Protective HLA Class I Alleles That Restrict Acute-Phase CD8+ T-Cell Responses Are Associated with Viral Escape Mutations Located in Highly Conserved Regions of Human Immunodeficiency Virus Type 1

The control of human immunodeficiency virus type 1 (HIV-1) associated with particular HLA class I alleles suggests that some CD8⁺ T-cell responses may be more effective than others at containing HIV-1. Unfortunately, substantial diversities in the breadth, magnitude, and function of these responses have impaired our ability to identify responses most critical to this control. It has been proposed that CD8 responses targeting conserved regions of the virus may be particularly effective, since the development of cytotoxic T-lymphocyte (CTL) escape mutations in these regions may significantly impair viral replication. To address this hypothesis at the population level, we derived near-full-length viral genomes from 98 chronically infected individuals and identified a total of 76 HLA class I-associated mutations across the genome, reflective of CD8 responses capable of selecting for sequence evolution. The majority of HLA-associated mutations were found in p24 Gag, Pol, and Nef. Reversion of HLA-associated mutations in the absence of the selecting HLA allele was also commonly observed, suggesting an impact of most CTL escape mutations on viral replication. Although no correlations were observed between the number or location of HLA-associated mutations and protective HLA alleles, limiting the analysis to mutations selected by acute-phase immunodominant responses revealed a strong positive correlation between mutations at conserved residues and protective HLA alleles. These data suggest that control of HIV-1 may be associated with acute-phase CD8 responses capable of selecting for viral escape mutations in highly conserved regions of the virus, supporting the inclusion of these regions in the design of an effective vaccine.Despite substantial advances in antiretroviral therapies, development of an effective human immunodeficiency virus type 1 (HIV-1) vaccine remains a critical goal (6, 39, 82). Unfortunately, current vaccine efforts have failed to reduce infection rates in humans (9, 75) and have only achieved modest decreases in viral loads in the simian immunodeficiency virus (SIV)/SHIV macaque model (21, 44, 81). A majority of these vaccine approaches have focused on inducing T-cell responses, utilizing large regions of the virus in an attempt to induce a broad array of immune responses (6, 34, 44, 81). While it is well established that CD8⁺ T-cell responses play a critical role in the containment of HIV-1 (45, 49, 67), supported in part by the strong association of particular HLA class I alleles with control of HIV (20, 33, 42, 61), it remains unclear which particular CD8⁺ T-cell responses are best able to control the virus and thus should be preferentially targeted by a vaccine. Studies comparing the magnitude, breadth, and function of CD8⁺ T-cell responses in subjects exhibiting either enhanced or poor control of HIV-1 have yielded few clues as to the specific factors associated with an effective CD8⁺ T-cell response (2, 28, 64, 67). Various differences in the functional capacity of T-cell responses have been observed in long-term nonprogressors (1, 26, 64), although it is possible that these differences may be reflective of an intact immune response, as opposed to having had directly enhanced immune control. As such, efforts are needed to identify factors or phenotypes associated with protective CD8⁺ T-cell responses in order to enable vaccines to induce the most effective responses.Recent studies have begun to suggest that the specificity of the CD8⁺ T-cell response, or the targeting of specific regions of the virus, may be associated with control of HIV-1. Preferential targeting of Gag, a structurally conserved viral protein responsible for multiple functions, has been associated with lower viral loads (25, 43, 56, 60, 77, 85). Furthermore, Kiepiela et al. (43) recently illustrated in a large cohort of 578 clade C-infected subjects that Gag-specific responses were associated with lowered viremia, in contrast to Env-specific responses, which were associated with higher viremia. These data are in line with previous observations that many of the major histocompatibility complex (MHC) class I alleles most strongly associated with control of HIV-1 and SIV, namely, HLA-B57, HLA-B27, and Mamu-A*01, restrict immunodominant CD8⁺ T-cell responses against the Gag protein (8, 10, 24, 63, 68, 83). However, other alleles associated with slower disease progression, such as HLA-B51 in humans and Mamu-B08 and B-17 in the rhesus macaque, do not immunodominantly target Gag, suggesting that targeting of some other regions of the virus may also be capable of eliciting control (8, 52-54). In addition, recent studies investigating the pattern of HIV-1-specific CD8⁺ T-cell responses during acute infection reveal that only a small subset of CD8⁺ T-cell responses restricted by any given HLA allele arise during acute infection and that there exist clear immunodominance patterns to these responses (8, 77, 85). Since control of HIV-1 is likely to be established or lost during the first few weeks of infection, these data suggest that potentially only a few key CD8⁺ T-cell responses may be needed to adequately establish early control of HIV-1.One of the major factors limiting the effectiveness of CD8⁺ T-cell responses is the propensity for HIV-1 to evade these responses through sequence evolution or viral escape (3, 13, 66). Even single point mutations within a targeted CD8 epitope can effectively abrogate recognition by either the HLA allele or the T-cell receptor. However, recent studies have begun to highlight that many sequence polymorphisms will revert to more common consensus residues upon transmission of HIV-1 to a new host, including many cytotoxic T-lymphocyte (CTL) escape mutations (4, 30, 33, 48, 50). Notably, the more rapidly reverting mutations have been observed to preferentially occur at conserved residues, indicating that structurally conserved regions of the virus may be particularly refractory to sequence changes (50). In support of these data, many CTL escape mutations have now been observed to directly impair viral replication (15, 23, 55, 74), in particular those known to either revert or require the presence of secondary compensatory mutations (15, 23, 73, 74). Taken together, these data suggest that, whereas CTL escape mutations provide a benefit to the virus to enable the evasion of host immune pressures, some of these mutations may come at a substantial cost to viral replication. These data may also imply that the association between Gag-specific responses and control of HIV-1 may be due to the targeting of highly conserved regions of the virus that are difficult to evade through sequence evolution.The propensity by which HIV-1 escapes CD8⁺ T-cell responses, and the reproducibility by which mutations arise at precise residues in targeted CD8 epitopes (3, 48), also enables the utilization of sequence data to predict which responses may be most capable of exerting immune selection pressure on the virus. Studies in HIV-1, SIV, and hepatitis C virus (16, 58, 65, 78) are now rapidly identifying immune-driven CTL escape mutations across these highly variable pathogens at the population level by correlating sequence polymorphisms in these viruses with the expression of particular HLA alleles. We provide here an analysis of HLA-associated mutations across the entire HIV-1 genome using a set of sequences derived from clade B chronically infected individuals. Through full-length viral genome coverage, these data provide an unbiased analysis of the location of these mutations and suggest that the control of HIV-1 by particular HLA alleles correlates with their ability to preferentially restrict early CD8⁺ T-cell responses capable of selecting for viral escape mutations at highly conserved residues of the virus. These data provide support for the inclusion of specific highly conserved regions of HIV-1 into vaccine antigens.     

