Differential expression in human and mouse cells of human immunodeficiency virus pseudotyped by murine retroviruses.

Expression of cell surface CD4 influences susceptibility of cells to human immunodeficiency virus (HIV) infection; however, some CD4-positive human and mouse cells are still resistant to HIV infection. To search for mechanisms of resistance to HIV independent of CD4 expression, HIV expression was studied in human and mouse cells normally resistant to HIV infection by introducing infectious virus by transfection of HIV DNA or infection with HIV pseudotyped with amphotropic or polytropic murine leukemia viruses. The results indicated that even when barriers to viral entry were bypassed, mouse NIH 3T3 cells and Dunni cells still showed a marked reduction in number of cells expressing HIV compared with the human cells studied, although the intensity of immunostaining of individual positive mouse cells was indistinguishable from that seen on permissive human cell lines. CD4 expression in mouse cells or human brain or skin cells did not influence the number of HIV foci observed after transfection with HIV DNA or infection with pseudotyped HIV. These results suggested that in addition to a block in the usual HIV fusion and entry process, CD4-positive mouse cells differed from human cells in exhibiting partial resistance to HIV infection which acted at a postpenetration step in the infection cycle. This resistance was partially overcome when mouse cells were infected by direct exposure to human lymphocytes producing HIV pseudotyped by amphotropic murine leukemia virus.     

Infection of granulocyte/monocyte progenitor cells with HIV1

In order to study whether cytopathic HIV1 infection of haemopoietic progenitor cells is involved in the derangement of haemopoiesis in patients with HIV1 infection, we infected enriched progenitor cells with HIV1, by addition of viral inoculate supernatants from HIV1-infected peripheral blood mononuclear cells or by coculture with HIV1-infected monocytes/macrophages. Progenitor cells were seeded into colony assays and single colonies were chosen for HIV1 mRNA determination by in situ hybridization. Growth of progenitors was not affected by infection. However, up to 42% of colonies of pluripotent progenitor cells (colony-forming unit/granulocyte-erythrocyte-monocyte; CFU-GEM) and committed progenitor cells CFU/granulocyte-monocyte (CFM-GM) contained HIV1 mRNA-expressing cells.In addition, we studied HIV1 infection of progenitor cells from the bone marrow of 6 patients with AIDS or AIDS-related complex. Two patients were negative, two had a few colonies expressing HIV1 mRNA in a minority of cells, and in the remaining two, up to 11% of CFU-GM contained HIV1-expressing cells.Thus, infection of progenitor cells with HIV1 was achieved experimentally in vitro and occurs in vivo. However, growth of progenitors after in vitro infection continues and therefore HIV1 infection does not seem to contribute directly to the reduced incidence of haemopoietic progenitor cells in vivo.     

HIV promoter activity in primary antigen-specific human T lymphocytes

Human retroviruses, such as the HIV, infects human T cells, and efficient HIV replication occurs primarily in activated T cells rather than resting cells. Increased HIV production is likely caused by the activation of the retroviral promoter, and the HIV promoter may be regulated by intracellular signals induced during immune stimulation. To examine the regulation of retroviral promoter activity in normal, Ag-specific primary T lymphoblasts, a heterogeneous population of primary human T cells was transfected with either the HIV promoter or a promoter from a different retrovirus, Rous sarcoma virus (RSV) by protoplast fusion technique. Transfected T cells responded normally to Ag or mitogen stimulation, and activation of these T cells increased both the HIV and RSV promoter activity. Promoter activity was assessed by using transient expression assays after the T cells were restimulated with Ag, mitogen, or IL-2. In situ hybridization of transfected human T cells showed that 68 to 95% of activated lymphocytes expressed CAT mRNA directed by HIV or RSV. Thus, protoplast transfection of primary T cells was efficient in that the majority of cells expressed CAT message. By deletion of different regions of the HIV promoter, the enhancer region was identified as necessary for effective HIV promoter activity. In addition these deletion studies identified a region that negatively affects HIV promoter activity in primary T cells. Cotransfection of the HIV promoter with the HIV transactivator protein, tat, increases HIV promoter activity in both resting and activated primary human T cells only when the tat target sequences were present.     

Failure of human immunodeficiency virus entry and infection in CD4-positive human brain and skin cells.

