Virus-specific CD8(+) T-cell responses play a pivotal role in limiting viral replication. Alterations in these responses, such as decreased cytolytic function, inappropriate maturation, and limited proliferative ability could reduce their ability to control viral replication. Here, we report on the capacity of HIV-specific CD8(+) T cells to secrete cytokines and proliferate in response to HIV antigen stimulation. We find that a large proportion of HIV-specific CD8(+) T cells that produce cytokines in response to cognate antigen are unable to divide and die during a 48-hour in vitro culture. This lack of proliferative ability of HIV-specific CD8(+) T cells is defined by surface expression of CD57 but not by absence of CD28 or CCR7. This inability to proliferate in response to antigen cannot be overcome by exogenous interleukin-2 (IL-2) or IL-15. Furthermore, CD57 expression on CD8(+) T cells, CD4(+) T cells, and NK cells is a general marker of proliferative inability, a history of more cell divisions, and short telomeres. We suggest, therefore, that the increase in CD57(+) HIV-specific CD8(+) T cells results from chronic antigen stimulation that is a hallmark of HIV infection. Thus, our studies define a phenotype associated with replicative senescence in HIV-specific CD8(+) T cells, which may have broad implications to other conditions associated with chronic antigenic stimulation.
The epidermal growth factor receptor (EGFR) is often amplified and rearranged structurally in tumors of the brain, breast, lung, and ovary. The most common mutation, EGFRvIII, is characterized by an in-frame deletion of 801 base pairs, resulting in the generation of a novel tumor-specific epitope at the fusion junction. A murine homologue of the human EGFRvIII mutation was created, and an IgG2a murine mAb, Y10, was generated that recognizes the human and murine equivalents of this tumor-specific antigen. In vitro, Y10 was found to inhibit DNA synthesis and cellular proliferation and to induce autonomous, complement-mediated, and antibodydependent cell-mediated cytotoxicity. Systemic treatment with i.p. Y10 of s.c. B16 melanomas transfected to express stably the murine EGFRvIII led to long-term survival in all mice treated (n ؍ 20; P < 0.001). Similar therapy with i.p. Y10 failed to increase median survival of mice with EGFRvIII-expressing B16 melanomas in the brain; however, treatment with a single intratumoral injection of Y10 increased median survival by an average 286%, with 26% long-term survivors (n ؍ 117; P < 0.001). The mechanism of action of Y10 in vivo was shown to be independent of complement, granulocytes, natural killer cells, and T lymphocytes through in vivo complement and cell subset depletions. Treatment with Y10 in Fc receptor knockout mice demonstrated the mechanism of Y10 to be Fc receptor-dependent. These data indicate that an unarmed, tumor-specific mAb may be an effective immunotherapy against human tumors and potentially other pathologic processes in the ''immunologically privileged'' central nervous system. central nervous system neoplasms ͉ epidermal growth factor receptor ͉ immunotherapy
The use of recombinant T cell receptors (TCRs) to target therapeutic interventions has been hindered by the naturally low affinity of TCR interactions with peptide major histocompatibility complex ligands. Here, we use multimeric forms of soluble heterodimeric ␣ TCRs for specific detection of target cells pulsed with cognate peptide, discrimination of quantitative changes in antigen display at the cell surface, identification of virusinfected cells, inhibition of antigen-specific cytotoxic T lymphocyte activation, and identification of cross-reactive peptides. Notably, the A6 TCR specific for the immunodominant HLA A2-restricted human T cell leukemia virus type 1 Tax 11-19 epitope bound to HLA A2-HuD 87-95 (K D 120 M by surface plasmon resonance), an epitope implicated as a causal antigen in the paraneoplastic neurological degenerative disorder anti-Hu syndrome. A mutant A6 TCR that exhibited dramatically increased affinity for cognate antigen (K D 2.5 nM) without enhanced cross-reactivity was generated; this TCR demonstrated potent biological activity even as a monomeric molecule. These data provide insights into TCR repertoire selection and delineate a framework for the selective modification of TCRs in vitro that could enable specific therapeutic intervention in vivo.Peptide major