Variants of Simian Virus 40-Transformed 3T3 Cells That Are Resistant to Concanavalin A

By treating populations of simian virus 40 (SV40)-transformed 3T3 cells with concanavalin A, variants have been isolated which are resistant to the killing action of the lectin. The variants (i) resemble 3T3 cells morphologically and in some of their growth characteristics; (ii) are not agglutinated by high concentrations of concanavalin A or wheat germ agglutinin, but can be rendered agglutinable by treatment with low concentrations of trypsin; (iii) bind the same number of concanavalin A molecules as 3T3 or SV3T3 cells; (iv) cannot be transformed by SV40 and are resistant to focus formation after infection with murine sarcoma virus; (v) contain SV40-specific T antigen and RNA and; (vi) yield wild-type SV40 virus after heterokaryon formation with BS-C-1 cells.     

Inhibition of Simian Immunodeficiency Virus (SIV) Replication by CD8+ T Lymphocytes from Macaques Immunized with Live Attenuated SIV

Characterization of immune responses induced by live attenuated simian immunodeficiency virus (SIV) strains may yield clues to the nature of protective immunity induced by this vaccine approach. We investigated the ability of CD8⁺ T lymphocytes from rhesus macaques immunized with the live, attenuated SIV strain SIVmac239Δnef or SIVmac239Δ3 to inhibit SIV replication. CD8⁺ T lymphocytes from immunized animals were able to potently suppress SIV replication in autologous SIV-infected CD4⁺ T cells. Suppression of SIV replication by unstimulated CD8⁺ T cells required direct contact and was major histocompatibility complex (MHC) restricted. However, CD3-stimulated CD8⁺ T cells produced soluble factors that inhibited SIV replication in an MHC-unrestricted fashion as much as 30-fold. Supernatants from stimulated CD8⁺ T cells were also able to inhibit replication of both CCR5- and CXCR4-dependent human immunodeficiency virus type 1 (HIV-1) strains. Stimulation of CD8⁺ cells with cognate cytotoxic T-lymphocyte epitopes also induced secretion of soluble factors able to inhibit SIV replication. Production of RANTES, macrophage inhibitory protein 1α (MIP-1α), or MIP-1β from stimulated CD8⁺ T cells of vaccinated animals was almost 10-fold higher than that from stimulated CD8⁺ T cells of control animals. However, addition of antibodies that neutralize these β-chemokines, either alone or in combination, only partly blocked inhibition of SIV and HIV replication by soluble factors produced by stimulated CD8⁺ T cells. Our results indicate that inhibition of SIV replication by CD8⁺ T cells from animals immunized with live attenuated SIV strains involves both MHC-restricted and -unrestricted mechanisms and that MHC-unrestricted inhibition of SIV replication is due principally to soluble factors other than RANTES, MIP-1α, and MIP-1β.     