CD4 molecules on human cells function as a major receptor for human immunodeficiency virus (HIV); however, certain CD4-negative cell types may also be susceptible to infection. Therefore, we attempted to quantitate the relationship between HIV infection and CD4 expression on human cell lines before and after introduction of the CD4 gene by using a retrovirus vector. Prior to introduction of the CD4 expression vector, low levels of HIV infection were detected by a sensitive focal immunoassay on all three cell types studied. With several HIV strains in clones of human cervical carcinoma (HeLa) cells expressing different levels of CD4, HIV titer increased with increasing CD4 expression. In contrast, in squamous cell carcinoma cells (SCL1) and astroglial cells (U87MG), even high levels of CD4 expression failed to augment HIV infection. The CD4 protein expressed in these two cell lines had the expected molecular weight and was capable of binding HIV virions. However, in contrast to CD4-positive HeLa cells, CD4-positive U87MG and SCL1 cells were unable to form syncytia when cultured with cells expressing HIV envelope protein. Thus, the inability of HIV to infect these cells appeared to be due to lack of fusion between HIV virion envelope proteins and CD4-positive cell membranes. This block is infectivity was overcome when cells were infected with HIV which was pseudotyped with the envelope protein of amphotropic murine leukemia virus. Thus, in addition to CD4, other cell surface molecules appear to be required for successful HIV entry into and infection of these two human cell lines.     

Immune complexes containing human immunodeficiency virus type 1 primary isolates bind to lymphoid tissue B lymphocytes and are infectious for T lymphocytes

This study investigated the interaction of tonsil B lymphocytes with immune complexes containing human immunodeficiency virus (HIV IC) primary isolates and the infectivity of the B cell-bound HIV IC. Treatment of virus with a source of antibody and complement increased HIV IC binding to B cells by 5.6-fold. Most of the HIV IC that bound to B cells were not internalized but remained on the cell surface and were gradually released over 72 h. Cell-bound HIV IC were highly infectious for T cells while virus released by cultured B cells was only slightly infectious. Removal of HIV IC from the B-cell surface by protease treatment reduced the infection of T cells to near-background levels, indicating that infectious virus remained on the B-cell surface. These studies show that B lymphocytes can carry and transfer infectious HIV IC to T cells and thus suggest a novel mode of infection of T cells in lymphoid tissue that could be important for pathogenesis during HIV infection.     

Semen protects CD4+ target cells from HIV infection but promotes the preferential transmission of R5 tropic HIV

Sexual intercourse is the major means of HIV transmission, yet the impact of semen on HIV infection of CD4(+) T cells remains unclear. To resolve this conundrum, we measured CD4(+) target cell infection with X4 tropic HIV IIIB and HC4 and R5 tropic HIV BaL and SF162 after incubation with centrifuged seminal plasma (SP) from HIV-negative donors and assessed the impact of SP on critical determinants of target cell susceptibility to HIV infection. We found that SP potently protects CD4(+) T cells from infection with X4 and R5 tropic HIV in a dose- and time-dependent manner. SP caused a diminution in CD4(+) T cell surface expression of the HIVR CD4 and enhanced surface expression of the HIV coreceptor CCR5. Consequently, SP protected CD4(+) T cells from infection with R5 tropic HIV less potently than it protected CD4(+) T cells from infection with X4 tropic HIV. SP also reduced CD4(+) T cell activation and proliferation, and the magnitude of SP-mediated suppression of target cell CD4 expression, activation, and proliferation correlated closely with the magnitude of the protection of CD4(+) T cells from infection with HIV. Taken together, these data show that semen protects CD4(+) T cells from HIV infection by restricting critical determinants of CD4(+) target cell susceptibility to HIV infection. Further, semen contributes to the selective transmission of R5 tropic HIV to CD4(+) target cells.     

Development of a sensitive quantitative focal assay for human immunodeficiency virus infectivity.

Accurate and sensitive quantitation of infectious human immunodeficiency virus (HIV) has been difficult to achieve. In this report, a quantitative focal immunoassay (FIA) for HIV was developed using human HeLa cells rendered susceptible to HIV infection by introduction of the CD4 gene via a retrovirus vector. Infected cells were identified by using human anti-HIV antibodies or mouse monoclonal antibodies specific for HIV together with secondary fluorescein- or peroxidase-conjugated antibody specific for mouse or human immunoglobulins. The assay identified cells infected with either wild-type or culture-adapted HIV isolates and was capable of detecting 1 positive cell in 10(6) cells. The FIA was also effective at detecting cell-free HIV, and in contrast to assays using A3.01, CEM, and other human leukemia cells, the FIA detected most wild-type HIV isolates. HIV neutralization could be determined by using the FIA, and two monoclonal antibodies reactive with HIV gp120 were found to neutralize only the LAV-IIIB strain of HIV. These monoclonal antibodies, as well as antibodies in serum samples from patients with acquired immune deficiency syndrome, were able to inhibit the spread of HIV infection in human lymphocyte suspension cultures but not in CD4-positive HeLa cells growing attached to plastic dishes.     

