Jennifer J. Lhost

Mauritian Cynomolgus Macaques Share Two Exceptionally Common Major Histocompatibility Complex Class I Alleles That Restrict Simian Immunodeficiency Virus-Specific CD8+ T Cells

ABSTRACT Vaccines that elicit CD8+ T-cell responses are routinely tested for immunogenicity in nonhuman primates before advancement to clinical trials. Unfortunately, the magnitude and specificity of vaccine-elicited T-cell responses are variable in currently utilized nonhuman primate populations, owing to heterogeneity in major histocompatibility (MHC) class I genetics. We recently showed that Mauritian cynomolgus macaques (MCM) have unusually simple MHC genetics, with three common haplotypes encoding a shared pair of MHC class IA alleles, Mafa-A*25 and Mafa-A*29. Based on haplotype frequency, we hypothesized that CD8+ T-cell responses restricted by these MHC class I alleles would be detected in nearly all MCM. We examine here the frequency and functionality of these two alleles, showing that 88% of MCM express Mafa-A*25 and Mafa-A*29 and that animals carrying these alleles mount three newly defined simian immunodeficiency virus-specific CD8+ T-cell responses. The epitopes recognized by each of these responses accumulated substitutions consistent with immunologic escape, suggesting these responses exert antiviral selective pressure. The demonstration that Mafa-A*25 and Mafa-A*29 restrict CD8+ T-cell responses that are shared among nearly all MCM indicates that these animals are an advantageous nonhuman primate model for comparing the immunogenicity of vaccines that elicit CD8+ T-cell responses.

MHC Heterozygote Advantage in Simian Immunodeficiency Virus–Infected Mauritian Cynomolgus Macaques

This manuscript demonstrates unambiguous major histocompatibility complex heterozygote advantage in macaque monkeys infected with the same strain of simian immunodeficiency virus, suggesting that a prophylactic HIV vaccine should elicit a population of CD8+ T cells with broad specificity. A Broad View of HIV Some studies of HIV-infected people have suggested that HIV is better controlled when the individual’s immune response is broader, that is, when more parts of the HIV virus are recognized by T cells. Indeed, the lack of a broad immune response may explain why HIV vaccines have generally not been successful. Despite the importance of this question for vaccine design, it has been difficult to answer definitively because of diversity in HIV strain, sampling time after infection, individual genetics, and other variables. Now, O’Connor et al. use genetically defined Mauritian cynomolgus macaques to get around these issues and test whether a broader immune response does in fact lead to better disease control. The immune response to a virus is determined in part by the genetics at the HLA locus. This locus is important because variability in HLA class I genes determines the number of major histocompatibility complex (MHC) molecules generated; the number of MHC molecules then determines the number of epitopes that can be presented to immune CD8 T cells. Individuals who are heterozygotes at this locus are expected to have a broader immune response than do homozygotes because they have the potential to present a more diverse set of epitopes to immune cells. O’Connor and colleagues measured viral blood concentrations and cellular immune responses in cynomolgus macaques harboring identical MHC genetics and infected with the same strain of simian immunodeficiency virus; this enabled them to unambiguously define the relationship among MHC diversity, CD8 T cell breadth, and disease outcome. They found that the vast majority of macaques homozygous for MHC had viral loads nearly 80 times those of their heterozygote counterparts; the associated CD8 T cell responses, measured by immune assays that rely on visualization techniques, were inconsistent. Therefore, to better understand their results, the authors examined how the animals’ CD8 T cell epitopes changed with time. They found that viral sequences isolated from MHC heterozygotes collected 1 year after infection matched variants observed in each of their MHC homozygote counterparts at 1 year after infection, which suggested that the CD8 T cell responses in MHC heterozygotes were an assemblage of the responses from their MHC homozygote counterparts. These data collectively indicate that the potential breadth of the immune response determines viral replication: The broader the response, the less replication. This study builds on previous observational studies showing heterozygote advantage in HIV-infected people, and sets the stage for future studies exploring the mechanisms responsible for this immunological control of immunodeficiency viruses. Furthermore, through the use of these macaques with identical MHC genetics, vaccine candidates can be tested for their effectiveness in the presence of limited CD8 T lymphocyte diversity. The importance of a broad CD8 T lymphocyte (CD8-TL) immune response to HIV is unknown. Ex vivo measurements of immunological activity directed at a limited number of defined epitopes provide an incomplete portrait of the actual immune response. We examined viral loads in simian immunodeficiency virus (SIV)–infected major histocompatibility complex (MHC)–homozygous and MHC-heterozygous Mauritian cynomolgus macaques. Chronic viremia in MHC-homozygous macaques was 80 times that in MHC-heterozygous macaques. Virus from MHC-homozygous macaques accumulated 11 to 14 variants, consistent with escape from CD8-TL responses after 1 year of SIV infection. The pattern of mutations detected in MHC-heterozygous macaques suggests that their epitope-specific CD8-TL responses are a composite of those present in their MHC-homozygous counterparts. These results provide the clearest example of MHC heterozygote advantage among individuals infected with the same immunodeficiency virus strain, suggesting that broad recognition of multiple CD8-TL epitopes should be a key feature of HIV vaccines.

