HIV-1 Vpr enhances viral burden by facilitating infection of tissue macrophages but not nondividing CD4+ T cells.

Prior experiments in explants of human lymphoid tissue have demonstrated that human immunodeficiency virus type 1 (HIV-1) productively infects diverse cellular targets including T cells and tissue macrophages. We sought to determine the specific contribution of macrophages and T cells to the overall viral burden within lymphoid tissue. To block infection of macrophages selectively while preserving infection of T cells, we used viruses deficient for viral protein R (Vpr) that exhibit profound replication defects in nondividing cells in vitro. We inoculated tonsil histocultures with matched pairs of congenic viruses that differed only by the presence of a wild-type or truncated vpr gene. Although these viruses exhibited no reduction in the infection or depletion of T cells, the ability of the Vpr-deficient R5 virus to infect tissue macrophages was severely impaired compared with matched wild-type R5 virus. Interestingly, the Vpr-deficient R5 virus also exhibited a 50% reduction in overall virus replication compared with its wild-type counterpart despite the fact that macrophages represent a small fraction of the potential targets of HIV-1 infection in these tissues. Collectively, these data highlight the importance of tissue macrophages in local viral burden and further implicate roles for CC chemokine receptor 5, macrophages, and Vpr in the life cycle and pathogenesis of HIV-1.

A trans-receptor mechanism for infection of CD4-negative cells by human immunodeficiency virus type 1.

Chemokine receptors, particularly CCR5 and CXCR4, act as essential coreceptors in concert with CD4 for cellular entry by human immunodeficiency virus type 1 (HIV-1; reviewed in [1]). But infection of CD4(-) cells has also been encountered in various tissues in vivo, including astrocytes, neurons and microvascular endothelial cells of the brain [2] [3] [4] [5] [6], epithelial cells [5] [7], CD4(-) lymphocytes and thymocytes [8] [9], and cardiomyocytes [10]. Here, we present evidence for the infection of CD4(-) cell lines bearing coreceptors by well-known HIV-1 strains when co-cultured with CD4(+) cells. This process requires contact between the coreceptor-bearing and CD4(+) cells and supports the full viral replication cycle within the coreceptor-bearing target cell. Furthermore, CD4 provided in trans facilitates infection of primary human cells, such as brain-derived astrocytes. Although the pathobiological significance of infection of CD4(-) cells in vivo remains to be elucidated, this trans-receptor mechanism may facilitate generation of hidden reservoirs of latent virus that confound antiviral therapies and that contribute to specific AIDS-associated clinical syndromes.

Primary and recombinant HIV type 1 strains resistant to protease inhibitors are pathogenic in mature human lymphoid tissues.

Preserved peripheral CD4+ T cell counts despite virologic failure in patients undergoing protease inhibitor (PI)-containing antiviral regimens are a frequent occurrence in human immunodeficiency virus (HIV) disease. One hypothesis to explain the relative sparing of CD4+ T cells is that HIV strains exhibiting PI resistance concomitantly are attenuated in terms of cytopathicity for mature T cells. To test this hypothesis, we used a three-dimensional human tonsil histoculture microenvironment to assess the pathogenic potential of a panel of primary and recombinant HIV-1 strains derived from patients experiencing PI failure. All the viruses tested replicated efficiently in these cultures and, in some cases, better than comparable wild-type viral isolates. Furthermore, the PI-resistant strains depleted CD4+ T cells potently and comparably with wild-type isolates in these ex vivo lymphoid tissues. These results demonstrate that PI-resistant viruses are not inherently less pathogenic for mature T cells. Therefore, the sustained peripheral lymphocyte counts in patients with selective virologic failure may be due to specific defects in viral replication in other cell compartments or to an undefined host adaptation to viral infection during PI therapy.

GSK3ß phosphorylation of the KLF6 tumor suppressor promotes its transactivation of p21.

