Menaquinone as well as ubiquinone as a bound quinone crucial for catalytic activity and intramolecular electron transfer in Escherichia coli membrane-bound glucose dehydrogenase

Escherichia coli membrane-bound glucose dehydrogenase (mGDH), which is one of quinoproteins containing pyrroloquinoline quinone (PQQ) as a coenzyme, is a good model for elucidating the function of bound quinone inside primary dehydrogenases in respiratory chains. Enzymatic analysis of purified mGDH from cells defective in synthesis of ubiquinone (UQ) and/or menaquinone (MQ) revealed that Q-free mGDH has very low levels of activity of glucose dehydrogenase and UQ2 reductase compared with those of UQ-bearing mGDH, and both activities were significantly increased by reconstitution with UQ1. On the other hand, MQ-bearing mGDH retains both catalytic abilities at the same levels as those of UQ-bearing mGDH. A radiolytically generated hydrated electron reacted with the bound MQ to form a semiquinone anion radical with an absorption maximum at 400 nm. Subsequently, decay of the absorbance at 400 nm was accompanied by an increase in the absorbance at 380 nm with a first order rate constant of 5.7 x 10(3) s(-1). This indicated that an intramolecular electron transfer from the bound MQ to the PQQ occurred. EPR analysis revealed that characteristics of the semiquinone radical of bound MQ are similar to those of the semiquinone radical of bound UQ and indicated an electron flow from PQQ to MQ as in the case of UQ. Taken together, the results suggest that MQ is incorporated into the same pocket as that for UQ to perform a function almost equivalent to that of UQ and that bound quinone is involved at least partially in the catalytic reaction and primarily in the intramolecular electron transfer of mGDH.     

Quinoproteins: structure, function, and biotechnological applications

A new class of oxidoreductase containing an amino acid-derived o-quinone cofactor, of which the most typical is pyrroloquinoline quinone (PQQ), is called quinoproteins, and has been recognized as the third redox enzyme following pyridine nucleotide- and flavin-dependent dehydrogenases. Some quinoproteins include a heme c moiety in addition to the quinone cofactor in the molecule and are called quinohemoproteins. PQQ-containing quinoproteins and quinohemoproteins have a common structural basis, in which PQQ is deeply embedded in the center of the unique superbarrel structure. Increased evidence for the structure and function of quinoproteins has revealed their unique position within the redox enzymes with respect to catalytic and electron transfer properties, and also to physiological and energetic function. The peculiarities of the quinoproteins, together with their unique substrate specificity, have encouraged their biotechnological application in the fields of biosensing and bioconversion of useful compounds, and also to environmental treatment.     

Transient formation of a neutral ubisemiquinone radical and subsequent intramolecular electron transfer to pyrroloquinoline quinone in the Escherichia coli membrane-integrated glucose dehydrogenase

The membrane-bound quinoprotein glucose dehydrogenase (mGDH) in Escherichia coli contains pyrroloquinoline quinone (PQQ) and participates in the direct oxidation of D-glucose to D-gluconate by transferring electrons to ubiquinone (UQ). To elucidate the mechanism of ubiquinone reduction by mGDH, we applied a pulse radiolysis technique to mGDH with or without bound UQ8. With the UQ8-bound enzyme, a hydrated electron reacted with mGDH to form a transient species with an absorption maximum at 420 nm, characteristic of formation of a neutral ubisemiquinone radical. Subsequently, the decay of the absorbance at 420 nm was accompanied by an increase in the absorbance at 370 nm. Experiments with the PQQ-free apoenzyme showed no such subsequent absorption changes, although ubisemiquinone was formed. These results indicate that a pathway for an intramolecular electron transfer from ubisemiquinone radical at the UQ8 binding site to PQQ exists in mGDH. The first-order rate constant of this process was calculated to be equal to 1.2 x 10(3) s(-1). These findings are consistent with our proposal that during the catalytic cycle of mGDH the bound UQ8 mediates electron transfer from the reduced PQQ to UQ8 pools.     

