bevirimat and Acquired-Immunodeficiency-Syndrome

More than 20 individual and fixed-dose combinations of antiretrovirals are approved for the treatment of human immunodeficiency virus (HIV) infection. However, owing to the ongoing limitations of drug resistance and adverse effects, new treatment options are still required. A number of promising new agents in existing or new drug classes are in development or have recently been approved by the US FDA. Since these agents will be used in combination with other new and existing antiretrovirals, understanding the potential for drug interactions between these compounds is critical to their appropriate use. This article summarizes the drug interaction potential of new and investigational protease inhibitors (darunavir), non-nucleoside reverse transcriptase inhibitors (etravirine and rilpivirine), chemokine receptor antagonists (maraviroc, vicriviroc and INCB 9471), integrase inhibitors (raltegravir and elvitegravir) and maturation inhibitors (bevirimat).

Topics: Acquired Immunodeficiency Syndrome; Anti-HIV Agents; Drug Interactions; Drug Therapy, Combination; Drugs, Investigational; HIV Integrase Inhibitors; HIV Protease Inhibitors; Humans; Molecular Structure; Receptors, Chemokine; Reverse Transcriptase Inhibitors; Succinates; Triterpenes

Existing antiretroviral treatments for HIV type-1 (HIV-1) disease are limited by problems of resistance and drug-drug interactions. Bevirimat is a novel HIV-1 maturation inhibitor with a mechanism of action that is distinct from other antiretroviral agents. Specific inhibition of the final rate-limiting step in Gag processing by bevirimat prevents release of mature capsid protein from its precursor (CA-SP1), resulting in the production of immature, non-infectious virus particles. Bevirimat inhibits replication of both wild-type and drug-resistant HIV-1 isolates in vitro, achieving similar 50% inhibitory concentration values with both categories. Serial drug passage studies have identified six single amino acid substitutions that independently confer bevirimat resistance. These resistance mutations occur at or near the CA-SP1 cleavage site, which is not a known target for resistance to other antiretroviral drugs. Bevirimat has demonstrated a consistent pharmacokinetic profile in healthy volunteers and HIV-infected patients, with peak plasma concentrations attained approximately 1-3 h after dosing. Plasma concentrations decrease in a log-linear manner with a mean plasma elimination halflife of 58-80 h, supporting once-daily dosing. Animal studies suggest that elimination of bevirimat is primarily by hepatic glucuronidation and hepatobiliary excretion. There is minimal renal elimination, with < 1% of the administered dose appearing in the urine. In responsive patients, bevirimat has demonstrated a robust dosedependent reduction in viral load (> 1.5 log10 copies/ml). Short-term administration (< or = 14 days) of bevirimat is well tolerated, even when used in combination with other antiretroviral agents. Further studies to evaluate the long-term efficacy and tolerability of bevirimat are currently underway.

Topics: Acquired Immunodeficiency Syndrome; Anti-HIV Agents; Drug Resistance, Viral; HIV-1; Humans; Succinates; Triterpenes

This review discusses anti-HIV natural products from several compound classes, including terpenoids, coumarins, alkaloids, polyphenols, tannins, and flavonoids. Natural products can provide novel anti-AIDS chemotherapeutic leads that are structurally unique or have new mechanisms of action. The drug discovery and development process proceeds from bioactivity-directed isolation and identification of a promising lead natural product, followed by rational design-based structural modification and structure-activity relationship analyses to optimize the lead compound as a drug candidate. This process is notably exemplified by the discovery of the modified betulinic acid derivative, DSB [PA-457], which is currently in Phase II clinical trial and is the first-in-class HIV maturation inhibitor (MI).

