Amit Sonkar

Distant Phe345 mutation compromises the stability and activity of Mycobacterium tuberculosis isocitrate lyase by modulating its structural flexibility

Isocitrate lyase (ICL), a potential anti-tubercular drug target, catalyzes the first step of the glyoxylate shunt. In the present investigation, we studied the conformational flexibility of MtbICL to better understand its stability and catalytic activity. Our biochemical results showed that a point mutation at Phe345, which is topologically distant (>10 Å) to the active site signature sequence (189KKCGH193), completely abolishes the activity of the enzyme. In depth computational analyses were carried out for understanding the structural alterations using molecular dynamics, time-dependent secondary structure and principal component analysis. The results showed that the mutated residue increased the structural flexibility and induced conformational changes near the active site (residues 170–210) and in the C-terminal lid region (residues 411–428). Both these regions are involved in the catalytic activity of MtbICL. Upon mutation, the residual mobility of the enzyme increased, resulting in a decrease in the stability, which was confirmed by the lower free energy of stabilization in the mutant enzyme suggesting the destabilization in the structure. Our results have both biological importance and chemical novelty. It reveals internal dynamics of the enzyme structure and also suggests that regions other than the active site should be exploited for targeting MtbICL inhibition and development of novel anti-tuberculosis compounds.

Structure-Based Screening And Molecular Dynamics Simulations Offer Novel Natural Compounds As Potential Inhibitors Of Mycobacterium Tuberculosis Isocitrate Lyase

Mycobacterium tuberculosis is the etiological agent of tuberculosis in humans and is responsible for more than two million deaths annually. M. tuberculosis isocitrate lyase (MtbICL) catalyzes the first step in the glyoxylate cycle, plays a pivotal role in the persistence of M. tuberculosis, which acts as a potential target for an anti-tubercular drug. To identify the potential anti-tuberculosis compound, we conducted a structure-based virtual screening of natural compounds from the ZINC database (n = 1,67,748) against the MtbICL structure. The ligands were docked against MtbICL in three sequential docking modes that resulted in 340 ligands having better docking score. These compounds were evaluated for Lipinski and ADMET prediction, and 27 compounds were found to fit well with re-docking studies. After refinement by molecular docking and drug-likeness analyses, three potential inhibitors (ZINC1306071, ZINC2111081, and ZINC2134917) were identified. These three ligands and the reference compounds were further subjected to molecular dynamics simulation and binding energy analyses to compare the dynamic structure of protein after ligand binding and the stability of the MtbICL and bound complexes. The binding free energy analyses were calculated to validate and capture the intermolecular interactions. The results suggested that the three compounds had a negative binding energy with −96.462, −143.549, and −122.526 kJ mol−1 for compounds with IDs ZINC1306071, ZINC2111081, and ZINC2134917, respectively. These lead compounds displayed substantial pharmacological and structural properties to be drug candidates. We concluded that ZINC2111081 has a great potential to inhibit MtbICL and would add to the drug discovery process against tuberculosis.

A combined biochemical and computational studies of the rho-class glutathione s-transferase sll1545 of Synechocystis PCC 6803.

Peroxides are one of the most important radicals that cause oxidative stress. Certain Glutathione S-transferases (GSTs) have been reported to show peroxidase activity. We report a novel peroxidase activity of Synechocystis GST- sll1545. The recombinant protein was purified to homogeneity and characterized. Low Km (0.109μM) and high Vmax (0.663μmolmin-1) values suggest a high preference of sll1545 for cumenehydroperoxide. Disc inhibition assay confirmed the ability of the enzyme to protect cells against peroxide-induced damage. sll1545 has very low sequence and structural similarity with theta and alpha class GSTs that exhibit glutathione-dependent peroxidase activity. Recent data from our laboratory shows that sll1545 is also strongly active against dichloroacetate (DCA), which is a characteristic of zeta class GST. Interestingly, sll1545 shows less than 20% sequence identity with zeta class GST. Molecular dynamic simulation results show that sll1545 was much more structurally different from alpha/theta classes. Our results suggest that sll1545 shows structural variation from zeta, theta/alpha classes of GSTs but have related enzymatic activity. Phylogenetic analysis reveal that sll1545 is evolutionally very distinct from the known GSTs. Overall, the data suggest that Synechocystis sll1545 does not belong to any known GST class and represent a novel GST class, which we have named rho.