PQQ and quinoprotein research--the first decade

On the occasion of the first international symposium on pyrroloquinoline quinone (PQQ) and quinoproteins (Delft, September 1988), a review of this novel field in enzymology is presented. Quinoproteins (PQQ-containing enzymes) are widespread, from bacteria to mammalian organisms (including man), and occur in several classes of enzymes. Indications already exist that PQQ is a versatile cofactor, involved not only in oxidation but also in hydroxylation, transamination, decarboxylation and hydration reactions. The current list of quinoproteins shows that it was overlooked in several well-studied enzymes where the presence of a common cofactor had already been established. Up until now, all eukaryotic quinoproteins have covalently bound PQQ (or perhaps pro-PQQ), while free PQQ occurs exclusively in a number of (bacterial) dehydrogenases and in the culture fluid of certain Gram-negative bacteria. Biosynthesis of free PQQ in methylotrophic bacteria starts with tyrosine and glutamic acid as precursors while intermediates in the route have not been detected and the presence of free PQQ is not required for synthesis of the covalently bound form of the cofactor in glutamic acid decarboxylase from Escherichia coli. Therefore, the assembly of covalently bound cofactor might occur in situ, i.e. in the quinoproteins themselves. If the latter also applies to mammalian quinoproteins, this implies that PQQ is not a vitamin. On the other hand, positive effects have been reported upon administration of PQQ to test animals. Methods suited to detach and to detect PQQ with a derivatized o-quinone moiety may answer questions on the uptake and processing of the compound.     

Occurrence of a bound ubiquinone and its function in Escherichia coli membrane-bound quinoprotein glucose dehydrogenase

The membrane-bound pyrroloquinoline quinone (PQQ)-containing quinoprotein glucose dehydrogenase (mGDH) in Escherichia coli functions by catalyzing glucose oxidation in the periplasm and by transferring electrons directly to ubiquinone (UQ) in the respiratory chain. To clarify the intramolecular electron transfer of mGDH, quantitation and identification of UQ were performed, indicating that purified mGDH contains a tightly bound UQ(8) in its molecule. A significant increase in the EPR signal was observed following glucose addition in mGDH reconstituted with PQQ and Mg(2+), suggesting that bound UQ(8) accepts a single electron from PQQH(2) to generate semiquinone radicals. No such increase in the EPR signal was observed in UQ(8)-free mGDH under the same conditions. Moreover, a UQ(2) reductase assay with a UQ-related inhibitor (C49) revealed different inhibition kinetics between the wild-type mGDH and UQ(8)-free mGDH. From these findings, we propose that the native mGDH bears two ubiquinone-binding sites, one (Q(I)) for bound UQ(8) in its molecule and the other (Q(II)) for UQ(8) in the ubiquinone pool, and that the bound UQ(8) in the Q(I) site acts as a single electron mediator in the intramolecular electron transfer in mGDH.     

Pyrroloquinoline quinone as cofactor in galactose oxidase (EC 1.1.3.9)

Galactose oxidase from Dactylium dendroides was shown to contain one molecule of covalently bound pyrroloquinoline quinone (PQQ/enzyme molecule. From the spectroscopic characteristics reported for the enzyme forms, a mechanistic role for PQQ could be deduced. In analogy with other quinoproteins, the initial formation of a PQQ-substrate adduct is proposed. Following internal hydrogen transfer, leading to aldehyde product and reduced pyrroloquinoline quinone, reoxidation of the organic cofactor with molecular oxygen could be mediated by the PQQ-liganded copper ion with concomitant formation of hydrogen peroxide. With PQQ as an additional (two-electron) redox center the occurrence of a "superoxidized" enzyme form must be considered. Possible consequences of this view, in relation to a physiological function of the enzyme and interpretation of ESR data, are discussed.     

