HIV induces expression of complement component C3 in astrocytes by NF-κB-dependent activation of interleukin-6 synthesis.

BACKGROUND: Abnormal activation of the complement system contributes to some central nervous system diseases but the role of complement in HIV-associated neurocognitive disorder (HAND) is unclear. METHODS: We used real-time PCR and immunohistochemistry to detect complement expression in postmortem brain tissue from HAND patients and controls. To further investigate the basis for viral induction of gene expression in the brain, we studied the effect of HIV on C3 expression by astrocytes, innate immune effector cells, and targets of HIV. Human fetal astrocytes (HFA) were infected with HIV in culture and cellular pathways and factors involved in signaling to C3 expression were elucidated using pharmacological pathway inhibitors, antisense RNA, promoter mutational analysis, and fluorescence microscopy. RESULTS: We found significantly increased expression of complement components including C3 in brain tissues from patients with HAND and C3 was identified by immunocytochemistry in astrocytes and neurons. Exposure of HFA to HIV in culture-induced C3 promoter activity, mRNA expression, and protein production. Use of pharmacological inhibitors indicated that induction of C3 expression by HIV requires NF-κB and protein kinase signaling. The relevance of NF-κB regulation to C3 induction was confirmed through detection of NF-κB translocation into nuclei and inhibition through overexpression of the physiological NF-κB inhibitor, I-κBα. C3 promoter mutation analysis revealed that the NF-κB and SP binding sites are dispensable for the induction by HIV, while the proximal IL-1ß/IL-6 responsive element is essential. HIV-treated HFA secreted IL-6, exogenous IL-6 activated the C3 promoter, and anti-IL-6 antibodies blocked HIV activation of the C3 promoter. The activation of IL-6 transcription by HIV was dependent upon an NF-κB element within the IL-6 promoter. CONCLUSIONS: These results suggest that HIV activates C3 expression in primary astrocytes indirectly, through NF-κB-dependent induction of IL-6, which in turn activates the C3 promoter. HIV induction of C3 and IL-6 in astrocytes may contribute to HIV-mediated inflammation in the brain and cognitive dysfunction.

[Molecular epidemiology of chronic hepatitis C (HCV) virus]. / Epidemiologia molekularna wirusa przewleklego zapalenia watroby typu C (HCV).

Hepatitis C virus (HCV) is a major etiologic causative agent of chronic hepatitis, cirrhosis with its attendant risks of hepatocellular carcinoma. Efforts to isolate the virus by standard immunologic and virologic techniques were unsuccessful and HCV was finally identified by direct cloning and sequencing of its genome. Although the virus was identified 15 years ago, its pathogenesis and replication are not fully understood. Progress in the molecular biology of HCV was achieved by expressing viral recombinant proteins in culture cells and utilizing recombination DNA techniques. An important feature of HCV is that the viral genomes display extensive genetic heterogeneity at the local as well as the global level. Within a host, the HCV genome population circulates as a 'quasi-species' of closely related sequences. Worldwide, a high degree of genetic variation exists resulting in at least six major genotypes of more distantly related subtypes. It has been reported, that the prevalence of each subtype varies in different geographical areas and that virus pathogenicity and sensitivity to interferon treatment, appear to vary with different subtypes.

[Chronic hepatitis C infection--mechanisms of virus "immune escape"]. / Przewlekle zakazenie wirusem zapalenia wattroby typu C--mechanizmy "ucieczki immunologicznej" wirusa.

The characteristic feature of HCV infection is the presence of both humoral and cellular immune response. In spite of the immune activation the host is unable to eradicate the virus. Spontaneous resolution of chronic infection is exceedingly rare--it is estimated at 0.6% per year. The currently available combination therapies with alpha interferon and ribavirin are effective in limited groups of patients. Factors involved in the mechanism(s) whereby HCV establishes and maintains its persistence are not well understood. The high genetic variability of HCV allows the virus to passively evade the immune system. Data obtained from experiments with cell culture expressing HCV proteins suggest that viral persistency is a multifactorial mechanism. Several viral genes impair cellular functions involved in immune responses.

