Oncolytic Viruses as a Potential Approach to Eliminate the HIV Reservoir

Costiniuk, Cecilia T.

12 March 2013

Similar to cancer cells, HIV-infected cells differ from HIV-uninfected cells in that they have altered interferon signaling pathways, the apparent reason for the selectivity of certain oncolytic viruses (OVs). Therefore, it was hypothesized that use of an OV, such as recombinant Maraba virus (MG1), may be a potential approach to eliminate latently-infected cells constituting the HIV reservoir while sparing HIV-uninfected cells. This was studied in U1, ACH-2, OM-10 and J1.1 cells and their respective HIV-uninfected parent cell lines in addition to CD4+CD25-HLADR- cells from HIV-infected individuals on effective antiretroviral therapy. Although MG1 infected and killed latently HIV-infected U1 cells to a greater degree than the HIV-uninfected parent U937 cells, this was not observed in the other HIV-infected cell lines and their respective parent cell lines. Furthermore, results from primary cells suggest that MG1 alone does not appear to eliminate cells which comprise the major HIV reservoir. Challenges of studying the HIV reservoir and priorities for future studies examining the use of OVs as a potential strategy to eliminate the HIV reservoir are discussed.

HIV reservoirs

HIV latency

HIV eradication

Oncolytic viruses

Oncolytic Viruses as a Potential Approach to Eliminate the HIV Reservoir

Costiniuk, Cecilia T.

12 March 2013

Similar to cancer cells, HIV-infected cells differ from HIV-uninfected cells in that they have altered interferon signaling pathways, the apparent reason for the selectivity of certain oncolytic viruses (OVs). Therefore, it was hypothesized that use of an OV, such as recombinant Maraba virus (MG1), may be a potential approach to eliminate latently-infected cells constituting the HIV reservoir while sparing HIV-uninfected cells. This was studied in U1, ACH-2, OM-10 and J1.1 cells and their respective HIV-uninfected parent cell lines in addition to CD4+CD25-HLADR- cells from HIV-infected individuals on effective antiretroviral therapy. Although MG1 infected and killed latently HIV-infected U1 cells to a greater degree than the HIV-uninfected parent U937 cells, this was not observed in the other HIV-infected cell lines and their respective parent cell lines. Furthermore, results from primary cells suggest that MG1 alone does not appear to eliminate cells which comprise the major HIV reservoir. Challenges of studying the HIV reservoir and priorities for future studies examining the use of OVs as a potential strategy to eliminate the HIV reservoir are discussed.

HIV reservoirs

HIV latency

HIV eradication

Oncolytic viruses

Oncolytic Viruses as a Potential Approach to Eliminate the HIV Reservoir

Costiniuk, Cecilia T.

January 2013

Similar to cancer cells, HIV-infected cells differ from HIV-uninfected cells in that they have altered interferon signaling pathways, the apparent reason for the selectivity of certain oncolytic viruses (OVs). Therefore, it was hypothesized that use of an OV, such as recombinant Maraba virus (MG1), may be a potential approach to eliminate latently-infected cells constituting the HIV reservoir while sparing HIV-uninfected cells. This was studied in U1, ACH-2, OM-10 and J1.1 cells and their respective HIV-uninfected parent cell lines in addition to CD4+CD25-HLADR- cells from HIV-infected individuals on effective antiretroviral therapy. Although MG1 infected and killed latently HIV-infected U1 cells to a greater degree than the HIV-uninfected parent U937 cells, this was not observed in the other HIV-infected cell lines and their respective parent cell lines. Furthermore, results from primary cells suggest that MG1 alone does not appear to eliminate cells which comprise the major HIV reservoir. Challenges of studying the HIV reservoir and priorities for future studies examining the use of OVs as a potential strategy to eliminate the HIV reservoir are discussed.

HIV reservoirs

HIV latency

HIV eradication

Oncolytic viruses

Understanding the Roles of Nuclear Receptors in the Maintenance of HIV Proviral Latency Using Novel Gene Editing Techonology

Milne, Stephanie Celeste

03 September 2015

No description available.

Molecular Biology

Virology

HIV latency

nuclear receptors

CRISPR

Visualizing HIV Latency and the Ribonucleoprotein Complexes That Regulate Proviral Transcription and Messenger RNA Processing in Latently Infected CD4+ T Cells

Kizito, Fredrick Mukalazi

23 May 2022

No description available.

Molecular Biology

Microbiology

Virology

The Individual Contribution of Transcription Factors Mobilized Following T-cell Receptor (TCR) or Mitogenic Activation in the Reactivation of HIV from Latency

Hokello, Joseph Francis

20 May 2010

No description available.

Biomedical Research

Molecular Biology

Virology

T-cell Receptor Signaling

Reactivation of HIV Latency

HIV transcription regulation

Cell-to-cell transmission and intrinsic mechanisms that influence human immunodeficiency virus infection

Pedro, Kyle D.

