum(Mahidol University), Jaranit Kaewkungwal(Mahidol University), Sorachai Nitayaphan(Royal Thai Army), Supachai Rerks‐Ngarm, Nelson L. Michael(Walter Reed Army Institute of Research), Jérôme H. Kim(Walter Reed Army Institute of Research)

New England Journal of Medicine

April 4, 2012

10.1056/nejmoa1113425

Cited by 1,830Open Access

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Abstract

BACKGROUND: In the RV144 trial, the estimated efficacy of a vaccine regimen against human immunodeficiency virus type 1 (HIV-1) was 31.2%. We performed a case-control analysis to identify antibody and cellular immune correlates of infection risk. METHODS: In pilot studies conducted with RV144 blood samples, 17 antibody or cellular assays met prespecified criteria, of which 6 were chosen for primary analysis to determine the roles of T-cell, IgG antibody, and IgA antibody responses in the modulation of infection risk. Assays were performed on samples from 41 vaccinees who became infected and 205 uninfected vaccinees, obtained 2 weeks after final immunization, to evaluate whether immune-response variables predicted HIV-1 infection through 42 months of follow-up. RESULTS: Of six primary variables, two correlated significantly with infection risk: the binding of IgG antibodies to variable regions 1 and 2 (V1V2) of HIV-1 envelope proteins (Env) correlated inversely with the rate of HIV-1 infection (estimated odds ratio, 0.57 per 1-SD increase; P=0.02; q=0.08), and the binding of plasma IgA antibodies to Env correlated directly with the rate of infection (estimated odds ratio, 1.54 per 1-SD increase; P=0.03; q=0.08). Neither low levels of V1V2 antibodies nor high levels of Env-specific IgA antibodies were associated with higher rates of infection than were found in the placebo group. Secondary analyses suggested that Env-specific IgA antibodies may mitigate the effects of potentially protective antibodies. CONCLUSIONS: This immune-correlates study generated the hypotheses that V1V2 antibodies may have contributed to protection against HIV-1 infection, whereas high levels of Env-specific IgA antibodies may have mitigated the effects of protective antibodies. Vaccines that are designed to induce higher levels of V1V2 antibodies and lower levels of Env-specific IgA antibodies than are induced by the RV144 vaccine may have improved efficacy against HIV-1 infection.

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