Your search keyword '"cofactor-binding"' showing total 2 results

1. Structural Basis of the Sulphate Starvation Response in E. coli: Crystal Structure and Mutational Analysis of the Cofactor-binding Domain of the Cbl Transcriptional Regulator

Author

Stec, Emilia, Witkowska-Zimny, Malgorzata, Hryniewicz, Monika M., Neumann, Piotr, Wilkinson, Anthony J., Brzozowski, Andrzej M., Verma, Chandra S., Zaim, Jolanta, Wysocki, Stanislaw, and D. Bujacz, Grzegorz

Subjects

*ESCHERICHIA coli, *ENTEROBACTERIACEAE, *NUCLEIC acids, *CARRIER proteins

Abstract

Abstract: Cbl is a member of the large family of LysR-type transcriptional regulators (LTTRs) common in bacteria and found also in Archaea and algal chloroplasts. The function of Cbl is required in Escherichia coli for expression of sulphate starvation-inducible (ssi) genes, associated with the biosynthesis of cysteine from organic sulphur sources (sulphonates). Here, we report the crystal structure of the cofactor-binding domain of Cbl (c-Cbl) from E. coli. The overall fold of c-Cbl is very similar to the regulatory domain (RD) of another LysR family member, CysB. The RD is composed of two subdomains enclosing a cavity, which is expected to bind effector molecules. We have constructed and analysed several full-length Cbl variants bearing single residue substitutions in the RD that affect cofactor responses. Using in vivo and in vitro transcription assays, we demonstrate that pssuE, a Cbl responsive promoter, is down-regulated not only by the cofactor, adenosine phosphosulphate (APS), but also by thiosulphate, and, that the same RD determinants are important for the response to both cofactors. We also demonstrate the effects of selected site-directed mutations on Cbl oligomerization and discuss these in the context of the structure. Based on the crystal structure and molecular modelling, we propose a model for the interaction of Cbl with adenosine phosphosulphate. [Copyright &y& Elsevier]

Published

2006

2. Crystal Structure and Biochemical Properties of the d-Arabinose Dehydrogenase from Sulfolobus solfataricus

Author

John van der Oost, Andrew P. Turnbull, Jasper Akerboom, Stan J. J. Brouns, and Hanneke L.D.M. Willemen

Subjects

Molecular Sequence Data, ved/biology.organism_classification_rank.species, Carbohydrates, Molecular Conformation, alternative pathway, Dehydrogenase, Reductase, Crystallography, X-Ray, Microbiology, Cofactor, cofactor-binding, glucose-dehydrogenase, evolutionary insight, Microbiologie, Structural Biology, Glucose dehydrogenase, Oxidoreductase, Catalytic Domain, Amino Acid Sequence, erythroascorbic acid, Protein Structure, Quaternary, Molecular Biology, VLAG, chemistry.chemical_classification, Cofactor binding, Binding Sites, liver alcohol-dehydrogenase, pseudomonas-aeruginosa, Sequence Homology, Amino Acid, biology, ved/biology, Sulfolobus solfataricus, Temperature, Hydrogen-Ion Concentration, thermoacidophilic archaeon, substrate-specificity, Biochemistry, chemistry, biology.protein, saccharomyces-cerevisiae, Crystallization, Sugar Alcohol Dehydrogenases, Protein Binding

Abstract

Sulfolobus solfataricus metabolizes the five-carbon sugar d-arabinose to 2-oxoglutarate by an inducible pathway consisting of dehydrogenases and dehydratases. Here we report the crystal structure and biochemical properties of the first enzyme of this pathway: the d-arabinose dehydrogenase. The AraDH structure was solved to a resolution of 1.80 A by single-wavelength anomalous diffraction and phased using the two endogenous zinc ions per subunit. The structure revealed a catalytic and cofactor binding domain, typically present in mesophilic and thermophilic alcohol dehydrogenases. Cofactor modeling showed the presence of a phosphate binding pocket sequence motif (SRS-X2-H), which is likely to be responsible for the enzyme's preference for NADP+. The homo-tetrameric enzyme is specific for d-arabinose, l-fucose, l-galactose and d-ribose, which could be explained by the hydrogen bonding patterns of the C3 and C4 hydroxyl groups observed in substrate docking simulations. The enzyme optimally converts sugars at pH 8.2 and 91 degrees C, and displays a half-life of 42 and 26 min at 85 and 90 degrees C, respectively, indicating that the enzyme is thermostable at physiological operating temperatures of 80 degrees C. The structure represents the first crystal structure of an NADP+-dependent member of the medium-chain dehydrogenase/reductase (MDR) superfamily from Archaea.

Published

2007