Quinoprotein ethanol dehydrogenase from <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis>: the unusual disulfide ring formed by adjacent cysteine residues is essential for efficient electron transfer to cytochrome <Emphasis Type="Italic">c</Emphasis><Subscript>550</Subscript>

All pyrroloquinoline quinone (PQQ)-dependent alcohol dehydrogenases contain an unusual disulfide ring formed between adjacent cysteine residues. A mutant enzyme that is lacking this structure was generated by replacing Cys105 and Cys106 with Ala in quinoprotein ethanol dehydrogenase (QEDH) from Pseudomonas aeruginosa ATCC17933. Heterologously expressed quinoprotein ethanol dehydrogenase in which Cys-105 and Cys-106 have been replaced by Ala (Cys105Ala/Cys106Ala apo-QEDH) was successfully converted to enzymatic active holo-enzyme by incorporation of its cofactor PQQ in the presence of Ca²⁺. The enzymatic activity of the mutant enzyme in the artificial dye test with N-methylphenazonium methyl sulfate (PMS) and 2,6-dichlorophenol indophenol (DCPIP) at pH 9 did not depend on an activating amine which is essential for wild type activity under these conditions. The mutant enzyme showed increased Michaelis constants for primary alcohols, while the affinity for the secondary alcohol 2-propanol was unaltered. Surprisingly, for all substrates tested the specific activity of the mutant enzyme in the artificial dye test was higher than that found for wild type QEDH. On the contrary, in the ferricyanide test with the natural electron acceptor cytochrome c ₅₅₀ the activity of mutant Cys105Ala/Cys106Ala was 15-fold lower than that of wild type QEDH. We demonstrate for the first time unambiguously that the unusual disulfide ring is essential for efficient electron transfer at pH 7 from QEDH to its natural electron acceptor cytochrome c ₅₅₀.     

Two distinct alcohol dehydrogenases participate in butane metabolism by Pseudomonas butanovora

The involvement of two primary alcohol dehydrogenases, BDH and BOH, in butane utilization in Pseudomonas butanovora (ATCC 43655) was demonstrated. The genes coding for BOH and BDH were isolated and characterized. The deduced amino acid sequence of BOH suggests a 67-kDa alcohol dehydrogenase containing pyrroloquinoline quinone (PQQ) as cofactor and in the periplasm (29-residue leader sequence). The deduced amino acid sequence of BDH is consistent with a 70.9-kDa, soluble, periplasmic (37-residue leader sequence) alcohol dehydrogenase containing PQQ and heme c as cofactors. BOH and BDH mRNAs were induced whenever the cell's 1-butanol oxidation activity was induced. When induced with butane, the gene for BOH was expressed earlier than the gene for BDH. Insertional disruption of bdh or boh affected adversely, but did not eliminate, butane utilization by P. butanovora. The P. butanovora mutant with both genes boh and bdh inactivated was unable to grow on butane or 1-butanol. These cells, when grown in citrate and incubated in butane, developed butane oxidation capability and accumulated 1-butanol. The enzyme activity of BOH was characterized in cell extracts of the P. butanovora strain with bdh disrupted. Unlike BDH, BOH oxidized 2-butanol. The results support the involvement of two distinct NAD(+)-independent, PQQ-containing alcohol dehydrogenases, BOH (a quinoprotein) and BDH (a quinohemoprotein), in the butane oxidation pathway of P. butanovora.     

Identification and characterization of the AgmR regulator of Pseudomonas putida: role in alcohol utilization