Control of Simian Immunodeficiency Virus Replication by Vaccine-Induced Gag- and Vif-Specific CD8+ T Cells

For development of an effective T cell-based AIDS vaccine, it is critical to define the antigens that elicit the most potent responses. Recent studies have suggested that Gag-specific and possibly Vif/Nef-specific CD8⁺ T cells can be important in control of the AIDS virus. Here, we tested whether induction of these CD8⁺ T cells by prophylactic vaccination can result in control of simian immunodeficiency virus (SIV) replication in Burmese rhesus macaques sharing the major histocompatibility complex class I (MHC-I) haplotype 90-010-Ie associated with dominant Nef-specific CD8⁺ T-cell responses. In the first group vaccinated with Gag-expressing vectors (n = 5 animals), three animals that showed efficient Gag-specific CD8⁺ T-cell responses in the acute phase postchallenge controlled SIV replication. In the second group vaccinated with Vif- and Nef-expressing vectors (n = 6 animals), three animals that elicited Vif-specific CD8⁺ T-cell responses in the acute phase showed SIV control, whereas the remaining three with Nef-specific but not Vif-specific CD8⁺ T-cell responses failed to control SIV replication. Analysis of 18 animals, consisting of seven unvaccinated noncontrollers and the 11 vaccinees described above, revealed that the sum of Gag- and Vif-specific CD8⁺ T-cell frequencies in the acute phase was inversely correlated with plasma viral loads in the chronic phase. Our results suggest that replication of the AIDS virus can be controlled by vaccine-induced subdominant Gag/Vif epitope-specific CD8⁺ T cells, providing a rationale for the induction of Gag- and/or Vif-specific CD8⁺ T-cell responses by prophylactic AIDS vaccines.     

NK and CD4+ T Cell Cooperative Immune Responses Correlate with Control of Disease in a Macaque Simian Immunodeficiency Virus Infection Model

Control of infectious disease may be accomplished by successful vaccination or by complex immunologic and genetic factors favoring Ag-specific multicellular immune responses. Using a rhesus macaque model, we evaluated Ag-specific T cell-dependent NK cell immune responses in SIV-infected macaques, designated "controlling" or "noncontrolling" based on long-term chronic viremia levels, to determine whether NK cell effector functions contribute to control of SIV infection. We observed that Gag stimulation of macaque PBMCs induced subset-specific NK cell responses in SIV-controlling but not SIV-noncontrolling animals, as well as that circulatory NK cell responses were dependent on Ag-specific IL-2 production by CD4(+) central memory T cells. NK cell activation was blocked by anti-IL-2-neutralizing Ab and by CD4(+) T cell depletion, which abrogated the Gag-specific responses. Among tissue-resident cells, splenic and circulatory NK cells displayed similar activation profiles, whereas liver and mucosal NK cells displayed a decreased activation profile, similar in SIV-controlling and -noncontrolling macaques. Lack of T cell-dependent NK cell function was rescued in SIV-noncontrolling macaques through drug-mediated control of viremia. Our results indicate that control of disease progression in SIV-controlling macaques is associated with cooperation between Ag-specific CD4(+) T cells and NK cell effector function, which highlight the importance of such cell-to-cell cooperativity in adaptive immunity and suggest that this interaction should be further investigated in HIV vaccine development and other prophylactic vaccine approaches.     

Temporal Analyses of Virus Replication, Immune Responses, and Efficacy in Rhesus Macaques Immunized with a Live, Attenuated Simian Immunodeficiency Virus Vaccine

Despite evidence that live, attenuated simian immunodeficiency virus (SIV) vaccines can elicit potent protection against pathogenic SIV infection, detailed information on the replication kinetics of attenuated SIV in vivo is lacking. In this study, we measured SIV RNA in the plasma of 16 adult rhesus macaques immunized with a live, attenuated strain of SIV (SIVmac239Δnef). To evaluate the relationship between replication of the vaccine virus and the onset of protection, four animals per group were challenged with pathogenic SIVmac251 at either 5, 10, 15, or 25 weeks after immunization. SIVmac239Δnef replicated efficiently in the immunized macaques in the first few weeks after inoculation. SIV RNA was detected in the plasma of all animals by day 7 after inoculation, and peak levels of viremia (10⁵ to 10⁷ RNA copies/ml) occurred by 7 to 12 days. Following challenge, SIVmac251 was detected in all of the four animals challenged at 5 weeks, in two of four challenged at 10 weeks, in none of four challenged at 15 weeks, and one of four challenged at 25 weeks. One animal immunized with SIVmac239Δnef and challenged at 10 weeks had evidence of disease progression in the absence of detectable SIVmac251. Although complete protection was not achieved at 5 weeks, a transient reduction in viremia (approximately 100-fold) occurred in the immunized macaques early after challenge compared to the nonimmunized controls. Two weeks after challenge, SIV RNA was also reduced in the lymph nodes of all immunized macaques compared with control animals. Taken together, these results indicate that host responses capable of reducing the viral load in plasma and lymph nodes were induced as early as 5 weeks after immunization with SIVmac239Δnef, while more potent protection developed between 10 and 15 weeks. In further experiments, we found that resistance to SIVmac251 infection did not correlate with the presence of antibodies to SIV gp130 and p27 antigens and was achieved in the absence of significant neutralizing activity against the primary SIVmac251 challenge stock.     