Amino acid residues interacting with both the bound quinone and coenzyme, pyrroloquinoline quinone, in Escherichia coli membrane-bound glucose dehydrogenase

The Escherichia coli membrane-bound glucose dehydrogenase (mGDH) as the primary component of the respiratory chain possesses a tightly bound ubiquinone (UQ) flanking pyrroloquinoline quinone (PQQ) as a coenzyme. Several mutants for Asp-354, Asp-466, and Lys-493, located close to PQQ, that were constructed by site-specific mutagenesis were characterized by enzymatic, pulse radiolysis, and EPR analyses. These mutants retained almost no dehydrogenase activity or ability of PQQ reduction. CD and high pressure liquid chromatography analyses revealed that K493A, D466N, and D466E mutants showed no significant difference in molecular structure from that of the wild-type mGDH but showed remarkably reduced content of bound UQ. A radiolytically generated hydrated electron (e(aq)(-)) reacted with the bound UQ of the wild enzyme and K493R mutant to form a UQ neutral semiquinone with an absorption maximum at 420 nm. Subsequently, intramolecular electron transfer from the bound UQ semiquinone to PQQ occurred. In K493R, the rate of UQ to PQQ electron transfer is about 4-fold slower than that of the wild enzyme. With D354N and D466N mutants, on the other hand, transient species with an absorption maximum at 440 nm, a characteristic of the formation of a UQ anion radical, appeared in the reaction of e(aq)(-), although the subsequent intramolecular electron transfer was hardly affected. This indicates that D354N and D466N are prevented from protonation of the UQ semiquinone radical. Moreover, EPR spectra showed that mutations on Asp-466 or Lys-493 residues changed the semiquinone state of bound UQ. Taken together, we reported here for the first time the existence of a semiquinone radical of bound UQ in purified mGDH and the difference in protonation of ubisemiquinone radical because of mutations in two different amino acid residues, located around PQQ. Furthermore, based on the present results and the spatial arrangement around PQQ, Asp-466 and Lys-493 are suggested to interact both with the bound UQ and PQQ in mGDH.     

The quinoprotein dehydrogenases for methanol and glucose

This review summarises our current understanding of two of the main types of quinoprotein dehydrogenase in which pyrroloquinoline quinone (PQQ) is the only prosthetic group. These are the soluble methanol dehydrogenase and the membrane glucose dehydrogenase (mGDH). The membrane GDH has an additional N-terminal domain by which it is tightly anchored to the membrane, and a periplasmic domain whose structure has been modelled on the X-ray structure of the alpha-subunit of MDH which contains PQQ in the active site. This review discusses their structures and mechanisms, concentrating particularly on the pathways for electron transfer from the reduced PQQ, through the protein, to their electron acceptors. In MDH, this is the specific cytochrome c(L), the electron transfer pathway probably involving the unique disulphide ring in the active site. By contrast, mGDH contains a permanently bound ubiquinone, which acts as a single electron carrier, mediating electron transfer through the protein to the membrane ubiquinone.     

PQQ and quinoprotein enzymes in microbial oxidations

Abstract Pyrroloquinoline quinone (PQQ) is found in a wide range of microorganisms, and several bacteria even excrete this compound into their culture medium when grown on alcohols. The existence of different classes of quinoprotein (PQQ-containing) enzymes is now well established (alcohol dehydrogenases, aldose (glucose) dehydrogenases, amine dehydrogenases and amine oxidases) while several other enzymes are suspected to be quinoproteins. In addition, many bacteria produce a quinoprotein apoenzyme, e.g., Escherichia coli and Pseudomonas testosteroni , producing glucose and ethanol dehydrogenase apoenzyme, respectively. It is unclear why these bacteria do not produce the holoenzyme form, but the apoenzymes have the ability to become functional, as was shown when the organisms were provided with PQQ. With this approach it could be demonstrated that E. coli has a non-phosphorylative route of glucose dissimilation via gluconate. Also, results with mixed cultures indicate that PQQ is a growth factor for certain bacteria under certain conditions. Despite the relatively high redox potential of the PQQ/PQQH₂ couple, quinoproteins transfer electrons to a variety of natural electron acceptors. Depending on the type of quinoprotein enzyme, the following components of the respiratory chain appear to be active: cytochrome c (sometimes with a copper protein as an intermediate), cytochrome b , and NADH dehydrogenase. PQQ is not restricted to a particular group of organisms, and reactions catalysed by quinoproteins can also be performed by NAD(P)-dependent or flavoprotein enzymes. Thus, these observations do not provide arguments for the view that quinoproteins have a unique role in microbial oxidations. Further comparative studies on oxidoreductases are necessary to reveal the special features of this novel group of enzymes.     

