Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:2.7.7.49 (
reverse transcriptase
)
31,746
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Issues, such as complexity, tolerability, and drug resistance and cross-resistance, limit the effectiveness of current antiretroviral regimens and make the continued development of newer agents important, despite the availability of 20 approved drugs for the treatment of HIV infection. Many new compounds are in development in existing classes: nucleoside and nucleotide analogue
reverse transcriptase
inhibitors (eg, D-d4FC and SPD754), non-nucleoside analogue
reverse transcriptase
inhibitors (eg, capravirine and TMC125), and protease inhibitors (eg, tipranavir and TMC114). In addition, newer classes of antiretroviral drugs, such as HIV entry inhibitors (eg,
TNX
-355, SCH 417690, UK-427,857, AMD 11070), that target the first step in the HIV life cycle are under development. Continued improvement in the treatment of HIV infection will result from the availability of convenient, well-tolerated, and affordable drugs with potent and durable antiretroviral activity.
...
PMID:New Antiretroviral Agents for the Treatment of HIV Infection. 1526 63
Current therapeutic intervention in HIV infection relies upon 20 different drugs. Despite the impressive efficacy shown by these drugs, we are confronted with an unexpected frequency of adverse effects, such as mitochondrial toxicity and lipodystrophy, and resistance, not only to individual drugs but to entire drug classes.Thus, there is now a great need for new antiretroviral drugs with reduced toxicity, increased activity against drug-resistant viruses and a greater capacity to reach tissue sanctuaries of the virus. Two different HIV molecules have been selected as targets of drug inhibition so far:
reverse transcriptase
and protease. Drugs that target the interactions between the HIV envelope and the cellular receptor complex are a 'new entry' into the scenario of HIV therapy and have recently raised great interest because of their activity against multidrug-resistant viruses. There are several compounds that are at different developmental stages in the pipeline to counter HIV entry, among them: (i) the attachment inhibitor dextrin-2-sulfate; (ii) the inhibitors of the glycoprotein (gp) 120/CD4 interaction PRO 542,
TNX
355 and BMS 488043; (iii) the co-receptor inhibitors subdivided in those targeting CCR5 (SCH 417690 [SCH D], UK 427857 GW 873140, PRO 140, TAK 220, AMD 887) and those targeting CXCR4 (AMD 070, KRH 2731); and (iv) the fusion inhibitors enfuvirtide (T-20) and tifuvirtide (T-1249). The story of the first of these drugs, enfuvirtide, which has successfully completed phase III clinical trials, has been approved by the US FDA and by the European Medicines Agency, and is now commercially available worldwide, is an example of how the knowledge of basic molecular mechanisms can rapidly translate into the development of clinically effective molecules.
...
PMID:The appealing story of HIV entry inhibitors : from discovery of biological mechanisms to drug development. 1589 86
Issues, such as complexity, tolerability, and drug resistance and cross-resistance, limit the effectiveness of current antiretroviral regimens and make the continued development of newer agents important, despite the availability of 20 approved drugs for the treatment of HIV infection. Many new compounds are in development in existing classes: nucleoside and nucleotide analogue
reverse transcriptase
inhibitors (eg, D-d4FC and SPD754), non-nucleoside analogue
reverse transcriptase
inhibitors (eg, capravirine and TMC125), and protease inhibitors (eg, tipranavir and TMC114). In addition, newer classes of antiretroviral drugs, such as HIV entry inhibitors (eg,
TNX
-355, SCH 417690, UK-427,857, AMD 11070), that target the first step in the HIV life cycle are under development. Continued improvement in the treatment of HIV infection will result from the availability of convenient, well-tolerated, and affordable drugs with potent and durable antiretroviral activity.
...
