Functional role of a conserved aspartic acid residue in the motor of the Na+-driven flagellum from Vibrio cholerae (original) (raw)

A structural basis for the mechanism of aspartate- -semialdehyde dehydrogenase from Vibrio cholerae

Protein Science, 2003

L-Aspartate-␤-semialdehyde dehydrogenase (ASADH) catalyzes the reductive dephosphorylation of ␤-aspartyl phosphate to L-aspartate-␤-semialdehyde in the aspartate biosynthetic pathway of plants and microorganisms. The aspartate pathway produces fully one-quarter of the naturally occurring amino acids, but is not found in humans or other eukaryotic organisms, making ASADH an attractive target for the development of new antibacterial, fungicidal, or herbicidal compounds. We have determined the structure of ASADH from Vibrio cholerae in two states; the apoenzyme and a complex with NADP, and a covalently bound active site inhibitor, S-methyl-L-cysteine sulfoxide. Upon binding the inhibitor undergoes an enzymecatalyzed reductive demethylation leading to a covalently bound cysteine that is observed in the complex structure. The enzyme is a functional homodimer, with extensive intersubunit contacts and a symmetrical 4-amino acid bridge linking the active site residues in adjacent subunits that could serve as a communication channel. The active site is essentially preformed, with minimal differences in active site conformation in the apoenzyme relative to the ternary inhibitor complex. The conformational changes that do occur result primarily from NADP binding, and are localized to the repositioning of two surface loops located on the rim at opposite sides of the NADP cleft.

Kinetic mechanism of asparagine synthetase from Vibrio cholerae

Bioorganic Chemistry, 2004

Asparagine synthetase B (AsnB) catalyzes the formation of asparagine in an ATP-dependent reaction using glutamine or ammonia as a nitrogen source. To obtain a better understanding of the catalytic mechanism of this enzyme, we report the cloning, expression, and kinetic analysis of the glutamine- and ammonia-dependent activities of AsnB from Vibrio cholerae. Initial velocity, product inhibition, and dead-end inhibition studies

The structure of a redundant enzyme: a second isoform of aspartate b-semialdehyde dehydrogenase in Vibrio cholerae

Acta Crystallogr D Biol Cryst, 2008

Aspartate--semialdehyde dehydrogenase (ASADH) is an essential enzyme that is found in bacteria, fungi and plants but not in humans. ASADH produces the first branch-point metabolite in the biosynthetic pathways that lead to the production of lysine, threonine, methionine and isoleucine as well as the cell-wall precursor diaminopimelate. As a consequence, ASADH appears to be an excellent target for the development of novel antibiotics, especially for Gramnegative bacteria that require diaminopimelate for cell-wall biosynthesis. In contrast to the Gram-negative ASADHs, which readily formed well diffracting crystals, the second isoform of aspartate--semialdehyde dehydrogenase from Vibrio cholerae (vcASADH2) was less well behaved in initial crystallization trials. In order to obtain good-quality single crystals of vcASADH2, a buffer-optimization protocol was used in which the initial purification buffer was exchanged into a new condition derived from a pre-crystalline hit. The unliganded structure of vcASADH2 has been determined to 2.2 Å resolution to provide additional insight into the structural and functional evolution of the ASADH enzyme family. The overall fold and domain organization of this new structure is similar to the Gram-negative, Gram-positive and archeal ASADH structures determined previously, despite having less than 50% sequence identity to any of these family members. The substrate-complex structure reveals that the binding of l-aspartate--semialdehyde (ASA) to vcASADH2 is accommodated by structural changes in the amino-acid binding site and in the helical subdomain that is involved in the dimer interface. Structural alignments show that this second isoform from Gram-negative V. cholerae most closely resembles the ASADH from a Gram-positive organism and is likely to bind the coenzyme in a different conformation to that observed in the other V. cholerae isoform.

Na+-driven flagellar motor of Vibrio

Biochimica et Biophysica Acta (BBA) - Bioenergetics, 2001

Bacterial flagellar motors are molecular machines powered by the electrochemical potential gradient of specific ions across the membrane. Bacteria move using rotating helical flagellar filaments. The flagellar motor is located at the base of the filament and is buried in the cytoplasmic membrane. Flagellar motors are classified into two types according to the coupling ion : namely the H-driven motor and the Na-driven motor. Analysis of the flagellar motor at the molecular level is far more advanced in the H-driven motor than in the Na-driven motor. Recently, the genes of the Na-driven motor have been cloned from a marine bacterium of Vibrio sp. and some of the motor proteins have been purified and characterized. In this review, we summarize recent studies of the Na-driven flagellar motor.

