A T-cell subset, defined as CD4+CD25hi (regulatory T-cells [Treg cells]), was recently shown to suppress T-cell activation. We demonstrate that human Treg cells isolated from healthy donors express the HIV-coreceptor CCR5 and are highly susceptible to HIV infection and replication. Because Treg cells are present in very few numbers and are difficult to expand in vitro, we genetically modified conventional human T-cells to generate Treg cells in vitro by ectopic expression of FoxP3, a transcription factor associated with reprogramming T-cells into a Treg subset. Overexpression of FoxP3 in naïve human CD4+ T-cells recapitulated the hyporesponsiveness and suppressive function of naturally occurring Treg cells. However, FoxP3 was less efficient in reprogramming memory T-cell subset into regulatory cells. In addition, FoxP3-transduced T-cells also became more susceptible to HIV infection. Remarkably, a portion of HIV-positive individuals with a low percentage of CD4+ and higher levels of activated T-cells have greatly reduced levels of FoxP3+CD4+CD25hi T-cells, suggesting disruption of the Treg cells during HIV infection. Targeting and disruption of the T-cell regulatory system by HIV may contribute to hyperactivation of conventional T-cells, a characteristic of HIV disease progression. Moreover, the ability to reprogram human T-cells into Treg cells in vitro will greatly aid in decoding their mechanism of suppression, their enhanced susceptibility to HIV infection, and the unique markers expressed by this subset.
Activation of naive T cells through the TCR and cytokine signals directs their differentiation into effector or memory subsets with different cytokine profiles. Here, we tested the flexibility of human Th1 or Th2 differentiation by forced expression of transcription factors T-bet and GATA-3. Ectopic expression of T-bet and GATA-3 in freshly isolated human TN cells resulted in their differentiation to a Th1 and Th2 phenotype, respectively, in the absence of polarizing cytokines. Introduction of GATA-3 into lineage-committed Th1 cells induced the expression of Th2-specific cytokines (IL-4 and IL-5) and chemotactic receptors (CCR4, chemoattractant receptor-homologous molecule expressed on Th2 cells (CRTH2). However, these cells partially maintained their Th1-specific profile (IFN-γ and IL-12Rβ2 expression). Conversely, expression of T-bet in lineage-committed Th2 cells caused a more profound switch to the Th1 phenotype, including the up-regulation of CXCR3 and down-regulation of CCR4 and CRTH2. Interestingly, similar to the naive T cell subset, central memory T cells were also largely programmed toward Th1 or Th2 effector cells upon expression of T-bet and GATA-3, respectively. However, expression of these transcription factors in effector memory T cells was much less influential on cytokine and chemokine receptor expression profiles. Our results reveal remarkable plasticity in the differentiation programs of human memory T cells. This flexibility is progressively diminished as cells mature from naive to effector T cells. These findings have important implications in understanding the molecular mechanisms of human T cell differentiation and for devising novel therapeutic strategies aimed at immunomodulation of skewed effector T cell responses.
