Although CD4+CD25+FoxP3+ regulatory T cells play a role in allograft tolerance, the role of CD8+ cells with immunosuppressive function is less clear. To address this issue, spleen cells from Rag-1-deficient TCR transgenic (Tg) mice expressing a receptor for ovalbumin (OVA) in the context of MHC class I (OT1) were activated with OVA expressing antigen-presenting cell (APC) in the presence or absence of exogenous transforming growth factor beta (TGFbeta). TGFbeta inhibited the expression of IFN-gamma, granzyme B and the lytic activity of the OT1 T cells while inducing FoxP3 expression in 5-15% of the cells. By contrast, FoxP3 expression was not detected in naive OT-1 T cells or OT-1 T cells activated without exogenous TGFbeta. TGFbeta-activated OT1 cells inhibited the activation of Kd-specific CD8+ CTL responses by normal B6 T cells and the proliferation by Kd-specific CD4+ TCR Tg T cells, but only if the OVA epitope was co-expressed by Kd+ APC. This antigen-specific inhibitory activity, referred to as linked suppression, was neither mediated by residual lytic activity within the activated OT1 T cells nor did it depend upon IL-10 or TGFbeta. Suppression correlated with inhibition of CD86 expression on CD11c+ APC. TGFbeta-activated OT1 T cells also delayed the rejection of heterotopic, vascularized cardiac allografts mediated by anti-Kd-specific CD4+ TCR Tg T cells, but only if the cardiac allograft expressed both OVA and Kd as transgenes. Prolonged survival of allografts was associated with rapid migration of the FoxP3+ OT1 T cells into the donor heart raising the possibility that suppression may be mediated within the allograft. These data show that TGFbeta-activated CD8+ T cells mediate antigen-specific, APC-focused patterns of suppression in vitro and in vivo.
HIV integration within host cell genomic DNA is a requisite step of the viral infection cycle. Yet, characteristics of the sites of provirus integration within the host genome remain obscure. The authors present evidence that in diseased tissues showing a high level of HIV DNA and macrophage-associated HIV p24 antigen expression from end stage forms of HIV disease, HIV-1 integration sites were favored within genes and transcriptionally active host cell genomic loci. Using an inverse PCR (IPCR) technique that identified dominant integrated forms of HIV, clonal IPCR products were isolated from AIDS dementia, AIDS lymphoma, and angioimmunoblastic lymphadenopathy tissues. Thirty of 34 disease-associated HIV-1 insertions were identified within annotated and hypothetical genes, an unexpected but highly nonrandom genetic coding region association (p <.026). The 1% sensitivity thresholds used for HIV IPCR suggested some form of selective expansion of cells containing these HIV proviruses. Consistent with this interpretation were the HIV-1 insertion sites identified within introns of genes that encoded for factors associated with signal transduction, apoptosis, and transcription regulation. In addition, HIV-1 proviruses were frequently found proximal to genes that encoded for receptor-associated, signal transduction-associated, transcription-associated, and translation-associated proteins. HIV-1 integration within host cell genomic DNA potentially represents a significant insertional mutagenic event. In certain cases, provirus insertions may mediate the dysregulation of specific gene expression events, providing mechanisms contributing to the pathogenesis associated with certain AIDS-related diseases.
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