Distribution and properties of the genes encoding the biosynthesis of the bacterial cofactor, pyrroloquinoline quinone.

Pyrroloquinoline quinone (PQQ) is a small, redox active molecule that serves as a cofactor for several bacterial dehydrogenases, introducing pathways for carbon utilization that confer a growth advantage. Early studies had implicated a ribosomally translated peptide as the substrate for PQQ production. This study presents a sequence- and structure-based analysis of the components of the pqq operon. We find the necessary components for PQQ production are present in 126 prokaryotes, most of which are Gram-negative and a number of which are pathogens. A total of five gene products, PqqA, PqqB, PqqC, PqqD, and PqqE, are identified as being obligatory for PQQ production. Three of the gene products in the pqq operon, PqqB, PqqC, and PqqE, are members of large protein superfamilies. By combining evolutionary conservation patterns with information from three-dimensional structures, we are able to differentiate the gene products involved in PQQ biosynthesis from those with divergent functions. The observed persistence of a conserved gene order within analyzed operons strongly suggests a role for protein-protein interactions in the course of cofactor biosynthesis. These studies propose previously unidentified roles for several of the gene products, as well as identifying possible new targets for antibiotic design and application.

Characterization of a protein-generated O2 binding pocket in PqqC, a cofactorless oxidase catalyzing the final step in PQQ production.

PQQ is an exogenous, tricyclic, quino-cofactor for a number of bacterial dehydrogenases. The final step of PQQ formation is catalyzed by PqqC, a cofactorless oxidase. This study focuses on the activation of molecular oxygen in an enzyme active site without metal or cofactor and has identified a specific oxygen binding and activating pocket in PqqC. The active site variants H154N, Y175F,S, and R179S were studied with the goal of defining the site of O(2) binding and activation. Using apo-glucose dehydrogenase to assay for PQQ production, none of the mutants in this "O(2) core" are capable of PQQ/PQQH(2) formation. Spectrophotometric assays give insight into the incomplete reactions being catalyzed by these mutants. Active site variants Y175F, H154N, and R179S form a quinoid intermediate (Figure 1) anaerobically. Y175S is capable of proceeding further from quinoid to quinol, whereas Y175F, H154N, and R179S require O(2) to produce the quinol species. None of the mutations precludes substrate/product binding or oxygen binding. Assays for the oxidation of PQQH(2) to PQQ show that these O(2) core mutants are incapable of catalyzing a rate increase over the reaction in buffer, whereas H154N can catalyze the oxidation of PQQH(2) to PQQ in the presence of H(2)O(2) as an electron acceptor. Taken together, these data indicate that none of the targeted mutants can react fully to form quinone even in the presence of bound O(2). The data indicate a successful separation of oxidative chemistry from O(2) binding. The residues H154, Y175, and R179 are proposed to form a core O(2) binding structure that is essential for efficient O(2) activation.

Pyrroloquinoline quinone biogenesis: characterization of PqqC and its H84N and H84A active site variants.

Pyrroloquinoline quinone [4,5-dihydro-4,5-dioxo-1H-pyrrolo[2,3-f]quinoline-2,7,9-tricarboxylic acid (PQQ)] is a bacterial vitamin that serves as a cofactor in numerous alcohol dehydrogenases. Its biosynthesis in Klebsiella pneumoniae is facilitated by six genes, pqqABCDEF, and proceeds by an unknown pathway. The protein encoded by pqqC catalyzes the final step of PQQ formation, which involves a ring closure and an overall eight-electron oxidation of 3a-(2-amino-2-carboxyethyl)-4,5-dioxo-4,5,6,7,8,9-hexahydroquinoline-7,9-dicarboxylic acid (AHQQ) in the absence of a redox-active metal or cofactor. A recent crystal structure has implicated numerous PQQ-PqqC interactions [Magnusson et al. (2004) Proc. Natl. Acad. Sci. U.S.A. 101, 7913-7918]. To investigate the mechanism of the PqqC reaction, the active site residue His84 has been mutated to H84A and H84N, and the kinetic and spectroscopic properties have been compared to each other and the wild-type enzyme using aerobic and anaerobic conditions. Both mutants form PQQ under aerobic conditions with rate constants of 0.09 min-1 and 0.056 min-1 relative to 0.34 min-1 for the wild-type enzyme. In addition to the initial E-AHQQ complex (532-536 nm) and the product E-PQQ complex (346-366 nm), a number of spectral intermediates are observed between 316 and 344 nm. The anaerobic reaction is particularly informative, showing that while mixing of H84N with AHQQ leads to a 344 nm intermediate, this is unable to proceed to a final 318 nm species; by contrast H84A forms the 344 nm species as a precursor to the 318 nm species. In the context of the proposed chemical mechanism for PqqC [Magnusson et al. (2004) Proc. Natl. Acad. Sci. U.S.A. 101, 7913-7918], we assign the 344 nm intermediate to a quinoid species and the 318 nm intermediate to an initial quinol species. The proposed role of H84 is as a proton donor to the oxyanion of the quinoid species such that subsequent C-H bond cleavage can occur to form a monoanionic quinol. In the absence of a proton donor (as occurs in H84N), the normal reaction path is precluded as this would require formation of an unstable, dianionic species. Unlike H84N, H84A appears to be small enough to allow entry of active site water, which is postulated to adopt the role of active site proton donor.