Two-phase partitioning bioreactors (TPPBs) comprise an aqueous phase containing all non-carbon nutrients necessary for microbial growth and a solvent phase containing high concentrations of inhibitory or toxic substrates that partition at sub-inhibitory levels to the aqueous phase in response to cellular demand. This work aimed at eliminating the growth of Pseudomonas putida ATCC 11172 on medium-chain-length (C8-C12) aliphatic alcohols, hence enabling their use as xenobiotic delivery solvents within two-phase partitioning bioreactors. Experiments resulted in the isolation of a mini-Tn5 mutant unable to utilize these alcohols. The mutation, which also eliminated growth on glycerol and ethanol, was identified to be within a homologue of the P aeruginosa agmR gene, which encodes a response regulator. Enzyme analysis of the agmR::Tn5Km mutant cell extracts revealed a 10-fold decrease in pyrroloquinoline quinone (PQQ)-dependent alcohol dehydrogenase activity. A knockout in a gene (exaA) encoding a PQQ-linked alcohol dehydrogenase slowed but did not eliminate growth on medium-chain-length alcohols or ethanol, suggesting metabolic redundancy within P. putida ATCC 11172. Analysis of P. putida KT2440 genome sequence data indicated the presence of two PQQ-linked alcohol dehydrogenase-encoding genes. The successful elimination of alcohol utilization in the agmR mutant indicates control by AgmR on multiple pathways and presents a useful strain for biotechnological applications requiring alcohol non-utilizing microbial catalysts.     

Characterisation of the PQQ cofactor radical in quinoprotein ethanol dehydrogenase of Pseudomonas aeruginosa by electron paramagnetic resonance spectroscopy

The binding pocket of the pyrroloquinoline quinone (PQQ) cofactor in quinoprotein alcohol dehydrogenases contains a characteristic disulphide ring formed by two adjacent cysteine residues. To analyse the function of this unusual structural motif we have investigated the wild-type and a double cysteine:alanine mutant of the quinoprotein ethanol dehydrogenase from Pseudomonas aeruginosa by electron paramagnetic resonance (EPR) spectroscopy. Thus, we have obtained the principal values for the full rhombic g-tensor of the PQQ semiquinone radical by high-field (94 GHz) EPR necessary for a discrimination of radical species in dehydrogenases containing PQQ together with other redox-active cofactors. Our results show that the characteristic disulphide ring is no prerequisite for the formation of the functionally important semiquinone form of PQQ.     

高浓度2-KLG对氧化葡萄糖酸杆菌WSH-003中2-KLG合成途径关键基因表达的影响

【目的】研究高浓度的2-KLG对其生产菌株氧化葡萄糖酸杆菌生产过程中关键的脱氢酶合成基因、辅因子合成基因及其转运蛋白编码基因的影响。【方法】测定高浓度梯度2-KLG下氧化葡萄糖酸杆菌的生长情况,确定合适的添加浓度对氧化葡萄糖酸杆菌进行胁迫。使用实时定量PCR技术检测2-KLG合成中关键山梨醇脱氢酶基因sld AB、关键辅因子PQQ合成基因pqq ABCDE及5个潜在转运蛋白合成基因的变化。【结果】根据氧化葡萄糖酸杆菌在2-KLG高浓度梯度下生长测定实验结果,选定40、80和120 g/L 2-KLG作为添加浓度。实时定量PCR结果显示,在高浓度的2-KLG压力下,PQQ合成基因pqq ABCDE未受到显著影响,山梨醇脱氢酶基因sld AB以及部分PQQ潜在转运蛋白编码基因的表达均显著下调。【结论】高浓度2-KLG会抑制氧化葡萄糖酸杆菌中山梨醇脱氢酶基因的表达,有可能会影响辅酶PQQ的转运,但不会显著影响辅酶PQQ的合成。     

Research on the metabolic engineering of the direct oxidation pathway for extraction of phosphate from ore has generated preliminary evidence for PQQ biosynthesis in Escherichia coli as well as a possible role for the highly conserved region of quinoprotein dehydrogenases

The ability of some bacteria to dissolve poorly soluble calcium phosphates (CaPs) has been termed 'mineral phosphate solubilizing' (MPS). Since most microorganisms and plants must assimilate P via membrane transport, biotransformation of CaP into soluble phosphate is considered an essential component of the global P cycle. In many Gram-negative bacteria, strong organic acids produced in the periplasm via the direct oxidation pathway have been shown to dissolve CaP in the adjacent environment. Therefore, the quinoprotein glucose dehydrogenase (PQQGDH) may function in the ecophysiology of many soil bacteria. There is interest in using MPS bacteria for industrial bioprocessing of rock phosphate ore (a substituted fluroapatite) or even for direct inoculation of soils as a 'biofertilizer' analogous to nitrogen fixation. Our laboratory has spent 20 years studying superior MPS bacteria. Screening genomic libraries in the appropriate E. coli genetic background can 'trap' PQQ or GDH genes from these bacteria via functional complementation. In setting the 'trap' for PQQ genes, we have identified DNA fragments that apparently induce PQQGDH activity in E. coli with no sequence homology to known PQQ genes. These data suggest that E. coli may have an alternative, inducible PQQ biosynthesis pathway. Finally, a novel protein engineering strategy to increase the catalytic rate of PQQGDH has emerged and will be discussed.     