Alterations in conformational topology and interaction dynamics caused by L418A mutation leads to activity loss of Mycobacterium tuberculosis isocitrate lyase

Mycobacterium tuberculosis isocitrate lyase (MtbICL) is a key enzyme of the glyoxylate cycle that catalyzes the cleavage of isocitrate to succinate and glyoxylate and is a potential antituberculosis drug target. The aim of this research was to explore the structural alterations induced by L418A point mutation that caused the loss of enzyme activity. In-depth structural analyses were carried out for understanding the influence of L418A mutation using techniques, viz. molecular dynamics, principal component analysis, time-dependent secondary structure, residue interaction network and molecular docking. Since L418A mutation site is structurally far from the active site, it cannot influence the binding of the substrate directly. Our results showed that collective motions, residual mobility, and flexibility of the enzyme increased upon mutation. The mutated residue changed the global conformational dynamics of the system along with the residue-residue interaction network, leading to a loss of the enzyme activity. The docking results suggest that L418A mutation influenced the binding interactions of the substrate with several residues in the active site of MtbICL. This study provides information on the structural dynamics of MtbICL and highlights the importance of residue level interactions in the protein. Thus, our results may provide significant guidance to the scientific community engaged in designing potent inhibitors targeting MtbICL.

Identification of potential inhibitors of Fasciola gigantica thioredoxin1: computational screening, molecular dynamics simulation, and binding free energy studies

Fasciola gigantica is the causative organism of fascioliasis and is responsible for major economic losses in livestock production globally. F. gigantica thioredoxin1 (FgTrx1) is an important redox-active enzyme involved in maintaining the redox homeostasis in the cell. To identify a potential anti-fasciolid compound, we conducted a structure-based virtual screening of natural compounds from the ZINC database (n = 1,67,740) against the FgTrx1 structure. The ligands were docked against FgTrx1 and 309 ligands were found to have better docking score. These compounds were evaluated for Lipinski and ADMET prediction, and 30 compounds were found to fit well for re-docking studies. After refinement by molecular docking and drug-likeness analysis, three potential inhibitors (ZINC15970091, ZINC9312362, and ZINC9312661) were identified. These three ligands were further subjected to molecular dynamics simulation (MDS) to compare the dynamics and stability of the protein structure after binding of the ligands. The binding free energy analyses were calculated to determine the intermolecular interactions. The results suggested that the two compounds had a binding free energy of –82.237, and –109.52 kJ.mol−1 for compounds with IDs ZINC9312362 and ZINC9312661, respectively. These predicted compounds displayed considerable pharmacological and structural properties to be drug candidates. We concluded that these two compounds could be potential drug candidates to fight against F. gigantica parasites.

UDP-N-Acetylglucosamine enolpyruvyl transferase (MurA) of Acinetobacter baumannii (AbMurA): Structural and functional properties.

Peptidoglycan (PG) is the key component of the bacterial cell wall. The enzyme UDP-N-Acetylglucosamine Enolpyruvyl Transferase (MurA) catalyzes the transfer of enolpyruvate from phosphoenolpyruvate (PEP) to uridinediphospho-N-acetylglucosamine (UNAG), which is the first committed step of PG biosynthesis. Here, we present the biochemical and structural features of the MurA enzyme of the opportunistic pathogen Acinetobacter baumannii (AbMurA). The recombinant AbMurA exists as a monomer in solution and shows optimal activity at pH 7.5 and 37°C. The Km for UDP-N-acetylglucosamine was 1.062±0.09mM and for PEP was 1.806±0.23mM. The relative enzymatic activity was inhibited ∼3 fold in the presence of 50mM fosfomycin (FFQ). Superimposition of the AbMurA model with E. coli demonstrated key structural similarity in the FFQ-binding site. AbMurA also has a surface loop that contains the active site Cys116 that interact with FFQ. Sequence analysis indicates the presence of the five conserved amino acids, i.e., K22, C116, D306, D370 and L371, required for the functional activity like other MurA enzymes from different bacteria. MurA enzymes are indispensable for cell integrity and their lack of counterparts in eukaryotes suggests them to be a promising drug target.