High level of coreceptor-independent HIV transfer induced by contacts between primary CD4 T cells

Cell-to-cell virus transmission is one of the most efficient mechanisms of human immunodeficiency virus (HIV) spread, requires CD4 and coreceptor expression in target cells, and may also lead to syncytium formation and cell death. Here, we show that in addition to this classical coreceptor-mediated transmission, the contact between HIV-producing cells and primary CD4 T cells lacking the appropriate coreceptor induced the uptake of HIV particles by target cells in the absence of membrane fusion or productive HIV replication. HIV uptake by CD4 T cells required cellular contacts mediated by the binding of gp120 to CD4 and intact actin cytoskeleton. HIV antigens taken up by CD4 T cells were rapidly endocytosed to trypsin-resistant compartments inducing a partial disappearance of CD4 molecules from the cell surface. Once the cellular contact was stopped, captured HIV were released as infectious particles. Electron microscopy revealed that HIV particles attached to the surface of target cells and accumulated in large (0.5-1.0 microm) intracellular vesicles containing 1-14 virions, without any evidence for massive clathrin-mediated HIV endocytosis. The capture of HIV particles into trypsin-resistant compartments required the availability of the gp120 binding site of CD4 but was independent of the intracytoplasmic tail of CD4. In conclusion, we describe a novel mechanism of HIV transmission, activated by the contact of infected and uninfected primary CD4 T cells, by which HIV could exploit CD4 T cells lacking the appropriate coreceptor as an itinerant virus reservoir.     

gp340 expressed on human genital epithelia binds HIV-1 envelope protein and facilitates viral transmission

During sexual transmission of HIV in women, the first cells likely to be infected are submucosal CD4(+) T cells and dendritic cells of the lower genital tract. HIV is segregated from these target cells by an epithelial cell layer that can be bypassed even when healthy and intact. To understand how HIV penetrates this barrier, we identified a host protein, gp340, that is expressed on genital epithelium and binds the HIV envelope via a specific protein-protein interaction. This binding allows otherwise subinfectious amounts of HIV to efficiently infect target cells and allows this infection to occur over a longer period of time after binding. Our findings suggest a mechanism of viral entry during heterosexual transmission where HIV is bound to intact genital epithelia, which then promotes the initial events of infection. Understanding this step in the initiation of infection will allow for the development of tools and methods for blocking HIV transmission.     

Human immunodeficiency virus pseudotypes with expanded cellular and species tropism.

One mechanism for expanding the cellular tropism of a virus is through the formation of phenotypically mixed particles or pseudotypes, a process commonly occurring during viral assembly in cells infected with two or more viruses. We report here that dual infection of cells with human immunodeficiency virus (HIV) and a murine amphotropic retrovirus leads to the production of HIV pseudotypes that have acquired the host range of the amphotropic retrovirus and are capable of infecting not only CD4- human cells but also mouse cells. The replication of the HIV pseudotypes in the various CD4- cells was determined by measuring the appearance of HIV antigens in the supernatants, by cocultivation of CD4+ CEM cells with the infected CD4- cells, and in some cases by assaying the culture supernatants directly for infectious virus. Of the cells tested, human foreskin fibroblasts were the best host cells, and by in situ cytohybridization, we were able to document that all cells in the culture were infected. In addition, the temporal appearance of HIV-specific proteins in the HIV pseudotype-infected fibroblasts was similar to that seen in CD4+ CEM cells. If the human fibroblasts were first infected with the amphotropic retrovirus, they demonstrated the property of superinfection exclusion and were resistant to subsequent infection by the HIV pseudotype. In other cell lines, including the human glioblastoma-derived cell line U373MG, HeLa cells, BALB/c mouse embryo cells, and SC-1 wild mouse cells, although the HIV pseudotype infection appeared to be less efficient, substantial amounts of HIV were nevertheless produced. These results indicate that the HIV (amphotropic retrovirus) pseudotypes may be useful for studying the molecular biology of HIV infections in a wide range of cells.     