Purification, crystallisation and characterization of quinoprotein ethanol dehydrogenase from Pseudomonas aeruginosa

Pseudomonas aeruginosa ATCC 17933 when grown on ethanol produces high levels of a quinoprotein ethanol dehydrogenase, which amounts to 7% of the soluble protein. The enzyme has been purified to homogeneity and it crystallizes readily in the presence of polyethylene glycol 1550 or 6000. The ethanol dehydrogenase (Km(ethanol) = 14 microM) resembles the dye-dependent quinoprotein methanol dehydrogenases of methylotrophic bacteria, but has a low affinity for methanol (Km (methanol) = 94mM). In addition the enzyme oxidizes secondary alcohols. With its catalytic properties the ethanol dehydrogenase is similar to the enzyme isolated from P. aeruginosa LMD 80.53 (Groen, B., Frank, J. Jzn. & Duine, J.A. (1984) Biochem. J. 223, 921-924). In contrast to this enzyme from P. aeruginosa LMD 80.53, which is a monomer, the ethanol dehydrogenase isolated from P. aeruginosa ATCC 17933 is a dimer of identical subunits of relative molecular mass 60,000. The N-terminal amino acid is lysine. Inactivation with cyclopropanone ethylhemiketal reveals one molecule of pyrroloquinoline quinone per subunit. As shown by active enzyme sedimentation, the dimer is the enzymatically active form.     

Cloning of an Erwinia herbicola gene necessary for gluconic acid production and enhanced mineral phosphate solubilization in Escherichia coli HB101: nucleotide sequence and probable involvement in biosynthesis of the coenzyme pyrroloquinoline quinone.

Escherichia coli is capable of synthesizing the apo-glucose dehydrogenase enzyme (GDH) but not the cofactor pyrroloquinoline quinone (PQQ), which is essential for formation of the holoenzyme. Therefore, in the absence of exogenous PQQ, E. coli does not produce gluconic acid. Evidence is presented to show that the expression of an Erwinia herbicola gene in E. coli HB101(pMCG898) resulted in the production of gluconic acid, which, in turn, implied PQQ biosynthesis. Transposon mutagenesis showed that the essential gene or locus was within a 1.8-kb region of a 4.5-kb insert of the plasmid pMCG898. This 1.8-kb region contained only one apparent open reading frame. In this paper, we present the nucleotide sequence of this open reading frame, a 1,134-bp DNA fragment coding for a protein with an M(r) of 42,160. The deduced sequence of this protein had a high degree of homology with that of gene III (M(r), 43,600) of a PQQ synthase gene complex from Acinetobacter calcoaceticus previously identified by Goosen et al. (J. Bacteriol. 171:447-455, 1989). In minicell analysis, pMCG898 encoded a protein with an M(r) of 41,000. These data indicate that E. coli HB101(pMCG898) produced the GDH-PQQ holoenzyme, which, in turn, catalyzed the oxidation of glucose to gluconic acid in the periplasmic space. As a result of the gluconic acid production, E. coli HB101(pMCG898) showed an enhanced mineral phosphate-solubilizing phenotype due to acid dissolution of the hydroxyapatite substrate.     

The enzymatic reaction-induced configuration change of the prosthetic group PQQ of methanol dehydrogenase

