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)

Didanosine is a dideoxynucleoside analogue which undergoes intracellular conversion to the putative active triphosphate metabolite. The active metabolite appears to inhibit viral reverse transcriptase and terminate the proviral DNA, and produces virustatic inhibition of actively replicating human immunodeficiency virus (HIV) at clinically relevant concentrations. In phase I studies didanosine had beneficial effects on various surrogate markers of clinical efficacy and also improved clinical manifestations of HIV infection, with a 21-month survival rate of 80% in patients with acquired immune deficiency syndrome (AIDS) and 93% in patients with AIDS-related complex (ARC) in 1 study. Didanosine also improved CD4+ cell counts in a phase II/III trial in patients previously treated with zidovudine, whereas cell counts declined in patients continuing zidovudine therapy. However, the effects of didanosine on clinical end-points (disease progression, survival, HIV encephalopathy) remain to be established. Peripheral neuropathy and pancreatitis are the predominant dose-limiting adverse events and didanosine therapy should be withdrawn in patients developing signs or symptoms of pancreatitis and during acute treatment of Pneumocystis carinii pneumonia. However, at currently recommended clinical dosages didanosine is generally well tolerated with minimal haematological toxicity. Thus, in a therapeutic area with few treatment options, didanosine offers a welcome alternative for patients intolerant of, or resistant to, zidovudine. There are a number of clinical trials in progress evaluating didanosine alone or in combination with other antiviral agents, and these results are awaited with considerable interest.
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PMID:Didanosine. A review of its antiviral activity, pharmacokinetic properties and therapeutic potential in human immunodeficiency virus infection. 137 14

Great strides have been made in the therapy of human immunodeficiency virus (HIV) infection. Currently approved drugs include zidovudine and didanosine. A third drug, dideoxycytidine (zalcitibine), has recently been filed for approval with the Food and Drug Administration. All these drugs work through inhibition of the reverse transcriptase enzyme. Zidovudine is the only drug that has shown clinical efficacy against HIV. Treatment of patients with advanced HIV disease (i.e., acquired immune deficiency syndrome [AIDS] or symptomatic infection with < 200 CD4+ lymphocytes per mm3), results in a prolongation and improved quality of life. Zidovudine is the only antiretroviral agent approved for the treatment of asymptomatic patients. Early intervention with zidovudine has been shown to delay progression to AIDS when patients' CD4+ lymphocyte counts decline to less than 500/mm3, irrespective of clinical signs or symptoms of HIV infection. Didanosine is currently indicated for the treatment of patients with advanced HIV disease who are intolerant to or failing zidovudine therapy. The major toxicity of zidovudine is bone marrow suppression with anemia and granulocytopenia (which occurs in from 1% to 45% of patients, depending on the clinical stage of disease and the dose of the drug). Didanosine and zalcitibine have both been associated with a severe peripheral neuropathy, which is generally reversible on cessation of the drug. In addition, didanosine has been implicated as a cause of pancreatitis that has been fatal in a small percentage of cases. The toxicities of didanosine and zalcitibine range from 1% to 10%, depending on dose, duration of therapy, and the presence of underlying HIV-related peripheral neuropathy or a previous history of pancreatitis. The clinical hallmark of HIV infection is the development of opportunistic infections and malignancies, which are a consequence of the profound immunodeficiency. The risk of an opportunistic infection increases significantly as the T-helper lymphocyte count declines to less than 20%, or 200 to 250/mm3. The spectrum of opportunistic infections ranges from viruses to protozoa. Patients with advanced HIV disease are also at increased risk of infection with nonopportunistic, community-acquired pathogens. Primary and secondary prophylaxis against the most common AIDS-defining opportunistic infection, Pneumocystis carinii pneumonia, is now recommended. Studies are currently underway to determine the efficacy of prophylaxis against other opportunistic pathogens. Treatment of opportunistic infections associated with AIDS has improved significantly over the past 5 years as new drugs and combination regimens of antimicrobials have been developed.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:AIDS: Part II. 139 36

