UV-inactivated vaccinia virus (VV) in a multi-envelope DNA-VV-protein (DVP) HIV-1 vaccine protects macaques from lethal challenge with heterologous SHIV

The pandemic of HIV-1 has continued for decades, yet there remains no licensed vaccine. Previous research has demonstrated the effectiveness of a multi-envelope, multi-vectored HIV-1 vaccine in a macaque-SHIV model, illustrating a potential means of combating HIV-1. Specifically, recombinant DNA, vaccinia virus (VV) and purified protein (DVP) delivery systems were used to vaccinate animals with dozens of antigenically distinct HIV-1 envelopes for induction of immune breadth. The vaccinated animals controlled disease following challenge with a heterologous SHIV. This demonstration suggested that the antigenic cocktail vaccine strategy, which has succeeded in several other vaccine fields (e.g. pneumococcus), might also succeed against HIV-1. The strategy remains untested in an advanced clinical study, in part due to safety concerns associated with the use of replication-competent VV. To address this concern, we designed a macaque study in which psoralen/ultraviolet light-inactivated VV (UV VV) was substituted for replication-competent VV in the multi-envelope DVP protocol. Control animals received a vaccine encompassing no VV, or no vaccine. All VV vaccinated animals generated an immune response toward VV, and all vaccinated animals generated an immune response toward HIV-1 envelope. After challenge with heterologous SHIV 89.6P, animals that received replication-competent VV or UV VV experienced similar outcomes. They exhibited reduced peak viral loads, maintenance of CD4+ T cell counts and improved survival compared to control animals that received no VV or no vaccine; there were 0/15 deaths among all animals that received VV and 5/9 deaths among controls. Results define a practical means of improving VV safety, and encourage advancement of a promising multi-envelope DVP HIV-1 vaccine candidate.     

Protection against chronic infection and AIDS by an HIV envelope peptide-cocktail vaccine in a pathogenic SHIV-rhesus model.

Based on our prior studies in mouse, monkey, chimpanzee, and human experimental systems, we identified six peptides encoded by highly conserved regions of the human immunodeficiency virus type 1 (HIV-1) envelope gene that selectively induce cellular immune responses in the absence of anti-viral antibody production. We tested a cocktail of the six peptides as a prototype vaccine for protection from simian human immunodeficiency virus (SHIV) infection and acquired immunodeficiency syndrome (AIDS) in a rhesus monkey model. Three monkeys were vaccinated with the peptide cocktail in Freund's adjuvant followed by autologous dendritic cells (DC) pulsed with these peptides. All the vaccinated animals exhibited significant induction of T-cell proliferation and cytotoxic T lymphocytes (CTL) responses, but no neutralizing antibodies. Two control mock-vaccinated monkeys showed no specific immune responses. Upon challenge with the pathogenic SHIV(KU-2), both the control and vaccinated monkeys were infected, but efficient clearance of virus-infected cells was observed in all the three vaccinated animals within 14 weeks. These animals also experienced a boosting of antiviral cellular immune responses after infection, and maintained antigen-specific IFN-gamma-producing cells in circulation beyond 42 weeks post-challenge. In contrast, the two mock-vaccinated monkeys had low to undetectable cellular immune responses and maintained significant levels of viral-infected cells and infectious virus in circulation. Further, in both the control monkeys plasma viremia was detectable beyond 38 weeks post-challenge indicating chronic phase infection. In one control monkey, the CD4+ cells dropped to very low levels by 2 weeks post-challenge and became undetectable by week 39 coinciding with high plasma viremia and AIDS, which included cachexia and ataxia. These results serve as proof of principle for the effectiveness of the HIV envelope peptide cocktail vaccine against chronic infection and AIDS, and support the development of multivalent peptide-based vaccine as a viable strategy to induce cell-mediated immunity (CMI) for protection against HIV and AIDS in humans.     

Efficient priming of simian/human immunodeficiency virus (SHIV)-specific T-cell responses with DNA encoding hybrid SHIV/hepatitis B surface antigen particles

Recent efforts to design an human immunodeficiency virus type 1 (HIV-1) vaccine candidate have focused on means of eliciting anti-viral T-cell responses. We tried to improve the immunogenicity of DNA vaccines by designing hybrid DNA constructs encoding hepatitis B surface antigen (HBsAg) fused to antigenic domains of simian/human immunodeficiency virus (SHIV 89.6P). Immunisation with hybrid DNA induced both effector and long-lasting precursor T-cells. Following boosting with a recombinant modified vaccinia Ankara (rMVA) producing full-length SIV and HIV antigens, it appeared that priming with hybrid DNA had increased virus-specific T-cell responses in terms of both the number of virus-specific IFN-gamma-secreting T-cells and virus-specific lymphoproliferation. After intrarectal challenge with SHIV 89.6P, immunised animals demonstrated early control of SHIV 89.6P replication and stable CD4+ T-cell counts.     

