Mucosal challenge of Macaca nemestrina with simian immunodeficiency virus (SIV) following SIV nucleocapsid mutant DNA vaccination.

A simian immunodeficiency virus (SIV)(Mne) DNA clone was constructed that produces viruses containing a four amino acid deletion in the second zinc finger of the nucleocapsid (NC) domain of the Gag polyprotein. Viruses produced from this clone, although non-infectious both in vitro and in vivo, complete a majority of the steps in a single retroviral infection cycle. Eight pig-tailed macaques (Macaca nemestrina) were inoculated intramuscularly and subcutaneously three times over the course of 24 weeks with the NC mutant expressing DNA. These macaques, and four controls, were then challenged mucosally (intrarectally) with the homologous virus (SIV Mne CL E11S) and monitored for evidence of infection and clinical disease. Prior to challenge, a measurable humoral immune response was noted in four of eight immunized macaques. After challenge, all 12 macaques became infected, although four immunized animals greatly restricted their viral replication, and one immunized animal that controlled replication remains antibody negative. No disease has been evidence during the 46-week period of monitoring after challenge.

Role of immune responses against the envelope and the core antigens of simian immunodeficiency virus SIVmne in protection against homologous cloned and uncloned virus challenge in Macaques.

We previously showed that envelope (gp160)-based vaccines, used in a live recombinant virus priming and subunit protein boosting regimen, protected macaques against intravenous and intrarectal challenges with the homologous simian immunodeficiency virus SIVmne clone E11S. However, the breadth of protection appears to be limited, since the vaccines were only partially effective against intravenous challenge by the uncloned SIVmne. To examine factors that could affect the breadth and the efficacy of this immunization approach, we studied (i) the effect of priming by recombinant vaccinia virus; (ii) the role of surface antigen gp130; and (iii) the role of core antigens (Gag and Pol) in eliciting protective immunity. Results indicate that (i) priming with recombinant vaccinia virus was more effective than subunit antigen in eliciting protective responses; (ii) while both gp130 and gp160 elicited similar levels of SIV-specific antibodies, gp130 was not as effective as gp160 in protection, indicating a possible role for the transmembrane protein in presenting functionally important epitopes; and (iii) although animals immunized with core antigens failed to generate any neutralizing antibody and were infected upon challenge, their virus load was 50- to 100-fold lower than that of the controls, suggesting the importance of cellular immunity or other core-specific immune responses in controlling acute infection. Complete protection against intravenous infection by the pathogenic uncloned SIVmne was achieved by immunization with both the envelope and the core antigens. These results indicate that immune responses to both antigens may contribute to protection and thus argue for the inclusion of multiple antigens in recombinant vaccine designs.

Protection of macaques against intrarectal infection by a combination immunization regimen with recombinant simian immunodeficiency virus SIVmne gp160 vaccines.

We previously reported that immunization with recombinant simian immunodeficiency virus SIVmne envelope (gp160) vaccines protected macaques against intravenous challenge by the cloned homologous virus E11S but that this protection was only partially effective against the uncloned virus, SIVmne. In the present study, we examine the protective efficacy of this immunization regimen against infection by a mucosal route. We found that the same gp160-based vaccines were highly effective against intrarectal infection not only with the E11S clone but also with the uncloned SIVmne. Protection against mucosal infection is therefore achievable by parenteral immunization with recombinant envelope vaccines. Protection appears to correlate with high levels of SIV-specific antibodies and, in animals protected against the uncloned virus, the presence of serum-neutralizing activities. To understand the basis for the differential efficacies against the uncloned virus by the intravenous versus the intrarectal routes, we examined viral sequences recovered from the peripheral blood mononuclear cells of animals early after infection by both routes. We previously showed that the majority (85%) of the uncloned SIVmne challenge stock contained V1 sequences homologous to the molecular clone from which the vaccines were made (E11S type), with the remainder (15%) containing multiple conserved changes (the variant types). In contrast to intravenously infected animals, from which either E11S-type or the variant type V1 sequences could be recovered in significant proportions, animals infected intrarectally had predominantly E11S-type sequences. Preferential transmission or amplification of the E11S-type viruses may therefore account in part for the enhanced efficacy of the recombinant gp160 vaccines against the uncloned virus challenge by the intrarectal route compared with the intravenous route.