KLF6, a ubiquitously expressed Krüppel-like transcription factor, is frequently inactivated in human cancer and has significant roles in cellular proliferation, apoptosis, differentiation and development. A key mechanism of KLF6-mediated growth suppression is through p53-independent transactivation of p21. Several cancer-derived KLF6 mutants lead to the loss of p21-mediated growth suppression through an unknown mechanism. Because several colorectal cancer and hepatocellular carcinoma-derived KLF6 mutations affect a glycogen synthase kinase 3ß (GSK3ß) phosphorylation consensus site, we investigated the role of GSK3ß in the regulation of KLF6 function. Based on transient transfection, GSK3ß augments the transactivation of a p21 promoter luciferase by KLF6. Reciprocal co-immunoprecipitation of hemagglutinin (HA)-GSK3ß and Flag-KLF6 validated the interaction between these two proteins. KLF6 phosphorylation is augmented in the presence of GSK3ß based on in vitro and in vivo (32)P incorporation assays. Site-directed mutagenesis of the candidate phosphorylation sites to alanines ('KLF6-4A' phosphomutant) eliminated a higher molecular weight phosphorylated isoform of KLF6 based on western blot. GSK3ß augmented the transactivation by wild-type KLF6, but not KLF6-4A, towards the p21 promoter, and increased p21 protein. Functionally, GSK3ß enhanced KLF6-mediated growth suppression, which was abrogated by the KLF6-4A phosphomutant. These data establish that GSK3ß directly phosphorylates KLF6, which augments its induction of p21 and resultant growth suppression. This interaction may account for the growth-promoting effects of cancer-derived KLF6 mutants that lack tumor suppressor activity.

Genetic dissociation of the encapsidation and reverse transcription functions in the 5' R region of human immunodeficiency virus type 1.

The efficient packaging of genomic RNA into virions of human immunodeficiency virus type 1 (HIV-1) is directed by cis-acting encapsidation signals, which have been mapped to particular RNA stem-loop structures near the 5' end of the genome. Earlier studies have shown that three such stem-loops, located adjacent to the major 5' splice donor, are required for optimal packaging; more recent reports further suggest a requirement for the TAR and poly(A) hairpins of the 5' R region. In the present study, we have compared the phenotypes that result from mutating these latter elements in the HIV-1 provirus. Using a single-round infectivity assay, we find that mutations which disrupt base pairing in either the TAR or poly(A) stems cause profound defects in both packaging and viral replication. Decreased genomic packaging in a given mutant was always accompanied by increased packaging of spliced viral RNAs. Compensatory mutations that restored base pairing also restored encapsidation, indicating that the secondary structures of the TAR and poly(A) stems, rather than their primary sequences, are important for packaging activity. Despite having normal RNA contents, however, viruses with compensatory mutations at the base of the TAR stem were severely replication defective, owing to a defect in proviral DNA synthesis. Our findings thus confirm that the HIV-1 TAR stem-loop is required for at least three essential viral functions (transcriptional activation, RNA packaging, and reverse transcription) and reveal that its packaging and reverse transcription activities can be dissociated genetically by mutations at the base of the TAR stem.

Human immunodeficiency virus type 1 coreceptor preferences determine target T-cell depletion and cellular tropism in human lymphoid tissue.

The present study sought to determine how usage of coreceptors by human immunodeficiency virus type 1 dictates cell tropism and depletion of CD4(+) T cells in human lymphoid tissues cultured ex vivo. We found that coreceptor preferences control the marked, preferential depletion of coreceptor-expressing CD4(+) lymphocytes. In addition, there was a strong, but not absolute, preference shown by CXCR4-using strains for lymphocytes and by CCR5-using strains for macrophages.

HIV-1 actively replicates in naive CD4(+) T cells residing within human lymphoid tissues.

Although HIV-1 gene expression is detected in naive, resting T cells in vivo, such cells are resistant to productive infection in vitro. However, we found that the endogenous microenvironment of human lymphoid tissues supports de novo infection and depletion of this population. Cell cycle analysis and DNA labeling experiments established that these cells were definitively quiescent and thus infected de novo. Quantitation of the "burst size" within naive cells further demonstrated that these cells were productively infected and contributed to the local viral burden. These findings demonstrate that lymphoid tissues support active HIV-1 replication in resting, naive T cells. Moreover, these cells are not solely reservoirs of latent virus but are permissive hosts for viral replication that likely targets them for elimination.