Endocytosis of endogenously synthesized HIV-1 envelope protein. Mechanism and role in processing for association with class II MHC.

CD4+ T cell clones specific for the HIV-1 envelope (env) protein are able to recognize not only uninfected APC that have taken up and processed exogenous env protein, but also virally infected cells expressing the env protein. We have evaluated the hypothesis that endocytosis of endogenously synthesized env protein from the plasma membrane of infected cells permits entry of the protein into the MHC class II-restricted Ag processing pathway. We show here that the env protein of HIV-1 is internalized at a surprisingly high rate through a mechanism that is dependent upon a tyrosine-containing motif located in the cytoplasmic domain of the gp41 subunit. Mutation of a critical cytoplasmic tyrosine residue or truncation of the C-terminal portion of the cytoplasmic domain resulted in forms of the env protein that did not undergo rapid internalization. However, by a variety of assays, these poorly internalized forms of the env protein were processed for class II-restricted Ag presentation as efficiently as wild-type env protein, indicating that internalization by this pathway is not essential for class II-restricted presentation. In addition, a secreted form of the env protein was presented efficiently by class II MHC under conditions that prevented re-uptake by endocytosis. Taken together, these results suggest that although rapid endocytosis from the cell surface is likely to be a major mechanism by which endogenously synthesized env protein is processed for association with class II MHC, an internal pathway may also be used.

Studies of the mechanism of cytolysis by HIV-1-specific CD4+ human CTL clones induced by candidate AIDS vaccines.

Vaccine-induced, virus-specific CTLs may rapidly eliminate the host cells that first become infected after virus exposure, thereby preventing disseminated infection. Thus, there is much interest in the ability of candidate AIDS vaccines to elicit CTLs. All HIV-1 envelope (env) protein-based vaccines tested to date in seronegative humans induce CTLs from the CD4+ subset. Because the mechanism of cytolysis by CD4+ CTLs is controversial, a detailed study of the cytolytic reactions mediated by vaccine-induced, HIV-1-specific human CD4+ CTL clones was conducted. CD4+ CTL clones induced rapid destruction of Ag-pulsed target cells. Lysis was readily detectable within 15 min. Lysis was not a result of syncytium formation between CD4+ effector cells and env-expressing targets. Target cell destruction was not dependent upon de novo RNA or protein synthesis in either the effector or the target cell. Expression of perforin mRNA was detected by Northern blotting and reverse-transcriptase-PCR in CD4+ CTL clones but not in autologous B lymphoblastoid cell lines. Immunohistochemical studies demonstrated perforin protein in cytoplasmic granules in CD4+ CTL clones. Lysis by CD4+ CTLs was strictly dependent upon extracellular Ca2+ and was highly specific, with no lysis of innocent bystander cells. DNA fragmentation was detectable in target cells, but did not precede 51Cr release. Taken together, these results provide a dramatically different view of cytolysis by human CD4+ CTLs. Target cells are lysed by a rapid and efficient mechanism that involves a preformed mediator and that is functionally similar to the mechanism used by CD8+ CTLs.

Cytokines from vaccine-induced HIV-1 specific cytotoxic T lymphocytes: effects on viral replication.

Cytolytic T lymphocytes (CTLs) specific for the human immunodeficiency virus (HIV-1) envelope glycoproteins have been cloned from HIV-1-seronegative human volunteers immunized with HIV-1 gp160-based candidate vaccines. Although vaccine-induced CTLs can potentially contribute to the antiviral response by direct lysis of infected cells, these CTLs may also produce cytokines that alter HIV-1 gene expression in other infected cells present in the microenvironment where CTL-target cell interactions occur. Vaccine-induced CTL clones were therefore examined for production of cytokines that affect HIV-1 gene expression in chronically infected T lymphocytic and promonocytic cell lines. Enhancement of HIV-1 gene expression was observed with supernatants from CD4+ CTL clones and with supernatants from a subset of CD8+ CTL clones. For each clone studied, upregulation of HIV-1 gene expression in chronically infected T cell lines resulted from the antigen-specific release by CTLs of tumor necrosis factor alpha (TNF-alpha). CD4+ and CD8+ CTLs that released TNF-alpha on antigen stimulation were also shown to express a biologically active 26-kDa transmembrane form of TNF-alpha, which was sufficient to induce upregulation of HIV-1 gene expression in chronically infected T cells placed in direct contact with the CTLs. Supernatants from antigen-activated, vaccine-induced CD4+ and CD8+ CTLs also caused upregulation of HIV-1 gene expression in chronically infected promonocytic cells. A subset of CD8+ CTL clones also produced a soluble factor(s) that inhibited HIV-1 replication in acutely infected autologous CD4+ blasts. Supernatants from CD4+ CTLs had no effect on HIV-1 replication in acutely infected CD4+ blasts. These results suggest that cytokine production as well as cytolytic activity should be evaluated in the analysis of the potential antiviral effects of vaccine-induced CTLs.