Nucleocapsid protein zinc-finger mutants of simian immunodeficiency virus strain mne produce virions that are replication defective in vitro and in vivo.

All retroviruses (except the spumaretroviruses) contain a nucleocapsid (NC) protein that encodes one or two copies of the Zn2+-finger sequence -Cys-X2-Cys-X4-His-X4-Cys-. This region has been shown to be essential for recognition and packaging of the genomic RNA during virion particle assembly. Additionally, this region has been shown to be involved in early infection events in a wide spectrum of retroviruses, including mammalian type C [e.g., murine leukemia virus (MuLV)], human immunodeficiency virus type 1 (HIV-1), Rous sarcoma virus, and other retroviruses. Mutations in the two Zn2+-fingers of the NC protein of simian immunodeficiency virus strain Mne [SIV(Mne)] have been generated. The resulting virions contained the normal complement of processed viral proteins with densities indistinguishable from wild-type SIV(Mne). All of the mutants had electron micrograph morphologies similar to those of immature particles observed in wild-type preparations. RNA packaging was less affected by mutations in the NC protein of SIV(Mne) than has been observed for similar mutants in the MuLV and HIV-1 systems. Nevertheless, in vitro replication of SIV(Mne) NC mutants was impaired to levels comparable to those observed for MuLV and HIV-1 NC mutants; replication defective NC mutants are typically 10(5)- to 10(6)-fold less infectious than similar levels of wild-type virus. One mutant, DeltaCys33-Cys36, was also found to be noninfectious in vivo when mutant virus was administered intravenously to a pig-tailed macaque. NC mutations can therefore be used to generate replication defective virions for candidate vaccines in the SIV macaque model for primate lentiviral diseases.

Limited breadth of the protective immunity elicited by simian immunodeficiency virus SIVmne gp160 vaccines in a combination immunization regimen.

We previously reported that immunization with recombinant simian immunodeficiency virus SIVmne envelope (gp160) vaccines protected macaques against an intravenous challenge by the cloned homologous virus, E11S. In this study, we confirmed this observation and found that the vaccines were effective not only against virus grown on human T-cell lines but also against virus grown on macaque peripheral blood mononuclear cells (PBMC). The breadth of protection, however, was limited. In three experiments, 3 of 10 animals challenged with the parental uncloned SIVmne were completely protected. Of the remaining animals, three were transiently virus positive and four were persistently positive after challenge, as were 10 nonimmunized control animals. Protection was not correlated with levels of serum-neutralizing antibodies against the homologous SIVmne or a related virus, SIVmac251. To gain further insight into the protective mechanism, we analyzed nucleotide sequences in the envelope region of the uncloned challenge virus and compared them with those present in the PBMC of infected animals. The majority (85%) of the uncloned challenge virus was homologous to the molecular clone from which the vaccines were made (E11S type). The remaining 15% contained conserved changes in the V1 region (variant types). Control animals infected with this uncloned virus had different proportions of the two genotypes, whereas three of four immunized but persistently infected animals had >99% of the variant types early after infection. These results indicate that the protective immunity elicited by recombinant gp160 vaccines is restricted primarily to the homologous virus and suggest the possibility that immune responses directed to the V1 region of the envelope protein play a role in protection.

Effectiveness of postinoculation (R)-9-(2-phosphonylmethoxypropyl) adenine treatment for prevention of persistent simian immunodeficiency virus SIVmne infection depends critically on timing of initiation and duration of treatment.