Methanol dehydrogenase is a heterotetrameric enzyme containing the prosthetic group pyrroloquinoline quinone (PQQ), which catalyzes the oxidation of methanol to formaldehyde. The crystal structure of methanol dehydrogenase from Methylophilus W3A1, previously determined at high resolution, exhibits a non-planar configuration of the PQQ ring system and lends support for a hydride transfer mechanism of the enzymatic reaction catalyzed by the enzyme. To investigate why PQQ is in the C5-reduced form and to better understand the catalytic mechanism of the enzyme, three structures of this enzyme in a new crystal form have been determined at higher resolution. Two of the three crystals were grown in the presence of 1 and 50 mM methanol, respectively, both structures of which show non-planar configurations of the PQQ ring system, confirming the previous conclusion; the other was crystallized in the presence of 50 mM ethanol, the structure of which displays a planar ring system for PQQ. Comparison of these structures reveals that the configuration change of PQQ is induced by the enzymatic reaction. The reaction takes place and the C5-reduced PQQ intermediate is produced when the enzyme co-crystallizes with methanol, but the enzymatic reaction does not take place and the PQQ ring retains a planar configuration of the oxidized orthoquinone form when ethanol instead of methanol is present in the crystallization solution.     

Physiological properties of a pyrroloquinoline quinone mutant of Methylobacterium organophilum

Abstract The grwoth of MTMl, a mutant of methylobacterium organophilum) blocked in the use of methanol as a carbon and energy source, was restored by addition of pyrroloquinoline quinone (PQQ) in the culture medium. No PQQ could be detected in crude medium. No PQQ could be of MTMl. Therefore, MTMl can be regarded as a mutant blocked in the biosynthesis of PQQ. Under the conditions of growth employed, growth rates of MTMl on methanol, comparable to those of the wild type, occured at a PQQ concentration of 1 μM. Since lower amounts of methanol dehydrogenase (MDH) wer found in cell-free extracts of PQQ-supplemented MTMl, the wild type strain synthesizes a surplus of MDH under these conditions. Growth of M. organophilum on ethanol proceeds via MDH as a catalyst for the first step, since (NAD(P) -dependent etanol. dehydrogenase was absent in cell-free extracts and growth of MTMl on ethanol only took place in the presence of PQQ. On the hand, growth of MTMl on mthylamine was unimpaired. This is in accordance with the fact that methylamine dehydrogenase was absent and N -methylamine mate dehydrogenase was present in cell-free extracts     

Tn5-directed cloning of pqq genes from Pseudomonas fluorescens CHA0: mutational inactivation of the genes results in overproduction of the antibiotic pyoluteorin.

Pseudomonas fluorescens CHA0 produces several secondary metabolites, e.g., the antibiotics pyoluteorin (Plt) and 2,4-diacetylphloroglucinol (Phl), which are important for the suppression of root diseases caused by soil-borne fungal pathogens. A Tn5 insertion mutant of strain CHA0, CHA625, does not produce Phl, shows enhanced Plt production on malt agar, and has lost part of the ability to suppress black root rot in tobacco plants and take-all in wheat. We used a rapid, two-step cloning-out procedure for isolating the wild-type genes corresponding to those inactivated by the Tn5 insertion in strain CHA625. This cloning method should be widely applicable to bacterial genes tagged with Tn5. The region cloned from P. fluorescens contained three complete open reading frames. The deduced gene products, designated PqqFAB, showed extensive similarities to proteins involved in the biosynthesis of pyrroloquinoline quinone (PQQ) in Klebsiella pneumoniae, Acinetobacter calcoaceticus, and Methylobacterium extorquens. PQQ-negative mutants of strain CHA0 were constructed by gene replacement. They lacked glucose dehydrogenase activity, could not utilize ethanol as a carbon source, and showed a strongly enhanced production of Plt on malt agar. These effects were all reversed by complementation with pqq+ recombinant plasmids. The growth of a pqqF mutant on ethanol and normal Plt production were restored by the addition of 16 nM PQQ. However, the Phl- phenotype of strain CHA625 was due not to the pqq defect but presumably to a secondary mutation. In conclusion, a lack of PQQ markedly stimulates the production of Plt in P. fluorescens.     

Pyrroloquinoline quinone biosynthesis in Escherichia coli through expression of the Gluconobacter oxydans pqqABCDE gene cluster

We have expressed the pqqABCDE gene cluster from Gluconobacter oxydans, which is involved in pyrroloquinoline quinone (PQQ) biosynthesis, in Escherichia coli, resulting in PQQ accumulation in the medium. Since the gene cluster does not include the tldD gene needed for PQQ production, this result suggests that the E. coli tldD gene, which shows high homology to the G. oxydans tldD gene, carries out that function. The synthesis of PQQ activated d-glucose dehydrogenase in E. coli and the growth of the recombinant was improved. In an attempt to increase the production of PQQ, which acts as a vitamin or growth factor, we transformed E. coli with various recombinant plasmids, resulting in the overproduction of the PQQ synthesis enzymes and, consequently, PQQ accumulation—up to 6 mM—in the medium. This yield is 21.5-fold higher than that obtained in previous studies.     