Identification of novel natural inhibitors of Opisthorchis felineus cytochrome P450 using structure-based screening and molecular dynamic simulation

Opisthorchis felineus is the etiological agent of opisthorchiasis in humans. O. felineus cytochrome P450 (OfCYP450) is an important enzyme in the parasite xenobiotic metabolism. To identify the potential anti-opisthorchid compound, we conducted a structure-based virtual screening of natural compounds from the ZINC database (n = 1,65,869) against the OfCYP450. The ligands were screened against OfCYP450 in four sequential docking modes that resulted in 361 ligands having better docking score. These compounds were evaluated for Lipinski and ADMET prediction, and 10 compounds were found to fit well with re-docking studies. After refinement by docking and drug-likeness analyses, four potential inhibitors (ZINC2358298, ZINC8790946, ZINC70707116, and ZINC85878789) were identified. These ligands with reference compounds (itraconazole and fluconazole) were further subjected to molecular dynamics simulation (MDS) and binding energy analyses to compare the dynamic structure of protein after ligand binding and the stability of the OfCYP450 and bound complexes. The binding energy analyses were also calculated. The results suggested that the compounds had a negative binding energy with −259.41, −110.09, −188.25, −163.30, −202.10, and −158.79 kJ mol−1 for itraconazole, fluconazole, and compounds with IDs ZINC2358298, ZINC8790946, ZINC70707116, and ZINC85878789, respectively. These lead compounds displayed significant pharmacological and structural properties to be drug candidates. On the basis of MDS results and binding energy analyses, we concluded that ZINC8790946, ZINC70707116, and ZINC85878789 have excellent potential to inhibit OfCYP450.

Salt-regulated reversible fibrillation of Mycobacterium tuberculosis isocitrate lyase: Concurrent restoration of structure and activity

Protein fibrillation is associated with a number of neurodegenerative diseases. Nevertheless, several proteins not related to disease can also form fibrils in vitro under specific conditions. In the present study, we demonstrate the reversible fibrillation of a globular protein that is modulated by salt under physiological pH. Mycobacterium tuberculosis Isocitrate lyase (MtbICL) is a crucial enzyme involved in the glyoxylate shunt and a potential drug target against M. tuberculosis infection. Under physiological pH, the enzyme self-assembles into a fibrillar structure in the absence of salt in vitro. The mature fibrillar structure of MtbICL is dynamic and restores its tetrameric structure as well as activity with the addition of salt. The kinetics of fibril formation was investigated spectroscopically using 8-Anilinonaphthalene-1-sulfonic acid (ANS). Further, Transmission electron microscopy (TEM) and Atomic force microscopy (AFM) imaging also confirmed the formation of elongated fibrils in the absence of salt. The results indicate the balance between stabilizing forces and the localized electrostatic repulsions destabilizing the tetrameric MtbICL is adjusted via ion shielding. Our result is in congruence of the hypothesis that amyloid formation is an intrinsic property of most, if not all natural proteins under an appropriate set of conditions.

Draft genome of the liver fluke Fasciola gigantica

Fascioliasis is a neglected food-borne disease caused by liver flukes (genus Fasciola) and affects more than 200 million people worldwide. Despite technological advances, little is known about the molecular biology and biochemistry of the fluke. We present the draft genome of Fasciola gigantica for the first time. The assembled draft genome has a size of ~1.04 Gb with an N50 of 129 kb. A total of 20,858 genes were predicted. The de novo repeats identified in the draft genome were 46.85%. In pathway analysis, all the genes of glycolysis, Kreb’s cycle and fatty acid metabolism were found to be present, but the key genes for fatty acid production in fatty acid biosynthesis were missing. This indicates that the fatty acid required for the survival of the fluke may be acquired from the host bile. The genomic information will provide a comprehensive resource to facilitate the development of novel interventions for fascioliasis control.

Fission yeast Ctf1, a cleavage and polyadenylation factor subunit is required for the maintenance of genomic integrity

Accurate segregation of chromosome during mitosis requires the coordinated action of several cell cycle checkpoints that monitor replication of the genome and the attachment of sister chromatids to the mitotic spindle apparatus. Here we have characterized the fission yeast Ctf1, an ortholog of S. cerevisiae Rna15 in the maintenance of genomic integrity. The ctf1 is nonessential for the cell survival and its deletion strain exhibit cold sensitivity. The ctf1 deleted cells exhibit genetic interaction with spindle checkpoint protein Mad2 and Bub1. The deletion of ctf1 gene affects the chromosomal attachment to the mitotic spindle leading to the accumulation of Bub1-GFP foci. Ctf1 localizes to the nucleus and physically interacts with Rna14, a cleavage and polyadenylation factor.