Transcriptionally Abundant Major Histocompatibility Complex Class I Alleles Are Fundamental to Nonhuman Primate Simian Immunodeficiency Virus-Specific CD8+ T Cell Responses

ABSTRACT Simian immunodeficiency virus (SIV)-infected macaques are the preferred animal model for human immunodeficiency virus (HIV) vaccines that elicit CD8+ T cell responses. Unlike humans, whose CD8+ T cell responses are restricted by a maximum of six HLA class I alleles, macaques express up to 20 distinct major histocompatibility complex class I (MHC-I) sequences. Interestingly, only a subset of macaque MHC-I sequences are transcriptionally abundant in peripheral blood lymphocytes. We hypothesized that highly transcribed MHC-I sequences are principally responsible for restricting SIV-specific CD8+ T cell responses. To examine this hypothesis, we measured SIV-specific CD8+ T cell responses in MHC-I homozygous Mauritian cynomolgus macaques. Each of eight CD8+ T cell responses defined by full-proteome gamma interferon (IFN-γ) enzyme-linked immunospot (ELISPOT) assay were restricted by four of the five transcripts that are transcriptionally abundant (>1% of total MHC-I transcripts in peripheral blood lymphocytes). The five transcriptionally rare transcripts shared by these animals did not restrict any detectable CD8+ T cell responses. Further, seven CD8+ T cell responses were defined by identifying peptide binding motifs of the three most frequent MHC-I transcripts on the M3 haplotype. Combined, these results suggest that transcriptionally abundant MHC-I transcripts are principally responsible for restricting SIV-specific CD8+ T cell responses. Thus, only a subset of the thousands of known MHC-I alleles in macaques should be prioritized for CD8+ T cell epitope characterization.

Extralymphoid CD8 + T cells resident in tissue from simian immunodeficiency virus SIVmac239△nef-vaccinated macaques suppress SIVmac239 replication ex vivo

ABSTRACT Live-attenuated vaccination with simian immunodeficiency virus (SIV) SIVmac239Δnef is the most successful vaccine product tested to date in macaques. However, the mechanisms that explain the efficacy of this vaccine remain largely unknown. We utilized an ex vivo viral suppression assay to assess the quality of the immune response in SIVmac239Δnef-immunized animals. Using major histocompatibility complex-matched Mauritian cynomolgus macaques, we did not detect SIV-specific functional immune responses in the blood by gamma interferon (IFN-γ) enzyme-linked immunospot assay at select time points; however, we found that lung CD8+ T cells, unlike blood CD8+ T cells, effectively suppress virus replication by up to 80%. These results suggest that SIVmac239Δnef may be an effective vaccine because it elicits functional immunity at mucosal sites. Moreover, these results underscore the limitations of relying on immunological measurements from peripheral blood lymphocytes in studies of protective immunity to HIV/SIV.

Differential MHC class I expression in distinct leukocyte subsets

BackgroundMHC class I proteins are partly responsible for shaping the magnitude and focus of the adaptive cellular immune response. In humans, conventional wisdom suggests that the HLA-A, -B, and -C alleles are equally expressed on the majority of cell types. While we currently have a thorough understanding of how total MHC class I expression varies in different tissues, it has been difficult to examine expression of single MHC class I alleles due to the homogeneity of MHC class I sequences. It is unclear how cDNA species are expressed in distinct cell subsets in humans and particularly in macaques which transcribe upwards of 20 distinct MHC class I alleles at variable levels.ResultsWe examined MHC gene expression in human and macaque leukocyte subsets. In humans, while we detected overall differences in locus transcription, we found that transcription of MHC class I genes was consistent across the leukocyte subsets we studied with only small differences detected. In contrast, transcription of certain MHC cDNA species in macaques varied dramatically by up to 45% between different subsets. Although the Mafa-B*134:02 RNA is virtually undetectable in CD4+ T cells, it represents over 45% of class I transcripts in CD14+ monocytes. We observed parallel MHC transcription differences in rhesus macaques. Finally, we analyzed expression of select MHC proteins at the cell surface using fluorescent peptides. This technique confirmed results from the transcriptional analysis and demonstrated that other MHC proteins, known to restrict SIV-specific responses, are also differentially expressed among distinct leukocyte subsets.ConclusionsWe assessed MHC class I transcription and expression in human and macaque leukocyte subsets. Until now, it has been difficult to examine MHC class I allele expression due to the similarity of MHC class I sequences. Using two novel techniques we showed that expression varies among distinct leukocyte subsets of macaques but does not vary dramatically in the human cell subsets we examined. These findings suggest pathogen tropism may have a profound impact on the shape and focus of the MHC class I restricted CD8+ T cell response in macaques.