(R)-9-(2-Phosphonylmethoxypropyl)adenine (PMPA), an acyclic nucleoside phosphonate analog, is one of a new class of potent antiretroviral agents. Previously, we showed that PMPA treatment for 28 days prevented establishment of persistent simian immunodeficiency virus (SIV) infection in macaques even when therapy was initiated 24 h after intravenous virus inoculation. In the present study, we tested regimens involving different intervals between intravenous inoculation with SIV and initiation of PMPA treatment, as well as different durations of treatment, for the ability to prevent establishment of persistent infection. Twenty-four cynomolgus macaques (Macaca fascicularis) were studied for 46 weeks after inoculation with SIV. All mock-treated control macaques showed evidence of productive infection within 2 weeks postinoculation (p.i.). All macaques that were treated with PMPA for 28 days beginning 24 h p.i. showed no evidence of viral replication following discontinuation of PMPA treatment. However, extending the time to initiation of treatment from 24 to 48 or 72 h p.i. or decreasing the duration of treatment reduced effectiveness in preventing establishment of persistent infection. Only half of the macaques treated for 10 days, and none of those treated for 3 days, were completely protected when treatment was initiated at 24 h. Despite the reduced efficacy of delayed and shortened treatment, all PMPA-treated macaques that were not protected showed delays in the onset of cell-associated and plasma viremia and antibody responses compared with mock controls. These results clearly show that both the time between virus exposure and initiation of PMPA treatment as well as the duration of treatment are crucial factors for prevention of acute SIV infection in the macaque model.

Autoimmunity in chronic active Helicobacter hepatitis of mice. Serum antibodies and expression of heat shock protein 70 in liver.

Male A/JCr mice with naturally occurring Helicobacter hepaticus infection develop a progressive chronic active hepatitis and liver tumors, despite the presence of serum antibodies to Helicobacter proteins. A rabbit antiserum prepared against the bacterial proteins immunoreacted with hepatocytes present in liver sections from infected mice with progressive lesions. We found that sera from these mice contained IgG antibodies that reacted in immunoblots with recombinant heat shock protein 70 (DmaK from Escherichia coli) but not with heat shock protein 60 (GroEL) or heat shock protein 10 (GroES). A rabbit antibody to heat shock protein 70 reacted with H. hepaticus in tissue sections and to a H. hepaticus protein (70 kd) in Western blots. Immunohistochemistry and in situ hybridization for heat shock protein 70 revealed that individual hepatocytes and other cells expressed the protein in livers with hepatitis but not usually in normal livers. Liver tumors and preneoplastic lesions in infected mice did not usually express heat shock protein 70 except focally in a few tumors. In situ hybridization for H. hepaticus 16S rRNA showed that the bacteria was found throughout the liver associated with hepatitis but not within tumors. CD3+ T lymphocytes were found in close association with hepatic lesions. These data suggest a role for autoimmunity in progressive hepatitis and carcinogenesis in livers infected with H. hepaticus.

Progression to AIDS in macaques is associated with changes in the replication, tropism, and cytopathic properties of the simian immunodeficiency virus variant population.

Human immunodeficiency virus type 1 (HIV-1) typically evolves from a macrophage-tropic, noncytopathic virus at early asymptomatic stages of infection to a T-cell-tropic, cytopathic, and syncytia-inducing virus population as humans progress to AIDS. This suggests that changes in virus phenotype may influence disease. Because simian immunodeficiency virus (SIV) infection in macaques is a common model system for HIV-1 pathogenesis, we determined whether SIV infection in macaques that develop simian AIDS is associated with a similar shift in viral tropism, replication, and cytopathic properties. The virus that infected the monkeys (SIVMneCL8) and predominated at early times in infection is a macrophage-tropic virus that replicates with relatively low efficiency in human T cell lines. The variant populations that arise in macaques as they progress to AIDS are more infectious for human T cell lines, exhibiting enhanced replication in CEM x 174 cells and an expanded host range that includes Molt-4 Clone 8 cells. Infections starting with equal doses of the viruses demonstrated that the late variants are cytopathic and syncytia-inducing compared to SIVMneCL8, but the variants replicate less efficiently in primary macaque macrophages. V3 sequences were generally conserved between the early and the late variants, suggesting that changes in SIVMne tropism, replication, and cytopathicity were apparently not due to alterations in V3. This study demonstrates important similarities in the phenotypic viral changes that accompany development of AIDS in SIV and HIV-1 infections and suggest that SIV may provide a model system for determining whether the rapidly replicating, T-cell-tropic cytopathic variants present late in infection and disease are indeed important in determining progression to AIDS.

