Identification of the site of covalent attachment of nafcillin, a reversible suicide inhibitor of beta-lactamase

Click chemistry inspired syntheses of new amide linked 1,2,3-triazoles from naphthols: biological evaluation and in silico computational study

In search of new active molecules, a small focused library of new 1,2,3-triazoles derived from naphthols were efficiently prepared via the click chemistry approach. The synthesized triazole derivatives were evaluated for their antifungal, antioxidant and antitubercular activities. Furthermore, to rationalize the observed biological activity data, the molecular docking study has also been carried out against the active site of cytochrome P450 lanosterol 14α-demethylase of C. albicans to understand the binding affinity and binding interactions of enzyme and synthesized derivatives, which revealed a significant correlation between the binding score and biological activity for these compounds. The results of the in vitro and In Silico study suggest that the 1,2,3-triazole derivatives may possess the ideal structural requirements for the further development of novel therapeutic agents.

Identification, Isolation, and Characterization of a New Degradation Impurity in Nafcillin Sodium

A new degradant of Nafcillin Sodium was found at a level of 1.8% w/w during the gradient reversed-phase HPLC analysis in stability storage samples. This impurity was identified by LC-MS and was characterized by (1)H-NMR, (13)C-NMR, LC/MS/MS, elemental analysis, and IR techniques. Based on the structural elucidation data, this impurity was named as N-[(2S)-2-carboxy-2-{[(2-ethoxynaphthalen-1-yl)carbonyl]amino}ethylidene]-3-({N-[(2-ethoxynaphthalen-1-yl)carbonyl]glycyl}sulfanyl)-D-valine. This impurity was prepared by isolation and was co-injected into the HPLC system to confirm the retention time. To the best of our knowledge, this impurity has not been reported elsewhere. The identification and structural elucidation of this degradant impurity has been discussed in detail.

Three decades of the class A beta-lactamase acyl-enzyme

The discovery that the mechanism of beta-lactam hydrolysis catalyzed by the class A (active site serine-dependent) beta-lactamases proceeds via an acyl-enzyme intermediate was made thirty years ago. Since this discovery, the active site circumstance that enables acylation of the active site serine and further enables hydrolytic deacylation of the acyl-serine intermediate, has received extraordinary scrutiny. The justification for this scrutiny is the direct relevance of the beta-lactamases to the manifestation of bacterial resistance to the beta-lactam antibiotics, and the subsequent (to the discovery of the beta-lactamase acyl-enzyme) recognition of the direct evolutionary relationship between the serine beta-lactamase acyl-enzyme, and the penicillin binding protein acyl-enzyme that is key to beta-lactam antibiotic activity. This short review describes the early events leading to the recognition that serine beta-lactamase catalysis proceeds via an acyl-enzyme intermediate, and summarizes several of the key mechanistic studies--including infrared spectroscopy, cryoenzymology, beta-lactam design, and x-ray crystallography--that have been exploited to understand this pivotal catalytic intermediate.