Metal-induced change in catalytic loop positioning in Helicobacter pylori arginase alters catalytic function.

Arginase is a bimetallic enzyme that utilizes mainly Mn2+ or Co2+ for catalytic function. In human homolog, the substitution of Mn2+ with Co2+ significantly reduces the Km value without affecting the kcat. However, in the Helicobacter pylori counterpart (important for pathogenesis), the kcat increases nearly 4-fold with Co2+ ions both in the recombinant holoenzyme and arginase isolated from H. pylori grown with Co2+ or Mn2+. This suggests that the active site of arginase in the two homologs is modulated differently by these two metal ions. To investigate the underlying mechanism for metal-induced difference in catalytic activity in the H. pylori enzyme, we used biochemical, biophysical and microsecond molecular dynamics simulations studies. The study shows that the difference in binding affinity of Co2+ and Mn2+ ions with the protein is linked to a different positioning of a loop (-122HTAYDSDSKHIHG134-) that contains a conserved catalytic His133. Consequently, the proximity of His133 and conserved Glu281 is varied. We found that the Glu281-His133 interaction is crucial for catalytic function and was previously unexplored in other homologs. We suggest that the proximity difference between these two residues in the Co2+- and Mn2+-proteins alters the proportion of protonated His133 via variation in its pKa. This affects the efficiency of proton transfer - an essential step of l-arginine hydrolysis reaction catalyzed by arginase and thus activity. Unlike in human arginase, the flexibility of the above segment observed in H. pylori homolog suggests that this region in the H. pylori enzyme may be explored to design its specific inhibitors.

Biochemical and biophysical studies of Helicobacter pylori arginine decarboxylase, an enzyme important for acid adaptation in host.

Despite importance of arginine decarboxylase (ADC: EC 4.1.1.19) of Helicobacter pylori (H. pylori) 26695 pathogenic strain for acid adaptation in host, the enzyme has not yet been studied at a molecular level. Using combined approaches that include kinetic assays, site-directed mutagenesis, circular dichroism, heat-induced denaturation, analytical gel-filtration, and homology modeling, we report here a detailed investigation of H. pylori ADC. The pyridoxal 5'-phosphate (PLP)-dependent enzyme exhibits higher catalytic activity in the presence of Mg2+ ions at pH ∼8.5. Unlike other bacterial ADCs, this homolog exists as a hexamer. The higher thermal stability (Tm ∼65.8 ± 0.2 °C) of the enzyme observed from the heat-induced circular dichroism measurements indicates its secondary structural stabilization in the presence of PLP. The kinetic parameters Km and kcat of the enzyme are determined to be 3.4 ± 0.2 mM and 55.2 ± 1.0 min-1 , respectively. We elucidate that Cys487, a conserved residue located at the active-site, is involved in the catalysis, whose pKa value was estimated to be ∼7.2. The homology model of the protein show conserved α/ß TIM barrel and ß-sandwich domains, which are characteristic features of fold III decarboxylases. A lower sequence identity (∼21%) of this enzyme compared with its human counterpart has enabled us to screen putative inhibitors of H. pylori ADC. We found that α-difluoromethylarginine inhibits the activity of the H. pylori enzyme competitively with a Ki value ∼118 µM and thus it can serve as a basis to design inhibitors with higher efficacy against this ADC. © 2018 IUBMB Life, 70(7):658-669, 2018.

Structural and functional insights into the regulation of Helicobacter pylori arginase activity by an evolutionary nonconserved motif.

Urea producing bimetallic arginases are essential for the synthesis of polyamine, DNA, and RNA. Despite conservation of the signature motifs in all arginases, a nonconserved ¹5³ESEEKAWQKLCSL¹65 motif is found in the Helicobacter pylori enzyme, whose role is yet unknown. Using site-directed mutagenesis, kinetic assays, metal analyses, circular dichroism, heat-induced denaturation, molecular dynamics simulations and truncation studies, we report here the significance of this motif in catalytic function, metal retention, structural integrity, and stability of the protein. The enzyme did not exhibit detectable activity upon deletion of the motif as well as on individual mutation of Glu155 and Trp159 while Cys163Ala displayed significant decrease in the activity. Trp159Ala and Glu155Ala show severe loss of thermostability (14-17°) by a decrease in the α-helical structure. The role of Trp159 in stabilization of the structure with the surrounding aromatic residues is confirmed when Trp159Phe restored the structure and stability substantially compared to Trp159Ala. The simulation studies support the above results and show that the motif, which was previously solvent exposed, displays a loop-cum-small helix structure (Lys161-Cys163) and is located near the active-site through a novel Trp159-Asp126 interaction. This is consistent with the mutational analyses, where Trp159 and Asp126 are individually critical for retaining a bimetallic center and thereby for function. Furthermore, Cys163 of the helix is primarily important for dimerization, which is crucial for stimulation of the activity. Thus, these findings not only provide insights into the role of this motif but also offer a possibility to engineer it in human arginases for therapeutics against a number of carcinomas.

Sample complexity reduction aids efficient detection of low-abundant proteins from human amniotic fluid.

Working with biological fluids poses a challenge of visualizing proteins present in lower concentrations. This study describes a batch-mode chromatographic method for the fractionation of human amniotic fluid (AF). This method is easy to use with minimal sample quantity, resin volume and sample processing time. For albumin depletion, two methods were evaluated. The results demonstrated that specific depletion of albumin, using affinity-ligand-based resin, is more efficient than the conventional dye-based method. The albumin-depleted human AF was fractionated by strong anion-exchange resin in spin devices, for sample, complexity reduction and enrichment of low-abundant proteins. Analysis of four eluate fractions generated after this step shows enrichment of few low-abundant proteins. Two novel low-abundant proteins, Rab GDP dissociation inhibitor beta and peptide methionine sulfoxide reductase, were identified from human AF. Alpha-1-B glycoprotein was successfully identified by this strategy, whereas the published literature reports that it was not identified by strong anion-exchange FPLC followed by SDS-PAGE. Therefore, the current method has distinct advantages over the conventional column-based chromatography. This study also reports altered expression of some proteins in Rh-isoimmunized AF samples in comparison with normal AF.