4-Hydroxy-α-tetralone and its derivative as drug resistance reversal agents in multi drug resistant Escherichia coli.

The purpose of present investigation was to understand the drug resistance reversal mechanism of 4-hydroxy-α-tetralone (1) isolated from Ammannia spp. along with its semi-synthetic derivatives (1a-1e) using multidrug resistant Escherichia coli (MDREC). The test compounds did not show significant antibacterial activity of their own, but in combination, they reduced the minimum inhibitory concentration (MIC) of tetracycline (TET). In time kill assay, compound 1 and its derivative 1e in combination with TET reduced the cell viability in concentration dependent manner. Compounds 1 and 1e were also able to reduce the mutation prevention concentration of TET. Both compounds showed inhibition of ATP dependent efflux pumps. In real time polymerase chain reaction (RT-PCR) study, compounds 1 and 1e alone and in combination with TET showed significant down expression of efflux pump gene (yojI) encoding multidrug ATP binding cassettes (ABC) transporter protein. Molecular mechanism was also supported by the in silico docking studies, which revealed significant binding affinity of compounds 1 and 1e with YojI. This study confirms that compound 1 and its derivative 1e are ABC efflux pump inhibitors which may be the basis for development of antibacterial combinations for the management of MDR infections from inexpensive natural product.

Tricyclic sesquiterpenes from Vetiveria zizanoides (L.) Nash as antimycobacterial agents.

Two bioactive constituents, khusenic acid (1) and khusimol (2), were isolated and characterized from hexane fraction of Vetiveria zizanoides roots. Compounds, 1 and 2, were tested against the various drug-resistant mutants of Mycobacterium smegmatis. The results showed that compound 1 was 4 times more active than the standard drugs ciprofloxacin (CF) and nalidixic acid (NA) against the ciprofloxacin (CSC 101) and lomefloxacin(LOMR5)-resistant mutants, whereas the compound 2 was 2 times more active against the CSC 101 than the NA and CF. Further, these compounds were tested against the virulent strain H37Rv of Mycobacterium tuberculosis, which showed that 1 was two times more active than NA, while 2 was equally active to NA. In in silico docking study, 1 showed better binding affinity than 2 with both subunits of the bacterial DNA gyrase, which was further confirmed from the in vitro bacterial DNA gyrase inhibition study. The in silico ADME analysis of 1 and 2 showed better intestinal absorption, aqueous solubility and ability to penetrate blood-brain barrier. Finally, compound 2 was found safe at the highest dose of 2000 mg/kg body weight. Being edible, fragrant natural products, 1 and 2 will have advantage over the existing synthetic drugs.

Improved production of alkaline protease from a mutant of alkalophilic Bacillus pantotheneticus using molasses as a substrate.

An alkalophilic bacterial isolate identified as Bacillus pantotheneticus, isolated from saline-alkali soils of Avadh region of UP, India, was studied for the production of alkaline protease. The mutant of the isolated species showed 44% improved production over the parent strain. Organic nitrogen sources supported better protease production than the inorganic sources. The production of alkaline protease was (242 U/ml) in the medium containing molasses, which was comparable with molasses and wheat bran (285 U/ml) as carbon and nitrogen sources, respectively. Protease production was best at pH 10 and temperature 30 degrees C. The Km (for casein) was 11 mg/ml and Vmax was 380-microg tyrosine/ml/min. The enzyme was stable between pH 7 and 10.7 and temperature between 30 and 60 degrees C with a pH and temperature optimum at 8.4 and 40 degrees C, respectively. The results indicated that molasses was an optimal substrate for alkaline protease production.