Escherichia coli PQQ-containing quinoprotein glucose dehydrogenase: its structure comparison with other quinoproteins

Membrane-bound glucose dehydrogenase (mGDH) in Escherichia coli is one of the pivotal pyrroloquinoline quinone (PQQ)-containing quinoproteins coupled with the respiratory chain in the periplasmic oxidation of alcohols and sugars in Gram-negative bacteria. We compared mGDH with other PQQ-dependent quinoproteins in molecular structure and attempted to trace their evolutionary process. We also review the role of residues crucial for the catalytic reaction or for interacting with PQQ and discuss the functions of two distinct domains, radical formation in PQQ, and the presumed existence of bound quinone in mGDH.     

Evidence for mutualism between a plant growing in a phosphate-limited desert environment and a mineral phosphate solubilizing (MPS) rhizobacterium

Alkaline desert soils are high in insoluble calcium phosphates but deficient in soluble orthophosphate (Pi) essential for plant growth. In this extreme environment, one adaptive strategy could involve specific associations between plant roots and mineral phosphate solubilizing (MPS) bacteria. The most efficient MPS phenotype in Gram-negative bacteria results from extracellular oxidation of glucose to gluconic acid via the quinoprotein glucose dehydrogenase. A unique bacterial population isolated from the roots of Helianthus annus jaegeri growing at the edge of an alkaline dry lake in the Mojave Desert showed no MPS activity and no gluconic acid production. Addition of a concentrated solution containing material washed from the roots to these bacteria in culture resulted in production of high levels of gluconic acid. This effect was mimicked by addition of the essential glucose dehydrogenase redox cofactor 2,7,9-tricarboxyl-1H-pyrrolo[2,3]-quinoline-4,5-dione (PQQ) but the bioactive component was not PQQ. DNA hybridization data confirmed that this soil bacterium carried a gene with homology to the Escherichia coli quinoprotein glucose dehydrogenase. These data suggest that expression of the direct oxidation pathway in this bacterium may be regulated by signaling between the bacteria and the plant root. The resultant acidification of the rhizosphere may play a role in nutrient availability and/or other ecophysiological parameters essential for the survival of this desert plant.     

Pyrroloquinoline quinone-dependent dehydrogenases from Ketogulonicigenium vulgare catalyze the direct conversion of L-sorbosone to L-ascorbic acid

A novel enzyme, L-sorbosone dehydrogenase 1 (SNDH1), which directly converts L-sorbosone to L-ascorbic acid (L-AA), was isolated from Ketogulonicigenium vulgare DSM 4025 and characterized. This enzyme was a homooligomer of 75-kDa subunits containing pyrroloquinoline quinone (PQQ) and heme c as the prosthetic groups. Two isozymes of SNDH, SNDH2 consisting of 75-kDa and 55-kDa subunits and SNDH3 consisting of 55-kDa subunits, were also purified from the bacterium. All of the SNDHs produced L-AA, as well as 2-keto-L-gulonic acid (2KGA), from L-sorbosone, suggesting that tautomerization of L-sorbosone causes the dual conversion by SNDHs. The sndH gene coding for SNDH1 was isolated and analyzed. The N-terminal four-fifths of the SNDH amino acid sequence exhibited 40% identity to the sequence of a soluble quinoprotein glucose dehydrogenase from Acinetobacter calcoaceticus. The C-terminal one-fifth of the sequence exhibited similarity to a c-type cytochrome with a heme-binding motif. A lysate of Escherichia coli cells expressing sndH exhibited SNDH activity in the presence of PQQ and CaCl2. Gene disruption analysis of K. vulgare indicated that all of the SNDH proteins are encoded by the sndH gene. The 55-kDa subunit was derived from the 75-kDa subunit, as indicated by cleavage of the C-terminal domain in the bacterial cells.