Structures of glycosylated mammalian glutaminyl cyclases reveal conformational variability near the active center.

Formation of N-terminal pyroglutamate (pGlu or pE) from glutaminyl or glutamyl precursors is catalyzed by glutaminyl cyclases (QC). As the formation of pGlu-amyloid has been linked with Alzheimer's disease, inhibitors of QCs are currently the subject of intense development. Here, we report three crystal structures of N-glycosylated mammalian QC from humans (hQC) and mice (mQC). Whereas the overall structures of the enzymes are similar to those reported previously, two surface loops in the neighborhood of the active center exhibit conformational variability. Furthermore, two conserved cysteine residues form a disulfide bond at the base of the active center that was not present in previous reports of hQC structure. Site-directed mutagenesis suggests a structure-stabilizing role of the disulfide bond. At the entrance to the active center, the conserved tryptophan residue, W(207), which displayed multiple orientations in previous structure, shows a single conformation in both glycosylated human and murine QCs. Although mutagenesis of W(207) into leucine or glutamine altered substrate conversion significantly, the binding constants of inhibitors such as the highly potent PQ50 (PBD150) were minimally affected. The crystal structure of PQ50 bound to the active center of murine QC reveals principal binding determinants provided by the catalytic zinc ion and a hydrophobic funnel. This study presents a first comparison of two mammalian QCs containing typical, conserved post-translational modifications.

Crystal structure of NADP(H)-dependent 1,5-anhydro-D-fructose reductase from Sinorhizobium morelense at 2.2 A resolution: construction of a NADH-accepting mutant and its application in rare sugar synthesis.

Recombinant 1,5-anhydro-d-fructose reductase (AFR) from Sinorhizobium morelense S-30.7.5 was crystallized in complex with the cofactor NADP(H) and its structure determined to 2.2 A resolution using selenomethionine SAD (refined R(work) and R(free) factors of 18.9 and 25.0%, respectively). As predicted from the sequence and shown by the structure, AFR can be assigned to the GFO/IDH/MocA protein family. AFR consists of two domains. The N-terminal domain displays a Rossmann fold and contains the cofactor binding site. The intact crystals contain the oxidized cofactor NADP(+), whose attachment to the cofactor binding site is similar to that of NADP(+) in glucose-fructose oxidoreductase (GFOR) from Zymomonas mobilis. Due to variations in length and sequence within loop regions L3 and L5, respectively, the adenine moiety of NADP(+) adopts a different orientation in AFR caused by residue Arg38 forming hydrogen bonds with the 2'-phosphate moiety of NADP(+) and cation-pi stacking interactions with the adenine ring. Amino acid replacements in AFR (S10G, A13G, and S33D) showed that Ala13 is crucial for the discrimination between NADPH and NADH and yielded the A13G variant with dual cosubstrate specificity. The C-terminal domain contains the putative substrate binding site that was occupied by an acetate ion. As determined by analogy to GFOR and by site-directed mutagenesis of K94G, D176A, and H180A, residues Lys94, Asp176, and His180 are most likely involved in substrate binding and catalysis, as substitution of any of these residues resulted in a significant decrease in k(cat) for 1,5-AF. In this context, His180 might serve as a general acid-base catalyst by polarizing the carbonyl function of 1,5-AF to enable the transfer of the hydride from NADPH to the substrate. Here we present the first structure of an AFR enzyme catalyzing the stereoselective reduction of 1,5-AF to 1,5-anhydro-d-mannitol, the final step of a modified anhydrofructose pathway in S. morelense S-30.7.5. We also emphasize the importance of the A13G variant in biocatalysis for the synthesis of 1,5-AM and related derivatives.

Structure of the cytochrome complex SoxXA of Paracoccus pantotrophus, a heme enzyme initiating chemotrophic sulfur oxidation.

The sulfur-oxidizing enzyme system (Sox) of the chemotroph Paracoccus pantotrophus is composed of several proteins, which together oxidize hydrogen sulfide, sulfur, thiosulfate or sulfite and transfers the gained electrons to the respiratory chain. The hetero-dimeric cytochrome c complex SoxXA functions as heme enzyme and links covalently the sulfur substrate to the thiol of the cysteine-138 residue of the SoxY protein of the SoxYZ complex. Here, we report the crystal structure of the c-type cytochrome complex SoxXA. The structure could be solved by molecular replacement and refined to a resolution of 1.9A identifying the axial heme-iron coordination involving an unusual Cys-251 thiolate of heme2. Distance measurements between the three heme groups provide deeper insight into the electron transport inside SoxXA and merge in a better understanding of the initial step of the aerobic sulfur oxidation process in chemotrophic bacteria.