Topics: Acquired Immunodeficiency Syndrome; Alkaloids; Anti-HIV Agents; Coumarins; Drug Design; Flavonoids; Humans; Phenols; Phytotherapy; Plant Extracts; Plants, Medicinal; Polyphenols; Succinates; Triterpenes

Bevirimat (1, BVM) is an anti-HIV agent that blocks HIV-1 replication by interfering with HIV-1 Gag-SP1 processing at a late stage of viral maturation. However, clinical trials of 1 have revealed a high baseline drug resistance that is attributed to naturally occurring polymorphisms in HIV-1 Gag. To overcome the drug resistance, 28 new derivatives of 1 were synthesized and tested against compound 1-resistant (BVM-R) HIV-1 variants. Among them, compound 6 exhibited much improved activity against several HIV-1 strains carrying BVM-R polymorphisms. Compound 6 was at least 20-fold more potent than 1 against the replication of NL4-3/V370A, which carries the most prevalent clinical BVM-R polymorphism in HIV-1 Gag-SP1. Thus, compound 6 merits further development as a potential anti-AIDS clinical trial candidate.

Topics: Acquired Immunodeficiency Syndrome; Anti-HIV Agents; Cell Line; Drug Resistance, Viral; gag Gene Products, Human Immunodeficiency Virus; HIV-1; Humans; Polymorphism, Genetic; Succinates; Triterpenes; Virus Replication

3-O-3'(or 2')-Methylsuccinyl-betulinic acid (MSB) derivatives were separated by using recycle HPLC. The structures of four isomers were assigned by NMR and asymmetric synthesis. 3-O-3'S-Methylsuccinyl-betulinic acid (3'S-MSB, 4) exhibited potent anti-HIV activity with an EC(50) value of 0.0087microM and a TI value of 6.3x10(3), which is comparable to the data for bevirimat (DSB, PA-457), a current clinical trials drug that was also derived from betulinic acid. The anti-HIV potency of 4 was slightly better than that of AZT.

Topics: Acquired Immunodeficiency Syndrome; Anti-HIV Agents; Cell Line, Tumor; HIV-1; Humans; Stereoisomerism; Structure-Activity Relationship; Succinates; Triterpenes; Virus Replication

Succinyl and 3'-substituted glutaryl betulin derivatives showed stronger anti-HIV activity and higher therapeutic index (TI) values than their dihydrobetulin counterparts, with ratios of 1.2:1 to 15:1 (cf. 7 and 15, 9 and 17, 10 and 18, 11 and 19, and 12 and 20). For various 3'-substituted glutaryl compounds, the order of anti-HIV effects, from strong to weak inhibition, was 3',3'-dimethyl, 3'-methyl, 3'-ethyl-3'-methyl, followed by 3',3'-tetramethylene glutaryl derivatives (10 > 9 > 11 > 12, 18 > 17 > 19 > 20). The most potent compound, 10, has two 3',3'-dimethylglutaryl groups and displays significant anti-HIV potency with an EC50 value of 0.000 66 microM and a TI of 21 515. Results for compounds (22 and 23) without a C-3 acyl group confirmed the importance of the C-3 acyl group to the anti-HIV effect. With 3',3'-tetramethylene glutaryl derivatives, triacyl 29 showed stronger inhibition than diacyl 12; in contrast, 3',3'-dimethylglutaryl compounds displayed opposite results. 3-Keto compounds (35 and 36) and 2,3-dihydro compounds (39 and 40) had EC50 values in the range of 4.3-10.0 microM, suggesting that A ring modification led to decreased potency. The reduced activity of amide (33 and 34), ester (41), and oxime (42) analogues suggested that the orientation and linkage of the C-3 acyl side chain play crucial roles in the potent anti-HIV activity. Finally, replacing the C-28 acyl group with a bulky non-carboxylic group produced a less potent compound (44). In the study of mechanism of action, our results indicated that fusion is not the primary target for the anti-HIV activity of 10. It appears to inhibit HIV replication at a late stage of the viral life cycle, i.e., after viral protein synthesis.

Topics: Acquired Immunodeficiency Syndrome; Animals; Anti-HIV Agents; Cell Fusion; Cell Line; Glutarates; HeLa Cells; HIV-1; Humans; Lymphocytes; Mice; Structure-Activity Relationship; Triterpenes; Virus Replication