Dynamics of Cytokine/Chemokine Responses in Intestinal CD4+ and CD8+ T Cells during Acute Simian Immunodeficiency Virus Infection

Loss of intestinal CD4⁺ T cells was associated with decreased production of several T-helper 1 (T_H1) and T_H2 cytokines and increased production of interleukin 17 (IL-17), gamma interferon (IFN-γ), CCL4, and granulocyte-macrophage colony-stimulating factor (GM-CSF) by CD8⁺ T cells 21 days after simian immunodeficiency virus (SIV) infection in rhesus macaques. Shifting of mucosal T_H1 to T_H2 or T-cytotoxic 1 (T_C1) to T_C2 cytokine profiles was not evident. Additionally, both CD4⁺ and CD8⁺ T cells showed upregulation of macrophage migration inhibition factor (MIF) and basic fibroblast growth factor (FGF-basic) cytokines that have been linked to HIV disease progression.     

Viral Escape Mutant Epitope Maintains TCR Affinity for Antigen yet Curtails CD8 T Cell Responses

T cells have the remarkable ability to recognize antigen with great specificity and in turn mount an appropriate and robust immune response. Critical to this process is the initial T cell antigen recognition and subsequent signal transduction events. This antigen recognition can be modulated at the site of TCR interaction with peptide:major histocompatibility (pMHC) or peptide interaction with the MHC molecule. Both events could have a range of effects on T cell fate. Though responses to antigens that bind sub-optimally to TCR, known as altered peptide ligands (APL), have been studied extensively, the impact of disrupting antigen binding to MHC has been highlighted to a lesser extent and is usually considered to result in complete loss of epitope recognition. Here we present a model of viral evasion from CD8 T cell immuno-surveillance by a lymphocytic choriomeningitis virus (LCMV) escape mutant with an epitope for which TCR affinity for pMHC remains high but where the antigenic peptide binds sub optimally to MHC. Despite high TCR affinity for variant epitope, levels of interferon regulatory factor-4 (IRF4) are not sustained in response to the variant indicating differences in perceived TCR signal strength. The CD8+ T cell response to the variant epitope is characterized by early proliferation and up-regulation of activation markers. Interestingly, this response is not maintained and is characterized by a lack in IL-2 and IFNγ production, increased apoptosis and an abrogated glycolytic response. We show that disrupting the stability of peptide in MHC can effectively disrupt TCR signal strength despite unchanged affinity for TCR and can significantly impact the CD8+ T cell response to a viral escape mutant.     

Tertiary Mutations Stabilize CD8+ T Lymphocyte Escape-Associated Compensatory Mutations following Transmission of Simian Immunodeficiency Virus

Compensatory mutations offset fitness defects resulting from CD8⁺ T lymphocyte (CD8_TL)-mediated escape, but their impact on viral evolution following transmission to naive hosts remains unclear. Here, we investigated the reversion kinetics of Gag_181–189CM9 CD8_TL escape-associated compensatory mutations in simian immunodeficiency virus (SIV)-infected macaques. Preexisting compensatory mutations did not result in acute-phase escape of the SIVmac239 CD8TL epitope Gag181-189CM9 and instead required a tertiary mutation for stabilization in the absence of Gag_181–189CM9 escape mutations. Therefore, transmitted compensatory mutations do not necessarily predict rapid CD8_TL escape.     

CD4+ T Cells Support Production of Simian Immunodeficiency Virus Env Antibodies That Enforce CD4-Dependent Entry and Shape Tropism In Vivo

CD4⁺ T cells rather than macrophages are the principal cells infected by human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus (SIV) in vivo. Macrophage tropism has been linked to the ability to enter cells through CCR5 in conjunction with limiting CD4 levels, which are much lower on macrophages than on T cells. We recently reported that rhesus macaques (RM) experimentally depleted of CD4⁺ T cells before SIV infection exhibit extensive macrophage infection as well as high chronic viral loads and rapid progression to AIDS. Here we show that early-time-point and control Envs were strictly CD4 dependent but that, by day 42 postinfection, plasma virus of CD4⁺ T cell-depleted RM was dominated by Envs that mediate efficient infection using RM CCR5 independently of CD4. Early-time-point and control RM Envs were resistant to neutralization by SIV-positive (SIV⁺) plasma but became sensitive if preincubated with sCD4. In contrast, CD4-independent Envs were highly sensitive to SIV⁺ plasma neutralization. However, plasma from SIV-infected CD4⁺ T cell-depleted animals lacked this CD4-inducible neutralizing activity and failed to neutralize any Envs regardless of sCD4 pre-exposure status. Enhanced sensitivity of CD4-independent Envs from day 42 CD4⁺ T cell-depleted RM was also seen with monoclonal antibodies that target both known CD4-inducible and other Env epitopes. CD4 independence and neutralization sensitivity were both conferred by Env amino acid changes E84K and D470N that arose independently in multiple animals, with the latter introducing a potential N-linked glycosylation site within a predicted CD4-binding pocket of gp120. Thus, the absence of CD4 T cells results in failure to produce antibodies that neutralize CD4-independent Envs and CD4-pretriggered control Envs. In the absence of this constraint and with a relative paucity of CD4⁺ target cells, widespread macrophage infection occurs in vivo accompanied by emergence of variants carrying structural changes that enable entry independently of CD4.     