Long-term vaccine protection from AIDS and clearance of viral DNA following SHIV89.6P challenge

In an earlier study, our group vaccinated rhesus macaques with vesicular stomatitis virus (VSV) vectors expressing Gag, Pol, and Env proteins from a hybrid simian/human immunodeficiency virus (SHIV). This was followed by a single boost with modified vaccinia virus Ankara (MVA) vectors expressing the same proteins. Following challenge with SHIV89.6P, vaccinated animals cleared challenge virus RNA from the blood by day 150 and maintained normal CD4 T cell counts for 8 months. Here we report on the long-term (>5-year post-challenge) status of these animals and the immunological correlates of long-term protection. Using real-time PCR, we found that viral DNA in peripheral blood mononuclear cells (PBMCs) of the vaccinees declined continuously and fell to below detection (<5 copies/10⁵ cells) by approximately 3 years post-challenge. SHIV DNA was also below the limit of detection in the lymph nodes of two of the four animals at 5 years post-challenge. We detected long-term persistence of multi-functional Gag-specific CD8⁺ T cells in both PBMCs and lymph nodes of the two protected animals with the Mamu A*01⁺ MHC I allele. All animals also maintained SHIV89.6P neutralizing antibody titers for 5 years. Our results show that this vaccine approach generates solid, long-term control of SHIV infection, and suggest that it is mediated by both cytotoxic T lymphocytes and neutralizing antibody.     

DNA vaccination of macaques by a full-genome SHIV plasmid that has an IL-2 gene and produces non-infectious virus particles

We previously reported that a mutant full-sized plasmid DNA vaccine regime in macaques was effective against a homologous challenge [Akahata W, Ido E, Shimada T, Katsuyama K, Yamamoto H, Uesaka H, et al. DNA vaccination of macaques by a full genome HIV-1 plasmid which produces non-infectious virus particles. Virology 2000;275:116-24; Akahata W, Ido E, Akiyama H, Uesaka H, Enose Y, Horiuchi R, et al. DNA vaccination of macaques by a full genome SHIV-1 plasmid that produces non-infectious virus particles. J Gen Virol 2003;84:2237-44]. In this study, to evaluate the DNA vaccination regime against a heterologous challenge, a novel plasmid named pSHIV-ZF1*IL-2 was constructed. Four monkeys were intramuscularly and intradermally injected four times with the pSHIV-ZF1*IL-2. Vaccinated monkeys were intravenously challenged with a highly pathogenic, heterologous SHIV at 11 weeks post vaccination. All the vaccinated monkeys suppressed the challenge virus rapidly under the detectable level by 16 weeks post challenge. One vaccinated monkey was protected from a loss of CD4+ T cells. These results suggest pSHIV-ZF1*IL-2 alone seems partially effective even against a challenge with a heterologous, pathogenic virus.     

Efficacy of a SHIV 89.6 proviral DNA vaccine against mucosal SIVmac239 challenge

Sixty percent of rhesus macaques infected with virulence attenuated virus SHIV 89.6 are protected from subsequent intravaginal challenge with pathogenic SIVmac239 [Abel K, Compton L, Rourke T, Montefiori D, Lu D, Rothaeusler K, et al. Simian-human immunodeficiency virus SHIV89.6-induced protection against intravaginal challenge with pathogenic SIVmac239 is independent of the route of immunization and is associated with a combination of cytotoxic T-lymphocyte and alpha interferon responses. J Virol 2003;77(5):3099-118; Miller CJ, McChesney MB, Lu X, Dailey PJ, Chutkowski C, Lu D, et al. Rhesus macaques previously infected with simian/human immunodeficiency virus (HIV) are protected from vaginal challenge with pathogenic SIVmac239. J Virol 1997;71(3):1911-21]. Previously, we have shown that inoculation with a proviral plasmid encoding SHIV 89.6 (pMA SHIV-89.6) results in systemic infection that is delayed compared to SHIV 89.6 virus inoculation [Busch M, Lu D, Fritts L, Lifson JD, Miller CJ. Comparison of virology and immunology in SHIV 89.6 proviral DNA and virus-inoculated rhesus macaques. J Med Primatol 2003;32(4-5):240-6]. We now report that, although monkeys inoculated with pMA SHIV-89.6 or SHIV 89.6 virus had similar plasma anti-SIV binding antibody titers and number of anti-SIV IFN-gamma secreting cells on the day of mucosal SIVmac239 challenge, a smaller proportion of monkeys immunized with pMA SHIV-89.6 were protected from vaginal SIVmac239 challenge compared to monkeys immunized using SHIV 89.6 virus. Protected DNA immunized monkeys had stronger anti-SIV IFN-gamma ELISPOT responses in the acute stage post-challenge than unprotected monkeys. Plasma anti-SIV binding antibody titers and PBMC cytokine responses in the acute stages post-challenge were similar in DNA vaccinated-protected and DNA vaccinated-unprotected monkeys. These results suggest that the delay in systemic infection resulting from delivery of SHIV 89.6 as a plasmid decreased the effectiveness of this live attenuated vaccine.     