The role of integration and clonal expansion in HIV infection: live long and prosper

Integration of viral DNA into the host genome is a central event in the replication cycle and the pathogenesis of retroviruses, including HIV. Although most cells infected with HIV are rapidly eliminated in vivo, HIV also infects long-lived cells that persist during combination antiretroviral therapy (cART). Cells with replication competent HIV proviruses form a reservoir that persists despite cART and such reservoirs are at the center of efforts to eradicate or control infection without cART. The mechanisms of persistence of these chronically infected long-lived cells is uncertain, but recent research has demonstrated that the presence of the HIV provirus has enduring effects on infected cells. Cells with integrated proviruses may persist for many years, undergo clonal expansion, and produce replication competent HIV. Even proviruses with defective genomes can produce HIV RNA and may contribute to ongoing HIV pathogenesis. New analyses of HIV infected cells suggest that over time on cART, there is a shift in the composition of the population of HIV infected cells, with the infected cells that persist over prolonged periods having proviruses integrated in genes associated with regulation of cell growth. In several cases, strong evidence indicates the presence of the provirus in specific genes may determine persistence, proliferation, or both. These data have raised the intriguing possibility that after cART is introduced, a selection process enriches for cells with proviruses integrated in genes associated with cell growth regulation. The dynamic nature of populations of cells infected with HIV during cART is not well understood, but is likely to have a profound influence on the composition of the HIV reservoir with critical consequences for HIV eradication and control strategies. As such, integration studies will shed light on understanding viral persistence and inform eradication and control strategies. Here we review the process of HIV integration, the role that integration plays in persistence, clonal expansion of the HIV reservoir, and highlight current challenges and outstanding questions for future research.     

Altering cell death pathways as an approach to cure HIV infection

Recent cases of successful control of human immunodeficiency virus (HIV) by bone marrow transplant in combination with suppressive antiretroviral therapy (ART) and very early initiation of ART have provided proof of concept that HIV infection might now be cured. Current efforts focusing on gene therapy, boosting HIV-specific immunity, reducing inflammation and activation of latency have all been the subject of recent excellent reviews. We now propose an additional avenue of research towards a cure for HIV: targeting HIV apoptosis regulatory pathways. The central enigma of HIV disease is that HIV infection kills most of the CD4 T cells that it infects, but those cells that are spared subsequently become a latent reservoir for HIV against which current medications are ineffective. We propose that if strategies could be devised which would favor the death of all cells which HIV infects, or if all latently infected cells that release HIV would succumb to viral-induced cytotoxicity, then these approaches combined with effective ART to prevent spreading infection, would together result in a cure for HIV. This premise is supported by observations in other viral systems where the relationship between productive infection, apoptosis resistance, and the development of latency or persistence has been established. Therefore we propose that research focused at understanding the mechanisms by which HIV induces apoptosis of infected cells, and ways that some cells escape the pro-apoptotic effects of productive HIV infection are critical to devising novel and rational approaches to cure HIV infection.     

Human colon epithelial cells productively infected with human immunodeficiency virus show impaired differentiation and altered secretion.

Selected strains of the human immunodeficiency virus (HIV) types 1 and 2 are able to infect human colon epithelial cells in vitro, suggesting a mechanism for the anal route of HIV transmission. In some cases, HIV is not produced by infected colon cells but can be rescued after coculture with T-lymphoid cells. One of the HIV strains (HIV1-NDK) replicated well in colonic cells. A transmission electron microscope study demonstrated two major structural perturbations in producer colon cells: an unusual number of secretion bodies and the appearance of intracellular lumina with disorganized microvilli, indicating a defect in brush border assembly and differentiation. Either abnormality could account for HIV-induced enteropathy consisting of chronic diarrhea and malabsorption in the absence of enteric pathogens. Moreover, HT29 cells infected with HIV provide a unique model for selection of enterotropic HIV strains.     

Characterization of a human cervical CD4+ T cell subset coexpressing multiple markers of HIV susceptibility

The HIV pandemic disproportionately affects women, with most infections acquired through receptive vaginal sex. Although the target cells by which HIV establishes infection in the female genital tract remain poorly defined, it is known that immune activation results in CD4(+) T cells with enhanced susceptibility, as does expression of the mucosal integrin α4β7 and the HIV coreceptor CCR5. Blood and cervical cytobrush specimens were collected from female sex workers (FSWs) in Nairobi, Kenya. Genital infection diagnostics were performed, T cell populations were defined by multiparameter flow cytometry based on their expression of surface receptors relevant to mucosal homing and/or HIV acquisition, and cytokine production was assayed by intracellular cytokine staining. The integrin α4β7 was expressed on 26.0% of cervical CD4(+) T cells, and these cells were more likely to express both the HIV coreceptor CCR5 (p < 0.0001) and the early activation marker CD69 (p < 0.0001) but not CXCR4 (p = 0.34). Cervical Th17 frequencies were enhanced compared with blood (7.02 versus 1.24%; p < 0.0001), and cervical IL-17A(+) CD4(+) T cells preferentially coexpressed α4β7 and CCR5. Expression of IFN-γ and IL-22 was greater in cervical Th17 cells than in blood Th17 cells. In keeping with the hypothesis that these cells are preferential HIV targets, gp120 preferentially bound CCR5(+) cervical T cells, and cervical Th17 cells were almost completely depleted in HIV(+) FSWs compared with HIV(-) FSWs. In summary, a subset of Th17 CD4(+) T cells in the cervical mucosa coexpresses multiple HIV susceptibility markers; their dramatic depletion after HIV infection suggests that these may serve as key target cells during HIV transmission.     