Development of a mouse model for human immunodeficiency virus type 1 (HIV-1) infection has advanced through the progressive identification of host cell factors required for HIV-1 replication. Murine cells lack HIV-1 receptor molecules, do not support efficient viral gene expression, and lack factors necessary for the assembly and release of virions. Many of these blocks have been described using mouse fibroblast cell lines. Here we identify a postentry block to HIV-1 infection in mouse T-cell lines that has not been detected in mouse fibroblasts. While murine fibroblastic lines are comparable to human T-cell lines in permissivity to HIV-1 transduction, infection of murine T cells is 100-fold less efficient. Virus entry occurs efficiently in murine T cells. However, reduced efficiency of the completion of reverse transcription and nuclear transfer of the viral preintegration complex are observed. Although this block has similarities to the restriction of murine retroviruses by Fv1, there is no correlation of HIV-1 susceptibility with cellular Fv1 genotypes. In addition, the block to HIV-1 infection in murine T-cell lines cannot be saturated by a high virus dose. Further studies of this newly identified block may lend insight into the early events of retroviral replication and reveal new targets for antiretroviral interventions.Murine cells are refractory to human immunodeficiency virus type 1 (HIV-1) replication at multiple stages of the viral life cycle. While this has allowed a finer inspection of the role of various host factors in HIV-1 replication, it has been an impediment to the development of a genetically modified mouse permissive to HIV-1 infection. A number of host factors have been identified that are indispensable for replication of HIV-1. Necessary factors absent in murine T cells include the human forms of the HIV-1 receptor and coreceptor molecules, CD4 and CCR5, whose murine orthologs do not support HIV-1 entry (10). In contrast, the murine form of CXCR4 can be utilized as a coreceptor by HIV-1 (7, 69). Postentry, human cyclin T1 is necessary for efficient Tat-mediated transactivation of the HIV-1 long terminal repeat (LTR) (22). Additional blocks in later steps of the HIV-1 life cycle in murine cells include excessive splicing of HIV-1 genomic RNA (49) and defects in Rev function (72). Aberrant splicing of HIV-1 mRNA appears to be partially corrected by the human splice inhibitor p32 (80). HIV-1 particle assembly is also impaired in murine cells (6,53). This restriction can be overcome by fusion of murine cells with human cells, suggesting that murine cells lack a factor (or factors) necessary for HIV-1 Gag assembly and release (52). Substitution of the HIV-1 matrix (MA) region with that of murine leukemia virus (MLV) also circumvents this block, supporting the notion that species-specific cofactors are critical for virion assembly and release (13,63).Not only do mouse cells lack some of the factors necessary for HIV-1 replication, they also express factors that actively interfere with retrovira...
Infection with HIV-1 perturbs homeostasis of human T cell subsets, leading to accelerated immunologic deterioration. While studying changes in CD4+ memory and naïve T cells during HIV-1 infection, we found that a subset of CD4+ effector memory T cells that are CCR7−CD45RO−CD45RA+ (referred to as TEMRA cells), was significantly increased in some HIV-infected individuals. This T cell subset displayed a differentiated phenotype and skewed Th1-type cytokine production. Despite expressing high levels of CCR5, TEMRA cells were strikingly resistant to infection with CCR5 (R5)–tropic HIV-1, but remained highly susceptible to CXCR4 (X4)–tropic HIV-1. The resistance of TEMRA cells to R5-tropic viruses was determined to be post-entry of the virus and prior to early viral reverse transcription, suggesting a block at the uncoating stage. Remarkably, in a subset of the HIV-infected individuals, the relatively high proportion of TEMRA cells within effector T cells strongly correlated with higher CD4+ T cell numbers. These data provide compelling evidence for selection of an HIV-1–resistant CD4+ T cell population during the course of HIV-1 infection. Determining the host factors within TEMRA cells that restrict R5-tropic viruses and endow HIV-1–specific CD4+ T cells with this ability may result in novel therapeutic strategies against HIV-1 infection.
HIV infection of primary human T cells requires T cell activation signals. However, how strength, duration, and quality of TCR signals affect susceptibility of resting human T cells to HIV infection remains poorly understood. We found that the same threshold and duration of antigen signals that lead to optimal T cell activation are required for HIV to progress beyond the level of reverse transcription within resting T cells. Remarkably, sustained cytokine signaling from the IL-2 receptor following TCR triggering was critical in establishing productive infection. While blockade of TCR signaling pathways with inhibitors of the phosphatidylinositol 3-kinase pathway caused a partial pre-integration block, another inhibitor, rapamycin, completely suppressed the infection. In contrast, cyclosporin A or FK506, inhibitors of NFAT, failed to block infection if the T cells were pre-activated. Collectively, these results bring to light significant parallels between successful HIV infection and optimal thresholds of T cell activation. Furthermore, our results underscore the critical role of IL-2 signaling in establishing productive HIV infection. These findings have important implications for our understanding of the complex interplay of HIV with host factors induced upon T cell activation.
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