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The design of an effective AIDS vaccine has eluded the efforts of the scientific community to the point that alternative approaches to classic vaccine formulations have to be considered. We propose here that HIV vaccine research could greatly benefit from the study of natural simian immunodeficiency virus (SIV) infections of African nonhuman primates. Natural SIV hosts (for example, sooty mangabeys, African green monkeys and mandrills) share many features of HIV infection of humans; however, they usually do not develop immunodeficiency. These natural, nonprogressive SIV infections represent an evolutionary adaptation that allows a peaceful coexistence of primate lentiviruses and the host immune system. This adaptation does not result in reduced viral replication but, rather, involves phenotypic changes to CD4+ T cell subsets, limited immune activation and preserved mucosal immunity, all of which contribute to the avoidance of disease progression and, possibly, to the reduction of vertical SIV transmission. Here we summarize the current understanding of SIV infection of African nonhuman primates and discuss how unraveling these evolutionary adaptations may provide clues for new vaccine designs that might induce effective immune responses without the harmful consequences of excessive immune activation.
Over 25 years after the discovery of HIV as the etiologic agent of AIDS, no effective vaccine for the disease is available. Indeed, the two large-scale clinical trials (AIDSVax and STEP) aimed at testing proof-of-principle vaccines that were based on the induction of HIV-specific antibodies and cytotoxic T cell responses, respectively, failed to show any of the desired clinical efficacy1. The reasons why an effective AIDS vaccine is not available are complex and, for the most part, are related to specific features of primate lentiviruses and their interaction with the host immune system. First, HIV establishes latency, that is, a persistent infection of cellular reservoirs that do not produce virions and thus are immunologically silent; thus, HIV is virtually never cleared by host immune responses2. Second, the HIV reverse transcriptase is an ‘error-prone’ enzyme that generates markedly diverse and constantly evolving virus populations within infected individuals3. This genetic diversity is fueled by high replication rates that lead to the rapid generation of viral variants that can escape the host immune responses. Third, HIV preferentially infects activated CD4+ T helper cells expressing the CCR5 co-receptor4. This latter point is of great importance because it raises the possibility that HIV-specific adaptive immune responses induced by a candidate AIDS vaccine can generate more targets for the virus and thus paradoxically facilitate HIV acquisition and disease progression. For these reasons, it is possible that conventional immunization strategies (those based solely on the elicitation of high levels of antiviral neutralizing antibodies and cytotoxic T lymphocyte (CTL) responses) may not be sufficient to provide protection against HIV infection and AIDS. Here we discuss how insights gained from studies of nonhuman primates naturally infected with SIV may uncover unconventional strategies to enhance the efficacy of conventional AIDS vaccine approaches.
Over 40 nonhuman primate species in Sub-Saharan Africa are infected in the wild with species-specific lentiviruses collectively termed SIV5. These infections represent virus-host relationships that are evolutionarily older than HIV infection of humans. Phylogenetic data indicate that cross-species transmissions of SIVs from two of these natural hosts, chimpanzees (SIVcpz) and sooty mangabeys (SIVsmm), to humans have generated HIV-1 and HIV-2, respectively5,6. Thus far, the majority of studies in natural primate hosts have been conducted in just three species, sooty mangabeys, African green monkeys (AGMs) and mandrills7–9, whereas SIV infection of other natural host species has been investigated only at a cursory level or has not yet been assessed. A major focus has been to investigate immunologic, virologic and clinical parameters in these natural SIV infections and to compare them to pathogenic HIV-1 infection of humans and SIVmac infection of macaques. These studies have uncovered a number of similarities between pathogenic and nonprogressive primate lentivirus infections, as well as a series of features unique to the natural SIV infections that have provided new clues as to why they remain nonpathogenic (Table 1).
The most salient feature of natural SIV infections is the general lack of progression to AIDS. Although a few cases of simian AIDS have been described in naturally or experimentally infected AGMs, sooty mangabeys and mandrills, these instances are exceedingly rare10. Nonetheless, these examples of disease progression demonstrate that the corresponding viruses have retained some of their pathogenic potential, even though the host is able to counteract it for a time period that generally exceeds the lifespan of the animal10. We believe that this balancing act is the result of a long-standing evolutionary coadaptation between primate lentiviruses and their hosts' immune systems. The recent observation that SIVcpz-infected chimpanzees have a substantially higher mortality rate (10- to 16-fold increased death hazard) than their uninfected counterparts11 supports this hypothesis, as these apes acquired their infection more recently by cross-species transmission of SIVs infecting the monkeys on which they prey12. Of note, a moderately pathogenic outcome is also observed after HIV-2 infection, which originated from cross-species transmission of SIVsmm from sooty mangabeys to humans6. Further studies in SIVcpz-infected chimpanzees and HIV-2-infected individuals will be essential to identify similarities and differences with both the typically nonprogressive infections of natural hosts and the more aggressive HIV-1 and SIVmac infections of humans and macaques.
