Development of LpxH Inhibitors Chelating the Active Site Dimanganese Metal Cluster of LpxH.

Despite the widespread emergence of multidrug-resistant nosocomial Gram-negative bacterial infections and the major public health threat it brings, no new class of antibiotics for Gram-negative pathogens has been approved over the past five decades. Therefore, there is an urgent medical need for developing effective novel antibiotics against multidrug-resistant Gram-negative pathogens by targeting previously unexploited pathways in these bacteria. To fulfill this crucial need, we have been investigating a series of sulfonyl piperazine compounds targeting LpxH, a dimanganese-containing UDP-2,3-diacylglucosamine hydrolase in the lipid A biosynthetic pathway, as novel antibiotics against clinically important Gram-negative pathogens. Inspired by a detailed structural analysis of our previous LpxH inhibitors in complex with K. pneumoniae LpxH (KpLpxH), here we report the development and structural validation of the first-in-class sulfonyl piperazine LpxH inhibitors, JH-LPH-45 (8) and JH-LPH-50 (13), that achieve chelation of the active site dimanganese cluster of KpLpxH. The chelation of the dimanganese cluster significantly improves the potency of JH-LPH-45 (8) and JH-LPH-50 (13). We expect that further optimization of these proof-of-concept dimanganese-chelating LpxH inhibitors will ultimately lead to the development of more potent LpxH inhibitors for targeting multidrug-resistant Gram-negative pathogens.

Synthesis and analysis of novel catecholic ligands as inhibitors of catechol-O-methyltransferase.

l-DOPA, a dopamine precursor, is commonly used as a treatment for patients with conditions such as Parkinson's disease. This therapeutic l-DOPA, as well as the dopamine derived from l-DOPA, can be deactivated via metabolism by catechol-O-methyltransferase (COMT). Targeted inhibition of COMT prolongs the effectiveness of l-DOPA and dopamine, resulting in a net increase in pharmacological efficiency of the treatment strategy. Following the completion of a previous ab initio computational analysis of 6-substituted dopamine derivatives, several novel catecholic ligands with a previously unexplored neutral tail functionality were synthesized in good yields and their structures were confirmed. The ability of the catecholic nitriles and 6-substituted dopamine analogues to inhibit COMT was tested. The nitrile derivatives inhibited COMT most effectively, in agreement with our previous computational work. pKa values were used to further examine the factors involved with the inhibition and molecular docking studies were performed to support the ab initio and experimental work. The nitrile derivatives with a nitro substituent show the most promise as inhibitors, confirming that both the neutral tail and the electron withdrawing group are essential on this class of inhibitors.