A soluble factor secreted by an HIV-1-resistant cell line blocks transcription through inactivating the DNA-binding capacity of the NF-kappa B p65/p50 dimer.

The identity and activity of several anti-HIV soluble factor(s) secreted by CD8 and CD4 T lymphocytes have been determined; however, some of them still await definition. We have established an HIV-1-resistant, transformed CD4 T cell line that secretes HIV-1 resistance protein(s). Our studies indicate that this protein(s), called HIV-1 resistance factor (HRF), inhibits transcription of the virus by interfering with the activity of NF-kappaB. In the present report we identified the site at which HRF exerts this inhibition by evaluating a set of discrete events in NF-kappaB action. We tested the kappaB oligonucleotide binding activity in nuclei of resistant cells, nuclear translocation and binding to the HIV-1 long terminal repeat of p65 and p50 proteins from susceptible cells after exposure to HRF, and the binding of recombinant p50 to the kappaB oligonucleotide in vitro as affected by prior or simultaneous exposure to HRF. The results of this experimental schema indicate that HRF interacts with p50 after it enters the nucleus, but before its binding to DNA and that this interaction impedes the formation of an NF-kappaB-DNA complex required for the promotion of transcription. These findings suggest that HRF mediates a novel innate immune response to virus infection.

A mouse model for study of systemic HIV-1 infection, antiviral immune responses, and neuroinvasiveness.

We created a model of HIV-1 infection of conventional mice for investigation of viral replication, control, and pathogenesis. To target HIV-1 to mice, the coding region of gp120 in HIV-1/NL4-3 was replaced with that of gp80 from ecotropic murine leukemia virus, a retrovirus that infects only rodents. The resulting chimeric virus construct, EcoHIV, productively infected murine lymphocytes, but not human lymphocytes, in culture. Adult, immunocompetent mice were readily susceptible to infection by a single inoculation of EcoHIV as shown by detection of virus in splenic lymphocytes, peritoneal macrophages, and the brain. The virus produced in animals was infectious, as shown by passage in culture, and immunogenic, as shown by induction of antibodies to HIV-1 Gag and Tat. A second chimeric virus based on clade D HIV-1/NDK was also highly infectious in mice; it was detected in both spleen and brain 3 wk after tail vein inoculation, and it induced expression of infection response genes, MCP-1, STAT1, IL-1beta, and complement component C3, in brain tissue as determined by quantitative real-time PCR. EcoHIV infection of mice forms a useful model of HIV-1 infection of human beings for convenient and safe investigation of HIV-1 therapy, vaccines, and potentially pathogenesis.

Productive infection of primary murine astrocytes, lymphocytes, and macrophages by human immunodeficiency virus type 1 in culture.

A mouse model of human immunodeficiency virus type 1 (HIV-1) infection would be extremely valuable for evaluation of therapies and vaccines; however, multiple blocks to productive infection of NIH 3T3 and other mouse cell lines have been reported. The authors investigated the replication of HIV-1 in primary mouse astrocytes, lymphocytes, and macrophages in culture by infection with intact HIV-1 pseudotyped with the vesicular stomatitis virus G envelope glycoprotein (VSV-G) or with the envelope glycoprotein of amphotropic murine leukemia virus. Astrocytes, lymphocytes, and macrophages were susceptible to productive infection as variously assayed by detection of p24 and Tat proteins, viral protease-mediated processing of Gag, appropriately spliced viral RNA, and infectious progeny virus. As expected, NIH 3T3 cells were not susceptible to productive infection by VSV/NL4. Susceptibility mapped neither to the Fv locus nor to a possible polymorphism in cyclin T1. This study indicates that there are no intrinsic intracellular barriers to HIV-1 replication in primary mouse cells when virus entry is efficient.