Recombinant Yellow Fever Vaccine Virus 17D Expressing Simian Immunodeficiency Virus SIVmac239 Gag Induces SIV-Specific CD8+ T-Cell Responses in Rhesus Macaques

Here we describe a novel vaccine vector for expressing human immunodeficiency virus (HIV) antigens. We show that recombinant attenuated yellow fever vaccine virus 17D expressing simian immunodeficiency virus SIVmac239 Gag sequences can be used as a vector to generate SIV-specific CD8⁺ T-cell responses in the rhesus macaque. Priming with recombinant BCG expressing SIV antigens increased the frequency of these SIV-specific CD8⁺ T-cell responses after recombinant YF17D boosting. These recombinant YF17D-induced SIV-specific CD8⁺ T cells secreted several cytokines, were largely effector memory T cells, and suppressed viral replication in CD4⁺ T cells.None of the vaccine regimens tested in human immunodeficiency virus (HIV) vaccine efficacy trials to date have either reduced the rate of HIV infection or reduced the level of HIV replication. Structural features and the enormous variability of the envelope glycoprotein have frustrated efforts to induce broadly reactive neutralizing antibodies against HIV (10). Investigators have therefore focused their attention on T-cell-based vaccines (40). Simian immunodeficiency virus (SIV) challenge of rhesus macaques vaccinated with T-cell-based vaccines has shown that it is possible to control virus replication after SIV infection (22, 41, 42). The recent STEP trial of a recombinant Ad5-vectored vaccine was widely seen as an important test of this concept (http://www.hvtn.org/media/pr/step111307.html) (9, 25). Unfortunately, vaccinees became infected at higher rates than the controls (9). While it is still not clear what caused the enhanced infection rate in the vaccinated group, future Ad5-based human vaccine trials may be difficult to justify. We therefore need to develop new vaccine vectors for delivering SIV and HIV genes. Several other viral vectors currently under consideration include nonreplicating adenovirus (Ad)-based vectors (1, 21, 22), Venezuelan equine encephalitis (VEE) virus (12, 20), adeno-associated virus (AAV) (19), modified vaccinia virus Ankara (MVA) (3, 4, 13, 15, 18, 38), NYVAC (6), cytomegalovirus (CMV) (16), and replicating Ad (30). However, only a few of these have shown promise in monkey trials using rigorous SIV challenges.We explored whether the small (11-kb) yellow fever vaccine flavivirus 17D (YF17D) might be a suitable vector for HIV vaccines. The YF17D vaccine is inexpensive, production and quality control protocols already exist, and it disseminates widely in vivo after a single dose (27). Importantly, methods for the manipulation of the YF17D genome were recently established (7, 8, 24, 28). This effective vaccine has been safely used on >400 million people in the last 70 years (27). Additionally, the YF17D strain elicits robust CD8⁺ T-cell responses in humans (26). Chimeric YF17D is presently being developed as a vaccine for other flaviviruses, such as Japanese encephalitis virus (28), dengue virus (14), and West Nile virus (29). Inserts expressing a malaria B-cell epitope have been engineered into the E protein of YF17D (7). In murine models, recombinant YF17D viruses have generated robust and specific responses to engineered antigens inserted between the 2B and NS3 proteins in vivo (24, 35).We first used the YF17D vaccine virus to infect four Mamu-A*01-positive macaques. The vaccine virus replicated in these four animals and induced neutralizing antibodies in all four macaques by 2 weeks postvaccination (Fig. 1A and B). To monitor the CD8⁺ T-cell immune response against YF17D, we scanned its proteome for peptides that might bind to Mamu-A*01 using the major histocompatibility complex (MHC) pathway algorithm (31). We synthesized the 52 YF17D-derived peptides most likely to bind to Mamu-A*01 based on their predicted affinity for this MHC class I molecule. We then used a gamma interferon (IFN-γ) enzyme-linked immunospot (ELISPOT) assay to screen these peptides in YF17D-immunized animals at several time points after vaccination and discovered that four Mamu-A*01-binding peptides, LTPVTMAEV (LV9_1285-1293), VSPGNGWMI (VI9_3250-3258), MSPKGISRM (MM9_2179-2187), and TTPFGQQRVF (TF10_2853-2862), were recognized in vivo (Fig. ​(Fig.1C).1C). Using a previously reported protocol (26), we also observed CD8⁺ T-cell activation in all four animals (Fig. 1D and E). Thus, as was observed previously, the YF17D vaccine virus replicates in Indian rhesus monkeys (36) and induces neutralizing antibodies, yellow fever 17D-specific Mamu-A*01-restricted CD8⁺ T-cell responses, and CD8⁺ T-cell activation.Open in a separate windowFIG. 