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Characterization of HIV-1 Proviral Latency Induced Through APOBEC3 Mutagenesis and Reverse Transcriptase ErrorGreig, Matthew 22 September 2020 (has links)
Human Immunodeficiency Virus 1 (HIV-1) is a lentivirus that forms persistent latently infected reservoirs that are the remaining major hurdle for current HIV-1 treatments. APOBEC3 (A3) proteins are intrinsic retroviral restriction factors that introduce GA mutations during reverse transcription, while Reverse Transcriptase (RT) introduces on average 2-3 mutations every reverse transcription cycle due to a lack of proofreading ability. The goal of this research is to characterize the infectivity and activation of mutated HIV-1 viruses that display reduced transcription upon infection, viruses that we term latency prone viruses (LPVs). We hypothesize that GA transition mutations in the HIV-1 Long Terminal Repeat (LTR) region of the LPVs introduced through Reverse Transcriptase and low levels of A3 protein activity can create HIV-1 sequences that display a reversible, latency-like phenotype. Variable levels of transcription and promoter activation were seen among the LPVs when tested against four classes of Latency Reversing Agents (LRAs). Subsequently, three tested LPVs demonstrated an initial latency-like phenotype before rebounding in infectivity. This project demonstrates for the first time that HIV-1 latency is not simply a byproduct of the infection timing and cellular conditions, but that replication-competent HIV-1 latent viruses can also be created through sublethal mutagenesis of their viral promoter sequence introduced through A3 and RT exposure. The characterization of the complete mechanism of HIV-1 latency induction, maintenance, and reversal is critical in the development of sterilizing and functional cures for HIV-1 infection.
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EPIGENETIC REGULATION OF HIV-1 LATENCY BY HISTONE H3 METHYLTRANSFERASES AND H3K27 DEMETHYLASENguyen, Kien 05 June 2017 (has links)
No description available.
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Molecular Mechanisms and Host Factors Involved in HIV-1 LatencyMadapuji Srinivasan, Mrudhula 03 January 2024 (has links)
The Human Immunodeficiency virus-1 can stay undetected and unaffected by host immune surveillance and antiretroviral therapy. This phenomenon is called proviral latency and the cells harbouring such viruses are part of the latently infected cell reservoir. In this situation, the viral genome integrates into the host's genome upon infection, whereby infected cells exhibit either very low levels or no viral transcription, and hence no viral proteins or egress viruses are produced that can be detected by the immune system. However, viral transcription can be re-activated to produce infectious viruses under certain circumstances. Host-encoded retroviral restriction factors like APOBEC3 (A3) proteins are part of our intrinsic immune defences against retroviral infection, introducing mutations in viral replication intermediates. We hypothesize that low levels of G-to-A transition mutations in the HIV-1 LTR region, introduced by APOBEC3G/F, could lead to a latency-like phenotype. These latent viruses pose major hurdles for HIV-1 cure therapies. Our lab previously created a library of clones possessing mutations in the LTR introduced by A3G/F. Later, mutated LTRs were cloned into 3 types of plasmid backbones: 1) a pEGFP expression vector to study the transcriptional activity of the mutated promoter, 2) into non-replicative pNL4 ∆env ∆vif viral expression vector, and 3) into a replicative pNL4-CXCR4 viral vector to study infection and induction by latency reversal agent (LRA) treatment to better understand the mechanism of latency and transcriptional induction. Viruses produced from these plasmids carrying mutated promoters are referred to as latency-prone viruses or LPVs in this thesis. Characterizing the transcription, infection, and induction to PMA/I of the LPVs would essentially help in evaluating the role of A3 mutations in viral latency and further help in the development of new therapeutics.
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Stochastic Models Suggest Guidelines for Protocols with Novel HIV-1 InterventionsGupta, Vipul January 2017 (has links) (PDF)
The treatment of human immunodeficiency virus (HIV-1) infection faces the challenge of drug resistance. The high mutation rate of HIV-1 allows it to develop resistance against all available drugs. New mechanisms of intervention that do not succumb to failure through resistance are thus being explored. Mutagens that increase the viral mutation rate are a promising class of drugs. They can drive HIV-1 past a critical mutation rate, called the error threshold, and induce a catastrophic loss of genetic information. The treatment duration for a mutagen to drive HIV-1 beyond this error threshold is not yet estimated. We devise a detailed stochastic simulation of HIV-1 infection to estimate this duration. The simulations predict that the required duration is inversely proportional to the difference between the mutation rate induced by a mutagen and the error threshold. This scaling is robust to changes in simulation parameters. Using this scaling, we estimate the required duration of treatment with mutagens to be many years.
Unfortunately, all available drugs, including mutagens, fail to clear the infection because HIV-1 establishes a reservoir of latently infected cells harbouring silent HIV-1 integrated genomes. A new \shock and kill" strategy that aims to activate latent cells and render them susceptible to immune killing or viral cytopathicity and thus to eradicate the HIV-1 latent reservoir has been suggested. Several latency reversal agents (LRAs) have been developed. Individual LRAs fail to show any decline in the HIV-1 latent reservoir in clinical trials. Combinations of LRAs have been tested in a few in-vitro and ex-vivo experiments. It has been found that in combination LRAs act synergistically. Finding the drug concentrations that yield the maximum synergy may be helpful in achieving a sterilizing cure. Here, we develop an intracellular model to estimate these drug concentrations. We choose drugs from two different classes of LRAs and show that our model captures quantitatively recent in-vitro experiments of their activity individually and in combination. With this model, we estimate the concentrations of the drugs required to obtain the maximum synergy.
Strong CD8+ T cell responses against viruses have been associated with low levels of viremia. Elite controllers of HIV-1, who are known to have low or undetectable viremia, mount a cross-reactive CD8+ T cell response against the pathogen which controls viral mutation-driven escape from immune activity. These cross-reactive responses are against specific epitopes of HIV-1. Our goal was to examine whether such epitopes could be identified systematically so that a cross-reactive immune response could be induced by using these epitopes as immunogens. Immune recognition of an epitope involves two parts: presentation of the epitope, or peptide, by the major histocompatibility complex (MHC) molecules in the host and high a finity binding of the peptide-MHC complex with a T cell receptor (TCR). Immune escape could occur at either of these steps. Here, we examined the first step. We devise the following procedure to identify peptides that sustain HLA binding despite mutations. First, from the full length HIV-1 (HCV) proteome, we identify viral peptides that bind tightly with MHC molecules using the software NetMHCpan2.8. Next, we pick the peptides and their complementary MHC molecules that yield tight binding and mutate the peptides bit by bit to examine whether binding was compromised. We identify several viral peptide-MHC pairs that display tight binding despite all possible single mutations of the peptides both with HIV-1 and HCV. These peptides present candidates which can be tested for their TCR binding and cross-reactive immunogenic potential.
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