Insilico studies on anthrax lethal factor inhibitors: pharmacophore modeling and virtual screening approaches towards designing of novel inhibitors for a killer.

Bacillus anthracis is a causative organism of anthrax. The main reason to use anthrax as a bioweapon is the combination of the spore's durability and the lethal toxaemia of the vegetative stage. In anthrax infection, lethal factor (LF) is playing crucial role in causing cell death, by inhibiting pathways that rely on this kinase family. The combination of vaccine and antibiotics is preferred as an effective treatment for this target. Till date, no small molecule inhibitor is identified as a drug on the target. In this study, we have performed pharmacophore modeling and docking studies to identify a novel small molecule inhibitor to target the Anthrax LF. The best pharmacophore model is used to screen approximately 2M drug-like small molecule database and yielded 2543 hits. Docking studies of the pharmacophore hits on to the active site of Anthrax LF resulted 120 structurally diverse hits. Out of 120 hits, based on synthetic feasibility, 17 hits are selected for further synthesis and pharmacological screening. In due course, we will publish the updated results.

Pharmacophore guided discovery of small-molecule human apurinic/apyrimidinic endonuclease 1 inhibitors.

Human apurinic/apyrimidinic endonuclease 1 (APE1) is an important enzyme in the base excision repair (BER) pathway that is essential for the repair of abasic sites in the genome. Evidence for APE1 as an attractive therapeutic target in anticancer drug development has been demonstrated by studies that link overexpression of APE1 in many cancers to resistance of tumor cells to radio- and chemotherapy. APE1 also shows a protective effect in several cancer cell models to a variety of DNA damaging agents. This study represents the first rational design of selective small-molecule APE1 inhibitors utilizing a three-dimensional interaction-based pharmacophore perception. All of our most potent molecules show inhibitory activity below 10 muM and are selective for APE1 inhibition.

HIV-1 integrase inhibitors: an emerging clinical reality.

From the discovery of HIV-1 integrase (IN) inhibitors using enzyme-based assays in 1992, it has taken 15 years to achieve success in human clinical trials. Currently available antiretroviral drugs set high clinical standards in efficacy and long-term safety for upcoming novel HIV/AIDS therapeutic agents. The results from advanced stages of human clinical trials with IN inhibitors indicate a promising future for these compounds as a novel class of antiretroviral drugs. Success and failure of previously discovered antiretroviral drugs have taught us that there are no magic bullets in eradicating HIV. However, approval of drugs selectively targeting IN has long been awaited. There is once again a surge of interest in the field focusing on clinical development of IN inhibitors. Here, we summarise the current status of IN inhibitors under clinical development. These agents include S-1360, GSK-364735, L-870,810, L-870,812, MK-0518, GS-9137, L-900564, GS-9224, and BMS-707035. Promising antiviral activity has already been achieved with MK-0518 and GS-9137 in late-stage clinical studies.

Beta-diketo acid pharmacophore hypothesis. 1. Discovery of a novel class of HIV-1 integrase inhibitors.

HIV-1 Integrase (IN) is an essential enzyme for viral replication. The discovery of beta-diketo acids was crucial in the validation of IN as a legitimate target in drug discovery against HIV infection. In this study, we discovered a novel class of IN inhibitors using a 3D pharmacophore guided database search. We used S-1360 (1), the first IN inhibitor to undergo clinical trials, and three other analogues to develop a common feature pharmacophore hypothesis. Testing this four-featured pharmacophore against a multiconformational database of 150,000 structurally diverse small molecules yielded 1,700 compounds that satisfied the 3D query. Subsequently, all 1,700 compounds were docked into the active site of IN. On the basis of docking scores, Lipinski's rule-of-five, and structural novelty, 110 compounds were selected for biological screening. We found that compounds that contain both salicylic acid and a 2-thioxo-4-thiazolidinone (rhodanine) group (e.g. 5-13) showed significant inhibitory potency against IN, while the presence of either salicylic acid or a rhodanine group alone did not. Although some of the compounds containing only a salicylic acid showed inhibitory potency against IN, none of the compounds containing only rhodanine exhibited considerable potency. Of the 52 compounds reported in this study, 11 compounds (5, 6, 8, 10-13, 32-33, 51, and 53) inhibited 3'-processing or strand transfer activities of IN with IC(50) < or = 25 microM. This is the first reported use of S-1360 and its analogues as leads in developing a pharmacophore hypothesis for IN inhibition and for identification of new compounds with potent inhibition of this enzyme.