Despite their resistance to disease progression, SIV infections of sooty mangabeys, AGMs and mandrills show numerous similarities with pathogenic infections, as illustrated in Table 1, thus underscoring their relevance to AIDS research. Common features of natural and pathogenic HIV and SIV infections include the following characteristics: the acute infection phase is characterized by a peak of virus replication, increased levels of many innate and adaptive immune responses, and depletion of mucosal CD4+ T cells13–19; the chronic phase of the infection is associated with persistently high levels of virus replication that are similar to those observed during pathogenic infections20–24; the bulk of virus replication occurs in short-lived activated CD4+ T cells25,26; and SIV-specific cellular and humoral immune responses are unable to fully suppress virus replication18,27–30 (T. Gaufin, M. Pattison, R. Gautam, C. Stoulig, J. Dufour et al., unpublished data). These similarities notwithstanding, natural SIV infections also have key distinctive features that clearly set them apart from pathogenic HIV and SIV infections (Tables 1 and and2).2). These include a benign clinical course, a relative rarity of vertical transmissions, the maintenance of peripheral CD4+ T cell counts at normal levels in the majority of animals, the absence of chronic immune activation, the preservation of mucosal immunity with normal levels of mucosal T helper type 17 (TH17) cells and absence of microbial translocation14,16,17,22–24,31–34. Thus, comparative studies of natural, nonprogressive hosts provide a unique opportunity to elucidate the mechanisms that underlie disease progression in hosts that show pathogenic infections (that is, humans and macaques).
The entire field of AIDS vaccinology is currently based on the premise that a strong adaptive immune response to HIV and SIV will decrease virus replication and disease progression. Theoretically, the fact that natural hosts of SIVs do not develop AIDS could be the result of adaptive immune responses (both humoral and cellular) that are significantly more effective than those mounted against pathogenic HIV and SIV infections of humans and macaques. However, one would expect that, if this hypothesis is correct, the levels of virus replication would be much lower than those observed in pathogenic HIV and SIV infections. On the contrary, the natural hosts investigated so far show levels of virus replication comparable to or higher than those observed during pathogenic HIV and SIV infections7–9. Although in all cases of SIV infection of natural hosts, a partial containment of viremia has been observed during the transition between acute and chronic infection, the relatively high set point level of viral replication does not support the notion of potentially more effective adaptive immune responses in natural hosts.
To assess more directly the potential role of adaptive immune responses in viral containment, a number of recent studies have used monoclonal antibody treatments to deplete lymphocyte subsets in vivo. In non-natural hosts (macaques), the central role of CD8+ lymphocytes was documented in numerous studies showing that depletion of these cells results in increased virus replication and accelerated disease progression35. The impact of CD8+ lymphocyte depletion on plasma viremia in natural hosts has generally been either less impressive36 or similar to that observed in SIV-infected macaques (C.A., I.P., T. Gaufin, M. Pattison, R. Gautam et al., unpublished data; J.E.S., R.C. Zahn, M.D. Rett, M. Li, H. Tang et al., unpublished data; A.K., Z. Wang, N. Kassis, R.M. Ribeiro, S. Pryputniewicz et al., unpublished data). Similarly, SIV-specific CD8+ T cell responses in natural SIV infections were found to be comparable or lower in breadth and magnitude than those reported in pathogenic HIV and SIV infections18,27–29,30. SIV-specific antibodies have also been documented in natural host infections, with both binding or neutralizing antibodies present at levels that are either similar to or lower than those observed in SIVmac-infected macaques and HIV-1–infected humans37,38 (T. Gaufin, M. Pattison, R. Gautam, C. Stoulig, J. Dufour et al., unpublished data). Notably, B cell depletion experiments were not associated with marked increases in viral replication or clinical signs of disease30 (T. Gaufin, M. Pattison, R. Gautam, C. Stoulig, J. Dufour et al., unpublished data; R.C. Zahn, M.D. Rett, M. Li, H. Tang, B. Korioth-Schmitz et al., unpublished data), suggesting a limited role of humoral immune responses in viral containment of SIV infections. The only consistent feature of the virus-specific humoral immune response in natural SIV hosts is a paucity of Gag-specific antibodies; however, the biological role of this finding remains to be determined. Collectively, these data indicate that natural SIV hosts generate virus-specific cellular and humoral responses that are lower than or comparable to those elicited by pathogenic HIV and SIV infections and similarly unable to suppress virus replication fully. However, more detailed investigations are required to better understand the contribution and possible limitations of adaptive immune responses in natural hosts. When translated in terms of AIDS vaccine research, the insights that have been obtained so far from the study of adaptive immune responses in natural SIV infections would argue that a new paradigm for the control of HIV disease progression should be explored, one that does not solely depend on conventional immunization strategies with viral immunogens.
