Analysis of cytotoxic T lymphocyte responses to SIV proteins in SIV-infected macaques using antigen-specific stimulation with recombinant vaccinia and fowl poxviruses

Induction of simian immunodeficiency virus (SIV)-specific CTL in rhesus macaques by vaccination with modified vaccinia virus Ankara expressing SIV transgenes: influence of pre-existing anti-vector immunity

A major aim in AIDS vaccine development is the definition of strategies to stimulate strong and durable cytotoxic T lymphocyte (CTL) responses. Here we report that simian immunodeficiency virus (SIV)-specific CTL developed in 4/4 macaques following a single intramuscular injection of modified vaccinia virus Ankara (MVA) constructs expressing both structural and regulatory/accessory genes of SIV. In two animals Nef-specific responses persisted, but other responses diminished and new responses were not revealed, following further vaccination. Vaccination of another two macaques, expressing Mamu A*01 MHC class I, with MVA constructs containing nef and gag-pol under the control of the moderate strength natural vaccinia virus early/late promoter P7.5, again induced an early Nef-specific response, whereas responses to Gag remained undetectable. Anti-vector immunity induced by this immunization was shown to prevent the efficient stimulation of CTL directed to the cognate Gag epitope, p11C C-M, following vaccination with another MVA construct expressing SIV Gag-Pol under a strong synthetic vaccinia virus-specific promoter. In contrast, vaccination of a previously unexposed animal resulted in a SIV-specific CTL response widely disseminated in lymphoid tissues including lymph nodes associated with the rectal and genital routes of SIV entry. Thus, despite the highly attenuated nature of MVA, repeated immunization may elicit sufficient anti-vector immunity to limit the effectiveness of later vaccination.

Detection of simian immunodeficiency virus (SIV)-specific T-cell-mediated cytotoxicity in the peripheral blood from infected cynomolgus monkeys

We have previously demonstrated that peptide immunization restimulates the memory CD4 T-cell response, but fails to induce cytotoxic T lymphocyte (CTL) in cynomolgus macaques. To examine the nature of protective immunity to simian immunodeficiency virus (SIV) in this study, freshly isolated peripheral blood mononuclear cells (PBMC) from four infected juvenile cynomolgus macaques and from three uninfected control macaques were assessed for CTL activity monthly for 9 consecutive months, beginning 1 month after detection of infection. Target cells consisted of major histocompatibility (MHC) haploidentical parental PBMC which were stimulated with mitogen and then pulsed with heat-killed SIVcyn. CTL activity was demonstrated in PBMCs from all four infected animals. The effector cells are T cells which mediate cytotoxicity against SIVcyn-pulsed target cells in an MHC-restricted manner. Furthermore, the cytotoxicity is virus specific and predominantly, if not exclusively, mediated by CD8+ T cells; it is also MHC class I restricted. Incubation of target cells with pepstatin A during antigen pulsing prior to the cytotoxic assay inhibited target cell generation, suggesting that viral antigens are processed via an endocytic pathway.

Antigen-specific cytokine responses in vaccinated Macaca nemestrina

We describe a new surrogate assay for CD8 + T lymphocyte activity that has the capability of discriminating between cytotoxic T lymphocyte (CTL) activity and cytokine-mediated suppressive activity. We applied this approach to two groups of Macaca nemestrina vaccinated with a minimally pathogenic strain of human immunodeficiency virus type 2 [HIV-2 (HIV-2(KR))] as a model of an attenuated virus vaccine. Group 1 was then inoculated with a non-infectious stock of a pathogenic strain, HIV-2287. Both groups 1 and 2 were subsequently challenged with an infectious stock of HIV-2287. Five out of six group 1 animals were protected against CD4 decline, whereas three out of six animals in group 2 were protected. Analysis of CTL responses demonstrated strong activity against HIV-2(KR)-Gag in group 1. It was determined that strong CTL responses correlate with antigen-specific T-helper (Th) type 1 responses. This antigen-specific cytokine assay has the potential to better elucidate the functional mechanisms of CD8 + T-cell-mediated protection than traditional methods to date.

New technologies for making vaccines

Technologies for making active vaccines fall into 3 general groups: live, subunit (killed or inactivated) and genetic. Each of these groups is further divisible into multiple categories, which include recombinant-derived antigens as well as native microorganisms and their components. In addition, there are new enabling technologies such as delivery systems and vectors which can be applied to these approaches. Most disease targets, whether infectious or noninfectious in origin, can be approached by the application of several different vaccine technologies, as can be tested during the discovery phase of research. The criteria for choosing early in a development program which of the vaccine technologies are likely to ultimately be most fruitful for a given application include: knowledge of the pathogenesis of the given infection/disease; technical feasibility; immunobiology and associated mechanisms; preclinical efficacy profile; anticipated clinical safety; regulatory; manufacturing; and marketing. All of these criteria should be considered together in making selections for an R&D program. This paper is reviewing the major vaccine technologies and relevant examples of how these criteria are used to make decisions in vaccine development.