PMID:New antiretroviral agents for the treatment of HIV infection. 1609 Dec 27
Current targets for antiretroviral therapy (ART) include the viral enzymes
reverse transcriptase
and protease. The use of a combination of inhibitors targeting these enzymes can reduce viral load for a prolonged period and delay disease progression. However, complications of ART, including the emergence of viruses resistant to current drugs, are driving the development of new antiretroviral agents targeting not only the
reverse transcriptase
and protease enzymes but novel targets as well. Indeed, enfuvirtide, an inhibitor targeting the viral envelope protein (Env) was recently approved for use in combination therapy in individuals not responding to current antiretroviral regimens. Emerging drug targets for ART include: (i) inhibitors that directly or indirectly target Env; (ii) the HIV enzyme integrase; and (iii) inhibitors of maturation that target the substrate of the protease enzyme. Env mediates entry of HIV into target cells via a multistep process that presents three distinct targets for inhibition by viral and cellular-specific agents. First, attachment of virions to the cell surface via nonspecific interactions and CD4 binding can be blocked by inhibitors that include cyanovirin-N, cyclotriazadisulfonamide analogues, PRO 2000,
TNX
355 and PRO 542. In addition, BMS 806 can block CD4-induced conformational changes. Secondly, Env interactions with the co-receptor molecules can be targeted by CCR5 antagonists including SCH-D, maraviroc (UK 427857) and aplaviroc (GW 873140), and the CXCR4 antagonist AMD 070. Thirdly, fusion of viral and cellular membranes can be inhibited by peptides such as enfuvirtide and tifuvirtide (T 1249). The development of entry inhibitors has been rapid, with an increasing number entering clinical trials. Moreover, some entry inhibitors are also being evaluated as candidate microbicides to prevent mucosal transmission of HIV. The integrase enzyme facilitates the integration of viral DNA into the host cell genome. The uniqueness and specificity of this reaction makes integrase an attractive drug target. However, integrase inhibitors have been slow to reach clinical development, although recent contenders, including L 870810, show promise. Inhibitors that target viral maturation via a unique mode of action, such as PA 457, also have potential. In addition, recent advances in our understanding of cellular pathways involved in the life cycle of HIV have also identified novel targets that may have potential for future antiretroviral intervention, including interactions between the cellular proteins APOBEC3G and TSG101, and the viral proteins Vif and p6, respectively. In summary, a number of antiretroviral agents in development make HIV entry, integration and maturation emerging drug targets. A multifaceted approach to ART, using combinations of inhibitors that target different steps of the viral life cycle, has the best potential for long-term control of HIV infection. Furthermore, the development of microbicides targeting HIV holds promise for reducing HIV transmission events.
...
PMID:Emerging drug targets for antiretroviral therapy. 1611 75
Human immunodeficiency virus (HIV) infection affects close to 40 million individuals worldwide. Since 1981 when the first case reports of individuals dying from a then rare opportunistic infection were published, twenty million people have died from this epidemic. With 3 or more antiretrovirals as the standard of care, the prevalence of single, double and triple-class resistant HIV strains has increased significantly over the last 5 years due to the tremendous replicative capacity of HIV and selective drug pressure. With greater resistance comes the need for novel and effective antiretrovirals to treat these resistant strains. The purpose of this review is to highlight the most promising agents and classes in Phase II-III drug development by assessing the clinical efficacy, pharmacology, resistance and tolerability. Three out of the four existing antiretroviral classes (nucleosides, non-nucleosides, protease inhibitors) with agents in clinical trials will be discussed such as nucleoside
reverse transcriptase
inhibitors (D-d4FC, SPD754), non-nucleoside
reverse transcriptase
inhibitors (capravirine, TMC125) and protease inhibitors (tipranavir, TMC114). In the next several years, antiretrovirals from novel pharmacologic classes will enter the HIV armamentarium. Based on the early clinical studies, these promising agents will be reviewed from the following classes: attachment inhibitors (
TNX
-355, BMS-488043), CCR5 coreceptor antagonists (SCH-D, UK-427857, GW 873140) and a maturation inhibitor (PA-457). It is hoped that these agents will represent a therapeutic advance and better activity against HIV resistant strains by providing effective therapy that will reduce viral load, increase the CD4+ cell count and ultimately, prolong survival with minimal adverse effects.
...
PMID:On the horizon: promising investigational antiretroviral agents. 1651 88