Adduct formation of pyrroloquinoline quinone and amino acid

When pyrroloquinoline quinone (PQQ) is mixed with an amino acid, a corresponding Schiff base PQQ adduct is readily formed between carbonyl groups of PQQ and the primary amino group. A potent growth stimulating effect for microorganisms was observed with the PQQ adduct when it was administered in a culture medium. Although PQQ itself shows a marked growth stimulating effect, PQQ adducts appeared to be more active than authentic PQQ when compared on a molar basis. Conversely, unlike authentic PQQ, PQQ adducts were shown to be less active (greater than or equal to 100-fold) as the prosthetic group for a quinoprotein apo-glucose dehydrogenase when examined by holoenzyme formation by exogenous addition of PQQ or PQQ adducts. These observations suggested that PQQ adduct formation readily occurs during isolation procedures for PQQ from biological materials or PQQ - chromophore from quinoproteins. Therefore, the presence of such adducts gives a PQQ estimation much lower than theoretically expected. As an example, formation, isolation and characterization of PQQ - serine are described.     

Soluble and Membrane-bound Quinoprotein D-Glucose Dehydrogenases of the Acinetobacter calcoaceticus: The Binding Process of PQQ to the Apoenzymes

Acinetohacter calcoaceticus LMD 79.41 is a unique bacterium containing a soluble quinoprotein D-glucose dehydrogenase (sGDH) in addition to the membrane-bound quinoprotein D-glucose dehydrogenase (mGDH) which is distributed extensively in Gram-negative bacteria. sGDH has been shown to be a distinct enzyme from mGDH, though both enzymes contain a tightly bound pyrroloquinoline quinone (PQQ) as their prosthetic group. In this study, sGDH was detectable in all strains tested of A. calcoaceticus but not in other Gram-negative bacteria tested, indicating that sGDH can be useful as a taxonomic marker for A. calcoaceticus.

The binding process of PQQ with both enzymes was examined by using the apoenzymes purified from a PQQ-deficient mutant strain of A. calcoaceticus. sGDH was able to bind two moles of PQQ in one mole of the homodimer with a fairly high affinity. The binding reaction was much faster at alkaline pH than at acidic pH, and required the presence of some divalent cations such as Cd²⁺, Ca²⁺, Sr²⁺, or Mn²⁺. On the other hand, mGDH bound one mol of PQQ in the monomeric enzyme with a relatively slow reacting process, which was optimum at acidic pH and in the presence of different types of divalent cations such as Mg²⁺, Ca²⁺, Zn²⁺, or Sr²⁺. Thus, it is suggested that sGDH and mGDH have distinct structures around their PQQ binding site. Furthermore, binding of PQQ affects the conformation of both enzymes, which can be shown from the diminishing intrinsic fluorescence of the enzymes and the increase in resistance against proteolysis upon PQQ binding. Data also suggest that the conformational changes caused by PQQ-binding are more dramatic in sGDH than in mGDH. Based on the results obtained, the differences in PQQ-binding mode between the enzymes and the physiological meanings of sGDH are discussed.     

Pyrroloquinoline quinone: excretion by methylotrophs and growth stimulation for microorganisms

A marked excretion of pyrroloquinoline quinone (PQQ) by methylotrophs into the culture medium was observed when incubation was prolonged to the late stationary phase. When the organisms were growing vigorously in the early exponential phase, accumulation of PQQ was repressed at a low level. Some evidence was obtained that the excretion of PQQ is related to turnover of quinoproteins of the organisms. The growth stimulation of microorganisms by PQQ was demonstrated using Acetobacter aceti. The presence of PQQ even at the pg/ml level in the culture medium stimulated the bacterial growth by reducing the lag time. The growth stimulating effect of PQQ was observed only by the reduction of the lag time but not by increase in either the subsequent growth rate or the total cell yield. The results indicated that PQQ must have an important role in the initiation of cell reproduction.     