Characterization of infectious type D retrovirus from baboons.

Infectious virus resembling type D simian retrovirus (SRV) was isolated from Ethiopian baboons (Papio cynocephalus) (SRV-Pc) housed at the University of Washington Regional Primate Research Center. When baboon peripheral blood mononuclear cells (PBMC) or tissues were cocultured with the H-9 human T-cell line or the Raji human B-cell line, large multinucleated syncytia positive for SRV-2 antigens were observed microscopically. Immunoblot analysis of purified SRV-Pc from cell culture supernatants demonstrated that the viral core and envelope proteins reacted with rabbit anti-SRV-2 serum. Fresh PBMC and cocultured cells were positive by polymerase chain reaction using two different sets of SRV-2 primers. Preliminary sequence analysis of two separate isolates from portions of the SRV-Pc p27 and gp20 regions revealed homology with SRV-1, SRV-2, and Mason-Pfizer monkey virus. The homologies in the p27 segment were 91-94% and the homologies in the gp20 segment were 72-75%.

T-cell proliferation to subinfectious SIV correlates with lack of infection after challenge of macaques.

OBJECTIVES: To analyze correlates of protection in macaques exposed to SIV. METHODS: Peripheral blood mononuclear cells (PBMC) from macaques inoculated intrarectally with various dilutions of SIV were examined for their in vitro proliferative response to SIV envelope peptides and generation of SIV-specific antibodies. Some macaques previously exposed intravenously to subinfectious doses of SIV were subsequently challenged 16 months later with an infectious intrarectal dose of SIV. RESULTS: The viral-specific immune responses of macaques exposed to infectious doses of SIV were characterized by generation of antibodies and weak or undetectable T-cell-mediated responses. In contrast, macaques inoculated with doses of SIV below the threshold required for seroconversion and recovery of virus exhibited T-cell proliferation in response to SIV envelope synthetic peptides. The macaques that had previously been exposed to SIV resisted the subsequent virus challenge, whereas the naive macaques (never exposed to SIV) all became infected. CONCLUSIONS: The inability to productively infect macaques previously exposed to subinfectious doses of SIV suggests that a T-cell-mediated response may confer long-term protection against infection, and that AIDS vaccines should be designed to optimize the cellular arm of the immune response.

Passively transferred antibodies directed against conserved regions of SIV envelope protect macaques from SIV infection.

Inactivated plasma collected from either SIV-infected or peptide-vaccinated macaques was transferred into 17 naive rhesus monkeys. Two additional macaques received normal plasma and served as controls. Following transfer all 19 monkeys were inoculated with SIV. While the controls became infected and were virus-isolation-positive, 3 of 6 recipients of SIV peptide vaccine plasma and 9 of 11 recipients of SIV-infected monkey plasma were protected. None of the 12 protected animals became virus-isolation-positive or seroconverted within 100 days of follow-up. One, however was SIV-PCR-positive. All 12 protected animals were rechallenged 100 days after the initial inoculation; 8 became infected and yielded virus as expected, but 4 remained uninfected. One of the latter was the SIV-PCR-positive monkey mentioned above, suggesting that cryptic SIV infection may be of significance in immunological protection. The results demonstrate that envelope anti-peptide antibodies have similar protective potential in vivo as antibodies directed to the whole virus. In vitro neutralization competition assays performed with sera from vaccinated macaques in the presence of the free peptides suggest that of the four conserved envelope peptides of the vaccine, the two originating from gp41 rather than the two from gp120 are responsible for inducing the neutralizing anti-syncytial activity.

Detection of serum antibodies in Ethiopian baboons that cross-react with SIV, HTLV-I, and type D retroviral antigens.