Integrin α4β7 Is Downregulated on the Surfaces of Simian Immunodeficiency Virus SIVmac239-Infected Cells

ABSTRACT Simian immunodeficiency virus (SIV) and human immunodeficiency virus (HIV) infection results in an early and enduring depletion of intestinal CD4+ T cells. SIV and HIV bind integrin α4β7, thereby facilitating infection of lymphocytes that home to the gut-associated lymphoid tissue (GALT). Using an ex vivo flow cytometry assay, we found that SIVmac239-infected cells expressed significantly lower levels of integrin α4β7 than did uninfected cells. This finding suggested a potential viral effect on integrin α4β7 expression. Using an in vitro model, we confirmed that integrin α4β7 was downregulated on the surfaces of SIVmac239-infected cells. Further, modulation of integrin α4β7 was dependent on de novo synthesis of viral proteins, but neither cell death, the release of a soluble factor, nor a change in activation state was involved. Downregulation of integrin α4β7 may have an unappreciated role in the CD4 depletion of the mucosal-associated lymphoid compartments, susceptibility to superinfection, and/or immune evasion.

Ex Vivo SIV-Specific CD8 T Cell Responses in Heterozygous Animals Are Primarily Directed against Peptides Presented by a Single MHC Haplotype

The presence of certain MHC class I alleles is correlated with remarkable control of HIV and SIV, indicating that specific CD8 T cell responses can effectively reduce viral replication. It remains unclear whether epitopic breadth is an important feature of this control. Previous studies have suggested that individuals heterozygous at the MHC class I loci survive longer and/or progress more slowly than those who are homozygous at these loci, perhaps due to increased breadth of the CD8 T cell response. We used Mauritian cynomolgus macaques with defined MHC haplotypes and viral inhibition assays to directly compare CD8 T cell efficacy in MHC-heterozygous and homozygous individuals. Surprisingly, we found that cells from heterozygotes suppress viral replication most effectively on target cells from animals homozygous for only one of two potential haplotypes. The same heterozygous effector cells did not effectively inhibit viral replication as effectively on the target cells homozygous for the other haplotype. These results indicate that the greater potential breadth of CD8 T cell responses present in heterozygous animals does not necessarily lead to greater antiviral efficacy and suggest that SIV-specific CD8 T cell responses in heterozygous animals have a skewed focus toward epitopes restricted by a single haplotype.

PRED mafa : a system for prediction of peptide binding to several MHC class I molecules in cynomolgus macaques

PREDmafa is a computational system for prediction of peptide binding to three transcriptionally abundant major histocompatibility complex (MHC) class I alleles of Mauritian cynomolgus macaque, an important animal model for the study of human disease. The prediction system utilizes quantitative matrices, which were validated using experimentally determined binders and supported by in vivo studies. We developed 8-mer and 9-mer prediction matrices for Mafa-A1*063:02, 9-mer, 10-mer, and 11-mer prediction matrices for Mafa-B*011:01, and a 9-mer prediction matrix for Mafa-B*075:01. To our knowledge, PREDmafa is the first online computational system for predicting peptides that bind Mafa molecules. It is available at http://cvc.dfci.harvard.edu/mafa/.

P16-46. CD8+ T cells from nonlymphoid tissues exhibit superior control of SIV replication.

Background CD8+ T cells are vital to controlling HIV replication in humans and SIV infection in nonhuman primates. However, several studies provided conflicting evidence about the role of CD8+ T cells in effective or complete control of viral replication. The vast majority of these studies use lymphocytes isolated from blood in assays that provide indirect measures of CD8+ T cell function including ELISpot or ICS. Here we assess lymphocyte function using ex vivo viral suppression assays that directly test the ability of lymphocytes to suppress viral replication.