Project description:Methionine aminopeptidase (MetAP) carries out an essential function of protein N-terminal processing in many bacteria and is a promising target for the development of novel antitubercular agents. Natural bengamides potently inhibit the proliferation of mammalian cells by targeting MetAP enzymes, and the X-ray crystal structure of human type 2 MetAP in complex with a bengamide derivative reveals the key interactions at the active site. By preserving the interactions with the conserved residues inside the binding pocket while exploring the differences between bacterial and human MetAPs around the binding pocket, seven bengamide derivatives were synthesized and evaluated for inhibition of MtMetAP1a and MtMetAP1c in different metalloforms, inhibition of M. tuberculosis growth in replicating and non-replicating states, and inhibition of human K562 cell growth. Potent inhibition of MtMetAP1a and MtMetAP1c and modest growth inhibition of M. tuberculosis were observed for some of these derivatives. Crystal structures of MtMetAP1c in complex with two of the derivatives provided valuable structural information for improvement of these inhibitors for potency and selectivity.

Project description:Methionine aminopeptidase (MetAP) carries out an important cotranslational N-terminal methionine excision of nascent proteins and represents a potential target to develop antibacterial and antitubercular drugs. We cloned one of the two MetAPs in Mycobacterium tuberculosis (MtMetAP1c from the mapB gene) and purified it to homogeneity as an apoenzyme. Its activity required a divalent metal ion, and Co(II), Ni(II), Mn(II), and Fe(II) were among activators of the enzyme. Co(II) and Fe(II) had the tightest binding, while Ni(II) was the most efficient cofactor for the catalysis. MtMetAP1c was also functional in E. coli cells because a plasmid-expressed MtMetAP1c complemented the essential function of MetAP in E. coli and supported the cell growth. A set of potent MtMetAP1c inhibitors were identified, and they showed high selectivity toward the Fe(II)-form, the Mn(II)-form, or the Co(II) and Ni(II) forms of the enzyme, respectively. These metalloform selective inhibitors were used to assign the metalloform of the cellular MtMetAP1c. The fact that only the Fe(II)-form selective inhibitors inhibited the cellular MtMetAP1c activity and inhibited the MtMetAP1c-complemented cell growth suggests that Fe(II) is the native metal used by MtMetAP1c in an E. coli cellular environment. Finally, X-ray structures of MtMetAP1c in complex with three metalloform-selective inhibitors were analyzed, which showed different binding modes and different interactions with metal ions and active site residues.

Project description:Natural-product-derived bengamides possess potent antiproliferative activity and target human methionine aminopeptidases (MetAPs) for their cellular effects. Several derivatives were designed, synthesized, and evaluated as MetAP inhibitors. Here, we present four new X-ray structures of human MetAP1 in complex with the inhibitors. Together with the previous structures of bengamide derivatives with human MetAP2 and tubercular MtMetAP1c, analysis of the interactions of these inhibitors at the active site provides structural basis for further modification of these bengamide inhibitors for improved potency and selectivity as anticancer and antibacterial therapeutics.

Project description:Methionine aminopeptidase (MetAP) carries out the cotranslational N-terminal methionine excision and is essential for bacterial survival. Mycobacterium tuberculosis expresses two MetAPs, MtMetAP1a and MtMetAP1c, at different levels in growing and stationary phases, and both are potential targets to develop novel antitubercular therapeutics. Recombinant MtMetAP1a was purified as an apoenzyme, and metal binding and activation were characterized with an activity assay using a fluorogenic substrate. Ni(II), Co(II) and Fe(II) bound tightly at micromolar concentrations, and Ni(II) was the most efficient activator for the MetAP-catalyzed substrate hydrolysis. Although the characteristics of metal binding and activation are similar to MtMetAP1c we characterized before, MtMetAP1a was significantly more active, and more importantly, a set of inhibitors displayed completely different inhibitory profiles on the two mycobacterial MetAPs in both potency and metalloform selectivity. The differences in catalysis and inhibition predicted the significant differences in active site structure.

Project description:M. tuberculosis (Mtb), which causes tuberculosis disease, continues to be a major global health threat. Correct identification of valid drug targets is important for the development of novel therapeutics that would shorten the current 6-9 month treatment regimen and target resistant bacteria. Methionine aminopeptidases (MetAP), which remove the N-terminal methionine from newly synthesized proteins, are essential in all life forms (eukaryotes and prokaryotes). The MetAPs contribute to the cotranslational control of proteins as they determine their half life (N-terminal end rule) and facilitate further modifications such as acetylation and others. Mtb (and M. bovis) possess two MetAP isoforms, MetAP1a and MetAP1c, encoded by the mapA and mapB genes, respectively. Conflicting evidence was reported in the literature on which of the two variants is essential. To resolve this question, we performed a targeted genetic deletion of each of these two genes. We show that a deletion mutant of mapA is viable with only a weak growth defect. In contrast, we provide two lines of genetic evidence that mapB is indispensable. Furthermore, construction of double-deletion mutants as well as the introduction of point mutations into mapB resulting in proteins with partial activity showed partial, but not full, redundancy between mapB and mapA. We propose that it is MetAP1c (mapB) that is essentially required for mycobacteria and discuss potential reasons for its vitality.