The HIV Envelope but Not VSV Glycoprotein Is Capable of Mediating HIV Latent Infection of Resting CD4 T Cells

HIV fusion and entry into CD4 T cells are mediated by two receptors, CD4 and CXCR4. This receptor requirement can be abrogated by pseudotyping the virion with the vesicular stomatitis virus glycoprotein (VSV-G) that mediates viral entry through endocytosis. The VSV-G-pseudotyped HIV is highly infectious for transformed cells, although the virus circumvents the viral receptors and the actin cortex. In HIV infection, gp120 binding to the receptors also transduces signals. Recently, we demonstrated a unique requirement for CXCR4 signaling in HIV latent infection of blood resting CD4 T cells. Thus, we performed parallel studies in which the VSV-G-pseudotyped HIV was used to infect both transformed and resting T cells in the absence of coreceptor signaling. Our results indicate that in transformed T cells, the VSV-G-pseudotyping results in lower viral DNA synthesis but a higher rate of nuclear migration. However, in resting CD4 T cells, only the HIV envelope-mediated entry, but not the VSV-G-mediated endocytosis, can lead to viral DNA synthesis and nuclear migration. The viral particles entering through the endocytotic pathway were destroyed within 1–2 days. These results indicate that the VSV-G-mediated endocytotic pathway, although active in transformed cells, is defective and is not a pathway that can establish HIV latent infection of primary resting T cells. Our results highlight the importance of the genuine HIV envelope and its signaling capacity in the latent infection of blood resting T cells. These results also call for caution on the endocytotic entry model of HIV-1, and on data interpretation where the VSV-G-pseudotyped HIV was used for identifying HIV restriction factors in resting T cells.     

NK cells in HIV infection: paradigm for protection or targets for ambush

Natural killer cells are a crucial component of the innate immune response to certain tumours and to various viruses, fungi, parasites and bacteria. HIV has infected more than 60 million people worldwide and has led to more than 23 million deaths. At present, there are approximately 40 million people who are living with HIV infection, and there were 5 million new infections in 2004. As part of the innate immune system, natural killer cells might have an important role in host defence against HIV infection, as well as in the control of HIV replication in vivo. In this regard, it is important to understand how natural killer cells and HIV interact. This Review focuses on the role of natural killer cells in controlling HIV infection and on the impact of HIV and HIV-viraemia-induced immune activation on natural-killer-cell function.     

Intraepithelial cell neutralization of HIV-1 replication by IgA

HIV is transmitted sexually through mucosal surfaces where IgA Abs are the first line of immune defense. In this study, we used paired IgA and IgG mAbs against HIV gp160 to study intraepithelial cell neutralization and inhibition of HIV replication. African green monkey kidney cells, Vero C1008, polarizable epithelial cells transfected to express the polymeric Ig receptor (pIgR), were transfected with HIV proviral DNA, and intracellular neutralization mediated by the mAbs was assessed. D47A and D19A IgA, which neutralized HIV in a conventional assay, potently inhibited intracellular HIV replication as assessed by infecting HeLa-CD4-long terminal repeat/beta-galactosidase cells (human cervical carcinoma cell line) and CEMx174 cells (human T cell line) with apical supernatant, basolateral medium, and cell lysate from transfected cells. D47A also inhibited the production of virus as assessed by direct assay of p24. In contrast, D47 and D19 IgG, sharing the same V regions, but which were not transcytosed by the pIgR, did not inhibit intracellular HIV replication, nor did D47A and D19A IgA in pIgR- cells, incapable of transcytosing IgA. Confocal immunofluorescence microscopy showed prominent colocalization of HIV protein and D47A, in agreement with the intracellular neutralization data. D10A, which did not neutralize HIV in the conventional assay, and irrelevant IgA did not show intracellular neutralization or colocalization. Control studies with two kinds of conditioned medium confirmed that HIV neutralization had indeed occurred inside the cells. Thus, during its transcytosis through epithelial cells, HIV-specific IgA can neutralize HIV replication.