A regulatory role for astrocytes in HIV-1 encephalitis. An overexpression of eicosanoids, platelet-activating factor, and tumor necrosis factor-alpha by activated HIV-1-infected monocytes is attenuated by primary human astrocytes.

HIV-1-infected brain macrophages participate in neurologic dysfunction through their continual secretion of neurotoxins. We previously demonstrated that astroglial cells activate HIV-1-infected monocytes to produce such neurotoxic activities. In this study, the mechanism underlying these monocyte secretory activities was unraveled and found dependent on HIV-1's ability to prime monocytes for activation. LPS stimulation of HIV-1-infected monocytes resulted in an overexpression of eicosanoids, platelet-activating factor (PAF), and TNF-alpha. This was dependent on the level of HIV-1 infection and monocyte stimulation. Cell to cell interactions between activated virus-infected monocytes and primary human astrocytes reduced monocyte secretions. The capacity of astrocytes to deactivate monocytes was, notably, TGF-beta independent. Although astrocytes constitutively produced latent TGF-beta 2, HIV-1-infected monocytes neither affected TGF-beta 2 production nor converted it into a bioactive molecule. Furthermore, addition of rTGF-beta 1 or rTGF-beta 2 or its Abs to LPS-stimulated monocyte-astrocyte mixtures had no effect on monokine production. In contrast, addition of rIL-10 to LPS-stimulated monocytes produced a dose-dependent decrease in TNF-alpha. IL-10 mRNAs were detected in monocytes, but not astrocytes, following LPS treatment. These results suggest that macrophage activation, a major component of HIV-1 infection in the brain, precipitates neuronal injury by causing virus-infected cells to synthesize neurotoxins. The neurotoxins produced by monocytes are then regulated by astrocytes. Astrocytes therefore, can play either positive or negative roles for disease depending on prior macrophage activation. These findings begin to unravel the cellular control mechanisms that influence cognitive and motor dysfunctions in HIV-1-infected individuals.

Platelet-activating factor: a candidate human immunodeficiency virus type 1-induced neurotoxin.

The pathogenesis of central nervous system disease during human immunodeficiency virus type 1 (HIV-1) infection revolves around productive viral infection of brain macrophages and microglia. Neuronal losses in the cortex and subcortical gray matter accompany macrophage infection. The question of how viral infection of brain macrophages ultimately leads to central nervous system (CNS) pathology remains unanswered. Our previous work demonstrated high-level production of tumor necrosis factor alpha, interleukin 1 beta, arachidonic acid metabolites, and platelet-activating factor (PAF) from HIV-infected monocytes and astroglia (H. E. Gendelman, P. Genis, M. Jett, and H. S. L. M. Nottet, in E. Major, ed., Technical Advances in AIDS Research in the Nervous System, in press; P. Genis, M. Jett, E. W. Bernton, H. A. Gelbard, K. Dzenko, R. Keane, L. Resnick, D. J. Volsky, L. G. Epstein, and H. E. Gendelman, J. Exp. Med. 176:1703-1718, 1992). These factors, together, were neurotoxic. The relative role(s) of each of these candidate neurotoxins in HIV-1-related CNS dysfunction was not unraveled by these initial experiments. We now report that PAF is produced during HIV-1-infected monocyte-astroglia interactions. PAF was detected at high levels in CSF of HIV-1-infected patients with immunosuppression and signs of CNS dysfunction. The biologic significance of the results for neurological disease was determined by addition of PAF to cultures of primary human fetal cortical or rat postnatal retinal ganglion neurons. Here, PAF at concentrations of > or = 300 pg/ml produced neuronal death. The N-methyl-D-aspartate receptor antagonist MK-801 or memantine partially blocked the neurotoxic effects of PAF. The identification of PAF as an HIV-1-induced neurotoxin provides new insights into how HIV-1 causes neurological impairment and how it may ultimately be ameliorated.

Regulation of interferon-alpha-inducible cellular genes in human immunodeficiency virus-infected monocytes.

Cellular mechanisms that control susceptibility to opportunistic infection in human immunodeficiency virus (HIV)-infected individuals remain poorly understood. HIV may induce certain cellular genes that restrict HIV replication and protect cells against other superinfecting viral pathogens. Indeed, HIV-infected monocytes resist infection by vesicular stomatitis virus (VSV). HIV-induced VSV interference in monocytes increases with time after HIV infection. Such interference was evident 6 h after HIV infection and reached maximal levels at 14 days. Monocytotropic but not T cell-tropic HIV strains elicited these effects, signaling a requirement for viral entry and/or replication. Viral interference was independent of interferon (IFN) and was unaffected by addition of neutralizing IFN-alpha and -beta antibodies. The well-described IFN-alpha-inducible antiviral pathways were examined to determine their relationship to the cellular mechanism(s) underlying VSV interference. HIV and IFN-alpha both induced the expression of 2-5A synthetase and Mx gene. In contrast, the guanylate-binding protein (GBP), 6-16, and 9-27 cellular genes were up-regulated by IFN-alpha but not HIV. MxA was detected in HIV-infected monocytes but not in uninfected monocytes. The association between Mx expression and resistance to VSV, coupled with previously described anti-VSV activities by human MxA, suggested that Mx may be an effector molecule for the HIV-induced anti-VSV activities. These results, taken together, suggest that HIV can induce antiviral cellular gene expression, independent of IFN.

An experimental model system for HIV-1-induced brain injury.