histocompatibility complex (pMHC) 1 antigens displayed on the surface of target cells are recognized by T cells via their specific T cell receptor (TCR) (1). The TCR coreceptors CD8 or CD4 bind to invariant domains of pMHC class I (pMHCI) or pMHC class II (pMHCII) and are known to facilitate the process of antigen recognition by T cells (2). Recent advances have enabled the generation of high quality soluble TCR, pMHCI, pMHCII, CD8, and CD4 proteins; these in turn have allowed the biophysical characterization of the interactions between these molecules. Accordingly, the TCR and CD4/8 co-receptors have been shown to have very low affinities (K D ϳ 10 Ϫ3 -10 Ϫ6 M) for cognate pMHC. Despite these low affinity interactions, however, the process of antigen engagement can initiate T cell recognition of antigen-presenting cells (APCs) bearing fewer than 10 copies of a specific pMHC complex (3, 4). The mechanisms by which these weak recognition events result in such exquisite sensitivity are not fully understood.The production of soluble recombinant ␣ T cell receptors has proved challenging. The main technical pitfall is heterodimeric instability in the absence of anchoring transmembrane domains and ␣/ pairing through an interchain disulfide bond. One of the commonest protein engineering strategies used in TCR studies to date has been the construction of singlechain TCRs. This technique, which takes advantage of the structural similarities between antibodies and TCRs, is based upon the single-chain Fv technology used to generate antibody fragments (5). In short, for the TCR it involves the cloning and expression of a unique chimerical open reading frame where the variable (V) ␣ and V domains are paired with a protein linker (6, 7). Thes...
In a murine melanoma model, immunization with DCs mixed with tumor-specific peptide results in an antigen-specific immunological response that recognizes the EGFRvIII mutation, has potent antitumor efficacy against intracerebral tumors that express EGFRvIII, and results in long-lasting antitumor immunity.
The use of anti-idiotype (anti-id) vaccines for immunotherapy of human cancers is attractive, as immunization with true anti-id reagents (Ab2 beta) has been shown to induce both cellular and humoral immunity, frequently when the original antigen does not, or when a state of anergy to the self-expressed tumor-associated antigen exists. The aim of this study was to investigate the potential of an anti-id vaccine approach to the glioma-associated antigen epidermal growth factor receptor variant III (EGFRvIII) for human clinical trials. By using conventional methodology, seven rat mAbs specific for the binding site of the murine anti-EGFRvIII-specific mAb Y10, as defined by the ability to inhibit the binding of mAb Y10 to EGFRvIII expressed on cells or as purified protein, were generated, and a subset (3/7) was found to be true Ab2 beta, as defined by the ability to induce the formation of antibody directed against EGFRvIII in two species (mouse and rabbit) when used as immunogen. The ability of these three Ab2 beta to elicit a protective anti-tumor response when used as a vaccine in the syngeneic, subcutaneous C57Bl/6-B16mseEGFRvIII tumor model was investigated. Following vaccination with one Ab2 beta mAb (2C7), 6/20 mice failed to develop tumor upon challenge, and 3/20 mice with outgrowing tumors exhibited dramatic regression of incipient tumors. Vaccination with a second mAb (5G8) resulted in one tumor-free survivor and one tumor regressor; vaccination with the third Ab2 beta mAb (7D3) did not confer protection, but did significantly increase the latency period until tumor outgrowth in all vaccinated recipients. The ability of Ab2 beta mAb 2C7 to induce an anti-EGFRvIII response in non-human primates was investigated by using the saponin adjuvant approved for human clinical trial, QS-21. Three of three macaques produced anti-EGFRvIII titers, as detected on EGFRvIII-expressing cells by both ELISA and fluorescence-activated cytometric analysis, following six immunizations with Ab2 beta mAb 2C7 and QS-21. The results obtained confirm that an anti-id response in the EGFRvIII antigen system can be induced in rodents, rabbits, and non-human primates, and it may prove a useful adjunct to immunotherapeutic approaches to EGFRvIII-positive gliomas, breast carcinomas, and non-small-cell lung tumors.
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