Methanol oxidation mutants in Methylobacterium extorquens AM1: identification of new genetic complementation groups

Transposon mutagenesis for methylotrophic bacteria using Methylorubrum extorquens AM1 as a model system

Transposon mutagenesis utilizes transposable genetic elements that integrate into a recipient genome to generate random insertion mutations which are easily identified. This forward genetic approach has proven powerful in elucidating complex processes, such as various pathways in methylotrophy. In the past decade, many methylotrophic bacteria have been shown to possess alcohol dehydrogenase enzymes that use lanthanides (Lns) as cofactors. Using Methylorubrum extorquens AM1 as a model organism, we discuss the experimental designs, protocols, and results of three transposon mutagenesis studies to identify genes involved in different aspects of Ln-dependent methanol oxidation. These studies include a selection for transposon insertions that prevent toxic intracellular formaldehyde accumulation, a fluorescence-imaging screen to identify regulatory processes for a primary Ln-dependent methanol dehydrogenase, and a phenotypic screen for genes necessary for function of a Ln-dependent ethanol dehydrogenase. We anticipate that the methods described in this chapter can be applied to understand other metabolic systems in diverse bacteria.

Lanthanide-Dependent Regulation of Methylotrophy in Methylobacteriumaquaticum Strain 22A

Methylobacterium species are representative of methylotrophic bacteria. Their genomes usually encode two types of methanol dehydrogenases (MDHs): MxaF and XoxF. The former is a Ca²⁺-dependent enzyme, and the latter was recently determined to be a lanthanide-dependent enzyme that is necessary for the expression of mxaF. This finding revealed the unexpected and important roles of lanthanides in bacterial methylotrophy. In this study, we performed transcriptome sequencing (RNA-seq) analysis using M. aquaticum strain 22A grown in the presence of different lanthanides. Expression of mxaF and xoxF1 genes showed a clear inverse correlation in response to La³⁺. We observed downregulation of formaldehyde oxidation pathways, high formaldehyde dehydrogenase activity, and low accumulation of formaldehyde in the reaction with cells grown in the presence of La³⁺; this might be due to the direct oxidation of methanol to formate by XoxF1. Lanthanides induced the transcription of AT-rich genes, the function of most of which was unknown, and genes possibly related to cellular survival, as well as other MDH homologues. These results revealed not only the metabolic response toward altered primary methanol oxidation, but also the possible targets to be investigated further in order to better understand methylotrophy in the presence of lanthanides. IMPORTANCE Lanthanides have been considered unimportant for biological processes. In methylotrophic bacteria, however, a methanol dehydrogenase (MDH) encoded by xoxF was recently found to be lanthanide dependent, while the classic-type mxaFI is calcium dependent. XoxF-type MDHs are more widespread in diverse bacterial genera, suggesting their importance for methylotrophy. Methylobacterium species, representative methylotrophic and predominating alphaproteobacteria in the phyllosphere, contain both types and regulate their expression depending on the availability of lanthanides. RNA-seq analysis showed that the regulation takes place not only for MDH genes but also the subsequent formaldehyde oxidation pathways and respiratory chain, which might be due to the direct oxidation of methanol to formate by XoxF. In addition, a considerable number of genes of unknown function, including AT-rich genes, were found to be upregulated in the presence of lanthanides. This study provides first insights into the specific reaction of methylotrophic bacteria to the presence of lanthanides, emphasizing the biological relevance of this trace metal.

Replacing the Ethylmalonyl-CoA Pathway with the Glyoxylate Shunt Provides Metabolic Flexibility in the Central Carbon Metabolism of Methylobacterium extorquens AM1

The ethylmalonyl-CoA pathway (EMCP) is an anaplerotic reaction sequence in the central carbon metabolism of numerous Proteo- and Actinobacteria. The pathway features several CoA-bound mono- and dicarboxylic acids that are of interest as platform chemicals for the chemical industry. The EMCP, however, is essential for growth on C1 and C2 carbon substrates and therefore cannot be simply interrupted to drain these intermediates. In this study, we aimed at reengineering central carbon metabolism of the Alphaproteobacterium Methylobacterium extorquens AM1 for the specific production of EMCP derivatives in the supernatant. Establishing a heterologous glyoxylate shunt in M. extorquens AM1 restored wild type-like growth in several EMCP knockout strains on defined minimal medium with acetate as carbon source. We further engineered one of these strains that carried a deletion of the gene encoding crotonyl-CoA carboxylase/reductase to demonstrate in a proof-of-concept the specific production of crotonic acid in the supernatant on a defined minimal medium. Our experiments demonstrate that it is in principle possible to further exploit the EMCP by establishing an alternative central carbon metabolic pathway in M. extorquens AM1, opening many possibilities for the biotechnological production of EMCP-derived compounds in future.

