Mutations of key substrate binding residues of leishmanial peptidase T alter its functional and structural dynamics

Drug targeting of aminopeptidases: importance of deploying a right metal cofactor

Aminopeptidases are metal co-factor-dependent hydrolases releasing N-terminal amino acid residues from peptides. Many of these enzymes, particularly the M24 methionine aminopeptidases (MetAPs), are considered valid drug targets in the fight against many parasitic and non-parasitic diseases. Targeting MetAPs has shown promising results against the malarial parasite, Plasmodium, which is regarded as potential anti-cancer targets. While targeting these essential enzymes represents a potentially promising approach, many challenges are often ignored by scientists when designing drugs or inhibitory scaffolds against the MetAPs. One such aspect is the metal co-factor, with inadequate attention paid to its role in catalysis, folding and remodeling of the catalytic site, and its role in inhibitor binding or potency. Knowing that a metal co-factor is essential for aminopeptidase enzyme activity and active site remodeling, it is intriguing that most computational biologists often ignore the metal ion while screening millions of potential inhibitors to find hits. Ironically, a similar trend is followed by biologists who avoid metal promiscuity of these enzymes while screening inhibitor libraries in vitro which may lead to false positives. This review highlights the importance of considering a physiologically relevant metal co-factor during the drug discovery processes targeting metal-dependent aminopeptidases.

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Exploration of seryl tRNA synthetase to identify potent inhibitors against leishmanial parasites

Aminoacyl-tRNA synthetases are crucial enzymes for cellular protein metabolism and have been considered as an attractive target for development of new antimicrobials. In the current study, seryl tRNA synthetase of Leishmania donovani (LdSerRS) and its mutants were purified and characterized through biochemical and structural methods. Purified LdSerRS was found to be enzymatically active and exhibited more alpha helices in secondary structure. The enzymatic activity of purified protein was observed as highest near physiological temperature and pH. Mutation in ATP binding residues (R295 and E297) demonstrated reduction in the affinity for cofactor with no significant deviation in secondary structure. In vitro inhibition studies with ureidosulfocoumarin derivatives helped to identify Comp 5l as a specific inhibitor for leishmanial SerRS that showed lesser potency towards purified HsSerRS. The identified compound presented competitive mode of inhibition for LdSerRS and also revealed druglikeness along with very low toxicity for human macrophages. Structural analysis of protein and ligand complex depicted the binding of Comp 5l into the cofactor binding site of LdSerRS with high affinity succeeded by validation employing molecular dynamics simulations. Altogether, our study presents a promising scaffold to explore small molecules to target the enzymatic activity of leishmanial SerRS to develop the specific therapeutics.

Biophysical and Structural Characterization of Ribulose-5-phosphate Epimerase from Leishmania donovani

Pentose phosphate pathway (PPP) plays a crucial role in the maintenance of NADPH/NADP⁺ homeostasis and provides protection against oxidative stress through detoxification of the reactive oxygen species. Ribulose-5-phosphate epimerase (RPE) participates in catalysis of the interconversion of ribulose-5-phosphate (Ru5P) to xylulose-5-phosphate (Xu5P) during PPP, however the structural attributes of this enzyme are still underexplored in many human pathogens including leishmanial parasites. The present study focuses upon cloning, purification and characterization of RPE of Leishmania donovani (LdRPE) using various biophysical and structural approaches. Sequence analysis has shown the presence of trypanosomatid-specific insertions at the N-terminus that are absent in humans and other eukaryotes. Gel filtration chromatography indicated recombinant LdRPE to exist as a dimer in the solution. Circular dichroism studies revealed a higher alpha helical content at physiological pH and temperature that comparatively varies with changing these parameters. Additionally, intrinsic fluorescence and quenching studies of LdRPE have depicted that tryptophan residues are mainly buried in the hydrophobic regions, and the recombinant enzyme is moderately tolerant to urea. Moreover, homology modeling was employed to generate the three-dimensional structure of LdRPE followed by molecular docking with the substrate, product, and substrate analogues. The modeled structure of LdRPE unravelled the presence of conserved active site residues as well as a single binding pocket for the substrate and product, while an in silico study suggested binding of substrate analogues into a similar pocket with more affinity than the substrate. Additionally, molecular dynamics simulation analysis has deciphered complexes of LdRPE with most of the ligands exhibiting more stability than its apo form and lesser fluctuations in active site residues in the presence of ligands. Altogether, our study presents structural insights into leishmanial RPE that could provide the basis for its implication to develop potent antileishmanials.

Structural and Functional Basis of Potent Inhibition of Leishmanial Leucine Aminopeptidase by Peptidomimetics

A leucine aminopeptidase primarily hydrolyzes amino acid leucine from the N-terminus end of proteins and is involved in free amino acid regulation, which makes it a potential therapeutic target against neglected tropical diseases including leishmaniasis. We here report the purification and characterization of the leucine aminopeptidase from Leishmania donovani (LdLAP). Using a set of biophysical and biochemical methods, we demonstrate that this enzyme was properly folded after expression in a bacterial system and catalytically active when supplemented with divalent metal cofactors with synthetic fluorogenic peptides. Subsequently, enzymatic inhibition assay denoted that LdLAP activity was inhibited by peptidomimetics, particularly actinonin, which caused potent inhibition and exhibited stronger binding association with the LdLAP. Stronger association of actinonin with the LdLAP was due to a stable complex formation mostly mediated by hydrogen bonding with catalytic and substrate-binding residues in the C-terminal catalytic domain. With molecular dynamics simulation studies, we demonstrate that peptidomimetics retain their topological space in the LdLAP catalytic pocket and form a stable complex. These results expand the current knowledge of aminopeptidase biochemistry and highlight that specific actinonin or peptidomimetic-based inhibitors may emerge as leads to combat leishmaniasis.