The structure of a redundant enzyme: a second isoform of aspartate β-semialdehyde dehydrogenase in Vibrio cholerae

Acta Crystallographica Section D Biological Crystallography, 2008

Kinetic characterization of Vibrio cholerae ApbE: Substrate specificity and regulatory mechanisms

PloS one, 2017

ApbE is a member of a novel family of flavin transferases that incorporates flavin mononucleotide (FMN) to subunits of diverse respiratory complexes, which fulfill important homeostatic functions. In this work a detailed characterization of Vibrio cholerae ApbE physiologic activity, substrate specificity and pH dependency was carried out. The data obtained show novel characteristics of the regulation and function of this family. For instance, our experiments indicate that divalent cations are essential for ApbE function, and that the selectivity depends largely on size and the coordination sphere of the cation. Our data also show that ApbE regulation by pH, ADP and potassium is an important mechanism that enhances the adaptation, survival and colonization of V. cholerae in the small intestine. Moreover, studies of the pH-dependency of the activity show that the reaction is favored under alkaline conditions, with a pKa of 8.4. These studies, together with sequence and structure analy...

Energy transducing redox steps of the Na + -pumping NADH:quinone oxidoreductase from Vibrio cholerae

Proceedings of the National Academy of Sciences, 2010

Na + -NQR is a unique respiratory enzyme that couples the free energy of electron transfer reactions to electrogenic pumping of sodium across the cell membrane. This enzyme is found in many marine and pathogenic bacteria where it plays an analogous role to the H + -pumping complex I. It has generally been assumed that the sodium pump of Na + -NQR operates on the basis of thermodynamic coupling between reduction of a single redox cofactor and the binding of sodium at a nearby site. In this study, we have defined the coupling to sodium translocation of individual steps in the redox reaction of Na + -NQR. Sodium uptake takes place in the reaction step in which an electron moves from the 2Fe-2S center to FMN C , while the translocation of sodium across the membrane dielectric (and probably its release into the external medium) occurs when an electron moves from FMN B to riboflavin. This argues against a single-site coupling model because the redox steps that drive these two parts of the...

Aspartic Acid 397 in Subunit B of the Na+-pumping NADH:Quinone Oxidoreductase from Vibrio cholerae Forms Part of a Sodium-binding Site, Is Involved in Cation Selectivity, and Affects Cation-binding Site Cooperativity

Journal of Biological Chemistry, 2013

Background: Na ϩ-NQR is the main sodium pump in Vibrio cholerae. Results: Mutations at position NqrB-Asp-397 alter cation specificity and interaction between binding sites. Conclusion: NqrB-Asp-397 is part of one Na ϩ-binding site and determines cation specificity and binding site cooperativity. Significance: The results provide new insights into the structure/function of Na ϩ uptake in Na ϩ-NQR. The Na ؉-pumping NADH:quinone complex is found in Vibrio cholerae and other marine and pathogenic bacteria. NADH:ubiquinone oxidoreductase oxidizes NADH and reduces ubiquinone, using the free energy released by this reaction to pump sodium ions across the cell membrane. In a previous report, a conserved aspartic acid residue in the NqrB subunit at position 397, located in the cytosolic face of this protein, was proposed to be involved in the capture of sodium. Here, we studied the role of this residue through the characterization of mutant enzymes in which this aspartic acid was substituted by other residues that change charge and size, such as arginine, serine, lysine, glutamic acid, and cysteine. Our results indicate that NqrB-Asp-397 forms part of one of the at least two sodiumbinding sites and that both size and charge at this position are critical for the function of the enzyme. Moreover, we demonstrate that this residue is involved in cation selectivity, has a critical role in the communication between sodium-binding sites, by promoting cooperativity, and controls the electron transfer step involved in sodium uptake (2Fe-2S 3 FMN C).

Functional role of a conserved aspartic acid residue in the motor of the Na+-driven flagellum from Vibrio cholerae (original) (raw)

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