A 21-mer synthetic peptide of toxic shock syndrome toxin 1, TSST-1[58-78], activates T cells by binding to MHC class II and by an MHC unrestricted xenostimulatory pathway.

Toxic shock syndrome toxin-1 (TSST-1) is a "superantigen" which binds to MHC class II molecules and induces a polyclonal stimulation of T cells. In this communication by using a FACS technique and a 21-mer synthetic peptide from the primary sequence of TSST-1 (KGEKVDLNTKRTKKSQHTSEG), designated TSST-1(58-78), we demonstrated binding of the peptide only to cells bearing MHC class II. The proliferative effect of TSST-1(58-78) on human T cells was shown to be inhibited much more by anti-HLA-DR than by anti-HLA class I antibody. Furthermore, human monocytes were able to present TSST-1(58-78) to a mouse VSV specific T cell clone by a xenostimulatory mechanism. These data indicate this peptide to contain an active site of the TSST-1 holotoxin.

Cellular expression of a GPI-linked T cell activation protein.

A T cell activation protein was identified by generating a monoclonal antibody (anti-D2) against a gamma delta T cell receptor bearing gibbon ape T cell line (MLA144). Immunoprecipitation studies revealed three polypeptides of 180, 150, and 120 kDa. The antigen was also found to be expressed on endothelial cells in vivo and in vitro and on tumor cell lines from a variety of tissues. Studies performed using a variety of antibodies reveal this protein to be identical to an endothelial cell protein previously identified by several antibodies to T cell activation proteins (CDw109). We demonstrate that this protein is anchored in the membrane via a glycosylphosphatidylinositol (GPI) tail in T cells, tumor cells, and endothelial cells. An analysis of tissue sections reveals this protein to be normally highly expressed on vascular endothelial cells.

Murine T cell hybridoma-derived products regulate the growth of skeletal muscle myoblasts.

We have analyzed the effects of T cell products on the growth of murine myoblasts. Supernatants from some T cell hybridomas were shown to have either growth factor activity or growth inhibitory activity on two myoblast lines raised in our laboratory from two different strains of mice and also on the C2C12 myoblast line. The hybridoma-derived growth factor activity was shown not to require cofactors contained in serum as its effects could be demonstrated in assays done in serum-free media. Further studies on the effects of purified lymphokines on myoblasts using recombinant IL-2, IL-3, IL-4, IL-6, and GM-CSF showed these lymphokines not to have any growth stimulatory activity indicating that factor(s) other than the ones tested may be operative. Characterization by dialysis and column chromatography of hybridoma supernatants revealed the presence of a low-molecular-weight inhibitor and a higher-molecular-weight growth factor that was found in several hybridoma supernatants.

Guanidine group specific ADP-ribosyltransferase in murine cells.

We have identified a guanidine group specific ADP-ribosyltransferase activity, capable of transferring an ADP-ribose group from NAD to a low molecular weight guanidine compound [p-(nitrobenzylidine)amino]guanidine and proteins such as histone and poly-L-arginine, in a variety of murine cell lines. The enzyme activity appears to be associated with an integral membrane protein of apparent molecular weight 30-33 kDa. Incubation of the viable cells in isotonic phosphate buffered saline with [32P]NAD results in the incorporation of label into cellular proteins. Dimethyl sulfoxide treatment of the cells downregulates the transferase activity as well as the ADP-ribosylation of cell proteins with extracellular NAD.

Protective cellular retroviral immunity requires both CD4+ and CD8+ immune T cells.

We have found previously that postexposure chemoprophylaxis with 3'-azido-3'-deoxythymidine (also known as zidovudine or AZT) in combination with recombinant human alpha A/D interferon fully protected mice exposed to a lethal dose of Rauscher murine leukemia virus (RLV) against viremia and disease. After cessation of therapy, over 90% of these mice were able to resist rechallenge with live RLV, thus demonstrating an acquired immunity. Adoptive cell transfer of 4 x 10(7) cells from immunized mice fully protected naive recipients from viremia and splenomegaly after RLV challenge. However, when these immune T cells were fractionated into CD4+ and CD8+ subpopulations, only partial protection was found when 4 x 10(7) T cells of either subset were given. Full protection against RLV challenge was seen again when the T-cell subsets from immunized mice were recombined and transferred at the same number into naive mice. We conclude that cellular immunity alone is protective and that both CD4+ and CD8+ cell types are required for conferring full protection against live virus challenge.

Vaccination with a live retrovirus: the nature of the protective immune response.

We tested 3'-azido-3'-deoxythymidine (zidovudine) combined with interferon alpha as chemoprophylaxis after exposing mice to Rauscher murine leukemia virus. Therapy started 4 hr after inoculation and administered for 20 days prevented viremia and disease in all 234 mice tested. When the animals were rechallenged with live virus after cessation of therapy, 96% were resistant. The nature of this protective immune response was analyzed: Passive serotherapy of naive mice challenged subsequently with Rauscher murine leukemia virus was only protective at a high dose of immune serum. Immune, but not naive, T cells alone were fully protective against virus challenge. We conclude that vaccination with a live retrovirus that cannot replicate because of pharmacological blockade induces a T-cell response capable of protecting against a lethal retrovirus-induced disease.

Trojan horse lymphocytes: a vesicular stomatitis virus-specific T-cell clone lyses target cells by carrying virus.

We have isolated a vesicular stomatitis virus (VSV)-specific CD4+ CD8- murine T-cell clone. This clone proliferates only in response to VSV and lyses infected tumor cells bearing class II major histocompatibility antigens in short-term chromium release assays. In addition, the cell has VSV antigens on its surface and is capable of killing uninfected tumor cells without major histocompatibility antigen restriction in a 2-day assay. This latter cytolytic activity is eliminated by anti-VSV antibody, indicating that its lytic activity is provided by the virus. [35S]methionine labeling and immunoprecipitation experiments demonstrated that viral protein translation is initiated after incubation of the clone with a tumor target cell, defining this as the mechanism of its cytolytic activity.

Human gamma delta+ T cells respond to mycobacterial heat-shock protein.

Most T cells recognize antigen through the T-cell antigen receptor (TCR)alpha beta-CD3 complex on the T-cell surface. A small percentage of T cells, however, do not express alpha beta but a second type of TCR complex designated gamma delta (ref. 2). Unlike alpha beta+ lymphocytes, gamma delta+ lymphocytes do not generally express CD4 or CD8 molecules, and the nature of antigen recognition by these cells is unknown. To study antigen recognition by gamma delta+ lymphocytes we raised a gamma delta+ alpha beta- -CD4-CD8- line from an individual immune to PPD (purified protein derivative). This line showed a specific proliferative response to PPD and to a recombinant mycobacterial heat-shock protein (HSP) of relative molecular mass 65,000 (65K). The gamma delta+ line was shown to exhibit a major response to HSP in the presence of autologous antigen-presenting cells (APCs). Minor responses occurred, however, with APCs matched for some HLA class I or II antigens, whereas no response occurred with HLA-mismatched APCs. These findings, therefore, document the requirement of HSP-reactive gamma delta+ lymphocytes for histocompatible APCs.