Evidence for PQQ as cofactor in 3,4-dihydroxyphenylalanine (dopa) decarboxylase of pig kidney

Pig kidney 3,4-dihydroxyphenylalanine (dopa) decarboxylase (EC 4.1.1.28) was purified to homogeneity. Treatment of the enzyme with phenylhydrazine (PH) according to a procedure developed for analysis of quinoproteins gave products which were identified as the hydrazone of pyridoxal phosphate (PLP) and the C(5)-hydrazone of pyrroloquinoline quinone (PQQ). This method failed, however, in quantifying the amounts of cofactor. Direct hydrolysis of the enzyme by refluxing with hexanol and concentrated HCl led to detachment of PQQ from the protein in a quantity of 1 PQQ per enzyme molecule. In view of the reactivity of PQQ towards amines and amino acids, we postulate that it participates as a covalently bound cofactor in the catalytic cycle of the enzyme, in interplay with PLP. Since several other enzymes have been reported to show the atypical behaviour of dopa decarboxylase, it seems that the PLP-containing group of enzymes can be subdivided into pyridoxoproteins and pyridoxo-quinoproteins.     

Identification of Pantoea ananatis gene encoding membrane pyrroloquinoline quinone (PQQ)-dependent glucose dehydrogenase and pqqABCDEF operon essential for PQQ biosynthesis

Pantoea ananatis accumulates gluconate during aerobic growth in the presence of glucose. Computer analysis of the P. ananatis SC17(0) sequenced genome revealed an ORF encoding a homologue (named gcd) of the mGDH (EC 1.1.99.17) apoenzyme from Escherichia coli and a putative pyrroloquinoline quinone (PQQ) biosynthetic operon homologous to pqqABCDEF from Klebsiella pneumoniae. Construction of Δgcd and Δpqq mutants of P. ananatis confirmed the proposed functions of these genetic elements. The P. ananatis pqqABCDEF was cloned in vivo and integrated into the chromosomes of P. ananatis and E. coli according to the Dual In/Out strategy. Introduction of a second copy of pqqABCDEF to P. ananatis SC17(0) doubled the accumulation of PQQ. Integration of the operon into E. coli MG1655ΔptsGΔmanXY restored the growth of bacteria on glucose. The obtained data show the essential role of pqqABCDEF in PQQ biosynthesis in P. ananatis and E. coli. We propose that the cloned operon could be useful for an efficient phosphoenolpyruvate-independent glucose consumption pathway due to glucose oxidation and construction of E. coli strains with the advantage of phosphoenolpyruvate-derived metabolite production.     

Factors relevant in the reaction of pyrroloquinoline quinone with amino acids. Analytical and mechanistic implications

In order to reveal the stability of pyrroloquinoline quinone (PQQ) in complex samples, its reaction on incubation with amino acids was followed spectrophotometrically by monitoring oxygen consumption, and with a biological assay. For several alpha-amino acids, the formation of a yellow coloured compound (lambda max = 420 nm) was accompanied by oxygen uptake and disappearance of biological activity from the reaction mixture. The yellow product appeared to be an oxazole of PQQ, the exact structure depending on the amino acid used. Oxazole formation also occurred under anaerobic conditions with concomitant formation of PQQH2, suggesting that PQQ is able to oxidize the presumed oxazoline to the oxazole. Besides the condensation reaction, there is also a catalytic cycle in which an aldimine adduct of PQQ and the amino acid is converted into the aminophenol form of the cofactor and an aldehyde resulting from oxidative decarboxylation of the amino acid. Addition of NH4+ salts, as well as that of certain divalent cations, greatly stimulated both the cyclic and the linear reaction. With basic amino acids, oxazole formation scarcely occurred. However, as oxygen consumption was observed (provided that certain divalent cations were present), conversion of these compounds took place. A reaction scheme is proposed accounting for the products formed and the effects observed. Since NH4+ ions activate several quinoproteins (PQQ-containing enzymes) and divalent cations (Ca2+, Fe2+, and Cu2+) are additional (co)factors in certain metallo quinoproteins, the effects of metal ions observed here could be related to the mechanistic features of these enzymes. Although all oxazoles were converted to PQQ by acid hydrolysis, PQQ was not detected when hydrolysis was carried out in the presence of tryptophan, a compound which appeared to have a deleterious effect on the cofactor under this condition. The results here described explain why analysis methods for free PQQ in complex samples fail in certain cases, or are not quantitative.     