Baboons (Papio cynocephalus) imported from Ethiopia were screened for antibodies to various primate retroviruses by immunoblotting. Antibodies that cross-reacted with SIV/Mne or with type D viral antigens were detected in approximately one-third of these animals. In addition, 20% of these baboons had antibodies that cross-reacted with HTLV-I viral antigens. These data suggest that wild-caught baboons are infected with retroviruses only partially related to known primate viral isolates.

Long-term protection of macaques against high-dose type D retrovirus challenge after immunization with recombinant vaccinia virus expressing envelope glycoproteins.

Recombinant vaccinia virus expressing the envelope proteins of type D retrovirus-Washington (SRV-2/W) was used to immunize macaques against SRV-2 infection. Four immunized macaques which had resisted a prior low-dose challenge were rechallenged with a high dose (10(6) infectious particles) of SRV-2 two years after being immunized. All four non-immunized control macaques became infected, but the four vaccinated animals resisted this intravenous challenge, as determined by the inability to detect SRV-2 in peripheral blood mononuclear cells and by the lack of seroconversion to new viral antigens.

Protection of vaccinia-primed macaques against SIVmne infection by combination immunization with recombinant vaccinia virus and SIVmne gp160.

Two Macaca fascicularis with preexisting immunity to vaccinia virus were immunized twice with recombinant vaccinia virus expressing SIVmne gp160. Their SIV-specific antibody responses were lower than that of vaccinia-naive animals immunized similarly. Upon repeated boosting with gp160, the SIV-specific antibody titers in vaccinia-primed animals reached similar levels as vaccinia-naive animals and with comparable neutralizing titers. Both animals were protected against repeated intravenous challenge with low-dose SIVmne E11S. These results are significant because SIVmne E11S infection in M. fascicularis is pathogenic and leads to AIDS-like diseases.

Prevention of transmission of simian immunodeficiency virus from vaccinated macaques that developed transient virus infection following challenge.

Macaque immunization with a mixture of four SIV peptides from conserved hydrophilic envelope regions has been shown to prevent virus persistence following challenge with SIVmne/E11s. Data shown here demonstrate that lymph node cells from all vaccinated monkeys and peripheral blood lymphocytes from one of the vaccinees were positive in a SIV-pol 'nested' polymerase chain reaction (PCR) amplification analysis. However, by 37 months after infection, all immunized monkeys were healthy while two of three controls had died and the remaining animal was virus culture-positive and had declining CD4+ lymphocytes. Viable lymph node cells and peripheral lymphoid cells in blood were transferred from the three immunized macaques to individual susceptible macaques. As a control for the transfer, one of the vaccine experiment controls that was actively producing virus in its peripheral blood was used. None of the recipients of cells from the vaccinated macaques seroconverted and all were virus coculture- and PCR-negative 25 weeks post-transfer (p.t.). The recipient of cells from the control infected macaque became positive in these tests by 2-3 weeks p.t. These results suggest that, while peptide-vaccinated macaques permitted some level of SIV replication following challenge, the vaccine prevented disease progression and virus transmission.

Cellular proteins bound to immunodeficiency viruses: implications for pathogenesis and vaccines.

Cellular proteins associated with immunodeficiency viruses were identified by determination of the amino acid sequence of the proteins and peptides present in sucrose density gradient-purified human immunodeficiency virus (HIV)-1, HIV-2, and simian immunodeficiency virus (SIV). beta 2 microglobulin (beta 2m) and the alpha and beta chains of human lymphocyte antigen (HLA) DR were present in virus preparations at one-fifth the concentration of Gag on a molar basis. Antisera to HLA DR, beta 2 m, as well as HLA class I precipitated intact viral particles, suggesting that these cellular proteins were physically associated with the surface of the virus. Antisera to class I, beta 2m, and HLA DR also inhibited infection of cultured cells by both HIV-1 and SIV. The specific, selective association of these cellular proteins in a physiologically relevant manner has major implications for our understanding of the infection process and the pathogenesis of immunodeficiency viruses and should be considered in the design of vaccines.

Protection of macaques against SIV infection by subunit vaccines of SIV envelope glycoprotein gp160.