Therapy of pediatric AIDS utilizes antiretroviral compounds; antibiotic, antifungal, and antiparasitic agents; and both active and passive immunization in a multifactorial approach. Currently, newly diagnosed pediatric AIDS cases are acquired predominantly through vertical transmission from HIV-infected mothers. Pediatric AIDS research is focused on strategies to prevent vertical transmission of HIV infection as well as therapy against opportunistic and progressive HIV disease. Zidovudine remains first-choice therapy for HIV infection and can reduce the rate of vertical transmission of HIV. Didanosine is also approved to treat HIV infection in pediatric AIDS. Other reverse transcriptase inhibitors are under investigation as alternative or combination therapies because of HIV resistance to zidovudine and didanosine. Alternative therapies for opportunistic infections are being investigated. Passive immunity with intravenous immunoglobulin is being reevaluated to determine efficacy in combination with other therapies. Finally, vaccination against usual childhood diseases with standard immunization schedules produces limited immunity, and alternative vaccination protocols warrant further investigation.
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PMID:Therapy of pediatric AIDS. 778 39

Human Immunodeficiency Virus replication offers several targets for inhibitory compounds, the foremost presently being the HIV reverse transcriptase. Since the beginning of the epidemic three nucleoside analogue drugs--Zidovudine, Didanosine and Zalcitabine--which act at the reverse transcriptase enzyme are already licensed for use in AIDS-therapy, and others--Stavudine, Alovudine and Lamivudine--are still under clinical evaluation. Although there is a very significant research work for newer drugs for HIV-therapy, it seems that for the next future Zidovudine will remain the most important drug of antiretroviral therapy.
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PMID:[Future possibilities of drug therapy of acquired immunodeficiency syndrome]. 801 18

Didanosine is a dideoxynucleoside analogue, which is phosphorylated to the active metabolite dideoxyadenosine triphosphate (ddATP) intracellularly. At therapeutic concentrations, ddATP inhibits HIV replication by inhibiting HIV reverse transcriptase. Didanosine is established as a first-line treatment for patients with HIV disease and has recently been shown to be superior to zidovudine monotherapy in the treatment of patients with intermediate-stage HIV infection. In clinical practice, however, combination regimens of antiretroviral drugs are generally considered preferable to monotherapy as first-line treatment for most patients with HIV disease. Importantly, 2 large multicentre studies have demonstrated that combination therapy with didanosine and zidovudine was more effective than zidovudine monotherapy in delaying disease progression and death in patients with intermediate or advanced HIV disease. In other comparative studies, improvements in surrogate markers of HIV disease were generally greater in patients who received combination therapy than in recipients of antiretroviral drug monotherapy. Improvements in surrogate markers were also observed in children who received didanosine monotherapy in several clinical trials. Although the efficacy of combination antiretroviral drug therapy has not yet been investigated extensively in children, a combination regimen of didanosine and zidovudine was well tolerated and achieved beneficial effects on surrogate markers if HIV disease. In addition, preliminary findings of a larger study have shown that disease progression was delayed in children and adolescents who received didanosine plus zidovudine combination therapy compared with those receiving zidovudine monotherapy. Didanosine has a tolerability profile that is distinctly different from that of zidovudine. In particular, didanosine exhibits only minimal haematological toxicity when administered either as a single agent or in combination with zidovudine. The most serious dose-limiting adverse effects associated with didanosine treatment are peripheral neuropathy and pancreatitis. In conclusion, didanosine monotherapy is an effective treatment of HIV infection. However, combination antiretroviral therapy is the optimal treatment strategy for most patients, and didanosine is now firmly established as a component of combination antiretroviral drug regimens for the first-line treatment of patients with HIV disease.
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PMID:Didanosine. An update on its antiviral activity, pharmacokinetic properties and therapeutic efficacy in the management of HIV disease. 895 61

