Expression of a bacterial transporter protein in Toxoplasma gondii results in parasite susceptibility to Formidomycin, a drug targeting isoprenoid precursor synthesis.
1-Deoxy-d-xylulose-5-phosphate reductoisomerase (DXR) in the non-mevalonate pathway found in most bacteria is a validated anti-infective drug target. Fosmidomycin, a potent DXR inhibitor, is active against Gram-negative bacteria. A coordination chemistry and structure based approach was used to discover a novel, lipophilic DXR inhibitor with an IC(50) of 1.4 microM. It exhibited a broad spectrum of activity against Gram-negative and -positive bacteria with minimal inhibition concentrations of 20-100 microM (or 3.7-19 microg/mL).
Sirtuins
(SIRTs) are NAD-dependent deacylases, known to be involved in a variety
of pathophysiological processes and thus remain promising therapeutic
targets for further validation. Previously, we reported a novel thienopyrimidinone
SIRT2 inhibitor with good potency and excellent selectivity for SIRT2.
Herein, we report an extensive SAR study of this chemical series and
identify the key pharmacophoric elements and physiochemical properties
that underpin the excellent activity observed. New analogues have
been identified with submicromolar SIRT2 inhibtory activity and good
to excellent SIRT2 subtype-selectivity. Importantly, we report a cocrystal
structure of one of our compounds (29c) bound to SIRT2.
This reveals our series to induce the formation of a previously reported selectivity
pocket but to bind in an inverted fashion to what might be intuitively
expected. We believe these findings will contribute significantly
to an understanding of the mechanism of action of SIRT2 inhibitors
and to the identification of refined, second generation inhibitors.
Histone lysine methyltransferases (HKMTs) are an important class of targets for epigenetic therapy. 1 (chaetocin), an epidithiodiketopiperazine (ETP) natural product, has been reported to be a specific inhibitor of the SU(VAR)3-9 class of HKMTs. We have studied the inhibition of the HKMT G9a by 1 and functionally related analogues. Our results reveal that only the structurally unique ETP core is required for inhibition, and such inhibition is time-dependent and irreversible (in the absence of DTT), ultimately resulting in protein denaturation. Mass spectrometric data provide a molecular basis for this effect, demonstrating covalent adduct formation between 1 and the protein. This provides a potential rationale for the selectivity observed in the inhibition of a variety of HKMTs by 1 in vitro and has implications for the activity of ETPs against these important epigenetic targets.
Fungi are one of the most neglected pathogens apparent from the fact that the Amphotericin B, a polyene antibiotic, discovered way back in 1956 is still used as a 'gold standard' for antifungal therapy. Past two decades have witnessed a dramatic rise in the incidences of life threatening systemic fungal infections. This can be ascribed to the increase in the number of immuno-compromised patients due to rise in HIV infected population, cancer chemotherapy and indiscriminate use of antibiotics. Majority of clinically used antifungals suffer from various drawbacks in terms of toxicity, efficacy and cost, and their frequent use has led to the emergence of resistant strains. Hence, there is a great demand for novel antifungals belonging to wide range of structural classes, selectively acting on novel targets with fewer side effects. This article aims at reviewing recent efforts made towards discovering novel antifungal drug targets and investigational molecules acting on them.
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