Surface CD4 expression modulated by a cellular factor induced by HIV type 1 infection

The Mtb-HIV syndemic interaction: why treating M. tuberculosis infection may be crucial for HIV-1 eradication

Accelerated tuberculosis and AIDS progression seen in HIV-1 and Mycobacterium tuberculosis (Mtb)-coinfected individuals indicates the important interaction between these syndemic pathogens. The immunological interaction between HIV-1 and Mtb has been largely defined by how the virus exacerbates tuberculosis disease pathogenesis. Understanding of the mechanisms by which pre-existing or subsequent Mtb infection may favor the replication, persistence and progression of HIV, is less characterized. We present a rationale for the critical consideration of ‘latent’ Mtb infection in HIV-1 prevention and cure strategies. In support of this position, we review evidence of the effect of Mtb infection on HIV-1 acquisition, replication and persistence. We propose that ‘latent’ Mtb infection may have considerable impact on HIV-1 pathogenesis and the continuing HIV-1 epidemic in sub-Saharan Africa.

HIV-1 induced nuclear factor I-B (NF-IB) expression negatively regulates HIV-1 replication through interaction with the long terminal repeat region

Background: Retroviruses rely on host factors for cell entry, replication, transcription, and other major steps during their life cycle. Human Immunodeficiency Virus-1 (HIV-1) is well known for utilizing a plethora of strategies to evade the host immune response, including the establishment of latent infection within a subpopulation of susceptible cells. HIV-1 also manipulates cellular factors in latently infected cells and persists for long periods of time, despite the presence of successful highly active antiretroviral therapy (HAART). Results: In this study we demonstrate that Nuclear Factor-IB (NF-IB) is induced during HIV-1 infection and its expression negatively impacts viral replication. During HIV-1 infection in peripheral blood mononuclear cells (PBMCs), and the T cell line, Jurkat or during induction of virus replication in latently infected cells, ACH2 and J1.1, we observed a time-dependent alteration in NF-IB expression pattern that correlated with HIV-1 viral expression. Using the Chip assay, we observed an association of NF-IB with the long terminal repeat region of HIV-1 (LTR) (-386 to -453 nt), and this association negatively correlated with HIV-1 transcription. Furthermore, knock-down of NF-IB levels in J1.1 cells resulted in an increase of HIV-1 levels. Knock-down of NF-IB levels in J-Lat-Tat-GFP (A1), (a Jurkat cell GFP reporter model for latent HIV-1 infection) resulted in an increase in GFP levels, indicating a potential negative regulatory role of NF-IB in HIV-1 replication. Conclusion: Overall, our results suggest that NF-IB may play a role in intrinsic antiretroviral defenses against HIV-1. These observations may offer new insights into the correlation of the latently infected host cell types and HIV-1, and help to define new therapeutic approaches for triggering the switch from latency to active replication thereby eliminating HIV-1 latent infection.

Genome-wide genetic associations with IFNγ response to smallpox vaccine

Smallpox is a deadly and debilitating disease that killed hundreds of millions of people in the past century alone. The use of Vaccinia virus-based smallpox vaccines led to the eradication of smallpox. These vaccines are remarkably effective, inducing the characteristic pustule or "take" at the vaccine site in >97 % of recipients, and inducing a wide spectrum of long-lasting humoral and cellular immune responses. The mechanisms behind inter-individual vaccine-response variability are likely to involve host genetic variation, but have not been fully characterized. We report here the first smallpox vaccine response genome-wide association study of over 1,000 recent recipients of Dryvax(®). The data presented here focus on cellular immune responses as measured by both production of secreted IFNγ and quantitation of IFNγ secreting cells by ELISPOT assay. We identified multiple significant SNP associations in genes (RASA1, ADRA1D, TCF7L1, FAS) that are critical components of signaling pathways that directly control lymphocyte IFNγ production or cytotoxic T cell function. Similarly, we found many associations with SNPs located in genes integral to nerve cell function; findings that, given the complex interplay between the nervous and immune systems, deserve closer examination in follow-up studies.

MicroRNAs-372/373 promote the expression of hepatitis B virus through the targeting of nuclear factor I/B

MicroRNAs (miRNAs) play important roles in the posttranscriptional regulation of gene expression. Recent evidence has indicated the pathological relevance of miRNA dysregulation in hepatitis virus infection; however, the roles of microRNAs in the regulation of hepatitis B virus (HBV) expression are still largely unknown. In this study we identified that miR-373 was up-regulated in HBV-infected liver tissues and that the members of the miRs-371-372-373 (miRs-371-3) gene cluster were also significantly co-up-regulated in HBV-producing HepG2.2.15 cells. A positive in vivo association was identified between hepatic HBV DNA levels and the copy number variation of the miRs-371-3 gene cluster. The enhanced expression of miRs-372/373 stimulated the production of HBV proteins and HBV core-associated DNA in HepG2 cells transfected with 1.3×HBV. Further, nuclear factor I/B (NFIB) was identified to be a direct functional target of miRs-372/373 by in silico algorithms and this was subsequently confirmed by western blotting and luciferase reporter assays. Knockdown of NFIB by small interfering RNA (siRNA) promoted HBV expression, whereas rescue of NFIB attenuated the stimulation in the 1.3×HBV-transfected HepG2 cells.