Delavirdine is a nonnucleoside reverse transcriptase inhibitor with in vitro activity against human immunodeficiency virus type 1 (HIV-1) that is currently being evaluated in combination regimens with various nucleoside analogs, including didanosine. Due to the pH-dependent solubility of delavirdine, the buffering agents in didanosine formulations may reduce delavirdine absorption. To evaluate the potential interaction between these agents, 12 HIV-infected patients (mean [+/- standard deviation] CD4+ cell count, 304 +/- 213/mm3) were enrolled in a three-way crossover single-dose study. Didanosine (125 to 200 mg given as buffered tablets) and delavirdine mesylate (400 mg) pharmacokinetics were evaluated when each drug was given alone (treatments A and B, respectively), when the two drugs were given concurrently (treatment C), and when didanosine was given 1 h after delavirdine (treatment D). Delavirdine exposure was reduced by concurrent administration of didanosine. The maximum drug concentration in serum (Cmax) was reduced from 7.22 +/- 4.0 to 3.51 +/- 1.9 microM, and the area under the concentration-time curve from 0 h to infinity (AUC0-->infinity) was reduced from 22.5 +/- 14 to 14 +/- 5.7 microM.h. The extent of N-dealkylation, as indicated by the ratio of the N-dealkylated delavirdine AUC0-->infinity to the delavirdine AUC0-->infinity, was unchanged across study treatments (P = 0.708). Reductions in didanosine exposure were observed during concurrent administration with delavirdine with a Cmax reduction from 4.65 +/- 2.0 to 3.22 +/- 0.59 microM and an AUC0-->infinity reduction from 7.93 +/- 3.9 to 6.54 +/- 2.3 microM.h. Thus, concurrent administration of delavirdine and didanosine may reduce the AUC0-->infinity of both drugs, although the clinical significance of this reduction is unknown. Administration of delavirdine 1 h before didanosine avoided the interaction. Due to the single-dose nature of this study, these findings require further evaluation at steady state.
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PMID:Single-dose pharmacokinetics of delavirdine mesylate and didanosine in patients with human immunodeficiency virus infection. 898 Jul 74

Didanosine (ddI) that inhibits the reverse transcriptase of human immunodeficiency virus (HIV) causes steatosis and fulminant hepatitis in some patients with HIV. We studied hepatic histopathologic changes with particular attention to ddI-induced Mallory body formation. Three liver biopsies were performed on three patients with HIV who were treated with ddI; an autopsy was performed on a patient with HIV who was also treated with ddI. All hepatic specimens were studied with a routine liver immunohistochemical panel including antibodies to ubiquitin and cytokeratin (CAM 5.2). Morphologically, all hepatic specimens showed focal to diffuse steatosis with a predominance of macrovesicular fatty change. Fibrosis was minimal in three cases. No secondary bacterial and fungal infections were noted. Single or clusters of "empty cells" were present, and some contained Mallory bodies validated by ubiquitin stain. Empty cells are hepatocytes that fail to stain positive for cytokeratin. The Mallory bodies were different from the others because they were randomly distributed and occurred in noncirrhotic hepatic tissue. In the autopsy specimen, the Mallory bodies had a centrilobular location with central fibrosis (central sclerosing hyaline necrosis).
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PMID:2',3'-Dideoxyinosine-induced Mallory bodies in patients with HIV. 929 55

The appearance in the clinic of two to three new antiretroviral agents yearly since 1995 has permitted unprecedented advances in HIV treatment. This remarkable pace of drug development is a testimony to an extraordinary international effort involving scientists, clinicians, governments, community activists and industry dedicated to the rapid and safe development of novel therapies. New drugs present the opportunity to improve HIV therapy. They also create an enormous challenge to the clinician, who must constantly assimilate data on new drugs and incorporate this information into practical management strategies. Combination therapy has proven the most effective approach to treat HIV disease. The profound and sustained viral suppression achievable with combinations such as indinavir (IDV), lamivudine (3TC) and zidovudine (ZDV) have resulted in a dramatic shift in HIV treatment paradigms over the last year. The full potential of combination therapy with available drugs has yet to be realized as only a limited number of the possible combinations incorporating new drugs have been fully tested. Even drugs available for many years may have untapped potential. Didanosine (ddI) and stavudine (d4T), once thought to be contraindicated in combination because of their overlapping peripheral neuropathy toxicity, have proven well tolerated and effective. Combination therapy can increase antiviral suppression, prevent drug resistance, optimize drug exposure and simplify dosing, but it can also result in pharmacologic antagonism, subtherapeutic drug concentrations and unexpected toxicities. Clinical studies have confirmed in vitro studies showing pharmacologic antagonism for the combination of ZDV and d4T. Combining protease inhibitors with each other or with non-nucleoside reverse transcriptase inhibitors is complicated by effects both classes of drugs have on drug metabolism and clearance. These observations underline the importance of carefully conducted clinical studies to characterize safety, pharmacokinetics and efficacy of combination therapies. In this review, we will first summarize the clinical profile of new drugs which either became commercially available last year [nelfinavir, nevirapine, delavirdine (DLV)] or are in the late stages of clinical development (DMP-266, abacavir and 141W94). Later we will summarize new data on nucleoside, protease inhibitor and non-nucleoside reverse transcriptase combination regimens. Finally, we will briefly mention new drugs in early stages of development.
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PMID:New antiretrovirals and new combinations. 963 99