Relatively little is known about the routes of SIV transmission in natural hosts, especially when compared to the wealth of information available for HIV transmission in humans. The high prevalence rates of SIV in adult sooty mangabeys, AGMs and mandrills both in captivity and in the wild5 suggest that horizontal transmission (either through sexual contacts or aggressive behavior) is common. However, it is currently impossible to compare the actual frequency of these transmissions with those reported for HIV-1 infection in humans, as all infections of sooty mangabeys, AGMs and mandrills in captivity were administered intravenously. Interestingly, vertical transmission in natural SIV hosts seems to be rare38–40, with an observed frequency of mother-to-offspring transmissions of SIV in naturally infected sooty mangabeys below 5%38 (T. Meeker, J.G.E. and G.S., unpublished data). The reasons for this phenomenon remain to be elucidated; however, recent data suggest that, at least in mandrills and AGMs, low CCR5 expression on CD4+ T cells in the offspring correlates with a resistance to SIV transmission via breastfeeding40. Regardless of the mechanism(s), the observation that SIV is not easily transmitted from mother to infant in natural SIV hosts is intriguing because it implies an evolutionary pressure against this type of infection. Whatever the reasons, we believe that understanding the mechanisms underlying SIV transmission in natural hosts, including the role of the observed low levels of activated CD4+CCR5+ T cells in fetuses and newborns, may provide crucial clues for a better understanding of HIV transmission in humans. In addition, reduced CCR5 expression on CD4+ T cells41 and low immune activation upon SIV infection may represent evolutionary adaptations that make the mucosal milieu of natural SIV hosts more resistant to virus transmission in a way that is independent of, or perhaps complementary to, classical adaptive antiviral immunity.
The unique features of natural SIV infections have been the subject of a number of recent reviews on the topic7–9. Here we focus on those features that we believe can be exploited for new vaccine strategies. There are two types of conventional HIV vaccine approaches currently being explored: HIV-specific CTL–based vaccines designed to delay disease progression by killing infected target cells and HIV-specific antibody–based vaccines designed to inhibit HIV transmission. We believe that studies of natural SIV infections point to additional avenues that should be exploited in an attempt to increase protection against both infection and disease progression.
Natural SIV infections are characterized by levels of chronic immune activation that are consistently and substantially lower than those observed in pathogenic HIV and SIV infections14–18,23,24,31,36,37,42. Notably, both innate and adaptive immune activation are observed during the acute phase of SIV infection of natural hosts16–18,37,42, including strong upregulation of type I interferon–stimulated genes in both peripheral blood and lymph nodes19 (J.G.E., G.S., S. Bosinger, S.N. Gordon, N.R. Klatt et al., unpublished data; Li, Q., Duan, L., Smith, A.J., Zeng, M., Masopust, D. et al., unpublished data; M.M.-T., B. Jacquelin, V. Mayau, B. Targat, A.S. Liovat et al., unpublished data) as well as type I interferon production by plasmacytoid dendritic cells in lymph nodes (J.D.E., L. Harris, S.N. Gordon, G.S. and J.M.B., unpublished data). However, marked differences in the levels of immune activation between natural and non-natural HIV and SIV hosts are observed after the transition from the acute to the chronic phase of infection. This finding suggests the presence of active immune downmodulatory mechanisms rather than an intrinsically attenuated innate immune response to SIV infection15,17,40,43. This conclusion is also supported by recent studies in which immune activation and CD4+ T cell depletion were successfully induced in AGMs after administration of lipopolysaccharide44. Several properties of the AGM and sooty mangabey hosts that may contribute to the low immune activation during chronic infection have recently been identified and warrant further investigation, particularly with regard to the association between increased immune activation and effective SIV-specific adaptive immune responses. These potential immunomodulatory mechanisms include the rapid establishment of an anti-inflammatory milieu, the early upregulation of the negative regulator PD-1 in lymph node–derived T cells, a partial refractoriness of plasmacytoid dendritic cells to produce type I interferon in response to SIV RNA, absence of microbial translocation from the intestinal lumen to the systemic circulation, low levels of CCR5 expression on CD4+ T cells and downregulation of CD4 expression by T cells15,17,33,40,42,43,45. In addition, lower immune activation in natural hosts may also be associated with virus-specific properties, particularly the lack of a vpu gene and the ability of the accessory Nef protein to suppress the activation of virally infected T cells46,47. The absence of chronic hyperimmune activation may be crucial to preserve T cell homeostasis (particularly at the level of naive and central memory cells), maintain normal lymphoid tissue architecture, preserve non–T cell immune functions, including those of antigen-presenting cells, and allow the natural host to better cope with instances of mucosal and generalized CD4+ T cell depletion16,17,34,37,48.