CONCLUSION

Our study revealed that miRNA (miRs-372/373) can promote HBV expression through a pathway involving the transcription factor (NFIB). This novel model provides new insights into the molecular basis in HBV and host interaction.

Toll-like receptor pathway gene expression is associated with human immunodeficiency virus-associated neurodegeneration

The innate immune system is a significant component of the brain's defense against infection, especially as the blood-brain barrier restricts access of the members of the adaptive immune system, such as T and B cells. The innate immune system includes Toll-like receptors (TLRs) that recognize pathogen-associated molecular patterns. Within the central nervous system, they are expressed on glial cells and their expression can be modulated by pathological states. Although their function is to recognize foreign pathogens and stimulate a protective immune response through the production of cytokines and interferons, there is emerging evidence that activation of these receptors can result in neurodegeneration. In the current study, the authors assessed the expression of TLR-related genes, using a customized Superarray gene chip, and correlated the expression findings with indices of neurodegeneration. We found that, using a stringent threshold for statistical significance to overcome the potential problem of multiple statistical testing, there were significant correlations between the expression of nine TLR-related genes and reduction in dendritic and synaptic staining. Two of these genes, TLR4 and SIGIRR, were validated by quantitative real-time polymerase chain reaction. Additionally, the authors demonstrated in vitro at the protein level that human primary astrocytes exposed to the toxic human immunodeficiency virus (HIV) envelope protein gp120 had a significant increase in TLR4 protein expression. In conclusion, these findings indicate that TLR-related gene expression may contribute to the development of HIV-related neurodegeneration.

In vivo CXCR4 expression, lymphoid cell phenotype, and feline immunodeficiency virus infection

Primary isolates of feline immunodeficiency virus (FIV) appear to require binding to CD134 in conjunction with CXCR4(X4) to infect IL-2-dependent T-cell-derived cells in culture. However, much less is known about the role of X4 for the infection of cells in vivo. To investigate the correlation between X4 expression and FIV infection in cats acutely infected with FIV-C-Pgmr we used high-speed fluorescence-activated cell sorting and realtime PCR to co-analyze cell phenotypes from lymph node, thymus, bone marrow and blood for FIV infection and X4 expression. X4 expression was greatest in lymph node, both in frequency and in mean fluorescence intensity. The thymus demonstrated a higher proviral burden in X4+ thymic T cells ( approximately 14% in X4+ thymic T cells and 7% in X4- cells) whereas, proviral loads were similar between X4+ and X4- cell populations in all other tissues examined. Assuming a minimum of one proviral copy per cell, a maximum of approximately 50% of FIV-positive cells were X4+. The highest fraction of FIV-infected X4- cells was present in bone marrow. Regardless of X4 status, proviral loads were higher in lymph node and blood T cells than in B cells. These studies provide both a positive association between X4 expression and FIV infection and introduce the probability that X4-independent infection occurs in other target cells in vivo.

Characterization of human immunodeficiency virus (HIV)-2 vector mobilization by HIV-1

Conditionally replicating human immunodeficiency virus type 2 (crHIV-2) vectors can compete with HIV-1 for packaging in HIV-1-infected cells, indicating that the mobilization of vectors could selectively target as well as protect reservoirs susceptible to HIV-1 infection. The incorporation of HIV-1-specific antiviral transgenes in crHIV-2 vectors, although increasing the direct antiviral effect, may decrease mobilization and transmission to surrounding cells. To investigate how HIV-1-specific catalytic RNA cassettes (ribozymes) affect this balance between antiviral activity and mobilization, crHIV-2 vectors shown to display anti-HIV-1 activity were packaged by HIV-2 and used to transduce cells previously infected with HIV-1 or to transduce uninfected cells that were subsequently challenged with HIV-1. Vector mobilization was greater when HIV-1-infected cells were transduced with vector than when transduced cells were infected with HIV-1, and approximately 3-fold lower vector production was observed in cultures transduced with vectors expressing anti-HIV-1 ribozymes. Vector and antiviral effects could be transferred to new cultures by passaging supernatants to fresh cultures. No evidence of recombination with HIV-1 was observed. Vector mobilization and protection from HIV-1 infection were also demonstrated in human peripheral blood mononuclear cells. These data suggest that strategies employing vector mobilization for HIV-1 gene therapy should use vectors with maximal antiviral potency, despite resulting reductions in mobilization of the vector.

Methamphetamine stimulates interferon inducible genes in HIV infected brain

OBJECTIVE

To study the synergism of HIV and methamphetamine.