1.YF17D replicates and induces neutralizing antibodies, virus-specific CD8⁺ T cells, and the activation of CD8⁺ T cells in rhesus macaques. (A) Replication of YF17D during the first 10 days after vaccination with two different doses, as measured by quantitative PCR (Q-PCR) using the following primers: forward primer YF-17D 10188 (5′-GCGGATCACTGATTGGAATGAC-3′), reverse primer YF-17D 10264 (5′-CGTTCGGATACGATGGATGACTA-3′), and probe 6-carboxyfluorescein (6Fam)-5′-AATAGGGCCACCTGGGCCTCCC-3′-6-carboxytetramethylrhodamine (TamraQ). (B) Titer of neutralizing antibodies determined at 2 and 5 weeks after YF17D vaccination. (C) Fresh PBMC from vaccinees (100,000 cells/well) were used in IFN-γ ELISPOT assays (41) to assess T-cell responses against YF17D. We used 4 epitopes (LTPVTMAEV [LV9_1285-1293], VSPGNGWMI [VI9_3250-3258], MSPKGISRM [MM9_2179-2187], and TTPFGQQRVF [TF10_2853-2862]) predicted to bind to Mamu-A*01 as defined by the MHC pathway algorithm (31). All IFN-γ ELISPOT results were considered positive if they were ≥50 SFC/10⁶ PBMC and ≥2 standard deviations over the background. (D) Identification of activated CD8⁺ T cells after vaccination with YF17D based on the expression of the proliferation and proapoptotic markers Ki-67 and Bcl-2, respectively (26). We stained whole blood cells with antibodies against CD3 and CD8. We then permeabilized and subsequently labeled these cells with Bcl-2- and Ki-67-specific antibodies. The flow graphs were gated on CD3⁺ CD8⁺ lymphocytes. (E) Expression kinetics of Ki-67 and Bcl-2 in CD8⁺ T cells after vaccination with YF17D.We next engineered the YF17D vaccine virus to express amino acids 45 to 269 of SIVmac239 Gag (rYF17D/SIVGag_45-269) by inserting a yellow fever codon-optimized sequence between the genes encoding the viral proteins E and NS1. This recombinant virus replicated and induced neutralizing antibodies in mice (data not shown). We then tested the rYF17D/SIVGag_45-269 construct in six Mamu-A*01-positive Indian rhesus macaques. We found evidence for the viral replication of rYF17D/SIVGag_45-269 for five of these six macaques (Fig. ​(Fig.2A).2A). However, neutralizing antibodies were evident for all six animals at 2 weeks postvaccination (Fig. ​(Fig.2B).2B). Furthermore, all animals developed SIV-specific CD8⁺ T cells after a single immunization with rYF17D/SIVGag_45-269 (Fig. ​(Fig.2C).2C). To test whether a second dose of this vaccine could boost virus-specific T-cell responses, we administered rYF17D/SIVGag_45-269 (2.0 × 10⁵ PFU) to four macaques on day 28 after the first immunization and monitored cellular immune responses. With the exception of animal r04091, the rYF17D/SIVGag_45-269 boost did not increase the frequency of the vaccine-induced T-cell responses. This recombinant vaccine virus also induced CD8⁺ T-cell activation in the majority of the vaccinated animals (Fig. ​(Fig.2D2D).Open in a separate windowFIG. 2.rYF17D/SIVGag_45-269 replicates and induces neutralizing antibodies, virus-specific CD8⁺ T cells, and the activation of CD8⁺ T cells in rhesus macaques. (A) Replication of rYF17D/SIVGag_45-269 during the first 10 days after vaccination with two different doses as measured by Q-PCR using the YF17D-specific primers described in the legend of Fig. ​Fig.1.1. (B) Titer of neutralizing antibodies determined at 2 and 5 weeks after rYF17D/SIVGag_45-269 vaccination. The low levels of neutralization for animal r02013 were observed in three separate assays. (C) Fresh PBMC from vaccinees (100,000 cells/well) were used in IFN-γ ELISPOT assays to assess T-cell responses against the YF17D vector (red) and the SIV Gag(45-269) insert (black) at several time points postvaccination. We measured YF17D-specific responses using the same epitopes described in the legend of Fig. ​Fig.1.1. For SIV Gag-specific responses, we used 6 pools of 15-mers overlapping by 11 amino acids spanning the entire length of the SIVmac239 Gag insert. In addition, we measured Mamu-A*01-restricted responses against the dominant Gag_181-189CM9 and subdominant Gag_254-262QI9 epitopes. Four animals received a second dose of rYF17D/SIVGag_45-269 on day 28 after the first vaccination (dashed line). (D) Expression kinetics of Ki-67 and Bcl-2 in CD8⁺ T cells after vaccination with rYF17D/SIVGag_45-269. This assay was performed as described in the legend of Fig. ​Fig.11.We could not detect differences in vaccine-induced immune responses between the group of animals vaccinated with YF17D and the group vaccinated with rYF17D/SIVGag_45-269. There was, however, considerable animal-to-animal variability. Animal r02034, which was vaccinated with YF17D, exhibited massive CD8⁺ T-cell activation (a peak of 35% at day 14) (Fig. ​(Fig.1E),1E), which was probably induced by the high levels of viral replication (16,800 copies/ml at day 