The low numbers of CD4+CCR5+ target cells observed in SIV natural hosts represent a striking contrast to what has been reported in Asian macaques and humans41. However, the biological relevance of this observation is still unclear—especially because these low amounts of CCR5 on CD4+ T cells do not result in lower virus replication in natural hosts or preclude CD4+ T cells from being the main source of virus production in natural SIV infections8,25,26,49. It is conceivable that, in natural SIV hosts, a restriction of CCR5 expression to more activated effector and/or CD4+ T cells may confine SIV replication to a subset of more ‘expendable’ cells, thus better preserving the homeostasis of central memory CD4+ T cells despite similarly high levels of viremia. Low CCR5 expression may also reduce the homing of activated CD4+ T cells to inflamed tissues, thus eliciting an anti-inflammatory effect41. Finally, a paucity of CD4+CCR5+ T cells in mucosal tissues may also influence SIV transmission, as it may affect the overall receptivity of the mucosal microenvironment to the establishment and early dissemination of the transmitted virus. Thus, a successful HIV vaccine may have to circumvent CD4+CCR5+ T cell activation, particularly at mucosal sites that are important for HIV transmission. Alternatively, it might be advantageous if an HIV vaccine induces T cell populations that can provide the proper T cell helper function but do not express the CD4 receptor and therefore are refractory to HIV infection (CD3+CD4neg)45 (C.A., T. Gaufin, E. Blake, R. Gautam and I.P. Pattison, unpublished data).
Given these specific features of natural SIV hosts, it seems clear that a more complete understanding of the mechanisms that have enabled natural SIV infections to avoid disease progression may provide major clues for the design of successful AIDS vaccines. We know that SIV-infected natural hosts elicit innate and adaptive immune responses to the virus; however, these responses are unable to stop virus replication. We also know that natural host species combine their antiviral innate and adaptive immune responses with low overall immune activation during the chronic phase, which may be a key in achieving an environment that is less conducive to immunodeficiency. As such, these observations suggest that designing vaccines that focus solely on increasing adaptive immune responses to HIV, similar to more conventional vaccine approaches, may not be sufficient to inhibit infection, progression to AIDS or both. Recently, a study by Phil Johnson and his colleagues explored a unique vaccine approach involving vector-mediated gene transfer to express SIV-specific antibodies or immunoadhesins50. This study provides insights above and beyond this particular approach, as it illustrates how one might design additional novel, ‘out-of-the-box’ approaches to elicit protection from HIV transmission, disease progression or both. In this regard, studies of SIV-infected natural hosts have provided a number of insights as to how evolutionary pressure resulted in the ability to resist progression to AIDS and suggest that this information will help the design of future new vaccine approaches.
In Table 2, we have defined six different AIDS prevention strategies, and for each of them, we have outlined lessons from the natural SIV hosts, key future research priorities and potential immunization strategies. For example, one potential new vaccine approach that might originate from studies of natural hosts may consist of decreasing the availability of target cells for the virus at the level of mucosal tissues (Table 2). This goal could be achieved either by limiting the number of activated CD4+CCR5+ cells or by increasing the levels of CD3+CD4neg cells that retain functions similar to CD4+ T helper cells. In addition, natural hosts seem to have a lower incidence of mother-to-offspring transmission (Table 2), suggesting that natural SIV hosts may help in developing vaccine strategies aimed at limiting virus transmission in addition to those aimed at inhibiting progression to clinical AIDS. We also believe that the type of adjuvant used in any future HIV vaccine, whether antibody or CTL based, could potentially be formulated such that it might result in an only transiently increased innate immune response or induce HIV-specific responses without inducing any bystander B or T cell activation (Table 2). Further studies of mucosal sites in SIV-infected natural hosts are necessary to identify any as yet uncharacterized adaptations or unknown factors that may protect from virus transmission and/or disease progression and thus shed insights into how such an adjuvant might be formulated. Finally the recent identification of viremic nonprogressors, HIV-1-infected individuals with relatively low immune activation and persistently high CD4+ T cell counts, further indicates that the adaptations in the natural hosts may be relevant to HIV infection in humans51. Although the use of natural SIV hosts to inform vaccine design is still in its infancy, we believe that studies in these African nonhuman primate species will ultimately generate new approaches that may lead to the development of a successful HIV vaccine.
We wish to thank A. Bernstein and N. Miller for their helpful discussions.