Simian immunodeficiency virus (SIV) is a primate lentivirus related to human immunodeficiency viruses and is an etiologic agent for acquired immunodeficiency syndrome (AIDS)-like diseases in macaques. To date, only inactivated whole virus vaccines have been shown to protect macaques against SIV infection. Protective immunity was elicited by recombinant subunit vaccines. Four Macaca fascicularis were immunized with recombinant vaccinia virus expressing SIVmne gp160 and were boosted with gp160 produced in baculovirus-infected cells. All four animals were protected against an intravenous challenge of the homologous virus at one to nine animal-infectious doses. These results indicate that immunization with viral envelope antigens alone is sufficient to elicit protective immunity against a primate immunodeficiency virus. The combination immunization regimen, similar to one now being evaluated in humans as candidate human immunodeficiency virus (HIV)-1 vaccines, appears to be an effective way to elicit such immune responses.

Protection of macaques with a simian immunodeficiency virus envelope peptide vaccine based on conserved human immunodeficiency virus type 1 sequences.

This report describes the vaccination of rhesus macaques with peptides selected from regions of the simian immunodeficiency virus (SIV) envelope that are hydrophilic, immunoreactive, and highly homologous with corresponding conserved envelope sequences of the human immunodeficiency virus (HIV). The peptides, produced as beta-galactosidase fusion proteins, induced virus-neutralizing and peptide-specific antibodies. After challenge with virulent virus, controls became virus positive and developed gradually rising antibody titers to SIV over 63 weeks. Immunized macaques developed a postchallenge anamnestic response to SIVenv antigens within 3-6 weeks followed by a gradual, fluctuating decline in SIV antibody titers and partial or total suppression of detectable SIV. Virus suppression correlated with prechallenge neutralizing antibody titers. Although the average CD4+ cell count in the blood of immunized macaques remained constant, the control macaques exhibited a progressive decrease developing about week 55 after challenge. The conserved nature of the HIV and SIV peptides and the similar humoral immunoreactivity in the respective hosts suggest that homologous HIV peptides may be important components of a successful immunization strategy.

Viral and cellular gene expression in CD4+ human lymphoid cell lines infected by the simian immunodeficiency virus, SIV/Mne.

Our laboratory has undertaken an analysis of cellular and viral gene expression in CD4+ human lymphoid cell lines infected by the human and simian immunodeficiency viruses, HIV-1 and SIV/Mne, respectively. The purpose of the current study was to: (i) examine the effects of SIV/Mne infection on host macromolecular synthesis and compare the results to those in the HIV-1 system; and (ii) investigate the mechanisms responsible for the restriction of SIV/Mne infection in CD4 positive lymphoid cells which are readily infected by HIV-1. First we determined that SIV does not impose selective blocks on host macromolecular synthesis, unlike HIV-1, which induces both the selective inhibition of cellular protein synthesis and the degradation of cellular mRNAs (Agy, M., Wambach, M., Foy, K., and Katze, M. G., 1990, Virology 177, 251-258). No such selective reduction in cellular mRNA stability or protein synthesis was observed in cells infected by SIV/Mne. Additional differences between SIV and HIV-1 were observed using a panel of CD4+ human cell lines. While HIV-1-infected all cell lines. SIV/Mne efficiently infected only the MT-4, C8166, and 174 x CEM cell lines. Repeated efforts to infect CEM or Jurkat cells were unsuccessful as determined by PCR analysis of viral DNA. HUT 78 cells supported a limited infection detectable only by PCR analysis. These data suggest the block in viral replication in the nonsusceptible cell lines is at an early step. Interestingly, all the SIV susceptible cells were virally transformed, C8166 and MT-4 by HTLV-1, and 174 x CEM by Epstein-Barr virus. Furthermore FACS analysis revealed that all susceptible cells expressed two B cell associated markers, B7/BB1 and CD40. These observations taken together highlight differences between the HIV and SIV viruses, and suggest that for efficient replication, SIV/Mne may require an additional cell surface molecule, cofactors provided by transforming viruses, or a complex interplay between the two.