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Regulation of cellular glucose metabolism by HIV-1 infectionSen, Satarupa January 2014 (has links)
Regulation of Glucose metabolism is known to play an important role in pathogenesis of many diseases. Primarily because deregulation of this metabolic pathway can lead to either apoptosis or extended life span of the cells involved. Viruses are parasitic in nature, they utilize the host cellular pathways to support their own progeny; hence it is expected that viruses would regulate the central glucose metabolism of infected host cells. Human immunodeficiency virus type 1 (HIV-1) causes acquired immune deficiency syndrome, and it uniquely infects both activated CD4+ T cells and terminally differentiated macrophages during the course of HIV-1 pathogenesis. While HIV-1 infection of CD4+ T cells induces G2 arrest and cell death within 2-3 days, HIV-1 infection of macrophages results in longer survival of infected cells and low constitutive viral production, generating viral reservoirs. Our studies show that HIV-1 infection lead to significant changes in the glycolytic pathway of infected cells by altering the enzymatic activity and protein expression of various glycolytic components. The data suggests that the two HIV-1 target cell types exhibit very different metabolic outcomes. During viral replication in monocyte/macrophage lineage cells we observe increase in glycolytic protein expression and the same proteins show no modulation in T-cell lines post viral replication. Similar differential regulation is observed in case of enzymatic activity of glycolytic enzymes as well. We also conducted proteomic studies in collaboration with the proteomics core. HIV-1 encoded viral protein Vpr is essential for infection of macrophages by HIV-1. Vpr is known to cause cell cycle block in infected cell and bring about cell death. However, macrophages are resistant to cell death and are viral reservoir, even Vpr over expression does not cause apoptosis in these cell types. The goal of the study was to use a stable-isotope labeling by amino acids in cell culture (SILAC) coupled with mass spectrometry-based proteomics approach to characterize the Vpr response in macrophages. More than 600 proteins were quantified in SILAC coupled with LC-MS/MS approach, among which 136 were significantly altered upon Vpr overexpression in macrophages. The proteomic data illustrating increase in abundance of enzymes in the glycolytic pathway (pentose phosphate and pyruvate metabolism) was further validated by western blot analysis. We observed that HIV-1 hijacks the macrophage glucose metabolism pathway via the Vpr-hypoxia inducible factor 1 alpha (HIF-1 alpha) axis to induce expression of hexokinase (HK), glucose-6-phosphate dehydrogenase (G6PD) and pyruvate kinase muscle type 2 (PKM2) that facilitates viral replication and biogenesis, and long-term survival of macrophages. We then focused on infected monocyte macrophages to identify if glycolytic components such as HK and G6PD were regulated by HIV-1 infection/replication. We report that Hexokinase-1 (HK-1) enzyme expression increases post infection of PBMCs where as the enzymatic activity of HK decreases. Similar effect is seen with HIV-1 replication in latently infected monocyte cell lines U1. The G6PD enzyme activity and expression both increases in infected PBMCs and in U1 cells post induction of viral replication with PMA. We also found that HK-1 translocate to the mitochondria of U1 cells post induction of HIV-1. It is known that the product of HK activity, Glucose 6-phosphate (G6P) releases HKI from the outer leaflet of mitochondria. Hence we conclude that the viral infection decreases HK activity to have less G6P produced in cell and increases G6PD enzyme activity ensuring the remaining G6P is quickly used up, supporting the adherence of outer mitochondrial membrane bound HK1. This sequence of cellular events ensures longer survival of infected cells supporting the viral progeny to propagate in the cell. We further show that suppressing the Pentose phosphate pathway (PPP) by blocking G6PD activity is not only detrimental to the survival of the infected cells it also suppresses viral replication and promoter level transactivation of the viral LTR. Next we sought to identify if glycolytic enzyme PKM2, that is also known to play a nonmetabolic dual role as a protein kinase regulating gene transcription has any effect on the transcription of HIV-LTR. Our study demonstrates upregulation of pyruvate kinase isoform M2 (PKM2) expression in whole cell extracts and nuclear extracts of HIV-1JRFL infected PBMCs and during reactivation of HIV-1 in chronically infected U1 cells. We then focused on understanding the potential role of PKM2 on HIV-1 LTR transactivation. Our studies demonstrate that over expression of PKM2 leads to transactivation of the HIV-1 LTR reporter construct. Using various deletions constructs of HIV-1 LTR, we mapped the region spanning between -120 bp to -80 bp to be essential for PKM2 mediated transactivation. This region contains the NFKB DNA binding site and mutation of NFKB binding site attenuated PKM2 mediated transactivation of HIV-LTR. Chromatin immune-precipitation (ChIP) analysis confirmed interaction of PKM2 with HIV-1 LTR. Our studies suggest that PKM2 is a transcriptional co-activator of HIV-1 LTR. Hence it opens up another possible target to curb HIV-1 replication at transcriptional level. This study sheds light on the regulation of glycolytic pathway of host cells by HIV-1 infection and its consequences for the virus, opening up new avenues to target viral replication and identify glycolytic markers of HIV-1 pathogenesis. / Biology
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