Understanding the basis of CD4(+) T-cell depletion in macaques infected by a simian-human immunodeficiency virus

The efficacy of candidate AIDS vaccines to mediate protection against viral infection and pathogenesis is evaluated, at a preclinical stage, in animal models. One model that is favored because the infecting virus is closely related to HIV-1 and because of the rapidity of pathogenic outcomes is the infection of Old World monkeys by simian-human immunodeficiency virus (SHIV) chimerae. We investigated the basis for the depletion of CD4(+) T lymphocytes in a SHIV-macaque model. Molecularly cloned SHIVs, SHIV-89.6 and SHIV-KB9, differ in the ability to cause CD4(+) T-cell loss at a given level of virus replication in monkeys. The envelope glycoproteins of the pathogenic SHIV-KB9 mediate membrane-fusion in cultured T lymphocytes more efficiently than the envelope glycoproteins of the non-pathogenic SHIV-89.6. The minimal envelope glycoprotein region that specifies this increase in membrane-fusing capacity was sufficient to convert SHIV-89.6 into a virus that causes profound CD4(+) T-cell depletion in monkeys. Conversely, two single amino acid changes that decrease the membrane-fusing ability of the SHIV-KB9 envelope glycoproteins also attenuated the CD4(+) T-cell destruction that accompanied a given level of virus replication in SHIV-infected monkeys. Thus, the ability of the HIV-1 envelope glycoproteins to fuse membranes, which has been implicated in the induction of viral cytopathic effects in vitro, contributes to the capacity of the pathogenic SHIV to deplete CD4(+) T lymphocytes in vivo.     

A Gag-Pol/Env-Rev SIV239 DNA vaccine improves CD4 counts,and reduce viral loads after pathogenic intrarectal SIV(mac)251 challenge in rhesus Macaques

DNA vaccines are an important vaccine approach for many infectious diseases including human immunodeficiency virus (HIV). Recently, there have been exciting results reported for plasmid vaccination in pathogenic SHIV model systems. In these studies, plasmid vaccines supplemented by IL-2 Ig cytokine gene adjuvants or boosted by recombinant MVA vectors expressing relevant SIV and HIV antigens prevented CD4(+) T-cell loss and lowered viral loads following pathogenic challenge. However, similar results have not been reported in a direct pathogenic macaque challenge model. Here we report on a study of the ability of a multiplasmid SIV DNA vaccine in a pathogenic SIV251 rhesus mucosal challenge study. We observed that pGag/Pol+pEnv/Rev plasmid vaccines could not prevent SIV infection; however, vaccinated animals exhibited significant improvement in control of viral challenge compared to control animals. Furthermore, vaccinated animals exhibited protection against CD4(+) T-cell loss.     

A recombinant subunit vaccine formulation protects against lethal Nipah virus challenge in cats

Nipah virus (NiV) and Hendra virus (HeV) are closely related deadly zoonotic paramyxoviruses that have emerged and re-emerged over the last 10 years. In this study, a subunit vaccine formulation containing only recombinant, soluble, attachment glycoprotein from HeV (sG(HeV)) and CpG adjuvant was evaluated as a potential NiV vaccine in the cat model. Different amounts of sG(HeV) were employed and sG-induced immunity was examined. Vaccinated animals demonstrated varying levels of NiV-specific Ig systemically and importantly, all vaccinated cats possessed antigen-specific IgA on the mucosa. Upon oronasal challenge with NiV (50,000TCID50), all vaccinated animals were protected from disease although virus was detected on day 21 post-challenge in one animal. The ability to elicit protective systemic and mucosal immunity in this animal model provides significant progress towards the development of a human subunit vaccine against henipaviruses.     

