3FN4 : Apo-form of NAD-dependent formate dehydrogenase from bacterium Moraxella sp.C-1 in closed conformation

  • I. G. Shabalin (Contributor)
  • E.V. Filippova (RAS - Engelhardt Institute of Molecular Biology) (Contributor)
  • K. M. Polyakov (Contributor)
  • E. G. Sadykhov (Contributor)
  • T. V. Tikhonova (Contributor)
  • V. I. Tishkov (Contributor)
  • V. O. Popov (Contributor)

Dataset

Description

Experimental Technique/Method:X-RAY DIFFRACTION
Resolution:1.96
Classification:OXIDOREDUCTASE
Release Date:2009-12-01
Deposition Date:2008-12-23
Revision Date:2011-07-13#2017-11-01
Molecular Weight:44255.79
Macromolecule Type:Protein
Residue Count:401
Atom Site Count:3017
DOI:10.2210/pdb3fn4/pdb

Abstract:
NAD(+)-dependent formate dehydrogenase (FDH) catalyzes the oxidation of formate ion to carbon dioxide coupled with the reduction of NAD(+) to NADH. The crystal structures of the apo and holo forms of FDH from the methylotrophic bacterium Moraxella sp. C-1 (MorFDH) are reported at 1.96 and 1.95 A resolution, respectively. MorFDH is similar to the previously studied FDH from the bacterium Pseudomonas sp. 101 in overall structure, cofactor-binding mode and active-site architecture, but differs in that the eight-residue-longer C-terminal fragment is visible in the electron-density maps of MorFDH. MorFDH also differs in the organization of the dimer interface. The holo MorFDH structure supports the earlier hypothesis that the catalytic residue His332 can form a hydrogen bond to both the substrate and the transition state. Apo MorFDH has a closed conformation of the interdomain cleft, which is unique for an apo form of an NAD(+)-dependent dehydrogenase. A comparison of the structures of bacterial FDH in open and closed conformations allows the differentiation of the conformational changes associated with cofactor binding and domain motion and provides insights into the mechanism of the closure of the interdomain cleft in FDH. The C-terminal residues 374-399 and the substrate (formate ion) or inhibitor (azide ion) binding are shown to play an essential role in the transition from the open to the closed conformation.
Date made available2009
PublisherRCSB-PDB

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