Human CD4+ cytolytic T lymphocyte responses to a human immunodeficiency virus type 1 gp160 subunit vaccine.

The development of an effective vaccine against human immunodeficiency virus type 1 (HIV-1) may require immunization protocols that elicit cytolytic T lymphocytes (CTL) in addition to neutralizing antibodies. This report demonstrates that vaccination of 4 HIV-1-seronegative volunteers with a recombinant HIV-1 gp160 vaccine produced in mammalian cells elicited a CTL response in 3. The observed CTL activity was not mediated by classic CD8+ CTL but rather by cells of the CD4+ phenotype. The level of CTL activity varied over time, did not correlate with the proliferative response to gp160, and was not increased by repeated immunization. At the clonal level, the vaccine was shown to elicit a functionally heterogeneous CD4+ T cell response that included clones with antigen-specific, major histocompatibility complex-restricted cytolytic activity. These clones were capable of lysing target cells expressing the HIV-1 env gene and thus might be active against HIV-1-infected cells in vivo.

An HIV-1 envelope protein vaccine elicits a functionally complex human CD4+ T cell response that includes cytolytic T lymphocytes.

T cell responses play a critical role in host defense against viral infection. Therefore, the functional properties of HIV-1-specific human T cells induced by an experimental AIDS vaccine were analyzed in detail at the clonal level. Seronegative human volunteers were immunized with a purified recombinant form of the HIV-1 envelope glycoprotein gp160 in a phase I vaccine trial. In a subset of gp160 recipients, this vaccine was shown to elicit a virus-specific CTL response. Antibody blocking and single cell cloning experiments demonstrated that the vaccine-induced cytolytic activity was mediated by CD4+, MHC class II-restricted T cells. Because little is known about the regulation of CD4+ CTL in any system, a detailed analysis of CTL responses in vaccinees was carried out. Longitudinal and cross-sectional studies revealed that the CD4+ CTL response was regulated in a complex manner and was not clearly correlated with MHC class II genotype, Ag dose, or number of immunizations. Cloning studies were carried out to determine what fraction of the vaccine-induced T cells were cytolytic and to examine patterns of cytokine production by vaccine-induced T cells. These experiments demonstrated that, for some vaccinees, CD4+ CTL dominated the in vitro T cell response to gp160 at certain time points. The level of cytolytic activity, which was a stable property of individual clones, varied among clones over a wide and continuous range. Analysis of cytokine secretion by gp160-specific CD4+ T cell clones revealed Th0-, Th1-, and Th2-like patterns, with CD4+ CTL clones showing Th0- or T'1-like patterns. Interestingly, many Th0- and Th1-like CTL clones produced very little IL-2, a finding that may explain the complicated regulation of this response. These results illustrate the complex nature of the human T cell response to subunit vaccines consisting of purified recombinant viral proteins.

Comparative clonal analysis of human immunodeficiency virus type 1 (HIV-1)-specific CD4+ and CD8+ cytolytic T lymphocytes isolated from seronegative humans immunized with candidate HIV-1 vaccines.