18 February 2021

Early in the course of human immunodeficiency virus (HIV) infection a population of latently infected cells is established which persists despite long-term anti-retroviral treatment. This latent reservoir of HIV-infected cells, which reflects mechanisms of transcriptional repression, is the major barrier to cure. Efforts to target the latent reservoir have been inefficient, indicating a need for a more complete understanding of how HIV transcription is regulated. The molecular networks involved in the regulation of HIV transcription remain incompletely defined. I hypothesized that utilization of a high throughput enhanced yeast one-hybrid assay would reveal novel host transcription factor-long terminal repeat (LTR) interactions and transcriptional networks that regulate HIV. The screen identified 42 human transcription factors and 85 total protein-DNA interactions with HIV LTRs. I investigated a subset of these factors for transcriptional activity in cell-based models of infection. Krüppel-like factors 2 and 3 (KLF2 and KLF3) are repressors of HIV-1 and HIV-2 transcription whereas PLAG1-like zinc finger 1 (PLAGL1) is an activator of HIV-2 transcription. These factors regulate HIV expression through direct protein-DNA interactions and correlate with epigenetic modifications of the HIV LTR. Multiple signals converging from the cellular environment and cell-cell interactions converge at the HIV LTR to determine HIV replication and transcription. Previous work in our lab has shown that strong signaling through the T cell receptor (TCR) was required to support HIV expression and the establishment of an inducible latent infection, whereas weak TCR signaling was insufficient for these outcomes. I hypothesized that dendritic cells-CD4+ T cell interactions provide signals that compensate for weak TCR signaling, supporting HIV-1 expression and generation of inducible latent infection. I used CD4+ T cells that express chimeric antigen receptors in a dendritic cell coculture model to deliver differential signals to CD4+ T cells during cell-to-cell transmission of HIV. I found that signals from dendritic cells compensate for weak TCR signaling, facilitating cell activation, HIV expression and establishment of an inducible infection.

Microbiology

CD4+ T cell

Chimeric antigen receptor

Dendritic cell

HIV latency

HIV transcription

T cell receptor signaling

Investigating the PI3K/AKT/ATM Pathway, Telomeric DNA Damage, T Cell Death, and CRISPR/Cas9-mediated Gene Editing During Acute and Chronic HIV Infection

Khanal, Sushant

01 December 2022

Human Immunodeficiency Virus (HIV) infection initiates major metabolic and cell- survival complications. Anti-retroviral therapy (ART) is the current approach to suppress active HIV replication to a level of undetected viral load, but it is not a curative approach. Newer and sophisticated gene editing technologies could indeed be a potent antiviral therapy to achieve a clinical sterilization/cure of HIV infection. Chronic HIV patients, even under a successful ART regimen, exhibit a low-grade inflammation, immune senescence, premature aging, telomeric DNA attrition, T cell apoptosis, and cellular homeostasis. In this dissertation, we investigated CD4 T cell homeostasis, degree of T cell apoptosis, an associated telomeric DNA damage, DNA damage repair signaling, and the apoptotic pathways in CD4 T cells during HIV infection with or without ART treatment. Our data support a DNA damage accumulation, and impaired DNA damage repair in chromosome ends via recruitment of 53BP1 protein to the damaged foci. We found that a key player of DNA damage and repair enzyme, ATM, and its associated checkpoint proteins (CHK1, CKH2) are affected by HIV infection. HIV infection also altered another multifunctional master regulator protein AKT that is crucial in maintaining cellular homeostasis. Curing HIV is the ultimate redemption against HIV-associated complications. To explore the possibility of a functional cure, we investigated the use of a transient and a non-viral CRISPR/Cas9-based gene editing technology targeting the latently incorporated HIV provirus. After performing a nucleofection/electroporation using an in vitro formulated ribonucleoprotein (RNP) constituting a synthetic guide RNA (gRNA) and Cas9 nuclease protein, we demonstrated a significant (maximum 97%) reduction of HIV-mRNA and p24-capsid protein expression, upon stimulation (using PMA) and latency reactivation of latently HIV-infected CD4 T cells and latent-monocytes. Notably, the RNP treatment did not induce any cytotoxic effects, without affecting the abilility of cell proliferation. A sequence specific cleavage of HIV-provirus in two crucial gene locations (targeting vpr/tat genes) showed the most significant suppression of HIV reactivation or latency reversal. We have used DNA sequencing, and T7EI assay to confirm the target-site-specific cleavage of the HIV-proviral genome. Our data confirm the activation of non- homologous end joining (NHEJ) pathway to repair the double-stranded DNA break created by the CRISPR/Cas9 treatment. Taken together, this study provides a new gene therapeutic approach using synthetic gRNA/Cas9 targeting HIV genome, which warrant further in vivo animal and human studies.

HIV

DNA damage

Apoptosis

Telomere

CRISPR/Cas9

gene editing

HIV cure

HIV latency

Immune System Diseases

Immunology of Infectious Disease

Immunotherapy

Medical Immunology

Medical Molecular Biology

Virology

Virus Diseases