The pathological hallmark of HIV infection in brain is productive viral replication in cells of mononuclear phagocyte lineage including brain macrophages, microglia and multinucleated giant cells (Koenig et al., 1986; Wiley et al., 1986; Gabuzda et al., 1986; Stoler et al., 1986). These cells secrete viral and cell encoded neurotoxins that lead to neuronal injury, glial proliferation and myelin pallor during advancing disease (Genis et al., 1992; Giulian et al., 1990, 1993; Pulliam et al., 1991). The apparent paradox between the distribution and numbers of virus infected cells and brain tissue pathology support indirect mechanisms for CNS damage (Epstein, 1993; Geleziunas et al., 1992; Merrill and Chen, 1992; Michaels et al., 1988; Price et al., 1988). First, brain macrophages and microglia can produce neurotoxins by secretion of viral proteins (for example, gp120) (Dawson et al., 1991; Merrill et al., 1989; Lipton et al., 1990; Lipton, 1993). Second, HIV primes macrophages for immune activation to produce neurotoxins including: cytokines (TNF alpha and IL-1 beta), eicosanoids: quinolinate and nitric oxide (NO). Chronic immune stimulation mediated by opportunistic infections and chronic interferon gamma (IFN gamma) production (in and outside the CNS) continues the process of macrophage activation leading to progressive neural injury. The hyperresponsiveness of HIV-infected macrophages to activation results in production of cellular factors that activate uninfected macrophages. This suggests that HIV-infected macrophages are both perpetrators and amplifiers for neurotoxic activities.

Cytokines and arachidonic metabolites produced during human immunodeficiency virus (HIV)-infected macrophage-astroglia interactions: implications for the neuropathogenesis of HIV disease.

Human immunodeficiency virus (HIV) infection of brain macrophages and astroglial proliferation are central features of HIV-induced central nervous system (CNS) disorders. These observations suggest that glial cellular interactions participate in disease. In an experimental system to examine this process, we found that cocultures of HIV-infected monocytes and astroglia release high levels of cytokines and arachidonate metabolites leading to neuronotoxicity. HIV-1ADA-infected monocytes cocultured with human glia (astrocytoma, neuroglia, and primary human astrocytes) synthesized tumor necrosis factor (TNF-alpha) and interleukin 1 beta (IL-1 beta) as assayed by coupled reverse transcription-polymerase chain reaction, enzyme-linked immunosorbent assay, and biological activity. The cytokine induction was selective, cell specific, and associated with induction of arachidonic acid metabolites. TNF-beta, IL-1 alpha, IL-6, interferon alpha (IFN-alpha), and IFN-gamma were not produced. Leukotriene B4, leukotriene D4, lipoxin A4, and platelet-activating factor were detected in large amounts after high-performance liquid chromatography separation and correlated with cytokine activity. Specific inhibitors of the arachidonic cascade markedly diminished the cytokine response suggesting regulatory relationships between these factors. Cocultures of HIV-infected monocytes and neuroblastoma or endothelial cells, or HIV-infected monocyte fluids, sucrose gradient-concentrated viral particles, and paraformaldehyde-fixed or freeze-thawed HIV-infected monocytes placed onto astroglia failed to induce cytokines and neuronotoxins. This demonstrated that viable monocyte-astroglia interactions were required for the cell reactions. The addition of actinomycin D or cycloheximide to the HIV-infected monocytes before coculture reduced, > 2.5-fold, the levels of TNF-alpha. These results, taken together, suggest that the neuronotoxicity associated with HIV central nervous system disorders is mediated, in part, through cytokines and arachidonic acid metabolites, produced during cell-to-cell interactions between HIV-infected brain macrophages and astrocytes.

Induction of IFN-alpha in peripheral blood mononuclear cells by HIV-infected monocytes. Restricted antiviral activity of the HIV-induced IFN.

PBMC cocultured with HIV-infected monocytes for 12 to 48 h released high levels of IFN activity. IFN titers were directly dependent upon time after virus infection and level of HIV replication in infected cells. IFN induction in PBMC was evident with HIV-infected monocytes and PBMC and with myeloid and lymphoblastoid cell lines with at least three different HIV strains. In HIV-infected cell line pairs in which virus infection occurs in both productive and restricted forms, IFN induction in PBMC occurred only with productive infection. IFN activity was acid stable and completely neutralized by antibodies against IFN-alpha. Induction of IFN required cell-cell contact between HIV-infected cells and PBMC, but was independent of MHC compatibility. With PBMC co-cultured with autologous HIV-infected monocytes, IFN induction was highly selective: IL-1 beta, IL-6, or TNF-alpha activity and mRNA were not detected. Cell surface determinants on HIV-infected monocytes that induced IFN in PBMC remained active after fixation in 4% paraformaldehyde. Both adherent and nonadherent PBMC produced IFN after coculture with HIV-infected monocytes. Ability to produce IFN by PBMC was not affected by depletion of T cell, NK cell, B cell, or monocyte subpopulations. The IFN activity produced by PBMC cocultured with HIV-infected cells was about 20-fold less active than equal quantities of rIFN-alpha 2b for inhibition of HIV replication in monocytes and at low concentrations enhanced virus growth. Clinical studies with HIV-infected patients and parallel findings in animal lentivirus disease suggest an adverse role for IFN in disease progression. Conditions for induction of IFN in the culture system described in this report may mimic those in the HIV-infected patient. Defining the molecular basis for IFN induction, the cells that produce IFN, and the altered biologic activity of this important cytokine may provide insight into the pathogenesis of HIV disease.