Evaluation of protection induced by a dengue virus serotype 2 envelope domain III protein scaffold/DNA vaccine in non-human primates

We describe the preclinical development of a dengue virus vaccine targeting the dengue virus serotype 2 (DENV2) envelope domain III (EDIII). This study provides proof-of-principle that a dengue EDIII protein scaffold/DNA vaccine can protect against dengue challenge. The dengue vaccine (EDIII-E2) is composed of both a protein particle and a DNA expression plasmid delivered simultaneously via intramuscular injection (protein) and gene gun (DNA) into rhesus macaques. The protein component can contain a maximum of 60 copies of EDIII presented on a multimeric scaffold of Geobacillus stearothermophilus E2 proteins. The DNA component is composed of the EDIII portion of the envelope gene cloned into an expression plasmid. The EDIII-E2 vaccine elicited robust antibody responses to DENV2, with neutralizing antibody responses detectable following the first boost and reaching titers of greater than 1:100,000 following the second and final boost. Vaccinated and naïve groups of macaques were challenged with DENV2. All vaccinated macaques were protected from detectable viremia by infectious assay, while naïve animals had detectable viremia for 2–7 days post-challenge. All naïve macaques had detectable viral RNA from day 2–10 post-challenge. In the EDIII-E2 group, three macaques were negative for viral RNA and three were found to have detectable viral RNA post challenge. Viremia onset was delayed and the duration was shortened relative to naïve controls. The presence of viral RNA post-challenge corresponded to a 10–30-fold boost in neutralization titers 28 days post challenge, whereas no boost was observed in the fully protected animals. Based on these results, we determine that pre-challenge 50% neutralization titers of >1:6000 correlated with sterilizing protection against DENV2 challenge in EDIII-E2 vaccinated macaques. Identification of the critical correlate of protection for the EDIII-E2 platform in the robust non-human primate model lays the groundwork for further development of a tetravalent EDIII-E2 dengue vaccine.     

Passive transfer studies to elucidate the role of antibody-mediated protection against HIV-1

In order to understand immune correlates of protection and to develop effective immunization strategies, it is important to know if antibodies can confer protection against HIV-1 infection or disease. The recent development of the pathogenic simian/human immunodeficiency virus (SHIV)-macaque model based on env genes from primary HIV-1 isolates permits the in vivo evaluation of anti-HIV-1 envelope glycoprotein immune responses. Using this model, we and others initially showed that passively infused antibody can protect against an intravenous SHIV-challenge. However, HIV-1 is most often transmitted across mucosal surfaces and the intravenous challenge model may not accurately predict the role of antibody in protection against mucosal exposure. We, therefore, adapted the SHIV89.6PD model to allow evaluation of anti-HIV-1 antibodies against vaginal challenge. In order to make comparisons to our prior intravenous challenge study, we used the same SHIV89.6PD stock and antibodies. Our data show that antibodies can confer protection against vaginal exposure to a pathogenic SHIV; if virus transmission occurs, their presence can ameliorate the subsequent pathogenic manifestations of virus infection. Compared to our previous intravenous challenge study, greater protection was achieved after vaginal challenge. Because the highest level of protection occurred when the most potent combinations of antibodies were used, the data confirm that in vitro neutralization assays on peripheral blood mononuclear cells (PBMC) targets cells are a relevant measure of protective antibody activity.     

Protection by dendritic cells-based HIV synthetic peptide cocktail vaccine: preclinical studies in the SHIV-rhesus model

Vaccine development efforts against HIV-1 have been hindered because of the high mutation rate of the virus, and limitations for direct testing of HIV antigens in animal models to discern the nature of protective immunity. We developed a multivalent vaccine comprised of highly conserved HIV envelope peptide cocktail focused on priming antigen-specific helper T cell and CTL responses. Here we report protection of rhesus macaques against pathogenic SHIV(89.6P) challenge through priming cell-mediated immunity by prophylactic vaccination with the peptide-cocktail delivered by dendritic cells. Compared to monkeys mock-vaccinated or immunized with the peptide cocktail using IFA, vaccination with peptide cocktail-pulsed DC showed significant protection from AIDS-associated mortality and reduction in plasma viremia to undetectable levels.     

