Cytotoxic T cells specifically induce Fas on target cells, thereby facilitating exocytosis-independent induction of apoptosis.

Cytotoxic T (Tc) cells deficient in perforin lyse Fas-negative targets after lengthy incubation periods. This process is independent of granzymes, and killing occurs via the Fas pathway for the following reasons. Interaction of perforin-deficient Tc cells with Fas-negative targets leads to an up-regulation of Fas that is dependent on Ag recognition, de novo synthesis, and transport of proteins to the target cell surface. Treatment of effectors with brefeldin A, but not with the exocytosis inhibitor concanamycin, inhibited this process. Lysis of targets is inhibited by anti-Fas Abs, soluble mouse Fas-Fc, and the caspase-cascade inhibitor, crm-A. Targets from Fas-mutant lpr mice are refractory to lysis, and Tc cells from mice deficient in Fas- and perforin-mediated lysis do not lyse Fas-negative targets. The possible relevance of this exocytosis-independent cytolytic process in the regulation of T cell activity and control of pathogens is discussed.

Perforin is essential for control of ectromelia virus but not related poxviruses in mice.

Lack of perforin renders the relatively resistant mouse strain C57BL/6 highly susceptible to the natural mouse pathogen ectromelia virus, a cytopathic orthopoxvirus. This is indicated by increased mortality, elevated virus titers and pathology in liver and spleen, and increased levels of liver enzymes in blood. Cowpox virus on the other hand is more virulent in the presence of perforin than in its absence. An additional lack of granzyme A which together with perforin is a constituent of cytoplasmic granules from cytotoxic T cells increases the virulence of cowpox virus.

Granzyme A is critical for recovery of mice from infection with the natural cytopathic viral pathogen, ectromelia.

Cytolytic lymphocytes are of cardinal importance in the recovery from primary viral infections. Both natural killer cells and cytolytic T cells mediate at least part of their effector function by target cell lysis and DNA fragmentation. Two proteins, perforin and granzyme B, contained within the cytoplasmic granules of these cytolytic effector cells have been shown to be directly involved in these processes. A third protein contained within these granules, granzyme A, has so far not been attributed with any biological relevance. Using mice deficient for granzyme A, we show here that granzyme A plays a crucial role in recovery from the natural mouse pathogen, ectromelia, by mechanisms other than cytolytic activity.

Down-regulation of human adenovirus E1a by E3 gene products: evidence for translational control of E1a by E3 14.5K and/or E3 10.4K products.

The mechanism for down-regulation of E1a expression by products encoded in the E3 transcription unit of human adenovirus types 2 and 5, that occurs in infected L929 cells, has been investigated further. We show that the phenomenon occurs in different mouse cells and also in some human cells suggesting that the observations have relevance to natural human infections. We also provide evidence that probably all viral proteins are down-regulated by E3 products, although to different extents, but that host proteins are unaffected. Whereas E1a protein levels and synthesis are reduced in the presence of E3 products, E1a protein half-life and polysomal E1a RNA levels and size distribution are not. These data suggest that E3 products down-regulate E1a protein levels by interfering with the translation of E1a-specific mRNA. Studies were additionally carried out with mutant adenoviruses containing different defects in the E3 transcription unit. Based on these studies it seems likely that the E3 14.5K and 10.4K proteins are crucially involved in E1a down-regulation. Our data are discussed in terms of strategies for immune evasion by group C human adenoviruses.

West Nile virus infection induces susceptibility of in vitro outgrown murine blastocysts to specific lysis by paternally directed allo-immune and virus-immune cytotoxic T cells.

Day 3 post-coitum BALB/c and (BALB/c x CBA/H)F1 blastocysts were isolated and hatched in replicate wells. Some were treated with interferon-gamma (IFN-gamma). Whilst others were infected with West Nile Virus (WNV) at 100 plaque-forming units per cell, for 18 h. Controls were mock-treated. Gamma-irradiated (2000 rads) CBA/H, (paternal) WNV-specific and allo(CBA/H)-specific cytotoxic T (Tc) cells were then added to replicates of infected, mock-infected or IFN-gamma-treated cultures for 20 h. [3H]Thymidine was then added for a further 8 h. [3H]Thymidine incorporation was inhibited by 40-50% in WNV-infected cultures exposed to WNV-paternal-specific Tc cells and by 30-40% in WNV-infected cultures exposed to allo-paternal-specific Tc cells compared to similarly exposed, uninfected, or unexposed, WNV-infected, or unexposed, uninfected cultures. No significant differences in [3H]thymidine incorporation were found between these controls and IFN-gamma-treated cultures exposed to allo-paternal-specific Tc cells or IFN-gamma-treated cultures not exposed to Tc cells. Parallel exposure of L929 fibroblasts to the same Tc cells irradiated with 500-8000 rads in doubling doses, showed that irradiation did not alter the efficacy or specificity of the Tc cells. Relevance to maternal anti-viral immune responses during implantation is discussed.

Alloreactive cytotoxic T cells recognize MHC class I antigen without peptide specificity.

