UDP-N-acetylmuramic acid l-alanine ligase (MurC) inhibition in a tolC mutant Escherichia coli strain leads to cell death.

The Mur ligases play an essential role in the biosynthesis of bacterial peptidoglycan and hence are attractive antibacterial targets. A screen of the AstraZeneca compound library led to the identification of compound A, a pyrazolopyrimidine, as a potent inhibitor of Escherichia coli and Pseudomonas aeruginosa MurC. However, cellular activity against E. coli or P. aeruginosa was not observed. Compound A was active against efflux pump mutants of both strains. Experiments using an E. coli tolC mutant revealed accumulation of the MurC substrate and a decrease in the level of product upon treatment with compound A ,: indicating inhibition of MurC enzyme in these cells. Such a modulation was not observed in the E. coli wild-type cells. Further, overexpression of MurC in the E. coli tolC mutant led to an increase in the compound A MIC by ≥16-fold, establishing a correlation between MurC inhibition and cellular activity. In addition, estimation of the intracellular compound A level showed an accumulation of the compound over time in the tolC mutant strain. A significant compound A level was not detected in the wild-type E. coli strain even upon treatment with high concentrations of the compound. Therefore, the lack of MIC and absence of MurC inhibition in wild-type E. coli were possibly due to suboptimal compound concentration as a consequence of a high efflux level and/or poor permeativity of compound A.

Identification and mitigation of a reactive metabolite liability associated with aminoimidazoles.

Reactive metabolites (RMs) have been implicated as causal factors in many drug-associated idiosyncratic toxicities. This study aims at identification and mitigation of an RM liability associated with aminoimidazole and amino(aza)benzimidazole structural motifs from an antimalarial project. Nineteen compounds with different structural modifications were studied in rat and human liver microsomes using glutathione (GSH) and N-acetyl cysteine (NAC) as trapping agents for RM. Metabolite profiling of aminoimidazole compounds in initial studies revealed the presence of dihydrodiol metabolites suggestive of reactive epoxide precursors, confirmed by the identification of a dihydrohydroxy GSH conjugate in GSH supplemented incubations. Substitution of methyl group at a potential site of metabolism blocked the epoxidation; however, formation of an imine-methide RM was suspected. Masking the site of metabolism via benzimidazole and 4/7-azabenzimidazole resulted in the possible formation of quinone-imine intermediates as a product of bioactivation. Further, substitutions with electron withdrawing groups and steric crowding did not address this liability. Mitigation of bioactivation was achieved with 5/6-azabenzimidazole and with CF3 substitution at the 6-position of the 7-azabenzimidazole ring. Moreover, compounds devoid of imidazole -NH2 do not undergo bioactivation. This study, therefore, establishes aminoimidazole and amino(aza)benzimidazoles as potential toxicophores and describes ways to mitigate this bioactivation liability by chemical modification.

Thiazolopyridone ureas as DNA gyrase B inhibitors: optimization of antitubercular activity and efficacy.

Scaffold hopping from the thiazolopyridine ureas led to thiazolopyridone ureas with potent antitubercular activity acting through inhibition of DNA GyrB ATPase activity. Structural diversity was introduced, by extension of substituents from the thiazolopyridone N-4 position, to access hydrophobic interactions in the ribose pocket of the ATP binding region of GyrB. Further optimization of hydrogen bond interactions with arginines in site-2 of GyrB active site pocket led to potent inhibition of the enzyme (IC50 2 nM) along with potent cellular activity (MIC=0.1 µM) against Mycobacterium tuberculosis (Mtb). Efficacy was demonstrated in an acute mouse model of tuberculosis on oral administration.