Induction of Gag-specific T-cell responses by therapeutic immunization with a Gag-expressing Sendai virus vector in macaques chronically infected with simian-human immunodeficiency virus

Recent prophylactic vaccine trials inducing virus-specific CD8+ T-cell responses have shown control of primary infections of a pathogenic simian-human immunodeficiency virus (SHIV) in macaques. In the chronic phase, therapeutic immunization replenishing virus-specific CD8+ T-cells is likely to contribute to sustained control of virus replication. In this study, we have administered a recombinant Sendai virus (SeV) vector into five rhesus macaques that had received prophylactic vaccinations and had controlled SHIV replication for more than 1 year after challenge. Our results indicate that virus-specific CD8+ T-cell responses can be expanded and broadened by therapeutic immunization with SeV vectors in the chronic phase after prophylactic vaccine-based control of primary immunodeficiency virus infections.     

Comparative analysis of immune responses and cytokine profiles elicited in rabbits by the combined use of recombinant fowlpox viruses,plasmids and virus-like particles in prime-boost vaccination protocols against SHIV

Three different prime-boost immunization protocols were tested in rabbits and their immune response was evaluated and compared with the final aim of identifying a vaccine strategy that might be able to protect non-human primates from infection with the pathogenic chimera simian/human immunodeficiency virus (SHIV)(89.6P). Protocols were based on priming with two fowlpox (FP) recombinant vectors and two expression plasmids, which express either the simian immunodeficiency virus (SIV)mac(239) gag/pol or the human immunodeficiency virus (HIV-1)env(89.6P) genes, followed by boosting with virus-like particles (VLP). All protocols were effective in eliciting homologous neutralizing Ab and highlighted the efficacy of VLP boosting. The FP vector was less efficient than plasmid DNA in inducing Ab against the gag core proteins. Analysis of cytokine expression 5 months after last immunization indicated that priming with pcDNA3gag/pol(SIV) and FPenv(89.6P) followed by VLP boosting generated a T helper (Th0) profile and a good Ab titer, suggesting a potential protocol to be tested in the SHIV-macaque model of HIV-1 infection.     

Evaluation of the immune response and protective effects of rhesus macaques vaccinated with biodegradable nanoparticles carrying gp120 of human immunodeficiency virus

We previously reported that biodegradable amphiphilic poly(γ-glutamic acid) nanoparticles (NPs) carrying the recombinant gp120 env protein of the human immunodeficiency virus type 1 (HIV-1) were efficiently taken up by dendritic cells, and induced strong CD8⁺ T cell responses against the gp120 in mice. To evaluate gp120-carrying NPs (gp120-NPs) as a vaccine candidate for HIV-1 infection, we vaccinated rhesus macaques with these gp120-NPs and examined the immune response and protective efficacy against a challenge inoculation of simian and human immunodeficiency chimeric virus (SHIV). We found that gp120-NP vaccination induced stronger responses for both gp120-specific cellular and humoral immunity than gp120-alone vaccination. After the challenge inoculation with SHIV, however, the peak value of viral RNA in the peripheral blood was higher in the vaccinated groups, especially the gp120-NP vaccinated group, than naive control group. Higher value of viral load was also maintained in gp120-NP vaccinated group. Furthermore, CD4⁺ T cells from the peripheral blood decreased more in the vaccinated groups than the control group. Thus, induced immune responses against gp120 enclosed in NPs were not effective for protection but, conversely enhanced the infection, although the gp120-NPs showed a stronger induction of immune responses against the vaccinated antigen in rhesus macaques. These results support the importance of determining immune correlate of protective immunity for vaccine development against HIV-1 infection.     

Heterologous prime/boost immunizations of rhesus monkeys using chimpanzee adenovirus vectors

Pre-existing immunity to human adenovirus serotype 5 (AdHu5) has been shown to suppress the immunogenicity of recombinant Ad5 (rAdHu5) vector-based vaccines for human immunodeficiency virus type 1 (HIV-1) in both preclinical studies and clinical trials. As a potential solution to this problem we developed adenovirus vaccine vectors of chimpanzee origin. In the present study we assessed the immunogenicity of various chimpanzee adenovirus vectors in a prime/boost regimen to HIV-1 envelope and SIV Gag-Pol in rhesus monkeys and their ability to protect against pathogenic viral challenge. Although rAdHu5-primed monkeys had higher magnitude T cell responses than rAdC7 or rAdC68 prior to challenge, the rAdC7-rAdC1/C5 and rAdHu5-rAdC1/C5 immunizations resulted in comparable magnitude recall cellular immune responses and comparable level of control of viremia post-challenge.     