In this report, experiments are described to differentiate between three potential models of class I MHC allorecognition, namely 1) recognition of peptide-free MHC, 2) peptide-MHC-specific recognition, and 3) peptide-MHC-nonspecific recognition. Using a nucleoprotein peptide (NPP) with a sequence derived from influenza virus nucleoprotein with high affinity for Kd class I MHC molecules, it is shown that target cells rapidly become lysable by Kd-NPP self-restricted cytotoxic T (Tc) cells, and retain sufficient Kd-NPP complexes for at least 72 h. Kd-specific alloreactive Tc cells at the clonal and polyclonal level do not show decreased lysis of Kd-bearing targets in the continuous long term (48 h) presence of NPP. Kd-stimulator cells modified with NPP are able to induce potent Kd-NPP-specific self-restricted Tc cells, however Kd-NPP stimulator cells do not generate Kd-NPP specific alloreactive Tc cells from CBA and B10.A (5R) mouse strains as tested by limiting dilution split clone experiments. Human cells infected with the vaccinia virus recombinant coding for the murine Kd class I MHC Ag can be lysed by murine Kd-specific alloreactive Tc cells. In addition the rate of reemergence of alloreactive and self-restricted Tc cell epitopes on virally infected target cells that had their cell-surface class I MHC Ag removed is identical. These results are consistent with model 3 namely that the majority of Tc precursor and effector cells recognize class I MHC Ag without peptide specificity.

Adenovirus type 5 E3 gene products interfere with the expression of the cytolytic T cell immunodominant E1a antigen.

Effects of mutations in the adenovirus 5 (Ad 5) E3 transcription unit on the immune Tc cell response to Ad 5 were investigated. We observed enhanced lysis of L929 target cells infected with the E3 defective mutant viruses dl 327 and dl 355 compared to wild-type (wt) Ad 5 by Ad 5 immune Tc cells. This enhanced lysability was not due to E3 effects on the cell surface expression of class I MHC H-2Kk molecules as determined by monoclonal antibody binding or alloreactive Tc cell recognition. Furthermore MHC class I molecules were able to efficiently present vaccinia virus antigens in the presence of the Ad 5 E3 genes, excluding functional modification of class I MHC antigens by E3 gene products. When levels of the Ad 5 immunodominant antigen E1a were compared between wt and E3 mutant viruses, we observed an 8- to 10-fold increase in E1a levels in E3 mutant-infected cells over wt Ad 5-infected cells. No differences were observed between these viruses at the mRNA level. We conclude that E3 products interfere with Ad 5 immune Tc cell responses by some post-transcriptional mechanism which reduces expression of the E1a immunodominant antigen.

The murine cellular immune response to adenovirus type 5.

We have characterized the cellular immune response to human adenovirus 5 (Ad-5) in mice, as a basis for future study of responses to foreign antigens in recombinant adenoviruses. Primary in vivo lytic effector cells contained both virus immune cytolytic T (Tc) cells and natural killer cells. The Tc effectors could be boosted in vitro to give a secondary Tc cell response. The Tc cell response to Ad-5 was major histocompatibility complex (MHC) restricted, and in CBA/H (H-2k) mice mapped to the K end of MHC. Kinetic experiments suggested the Tc cell response was directed against early rather than late viral proteins. Experiments with viral mutants showed that the main responses were to the E1A and E1B proteins, with some involvement of E2. Expression of E3 and E4 in infected targets was not required, in fact lysis of target cells infected by viruses with a deletion in E3 was augmented.

Gamma-irradiated influenza A virus can prime for a cross-reactive and cross-protective immune response against influenza A viruses.

A-strain influenza virus A/JAP (H2N2) was tested for its ability to induce cytotoxic T cells (Tc) after being rendered non-infectious by either UV or gamma irradiation. Gamma-irradiated virus proved to be more efficient than UV-inactivated virus in priming for a memory Tc cell response or in boosting memory spleen cells in vitro. Most importantly, gamma-inactivated, but not UV-inactivated, A/JAP immunized animals survived lethal challenge with heterologous (A/PC(H3N2), A/WSN(H1N1)) virus as effectively as mice primed with infectious virus.

Changes in the surface of virus-induced cells recognized by cytotoxic T cells. I. Minimal requirements for lysis of ectromelia-infected P-815 cells.

P-815 mastocytoma cells developed susceptibility to immune T-cell-mediated cytolysis shortly after infection by ectromelia virus. Intracellular viral replication and late protein synthesis seem to bu unnecessary events. Interference with early protein synthesis, however, inhibits the development of susceptibility to lysis. The important intracellular events necessary for subsequent cytolysis appear to occur within 1 hour of infection. Virus rendered non-infectious by ultraviolet irradiation but not by gamma irradiation is able to induce these changes. By determining the minimum and essential events of the infectious process which result in T-cell-mediated cytolysis, the task of establishing the molecular changes occurring in the target cell surface membrane necessary for immune T-cell recognition should be simplified.