The 1.3 A crystal structure of the flavoprotein YqjM reveals a novel class of Old Yellow Enzymes.

Here we report the crystal structure of YqjM, a homolog of Old Yellow Enzyme (OYE) that is involved in the oxidative stress response of Bacillus subtilis. In addition to the oxidized and reduced enzyme form, the structures of complexes with p-hydroxybenzaldehyde and p-nitrophenol, respectively, were solved. As for other OYE family members, YqjM folds into a (alpha/beta)8-barrel and has one molecule of flavin mononucleotide bound non-covalently at the COOH termini of the beta-sheet. Most of the interactions that control the electronic properties of the flavin mononucleotide cofactor are conserved within the OYE family. However, in contrast to all members of the OYE family characterized to date, YqjM exhibits several unique structural features. For example, the enzyme exists as a homotetramer that is assembled as a dimer of catalytically dependent dimers. Moreover, the protein displays a shared active site architecture where an arginine finger (Arg336) at the COOH terminus of one monomer extends into the active site of the adjacent monomer and is directly involved in substrate recognition. Another remarkable difference in the binding of the ligand in YqjM is represented by the contribution of the NH2-terminal Tyr28 instead of a COOH-terminal tyrosine in OYE and its homologs. The structural information led to a specific data base search from which a new class of OYE oxidoreductases was identified that exhibits a strict conservation of active site residues, which are critical for this subfamily, most notably Cys26, Tyr28, Lys109, and Arg336. Therefore, YqjM is the first representative of a new bacterial subfamily of OYE homologs.

Structural and functional impairment of an Old Yellow Enzyme homologue upon affinity tag incorporation.

Recently, it has been reported that the previously uncharacterized YqjM protein from Bacillus subtilis is a true homologue of the physiologically enigmatic yeast Old Yellow Enzyme (OYE). In this study, it was also demonstrated that YqjM is involved in the oxidative stress response of B. subtilis, thus highlighting a novel direction to pursue the role of the OYE family of proteins in the cell. As part of an attempt to pin down the exact physiological role of these enzymes, both a N-terminal glutathione S-transferase and a C-terminal histidine-tagged form of the protein were created to enable "pull-down" assays and identify interacting partners which could aid in the functional definition. However, here we report on a comparison of the biochemical properties of the tagged forms with the native/untagged YqjM, revealing critical differences in the catalytic activities and quaternary structure of the protein forms. UV-visible spectrophotometric features as well as steady state and individual half-reaction kinetic parameters show that the affinity tagged forms are severely impaired both in ligand binding and catalysis. Gel filtration and dynamic light scattering studies show that incorporation of a tag also has major effects on the quaternary structure of the protein by disrupting the native tetrameric conformation which may help to explain the observed differences. The study thus highlights important considerations for expression construct design when isolating members of the OYE family of proteins.

Crystal structure of the DegS stress sensor: How a PDZ domain recognizes misfolded protein and activates a protease.

Gram-negative bacteria respond to misfolded proteins in the cell envelope with the sigmaE-driven expression of periplasmic proteases/chaperones. Activation of sigmaE is controlled by a proteolytic cascade that is initiated by the DegS protease. DegS senses misfolded protein in the periplasm, undergoes autoactivation, and cleaves the antisigma factor RseA. Here, we present the crystal structures of three distinct states of DegS from E. coli. DegS alone exists in a catalytically inactive form. Binding of stress-signaling peptides to its PDZ domain induces a series of conformational changes that activates protease function. Backsoaking of crystals containing the DegS-activator complex revealed the presence of an active/inactive hybrid structure and demonstrated the reversibility of activation. Taken together, the structural data illustrate in molecular detail how DegS acts as a periplasmic stress sensor. Our results suggest a novel regulatory role for PDZ domains and unveil a novel mechanism of reversible protease activation.

Mechanism of chorismate synthase. Role of the two invariant histidine residues in the active site.

Chorismate synthase catalyzes the last step in the common shikimate pathway leading to aromatic compounds such as the aromatic amino acids. The reaction consists of the 1,4-anti-elimination of the 3-phosphate group and the C-(6proR) hydrogen from 5-enolpyruvylshikimate 3-phosphate to yield chorismate. Although this reaction does not involve a net redox change, the enzyme has an absolute requirement for reduced flavin mononucleotide, which is not consumed during the reaction. Two invariant histidine residues are found in the active site of the enzyme: His(17) and His(106). Using site-directed mutagenesis, both histidines were replaced by alanine, reducing the activity 10- and 20-fold in the H106A and H17A mutant protein, respectively. Based on the characterization of the two single mutant proteins, it is proposed that His(106) serves to protonate the monoanionic reduced FMN, whereas His(17) protonates the leaving phosphate group of the substrate. An enzymatic reaction mechanism in keeping with the experimental results is presented.