An inactivated H5N2 vaccine reduces transmission of highly pathogenic H5N1 avian influenza virus among native chickens

Vaccination against H5N1 highly pathogenic avian influenza in endemically affected areas is a potentially attractive option for local prevention and control. In Indonesia the majority of local outbreaks have occurred in back yard flocks with native chickens, and it is therefore of interest to determine whether these birds can be protected against infection by vaccination. To this end two transmission experiments were carried out with H5N1 virus (A/chicken/Legok/2003) in vaccinated and unvaccinated native chickens. The vaccine contained an inactivated heterologous H5N2 strain (A/turkey/England/N28/73 H5N2). Birds were vaccinated at 4 and 7 weeks of age and challenged at 10 weeks of age. During 10 days post-challenge tracheal and cloacal swabs were taken for virus isolation, and serum blood was collected regularly to measure haemaglutinin inhibiting (HI) antibody responses. The results show that transmission of H5N1 virus was rapid and efficient in unvaccinated birds, that infection and transmission were completely prevented in vaccinated birds, and that vaccinated birds that were exposed to unvaccinated inoculated birds were still protected from infection. These findings indicate that vaccination with a heterologous H5N2 vaccine is able to prevent virus transmission in flocks of native chickens.     

Emergency vaccination of sheep against foot-and-mouth disease: significance and detection of subsequent sub-clinical infection

This study has quantified the level of foot-and-mouth disease virus (FMDV) replication and shedding in vaccinated sheep and correlated this to the severity of clinical signs, the induction of antibodies against FMDV non-structural proteins (NSPs) and the transmission of virus to in-contact vaccinated sentinel sheep. To mimic an emergency vaccination regime in the field, sheep were vaccinated with O(1) Manisa vaccine and 4 or 10 days later were indirectly challenged with aerosols from O(1) UKG FMDV infected pigs. Vaccinated and control unvaccinated sheep were monitored for a minimum of 39 days post-challenge. The vaccinated sheep became sub-clinically infected, with reduced virus replication and excretion compared to unvaccinated and clinically infected sheep. Seroconversion to NSP was weak and transient in sheep in which virus replication was of low level and short duration. Virus transmission from vaccinated sub-clinically infected sheep to introduced vaccinated sentinels was not sufficient to cause NSP seroconversion or significant virus shedding. 10% of 10 days and 20% of 4 days vaccinated sheep were virus carriers at greater than 28 days post-challenge compared to 37.5% in the unvaccinated and clinically infected sheep. These results suggest that the low levels of virus replication likely if an effective vaccine is administered at least 4 days prior to challenge exposure are unlikely to result in the spread of infection even under intensive management conditions. Although it may be difficult to detect this infection by serosurveillance, the significance of missing it is likely to be low and the main value of such testing will be to detect undisclosed clinical infection resulting from lack of observation or from exposure to virus before or very soon after vaccination or from vaccine failure due to maladministration or inappropriate strain selection.     

Multimodality vaccination against clade C SHIV: Partial protection against mucosal challenges with a heterologous tier 2 virus

We sought to test whether vaccine-induced immune responses could protect rhesus macaques (RMs) against upfront heterologous challenges with an R5 simian-human immunodeficiency virus, SHIV-2873Nip. This SHIV strain exhibits many properties of transmitted HIV-1, such as tier 2 phenotype (relatively difficult to neutralize), exclusive CCR5 tropism, and gradual disease progression in infected RMs. Since no human AIDS vaccine recipient is likely to encounter an HIV-1 strain that exactly matches the immunogens, we immunized the RMs with recombinant Env proteins heterologous to the challenge virus. For induction of immune responses against Gag, Tat, and Nef, we explored a strategy of immunization with overlapping synthetic peptides (OSP). The immune responses against Gag and Tat were finally boosted with recombinant proteins. The vaccinees and a group of ten control animals were given five low-dose intrarectal (i.r.) challenges with SHIV-2873Nip. All controls and seven out of eight vaccinees became systemically infected; there was no significant difference in viremia levels of vaccinees vs. controls. Prevention of viremia was observed in one vaccinee which showed strong boosting of virus-specific cellular immunity during virus exposures. The protected animal showed no challenge virus-specific neutralizing antibodies in the TZM-bl or A3R5 cell-based assays and had low-level ADCC activity after the virus exposures. Microarray data strongly supported a role for cellular immunity in the protected animal. Our study represents a case of protection against heterologous tier 2 SHIV-C by vaccine-induced, virus-specific cellular immune responses.