Innate protection against intrarectal SIV acquisition by a live SHIV vaccine
Yongjun Sui, Thomas J. Meyer, Christine M. Fennessey, Brandon F. Keele, Kimia Dadkhah, Chi Ma, Celia C. LaBranche, Matthew W. Breed, Josh A. Kramer, Jianping Li, Savannah E. Howe, Guido Ferrari, LaTonya D. Williams, Maggie Cam, Michael C. Kelly, Xiaoying Shen, Georgia D. Tomaras, David Montefiori, Tim F. Greten, Christopher J. Miller, Jay A. Berzofsky
Yongjun Sui, Thomas J. Meyer, Christine M. Fennessey, Brandon F. Keele, Kimia Dadkhah, Chi Ma, Celia C. LaBranche, Matthew W. Breed, Josh A. Kramer, Jianping Li, Savannah E. Howe, Guido Ferrari, LaTonya D. Williams, Maggie Cam, Michael C. Kelly, Xiaoying Shen, Georgia D. Tomaras, David Montefiori, Tim F. Greten, Christopher J. Miller, Jay A. Berzofsky
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Research Article AIDS/HIV Vaccines

Innate protection against intrarectal SIV acquisition by a live SHIV vaccine

Abstract

Identifying immune correlates of protection is a major challenge in AIDS vaccine development. Anti-Envelope antibodies have been considered critical for protection against SIV/HIV (SHIV) acquisition. Here, we evaluated the efficacy of an SHIV vaccine against SIVmac251 challenge, where the role of antibody was excluded, as there was no cross-reactivity between SIV and SHIV envelope antibodies. After 8 low-dose intrarectal challenges with SIVmac251, 12 SHIV-vaccinated animals demonstrated efficacy, compared with 6 naive controls, suggesting protection was achieved in the absence of anti-envelope antibodies. Interestingly, CD8+ T cells (and some NK cells) were not essential for preventing viral acquisition, as none of the CD8-depleted macaques were infected by SIVmac251 challenges. Initial investigation of protective innate immunity revealed that protected animals had elevated pathways related to platelet aggregation/activation and reduced pathways related to interferon and responses to virus. Moreover, higher expression of platelet factor 4 on circulating platelet-leukocyte aggregates was associated with reduced viral acquisition. Our data highlighted the importance of innate immunity, identified mechanisms, and may provide opportunities for novel HIV vaccines or therapeutic strategy development.

Authors

Yongjun Sui, Thomas J. Meyer, Christine M. Fennessey, Brandon F. Keele, Kimia Dadkhah, Chi Ma, Celia C. LaBranche, Matthew W. Breed, Josh A. Kramer, Jianping Li, Savannah E. Howe, Guido Ferrari, LaTonya D. Williams, Maggie Cam, Michael C. Kelly, Xiaoying Shen, Georgia D. Tomaras, David Montefiori, Tim F. Greten, Christopher J. Miller, Jay A. Berzofsky

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Figure 6

Vac-protected animals demonstrated an immune tolerance gene signature in the SIV-exposed myeloid cells.

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Vac-protected animals demonstrated an immune tolerance gene signature in...
(A) Downregulated GSEA pathway (GO_ responses to type I interferon). The negative normalized enrichment scores indicate the downregulation of the pathways. (B) Heatmap of the downregulated gene pathway (innate immune responses GO 0045087). (C) The M (myeloid cell enriched) samples were incubated with SIVmac251 for 18 hours. RNA was isolated. Gag RNA level in the M samples from all 18 animals. (D and E) Quantitative PCR (qPCR) was used for validation of the down- and upregulated DEGs between the protected and infected animals (n = 18). Genes that were not significantly changed are shown in D, and those that were significantly changed are shown in E. These genes were involved in the following pathways: interferon alpha/beta/gamma signaling; response to LPS, cytokines; responses to virus; and influenza A. Two upregulated genes, SPP1 and PDGFA, were included as technical controls. Mann-Whitney was used for comparisons between the protected animals and the infected animals.