DESIGN AND METHODS

We undertook a microarray study using RNA from the frontal cortex of 15 individuals with HIV infection to initially identify genes that are differentially regulated by HIV encephalitis (HIVE). From the analysis of the microarray data, we identified candidate genes to be validated by quantitative real time PCR (qRT-PCR) and to assess if these genes were differentially modulated in individuals with HIVE and documented methamphetamine use.

RESULTS

Analysis of microarray data revealed that genes involved in several categories were dysregulated in HIVE. We then chose 15 candidate genes for validation by qRT-PCR and analyzed the tissue concentration of these genes across three groups: those with HIV infection and no brain pathology, those with HIVE, and those with both HIVE and a history of methamphetamine use. We noted that there was upregulation of interferon inducible genes in the HIVE with methamphetamine using group, which together as a gene group was highly statistically significant (p=0.0064).

CONCLUSION

These findings indicate that dysregulation of interferon inducible genes may underlie the pathogenic mechanism resulting in greater neurodegenerative and neurocognitive burden that occurs in methamphetamine using HIV infected individuals.

Employment of microarray analysis to characterize biologic differences associated with tropism-modified adenoviral vectors: utilization of non-native cellular entry pathways

In this study, we have applied high-density oligonucleotide microarray technology to characterize biologic changes associated with adenoviral vector-mediated target cell infection. We infected a human melanoma cell line, M21, with the tropism-modified vectors, Ad5lucRGD and Ad5/3luc1. In addition, we infected the M21 cell line with the Ad5luc1, a vector which primarily exploits the coxsackie and adenovirus receptor, as its primary native receptor. We found significant changes in gene expression of 5492 genes induced by Ad5luc1 infection, 2439 genes induced by Ad5/3luc1 infection, and 1251 genes induced by Ad5lucRGD infection, compared to uninfected cells. Among these changes in gene expression, 783 changes were common to Ad5/3luc1 and Ad5luc1 infections, 266 were common to Ad5lucRGD and Ad5luc1 infections, and 185 changes in gene expression were common to Ad5/3luc1 and Ad5lucRGD infections. Interestingly, 89 changes in gene expression were common to all the three groups, suggesting a commonly affected pathway. This analysis represents a unique application of microarray to study vector-related issues. Furthermore, these studies demonstrate the utility of microarray for characterizing the biologic sequelae of host-vector interaction.

Transduction of cell lines and primary cells by FIV-packaged HIV vectors

Human immunodeficiency virus type 1 (HIV-1), simian immunodeficiency virus, and feline immunodeficiency virus (FIV) are capable of packaging viral RNA derived from heterologous as well as homologous lentiviruses, a phenomenon referred to as "cross packaging." To remove the possibility of seroconversion to HIV proteins, and to avoid potential problems arising due to targeting of vector or packaging construct by antiviral genes, we investigated the feasibility of using an FIV-based packaging system to deliver human immunodeficiency virus type 2 (HIV-2)-based vectors bearing anti-HIV-1 RNA expression cassettes to target cells. In the absence of FIV rev, FIV was packaged by HIV-2 at only 3% the efficiency of FIV packaging by FIV, but this was increased to 39% of homologous controls by supplying FIV rev in trans. HIV-2 vectors were packaged by FIV at levels equal to or exceeding the homologous HIV-2 packaging system in the absence of HIV-1 tat and rev, and levels increased approximately four- to fivefold with the addition of tat and rev in trans. HIV-2 vectors bearing a polyribozyme cassette targeting multiple regions of HIV RNA were efficiently packaged by FIV and transferred to target cells. Upon challenge with cell-free HIV-1 (m.o.i. = 0.1) a significant reduction in replication was observed. These findings demonstrate that packaging HIV vectors with FIV is a viable alternative, which avoids use of HIV structural proteins.

Microarray analysis of differentially expressed genes in cells resistant to HIV-1

We have previously isolated two matched transformed human T cell clones: one of which is resistant to HIV-1 replication and secretes an HIV-1 resistance factor(s) (HRF) and the second which retains the susceptibility of the parental cell line to HIV-1 infection. We employed cDNA arrays to investigate the spectrum of changes in cellular gene expression that correlate with the acquisition of HIV-1 resistance and the secretion of HRF. Using a tissue based immunology/hematology array, we identified 29 transcripts that were differentially expressed by HRF(+) and HRF(-) cells. HRF(+) cells showed a selective down-regulation of 11 genes involved in transcription, several of which are implicated in either susceptibility of cells to HIV-1 or the promotion of HIV-1 transcription itself. In the group of the up-regulated genes, three were linked directly to the cellular resistance to HIV-1. One of the cDNAs placed on the array, representing the hypothetical protein KIAA0117 hybridized only with poly A+ RNA probes derived from HRF(+) cells. The specific up-regulation of two genes, the transcription repressor (CTCF) and hypothetical protein KIAA0117 was confirmed by RT-PCR and Northern blot. The role of KIAA0117 transcript in the resistance to HIV-1 replication needs to be determined.