5) (Fig. ​(Fig.1A).1A). It was difficult to see differences between the neutralizing antibody responses induced by YF17D and those induced by rYF17D/SIVGag_45-269 (Fig. ​(Fig.1B1B and ​and2B).2B). However, neutralizing antibodies in animal r02013 decreased by 5 weeks postvaccination. It was also difficult to detect differences in the YF17D-specific CD8⁺ T-cell responses induced by these two vaccines. Peak Mamu-A*01-restricted CD8⁺ T-cell responses against YF17D ranged from barely detectable (animal r02110 at day 11) (Fig. ​(Fig.1C)1C) to 265 spot-forming cells (SFCs)/10⁶ peripheral blood mononuclear cells (PBMC) (animal r02034 at day 28) (Fig. ​(Fig.1C).1C). Similarly, three of the rYF17D/SIVGag_45-269-vaccinated animals (animals r04091, r04051, and r02013) made low-frequency CD8⁺ T-cell responses against the Mamu-A*01-bound YF17D peptides, whereas the other three animals (animals r03130, r02049, and r02042) recognized these epitopes with responses ranging from 50 to 200 SFCs/10⁶ PBMC (Fig. ​(Fig.2C).2C). For almost every rYF17D/SIVGag_45-269-vaccinated animal, the Gag_181-189CM9-specific responses (range, 50 to 750 SFCs/10⁶ PBMC) were higher than those generated against the Mamu-A*01-restricted YF17D epitopes (range, 0 to 175 SFCs/10⁶ PBMC), suggesting that the recombinant virus replicated stably in vivo (Fig. ​(Fig.2C).2C). Thus, the recombinant YF17D virus replicated and induced both virus-specific neutralizing antibodies and CD8⁺ T cells that were not demonstrably different from those induced by YF17D alone.Most viral vectors are usually more efficient after a prime with DNA or recombinant BCG (rBCG) (4, 11, 15, 18). We therefore used rYF17D/SIVGag_45-269 to boost two macaques that had been primed with rBCG expressing SIV proteins (Fig. ​(Fig.3A).3A). We detected no SIV-specific responses after either of the two priming rBCG vaccinations. Unfortunately, while the recombinant YF17D virus replicated well in animal r01056, we found evidence for only low levels of replication of rYF17D/SIVGag_45-269 on day 5 postvaccination for animal r01108 (7 copies/ml) (Fig. ​(Fig.3B).3B). Both animals, however, generated neutralizing antibodies at 2 weeks postvaccination (Fig. ​(Fig.3C).3C). Encouragingly, we detected high-frequency CD8⁺ T-cell responses in the Mamu-A*01-positive macaque (animal r01056) after boosting with rYF17D/SIVGag_45-269 (Fig. 3D to F). These responses were directed mainly against the Mamu-A*01-restricted Gag_181-189CM9 epitope, which is contained in the peptide pool Gag E (Fig. ​(Fig.3D).3D). Furthermore, the boost induced a massive activation of animal r01056''s CD8⁺ T cells, peaking at 35% at 17 days postvaccination (Fig. ​(Fig.3E).3E). Of these activated CD8⁺ T cells, approximately 10% were directed against the Gag_181-189CM9 epitope, with a frequency of 3.5% of CD8⁺ T cells (Fig. ​(Fig.3E).3E). These epitope-specific CD8⁺ T cells made IFN-γ, tumor necrosis factor alpha (TNF-α), macrophage inflammatory protein 1β (MIP-1β), and degranulated (Fig. ​(Fig.3F3F and data not shown). Thus, an rBCG prime followed by a recombinant yellow fever 17D boost induced polyfunctional antigen-specific CD8⁺ T cells.Open in a separate windowFIG. 3.rYF17D/SIVGag_45-269 vaccination induced a robust expansion of Gag-specific responses in an rBCG-primed macaque. (A) Vaccination scheme. We immunized two rhesus macaques with rBCG intradermally (i.d.) (2.0 × 10⁵ CFU), rBCG orally (10⁷ CFU), and rYF17D/SIVGag_45-269 subcutaneously (2.0 × 10⁵ PFU) at 6-month intervals. rBCG was engineered to express 18 minigenes containing sequences of Gag, Vif, Nef, Rev, and Tat from SIVmac239. (B) Replication of rYF17D/SIVGag_45-269 during the first 10 days after vaccination as measured by Q-PCR using the YF17D-specific primers described in the legend of Fig. ​Fig.1.1. (C) Titer of neutralizing antibodies determined at 2 and 5 weeks after rYF17D/SIVGag_45-269 vaccination. (D) Fresh PBMC from animal r01056 (100,000 cells/well) were used in IFN-γ ELISPOT assays to assess T-cell responses against the YF17D vector (red) and the SIV Gag(45-269) insert (black) at several time points postvaccination. (E) Kinetics of CD8⁺ T-cell activation (as described in the legend of Fig. ​Fig.1)1) and expansion of Gag_181-189CM9-specific CD8⁺ T cells in animal r01056 after vaccination with rYF17D/SIVGag_45-269. (F) Vaccination with rYF17D/SIVGag_45-269 induced robust CD8⁺ T-cell responses against Gag_181-189CM9 in r01056. CD8⁺ T-cell activation (Ki-67⁺/Bcl-2⁻) for baseline and day 13 are shown. Gag_181-189CM9-specific responses were measured by tetramer staining and intracellular cytokine staining (ICS) with antibodies against MIP-1β and IFN-γ.Vaccine-induced CD8⁺ T cells are usually central memory T cells (T_CM) or effector memory