Resistance mutations selected in reverse transcriptase (RT) by incompletely suppressive therapy with combination zidovudine and didanosine with or without nevirapine were identified in 141 human immunodeficiency virus type 1 isolates from peripheral blood mononuclear cells of 57 individuals in the AIDS Clinical Trials Group protocol 241. After prolonged treatment (16-48 weeks), the most common nevirapine-selected mutations were RT 181C (15/30 isolates [50%]), 190A (15/30 [50%]), and 101E (9/30 [30%]). RT 103N and 188L, which individually confer cross-resistance to all nonnucleoside RT inhibitors, were seen in a minority of viruses (6/30 [20%] and 4/30 [13%], respectively). Didanosine-resistance mutations arose rarely. A newly recognized mutation, RT 44D, was selected by the nucleosides. Two distinct zidovudine-resistance mutational patterns were noted. Mutations selected during treatment with zidovudine, didanosine, and nevirapine differed among individuals and changed over time. Resistance testing is necessary to identify which mutations are selected by nevirapine-containing combinations.
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PMID:Patterns of resistance mutations selected by treatment of human immunodeficiency virus type 1 infection with zidovudine, didanosine, and nevirapine. 1072 May 11

Hydroxyurea inhibits cellular ribonucleotide reductase, resulting in decreased pools of dNTPs and thus inhibition of DNA synthesis. Studies in vitro have shown that hydroxyurea reduces dNTP pools in cells infected with human immunodeficiency virus type 1 (HIV-1), inhibiting HIV-1 DNA synthesis in infected quiescent and activated primary human lymphocytes and macrophages. Hydroxyurea also potentiates the activity of nucleoside reverse transcriptase inhibitors (NRTIs): the activated triphosphate forms of NRTIs compete with naturally occurring dNTPs for incorporation into nascent viral DNA during reverse transcription. A synergistic effect is observed between hydroxyurea and didanosine (2',3'-dideoxyinosine; DDI). This combination exerts persistent suppression of HIV-1 replication without evidence of viral rebound for over 1 year in HIV-1-infected patients. Didanosine-resistant HIV-1 mutants retain sensitivity to didanosine in the presence of hydroxyurea. The incorporation of didanosine triphosphate by resistant reverse transcriptase is increased in the context of the hydroxyurea-induced depletion of dATP. Although hydroxyurea has a reduced effect on dNTPs competing with the triphosphate forms of pyrimidine NRTIs, it appears to augment the anti-HIV-1 activity of these agents by increasing their intracellular phosphorylation; this may be of particular interest for salvage strategies given recent data indicating disruption of NRTI phosphorylation with specific NRTI treatment regimens. Finally, by exerting a cytostatic effect on CD4 and CD8 T lymphocytes, hydroxyurea may (i) reduce HIV-1 replication by decreasing CD4 T cell proliferation; and (ii) prevent the exhaustion of CD8 T cell populations that may occur as a result of excessive activation in the context of HIV-1 infection.
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PMID:Hydroxyurea: mechanisms of HIV-1 inhibition. 1072 6


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