The lysis of infected host cells by virus-specific cytolytic T lymphocytes (CTL) is an important factor in host resistance to viral infection. An optimal vaccine against human immunodeficiency virus type 1 (HIV-1) would elicit virus-specific CTL as well as neutralizing antibodies. The induction by a vaccine of HIV-1-specific CD8+ CTL in humans has not been previously reported. In this study, CTL responses were evaluated in HIV-1-seronegative human volunteers participating in a phase I acquired immune deficiency syndrome (AIDS) vaccine trial involving a novel vaccine regimen. Volunteers received an initial immunization with a live recombinant vaccinia virus vector carrying the HIV-1 env gene and a subsequent boost with purified env protein. An exceptionally strong env-specific CTL response was detected in one of two vaccine recipients, while modest but significant env-specific CTL activity was present in the second vaccinee. Cloning of the responding CTL gave both CD4+ and CD8+ env-specific CTL clones, permitting a detailed comparison of critical functional properties of these two types of CTL. In particular, the potential antiviral effects of these CTL were evaluated in an in vitro system involving HIV-1 infection of cultures of normal autologous CD4+ lymphoblasts. At extremely low effector-to-target ratios, vaccine-induced CD8+ CTL clones lysed productively infected cells present within these cultures. When tested for lytic activity against target cells expressing the HIV-1 env gene, CD8+ CTL were 3-10-fold more active on a per cell basis than CD4+ CTL. However, when tested against autologous CD4+ lymphoblasts acutely infected with HIV-1, CD4+ clones lysed a much higher fraction of the target cell population than did CD8+ CTL. CD4+ CTL were shown to recognize not only the infected cells within these acutely infected cultures but also noninfected CD4+ T cells that had passively taken up gp120 shed from infected cells and/or free virions. These results were confirmed in studies in which CD4+ lymphoblasts were exposed to recombinant gp120 and used as targets for gp120-specific CD4+ and CD8+ CTL clones. gp120-pulsed, noninfected targets were lysed in an antigen-specific fashion by CD4+ but not CD8+ CTL clones. Taken together, these observations demonstrate that in an in vitro HIV-1 infection, sufficient amounts of gp120 antigen are produced and shed by infected cells to enable uptake by cells that are not yet infected, resulting in the lysis of these noninfected cells by gp120-specific, CD4+ CTL.(ABSTRACT TRUNCATED AT 400 WORDS)

Clonal analysis of T-cell responses to the HIV-1 envelope proteins in AIDS vaccine recipients.

Both CD4+ and CD8+ CTL responses specific for the HIV-1 envelope proteins can be elicited in seronegative humans by candidate AIDS vaccines. The phenotype of the responding CTL depends upon the nature of the vaccine, with CD8+ CTL being found exclusively in recipients of live virus vaccines. Both types of CTL are active against HIV-1-infected cells in vitro. However, the potential efficacy of vaccine-induced CTL in preventing infection in vaccinated individuals exposed to HIV-1 is unknown and is likely to be dependent upon complex factors including lytic activity against divergent strains, cytokines produced, and the lysis of noninfected CD4+ T cells.

Production of transmembrane and secreted forms of tumor necrosis factor (TNF)-alpha by HIV-1-specific CD4+ cytolytic T lymphocyte clones. Evidence for a TNF-alpha-independent cytolytic mechanism.

Candidate AIDS vaccines consisting of recombinant forms of the HIV-1 envelope glycoprotein induce, in seronegative human volunteers, an env-specific T cell response that includes CD4+, MHC class II-restricted CTL capable of lysing HIV-1-infected target cells. In this study, we have analyzed the production of the cytokines TNF-alpha and lymphotoxin (LT) by a set of env-specific CD4+ human CTL clones. TNF-alpha and LT are of interest because of their potential role in target cell destruction by CD4+ CTL. Our studies focused on the possibility that a cell surface form of TNF-alpha expressed by CTL after physiologic activation with target APC might participate in the cytolytic reactions mediated by these clones. We found that, upon interaction with target cells expressing env epitopes in the context of the appropriate MHC class II molecules, CD4+ CTL released TNF-alpha with kinetics that were rapid, compared with other cytokines, and that were generally similar to the kinetics of target cell destruction. LT secretion was not detected during the time course of the cytolytic reactions. A novel flow cytometric assay was used to show that physiologic activation of CD4+ CTL with target APC induced expression by the CTL of cell surface forms of TNF-alpha. Immunoprecipitations from activated, surface-iodinated CTL clones revealed two forms of surface TNF-alpha, a 26-kDa form, representing the transmembrane precursor of secreted TNF-alpha, as well as the 17-kDa secreted form bound to the cell surface. For a subset of CD4+ CTL, we found that treatment of CTL with cyclosporin A inhibited Ag-induced production of both transmembrane and secreted forms of TNF-alpha but had no effect on cytolysis. Thus, although transmembrane and secreted TNF-alpha produced by HIV-1-specific CD4+ CTL may have important effects in vivo, the rapid destruction of target APC by the set of CD4+ CTL clones described here occurs through a TNF-alpha-independent mechanism.