Mechanisms of protection induced by attenuated simian immunodeficiency virus. II. Lymphocyte depletion does not abrogate protection

To determine the role that cellular immune responses play in the protection conferred by vaccination with attenuated SIVmac32H (pC8), we have attempted to deplete macaques of their CD8+ cells prior to challenge with wild-type SIVmac32H (pJ5). In two of four pC8-infected macaques, N109 and N112, a transient partial depletion of CD8+ cells by antibody treatment was achieved. On the day of challenge peripheral CD2+CD4-CD8+ cell counts were reduced by 92 and 95%, respectively, in animals N109 and N112 and their lymph nodes revealed a 46 and 58% reduction, respectively, in CD2+CD4-CD8+ cells. Two other pC8-immunized macaques, N110 and N111, treated in the same way, did not show significant depletion of CD8+ cells. None of these four pC8-immunized animals became infected when challenged with 50 MID50 of pJ5. Treatment of a further four pC8-infected and protected macaques and two naive control animals with Campath-1H antibody successfully depleted peripheral CD3+ cell counts by >99% in all treated animals. Campath-1H depletion resulted in enhanced, longer lasting lymphoid depletion. Yet subsequent challenge with 20 MID50 of pJ5 still failed to infect the pC8-immunized animals. All eight of the naive controls, including two Campath-1H-treated animals, became infected following challenge. In summary, partial depletion of circulating CD8+ cells or total lymphocytes prior to challenge failed to abrogate the protection conferred by vaccination with pC8.

Diversified prime and boost protocols using recombinant vaccinia virus and recombinant non-replicating avian pox virus to enhance T-cell immunity and antitumor responses

Recombinant vaccinia viruses containing tumor associated genes represent an attractive vector to induce immune responses to weak immunogens in cancer immunotherapy protocols. The property of intense immunogenicity of vaccinia proteins, however, also serves to limit the number of inoculations of recombinant vaccinia viruses. Host immune responses to the first immunization have been shown to limit the replication of subsequent vaccinations and thus reduce effectiveness of boost inoculations. The use of recombinant avian pox viruses (avipox) such as the canarypox (ALVAC) or fowlpox are potential candidates for immunization protocols in that they can infect mammalian cells and express the inserted transgene, but do not replicate in mammalian cells. We report here the construction and characterization of a canarypox (ALVAC) recombinant expressing the human carcinoembryonic antigen (CEA) gene (designated ALVAC-CEA). Antibody, lymphoproliferative and cytolytic T-cell responses as well as tumor inhibition were shown to be elicited by the ALVAC-CEA recombinant in a murine model. The utilization of a diversified immunization scheme using a recombinant vaccinia virus followed by recombinant avian pox virus was shown to be far superior than the use of either one alone in eliciting CEA-specific T-cell responses. Experiments were conducted to determine if the use of a diversified immunization scheme using a recombinant vaccinia virus (rV-CEA) and ALVAC-CEA would be superior to the use of either one alone in eliciting CEA-specific T-cell responses. When mice were immunized with rV-CEA and then ALVAC-CEA. CEA-specific T-cell responses were at least four times greater, and for superior to those achieved with three immunizations of ALVAC-CEA. Multiple boosts of ALVAC-CEA following rV-CEA immunization further potentiated anti-tumor effects and CEA specific T-cell responses. These studies demonstrate the proof of concept of the advantage of diversified immunization protocols employing both recombinant vaccinia and recombinant avipox vectors.

Detection of simian immunodeficiency virus (SIV)-specific CD8+ T cells in macaques protected from SIV challenge by prior SIV subunit vaccination

Vaccines for lentiviruses would ideally induce in the host complete resistance to infection of host cells. However, such sterilizing immunity may be neither readily achievable nor absolutely necessary to provide protection from exposure to the immunodeficiency viruses. To examine the nature of protective immunity to simian immunodeficiency virus (SIV), we studied three macaques that had been immunized with a recombinant vaccinia virus-based SIV subunit vaccine regimen and exhibited protection from a challenge with cell-free SIV (MNE) as determined by viral cultures, serology, and PCR for viral genomes. Peripheral blood mononuclear cells were obtained from the protected macaques and analyzed for CD8+ cytotoxic T-lymphocyte (CTL) responses to SIV proteins. CTL reactive to SIV proteins not included in the subunit vaccine, and thus to which these animals had not been exposed prior to challenge, were detected postchallenge in the vaccine-protected animals and persisted for up to 1 year. These CTL, as reflected by studies of cytolytic lines and derived T-cell clones, were CD8+, did not recognize allogeneic targets, and recognized the SIV proteins in the context of class I major histocompatibility complex molecules. The frequency of precursor CD8+ CTL reactive to SIV proteins was determined by limiting-dilution analysis and demonstrated that the responses elicited following challenge of protected animals to SIV proteins not present in the vaccine were quantitatively similar to those of animals persistently infected with SIV. The presence of these CD8+ CTL responses to SIV proteins present only in the challenge virus suggests that infection of some host cells occurred postchallenge. These results suggest that the development of a low level of SIV infection following exposure of vaccinated hosts to SIV does not preclude protection from lethal SIV disease by vaccine-induced immunity.

Cytotoxic and proliferative T cell responses in HIV-1-infected Macaca nemestrina

Macaca nemestrina has been described as an animal model for acute HIV-1 infection. This animal, unlike most infected humans, appears to contain HIV-1 replication. Therefore analysis of HIV-1-specific proliferative and cytotoxic T lymphocyte (CTL) responses following HIV-1 challenge of M. nemestrina may provide information into the role of such responses in both the control of acute HIV infection and protective immunity. Although CD4+ T cell responses to HIV-1 are generally difficult to detect in HIV-1-infected humans, early and persistent CD4+ T cell proliferative responses to HIV-1 antigens were detected in all HIV-1-inoculated M. nemestrina. HIV-1-specific CD8+ CTL responses were evaluated in PBMC by stimulation with autologous cells expressing HIV-1 genes, limiting dilution precursor frequency analysis, and T cell cloning. CTL reactive with gag, env, and nef were present 4-8 wk after infection, and persisted to 140 wk after infection. The presence of both CD4+ and CD8+ T cell responses before and after clearance of HIV-1 viremia is consistent with a role for these responses in the successful control of HIV-1 viral replication observed in M. nemestrina. Further studies of T cell immunity in these animals that resist disease should provide insights into the immunobiology of HIV-1 infection.