T cells (T_EM). These two subsets of CD8⁺ T cells differ in function and surface markers (23). Repeated boosting drives CD8⁺ T cells toward the T_EM subset (23). We therefore determined whether a rBCG prime followed by a rYF17D/SIVGag_45-269 boost induced T_CM or T_EM CD8⁺ T cells. Staining of PBMC obtained on day 30 postvaccination revealed that the SIV-specific CD8⁺ T cells were largely T_EM cells since the majority of them were CD28 negative (Fig. ​(Fig.4A).4A). Furthermore, these cells persisted with the same phenotype until day 60 after vaccination (Fig. ​(Fig.4B).4B). It was recently suggested that T_EM cells residing in the mucosae can effectively control infection after a low-dose challenge with SIVmac239 (16).Open in a separate windowFIG. 4.rYF17D/SIVGag_45-269 vaccination of animal r01056 induced effector memory Gag_181-189CM9-specific CD8⁺ T cells that suppressed viral replication in CD4⁺ targets. (A and B) Frequency and memory phenotype of tetramer-positive Gag_181-189-specific CD8⁺ T cells in animal r01056 on day 30 (A) and day 60 (B) after rYF17D/SIVGag_45-269 vaccination. CD28 and CD95 expression profiles of tetramer-positive cells show a polarized effector memory phenotype. Cells were gated on CD3⁺ CD8⁺ lymphocytes. (C) Ex vivo Gag_181-189CM9-specific CD8⁺ T cells from animal r01056 inhibit viral replication from SIVmac239-infected CD4⁺ T cells. Gag_181-189CM9-specific CD8⁺ T cells from three SIV-infected Mamu-A*01-positive animals and rYF17D/SIVGag_45-269-vaccinated animal r01056 were tested for their ability to suppress viral replication from SIV-infected CD4⁺ T cells (39). Forty-eight hours after the incubation of various ratios of SIV-infected CD4⁺ T cells and Gag_181-189CM9-specific CD8⁺ T cells, the supernatant was removed and measured for viral RNA (vRNA) copies per ml by Q-PCR. We observed no suppression when effectors were incubated with CD4⁺ targets from Mamu-A*01-negative animals (data not shown). Animal rh2029 was infected with SIVmac239 (viral load, ∼10⁵ vRNA copies/ml) containing mutations in 8 Mamu-B*08-restricted epitopes as part of another study (37). Animal r01080 was vaccinated with a DNA/Ad5 regimen expressing Gag, Rev, Tat, and Nef and later infected with SIVmac239 (viral load, ∼10³ vRNA copies/ml) (42). Animal r95061 was vaccinated with a DNA/MVA regimen containing Gag_181-189CM9 and was later challenged with SIVmac239 (undetectable viral load) (2).We then assessed whether rYF17D/SIVGag_45-269-induced CD8⁺ T cells could recognize virally infected CD4⁺ T cells. We have shown that these vaccine-induced CD8⁺ T cells stain for tetramers and produce cytokines after stimulation with synthetic peptides (Fig. ​(Fig.3).3). None of these assays, however, tested whether these SIV-specific CD8⁺ T cells recognize SIV-infected cells and reduce viral replication. We therefore used a newly developed assay (39) to determine whether vaccine-induced CD8⁺ T cells can reduce viral replication in CD4⁺ T cells. We sorted tetramer-positive (Gag_181-189CM9-specific) lymphocytes directly from fresh PBMC and incubated them for 48 h with SIVmac239-infected CD4⁺ T cells expressing Mamu-A*01. We assessed the percentage of CD4⁺ T cells that expressed SIV Gag p27 (data not shown) and the quantity of virus in the culture supernatant (Fig. ​(Fig.4C).4C). Vaccine-induced CD8⁺ T cells reduced viral replication to the same extent as that seen with Gag_181-189CM9-specific CD8⁺ T cells purified from three SIVmac239-infected rhesus macaques, including an elite controller rhesus macaque, animal r95061 (Fig. ​(Fig.4C4C).The most encouraging aspect of this study is that rBCG primed a high-frequency CD8⁺ T-cell response after boosting with rYF17D/SIVGag_45-269. These CD8⁺ T cells reached frequencies that were similar to those induced by an rBCG prime followed by an Ad5 boost (11). Even without the benefit of the rBCG prime, the levels of CD8⁺ T cells induced by a single rYF17D/SIVGag_45-269 vaccination were equivalent to those induced by our best SIV vaccine, SIVmac239ΔNef. Recombinant YF17D generated an average of 195 SFCs/10⁶ PBMC (range, 100 to 750 SFCs/10⁶ PBMC) (n = 6), whereas SIVmac239ΔNef induced an average of 238 SFCs/10⁶ PBMC (range, 150 to 320 SFCs/10⁶ PBMC) (n = 3) (32). It is also possible that any YF17D/HIV recombinants would likely replicate better in humans than they have in rhesus macaques and thus induce more robust immune responses. Also, rBCG was shown previously to be effective in humans (5, 17, 33, 34) and may be more useful at priming T-cell responses in humans than it has been in our limited study with rhesus macaques. These two vectors have long-distinguished safety and efficacy histories in humans and may therefore be well suited for HIV vaccine development.