PQQ-dependent methanol dehydrogenases: rare-earth elements make a difference

Methanol dehydrogenase (MDH) catalyzes the first step in methanol use by methylotrophic bacteria and the second step in methane conversion by methanotrophs. Gram-negative bacteria possess an MDH with pyrroloquinoline quinone (PQQ) as its catalytic center. This MDH belongs to the broad class of eight-bladed β propeller quinoproteins, which comprise a range of other alcohol and aldehyde dehydrogenases. A well-investigated MDH is the heterotetrameric MxaFI-MDH, which is composed of two large catalytic subunits (MxaF) and two small subunits (MxaI). MxaFI-MDHs bind calcium as a cofactor that assists PQQ in catalysis. Genomic analyses indicated the existence of another MDH distantly related to the MxaFI-MDHs. Recently, several of these so-called XoxF-MDHs have been isolated. XoxF-MDHs described thus far are homodimeric proteins lacking the small subunit and possess a rare-earth element (REE) instead of calcium. The presence of such REE may confer XoxF-MDHs a superior catalytic efficiency. Moreover, XoxF-MDHs are able to oxidize methanol to formate, rather than to formaldehyde as MxaFI-MDHs do. While structures of MxaFI- and XoxF-MDH are conserved, also regarding the binding of PQQ, the accommodation of a REE requires the presence of a specific aspartate residue near the catalytic site. XoxF-MDHs containing such REE-binding motif are abundantly present in genomes of methylotrophic and methanotrophic microorganisms and also in organisms that hitherto are not known for such lifestyle. Moreover, sequence analyses suggest that XoxF-MDHs represent only a small part of putative REE-containing quinoproteins, together covering an unexploited potential of metabolic functions.     

The metal ion in the active site of the membrane glucose dehydrogenase of Escherichia coli

All pyrroloquinoline quinone (PQQ)-containing dehydrogenases whose structures are known contain Ca(2+) bonded to the PQQ at the active site. However, membrane glucose dehydrogenase (GDH) requires reconstitution with PQQ and Mg(2+) ions (but not Ca(2+)) for activity. To address the question of whether the Mg(2+) replaces the usual active site Ca(2+) in this enzyme, mutant GDHs were produced in which residues proposed to be involved in binding metal ion were modified (D354N-GDH and N355D-GDH and D354N-GDH/N355D-GDH). The most remarkable observation was that reconstitution with PQQ of the mutant enzymes was not supported by Mg(2+) ions as in the wild-type GDH, but it could be supported by Ca(2+), Sr(2+) or Ba(2+) ions. This was competitively inhibited by Mg(2+). This result, together with studies on the kinetics of the modified enzymes have led to the conclusion that, although a Ca(2+) ion is able to form part of the active site of the genetically modified GDH, as in all other PQQ-containing quinoproteins, a Mg(2+) ion surprisingly replaces Ca(2+) in the active site of the wild-type GDH.     

Effects of membrane-bound glucose dehydrogenase overproduction on the respiratory chain of Gluconobacter oxydans

