Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.49 (reverse transcriptase)
 31,746 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The success of nucleoside reverse transcriptase inhibitors (NRTIs) in treating HIV-1 infection and reducing mother-to-child transmission of the virus during pregnancy is accompanied by evidence that NRTIs cause long-term health risks for cancer and mitochondrial disease. Thus, agents that mitigate toxicities of the current combination drug therapies are needed. Previous work had shown that the NRTI-drug pair zidovudine (AZT)-didanosine (ddI) was highly cytotoxic and mutagenic; thus, we conducted preliminary studies to investigate the ability of the active moiety of amifostine, WR1065, to protect against the deleterious effects of this NRTI-drug pair. In TK6 cells exposed to 100 muM AZT-ddI (equimolar) for 3 days with or without 150 muM WR1065, WR1065 enhanced long-term cell survival and significantly reduced AZT-ddI-induced mutations. Follow-up studies were conducted to determine if coexposure to AZT and WR1065 abrogated the antiretroviral efficacy of AZT. In human T-cell blasts infected with HIV-1 in culture, inhibition of p24 protein production was observed in cells treated with 10 muM AZT in the absence or presence of 5-1,000 muM WR1065. Surprisingly, WR1065 alone exhibited dose-related inhibition of HIV-1 p24 protein production. WR1065 also had antiviral efficacy against three species of adenovirus and influenza A and B. Intracellular levels of unbound WR1065 were measured following in vitro/in vivo drug exposure. These pilot study results indicate that WR1065, at low intracellular levels, has cytoprotective and antimutagenic activities against the most mutagenic pair of NRTIs and has broad spectrum antiviral effects. These findings suggest that the activities have a possible common mode of action that merits further investigation.
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PMID:WR1065 mitigates AZT-ddI-induced mutagenesis and inhibits viral replication. 1933 55

Mitochondrial toxicity is a well-recognized adverse effect of nucleoside reverse transcriptase inhibitor therapy for human immunodeficiency virus (HIV) infection. Transient lactic acidosis is often observed in children born after in utero antiretroviral prophylaxis against mother-to-child transmission of HIV. However, the extent and the mechanism of in utero adverse effects are largely unknown. We describe a 4-year-old girl who presented with manifestations of severe mitochondrial disease, specifically, developmental and growth delay, hypotonia, lactic acidosis, congenital cataracts, and pancreatitis. Her HIV-positive mother was receiving lamivudine, zidovudine, and nelfinavir mesylate during her pregnancy. The child tested HIV negative after birth. She was found to have a homoplastic T9098C sequence change in the mitochondrial gene coding for adenosine 5'-triphosphate synthase 6 (MTATP6) that was previously reported as a mitochondrial polymorphism. This polymorphism is in the MTATP6 gene-coding sequence and leads to the replacement of a nonpolar amino acid with a polar amino acid. Because of the typical clinical manifestations of mitochondrial disorder and because of the nature of the mitochondrial sequence change, the observed polymorphism likely predisposed this patient to develop severe antiretroviral-associated mitochondrial disease. Mitochondrial sequence alterations may be important factors in mitochondrial toxicity associated with antiretroviral treatment. Mitochondrial sequencing may be warranted in cases of persistent lactic acidosis after antiretroviral prophylaxis to further study this association.
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PMID:Mitochondrial T9098C sequence change in the MTATP6 gene and development of severe mitochondrial disease after in utero antiretroviral prophylaxis. 1994 8

The most common group of mitochondrial disease is due to mutations within the mitochondrial DNA polymerase, polymerase gamma 1 (POLG). This gene product is responsible for replication and repair of the small mitochondrial DNA genome. The structure-function relationship of this gene product produces a wide variety of diseases that at times, seems to defy the common perceptions of genetics. The unique features of mitochondrial physiology are in part responsible, but POLG structure and function add to the conundrum of how one gene product can demonstrate autosomal recessive and autosomal dominant transmission, while also being responsible for pharmacogenetic disease, and exhibiting strong gene-environment interactions. The wide spectrum of clinical manifestations of POLG disease can arise from infancy to old age. The modulation of clinical findings relate in part to the molecular architecture of the POLG protein. POLG has three distinct molecular domains: exonuclease, linker, and polymerase domains. Most of the mutations leading to dominant forms of POLG disease are located in the Polymerase domain. Mutations leading to recessive inheritance are distributed in all three domains of the gene. Environmental factors like valproic acid and infection can unmask POLG disease, causing it to occur earlier in life than when not exposed to these factors. Other drugs like nucleoside reverse transcriptase inhibitors can produce genotype-specific POLG pharmacogenetic disease. Our current state of POLG understanding cannot account for many features of POLG disease. There is no answer for why the same mutation can give rise to varying diseases, disease severity, and age of onset. We introduce the term Ecogenetics in the context these features of POLG disease, to emphasize the important interactions between genes and environment in determining the expression of mitochondrial disease. In this article, we identify some of the key features that will help the reader understand POLG pathophysiology. When possible, we also identify genotype-phenotype relationships, give clues for diagnosis, and summarize the major clinical phenotypes in the spectrum of POLG disease presenting from birth to old age.
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PMID:Polymerase gamma disease through the ages. 2081 31