Project description:Methionine aminopeptidases (MetAPs) are metalloenzymes that cleave the N-terminal methionine from newly synthesized peptides and proteins. These MetAP enzymes are present in bacteria, and knockout experiments have shown that MetAP activity is essential for cell life, suggesting that MetAPs are good antibacterial drug targets. MetAP enzymes are also present in the human host and selectivity is essential. There have been significant structural biology efforts and over 65 protein crystal structures of bacterial MetAPs are deposited into the PDB. This review highlights the available crystallographic data for bacterial MetAPs. Structural comparison of bacterial MetAPs with human MetAPs highlights differences that can lead to selectivity. In addition, this review includes the chemical diversity of molecules that bind and inhibit the bacterial MetAP enzymes. Analysis of the structural biology and chemical space of known bacterial MetAP inhibitors leads to a greater understanding of this antibacterial target and the likely development of potential antibacterial agents.

Project description:Two divalent metal ions are commonly seen in the active-site cavity of methionine aminopeptidase, and at least one of the metal ions is directly involved in catalysis. Although ample structural and functional information is available for dimetalated enzyme, methionine aminopeptidase likely functions as a monometalated enzyme under physiological conditions. Information on structure, as well as catalysis and inhibition, of the monometalated enzyme is lacking. By improving conditions of high-throughput screening, we identified a unique inhibitor with specificity toward the monometalated enzyme. Kinetic characterization indicates a mutual exclusivity in binding between the inhibitor and the second metal ion at the active site. This is confirmed by X-ray structure, and this inhibitor coordinates with the first metal ion and occupies the space normally occupied by the second metal ion. Kinetic and structural analyses of the inhibition by this and other inhibitors provide insight in designing effective inhibitors of methionine aminopeptidase.

Project description:Methionine aminopeptidase is a potential target of future antibacterial and anticancer drugs. Structural analysis of complexes of the enzyme with its inhibitors provides valuable information for structure-based drug design efforts.Five new X-ray structures of such enzyme-inhibitor complexes were obtained. Analysis of these and other three similar structures reveals the adaptability of a surface-exposed loop bearing Y62, H63, G64 and Y65 (the YHGY loop) that is an integral part of the substrate and inhibitor binding pocket. This adaptability is important for accommodating inhibitors with variations in size. When compared with the human isozymes, this loop either becomes buried in the human type I enzyme due to an N-terminal extension that covers its position or is replaced by a unique insert in the human type II enzyme.The adaptability of the YHGY loop in E. coli methionine aminopeptidase, and likely in other bacterial methionine aminopeptidases, enables the enzyme active pocket to accommodate inhibitors of differing size. The differences in this adaptable loop between the bacterial and human methionine aminopeptidases is a structural feature that can be exploited to design inhibitors of bacterial methionine aminopeptidases as therapeutic agents with minimal inhibition of the corresponding human enzymes.

Project description:In this study, screening efforts identified novel antifolates with potent, targeted activity against whole cell Mycobacterium tuberculosis. Liquid chromatography-mass spectrometry analysis of antifolate-treated cultures revealed unique metabolic disruption, including decreased pools of methionine and S-adenosylmethionine. Transcriptomic analysis highlighted up-regulation genes involved in the biosynthesis and utilization of methionine. Supplementation with amino acids or methionine derivatives was sufficient to rescue cultures from MIC-level antifolate treatment. Instead of the “thymineless death” that characterizes folate pathway inhibition in a wide variety of organisms, these data suggest that M. tuberculosis is vulnerable to a critical disruption of the biosynthesis of methionine-derived compounds.

Project description:In this study, screening efforts identified novel antifolates with potent, targeted activity against whole cell Mycobacterium tuberculosis. Liquid chromatography-mass spectrometry analysis of antifolate-treated cultures revealed unique metabolic disruption, including decreased pools of methionine and S-adenosylmethionine. Transcriptomic analysis highlighted up-regulation genes involved in the biosynthesis and utilization of methionine. Supplementation with amino acids or methionine derivatives was sufficient to rescue cultures from MIC-level antifolate treatment. Instead of the “thymineless death” that characterizes folate pathway inhibition in a wide variety of organisms, these data suggest that M. tuberculosis is vulnerable to a critical disruption of the biosynthesis of methionine-derived compounds. These arrays look at the expression profile triggered by exposure to three different anti-folates (WR99210, dimethyl and diethyl methotrexate) in three biological replicates and in a matched set of untreated samples.