The acetic acid bacterium Gluconobacter oxydans incompletely oxidizes carbon sources as a natural part of its metabolism, and this feature has been exploited for many biotechnological applications. The most important enzymes used to harness the biocatalytic oxidative capacity of G. oxydans are the pyrroloquinoline quinone (PQQ)-dependent dehydrogenases. The membrane-bound PQQ-dependent glucose dehydrogenase (mGDH), encoded by gox0265, was used as model protein for homologous membrane protein production using the previously described Gluconobacter expression vector pBBR1p452. The mgdh gene had ninefold higher expression in the overproduction strain compared to the parental strain. Furthermore, membranes from the overexpression strain had a five- and threefold increase of mGDH activity and oxygen consumption rates, respectively. Oxygen consumption rate of the membrane fraction could not be increased by the addition of a substrate combination of glucose and ethanol in the overproduction strain, indicating that the terminal quinol oxidases of the respiratory chain were rate limiting. In contrast, addition of glucose and ethanol to membranes of the control strain increased oxygen consumption rates approaching the observed rates with G. oxydans overproducing mGDH. The higher glucose oxidation rates of the mGDH overproduction strain corresponded to a 70 % increase of the gluconate production rate compared to the control strain. The high rate of glucose oxidation may be useful in the industrial production of gluconates and ketogluconates, or as whole-cell biosensors. Furthermore, mGDH was purified to homogeneity by one-step strep-tactin affinity chromatography and characterized. To our knowledge, this is the first report of a membrane integral quinoprotein being purified by affinity chromatography and serves as a proof-of-principle for using G. oxydans as a host for membrane protein expression and purification.     

On the biosynthesis of free and covalently bound PQQ. Glutamic acid decarboxylase from Escherichia coli is a pyridoxo-quinoprotein

Analysis of glutamic acid decarboxylase (GDC) (EC 4.1.1.15) from Escherichia coli ATCC 11246 revealed the presence of six pyridoxal phosphates (PLPs) as well as six covalently bound pyrroloquinoline quinones (PQQs) per hexameric enzyme molecule. This is the second example of a pyridoxo-quinoprotein, suggesting that other atypical pyridoxoproteins (PLP-containing enzymes) have similar cofactor composition. Since the organism did not produce free PQQ and its quinoprotein glucose dehydrogenase was present in the apo form, free PQQ is not used in the assemblage of GDC. Most probably, biosynthesis of covalently bound cofactor occurs in situ via a route which is different from that of free PQQ. Thus, organisms previously believed to be unable to synthesize (free) PQQ could in fact be able to produce quinoproteins with covalently bound cofactor. Implications for the role of PQQ in eukaryotic cells are discussed.     

Determination of enzyme mechanisms by molecular dynamics: studies on quinoproteins, methanol dehydrogenase, and soluble glucose dehydrogenase

Molecular dynamics (MD) simulations have been carried out to study the enzymatic mechanisms of quinoproteins, methanol dehydrogenase (MDH), and soluble glucose dehydrogenase (sGDH). The mechanisms of reduction of the orthoquinone cofactor (PQQ) of MDH and sGDH involve concerted base-catalyzed proton abstraction from the hydroxyl moiety of methanol or from the 1-hydroxyl of glucose, and hydride equivalent transfer from the substrate to the quinone carbonyl carbon C5 of PQQ. The products of methanol and glucose oxidation are formaldehyde and glucolactone, respectively. The immediate product of PQQ reduction, PQQH- [-HC5(O-)-C4(=O)-] and PQQH [-HC5(OH)-C4(=O)-] converts to the hydroquinone PQQH2 [-C5(OH)=C4(OH)-]. The main focus is on MD structures of MDH * PQQ * methanol, MDH * PQQH-, MDH * PQQH, sGDH * PQQ * glucose, sGDH * PQQH- (glucolactone, and sGDH * PQQH. The reaction PQQ-->PQQH- occurs with Glu 171-CO2- and His 144-Im as the base species in MDH and sGDH, respectively. The general-base-catalyzed hydroxyl proton abstraction from substrate concerted with hydride transfer to the C5 of PQQ is assisted by hydrogen-bonding to the C5=O by Wat1 and Arg 324 in MDH and by Wat89 and Arg 228 in sGDH. Asp 297-COOH would act as a proton donor for the reaction PQQH(-)-->PQQH, if formed by transfer of the proton from Glu 171-COOH to Asp 297-CO2- in MDH. For PQQH-->PQQH2, migration of H5 to the C4 oxygen may be assisted by a weak base like water (either by crystal water Wat97 or bulk solvent, hydrogen-bonded to Glu 171-CO2- in MDH and by Wat89 in sGDH).