Methylobacterium extorquens: methylotrophy and biotechnological applications

Methylotrophy is the ability to use reduced one-carbon compounds, such as methanol, as a single source of carbon and energy. Methanol is, due to its availability and potential for production from renewable resources, a valuable feedstock for biotechnology. Nature offers a variety of methylotrophic microorganisms that differ in their metabolism and represent resources for engineering of value-added products from methanol. The most extensively studied methylotroph is the Alphaproteobacterium Methylobacterium extorquens. Over the past five decades, the metabolism of M. extorquens has been investigated physiologically, biochemically, and more recently, using complementary omics technologies such as transcriptomics, proteomics, metabolomics, and fluxomics. These approaches, together with a genome-scale metabolic model, facilitate system-wide studies and the development of rational strategies for the successful generation of desired products from methanol. This review summarizes the knowledge of methylotrophy in M. extorquens, as well as the available tools and biotechnological applications.

MdoR is a novel positive transcriptional regulator for the oxidation of methanol in Mycobacterium sp. strain JC1

Mycobacterium sp. strain JC1 is able to grow on methanol as a sole source of carbon and energy using methanol:N,N'-dimethyl-4-nitrosoaniline oxidoreductase (MDO) as a key enzyme for methanol oxidation. The second open reading frame (mdoR) upstream of, and running divergently from, the mdo gene was identified as a gene for a TetR family transcriptional regulator. The N-terminal region of MdoR contained a helix-turn-helix DNA-binding motif. An electrophoretic mobility shift assay (EMSA) indicated that MdoR could bind to a mdo promoter region containing an inverted repeat. The mdoR deletion mutant did not grow on methanol, but growth on methanol was restored by a plasmid containing an intact mdoR gene. In DNase I footprinting and EMSA experiments, MdoR bound to two inverted repeats in the putative mdoR promoter region. Reverse transcription-PCR indicated that the mdoR gene was transcribed only in cells growing on methanol, whereas β-galactosidase assays showed that the mdoR promoter was activated in the presence of methanol. These results indicate that MdoR serves as a transcriptional activator for the expression of mdo and its own gene. Also, MdoR is the first discovered member of the TetR family of transcriptional regulators to be involved in the regulation of the methanol oxidation, as well as to function as a positive autoregulator.

Functional investigation of methanol dehydrogenase-like protein XoxF in Methylobacterium extorquens AM1

Methanol dehydrogenase-like protein XoxF of Methylobacterium extorquens AM1 exhibits a sequence identity of 50 % to the catalytic subunit MxaF of periplasmic methanol dehydrogenase in the same organism. The latter has been characterized in detail, identified as a pyrroloquinoline quinone (PQQ)-dependent protein, and shown to be essential for growth in the presence of methanol in this methylotrophic model bacterium. In contrast, the function of XoxF in M. extorquens AM1 has not yet been elucidated, and a phenotype remained to be described for a xoxF mutant. Here, we found that a xoxF mutant is less competitive than the wild-type during colonization of the phyllosphere of Arabidopsis thaliana, indicating a function for XoxF during plant colonization. A comparison of the growth parameters of the M. extorquens AM1 xoxF mutant with those of the wild-type during exponential growth revealed a reduced methanol uptake rate and a reduced growth rate for the xoxF mutant of about 30 %. Experiments with cells starved for carbon revealed that methanol oxidation in the xoxF mutant occurs less rapidly compared with the wild-type, especially in the first minutes after methanol addition. A distinct phenotype for the xoxF mutant was also observed when formate and CO2 production were measured after the addition of methanol or formaldehyde to starved cells. The wild-type, but not the xoxF mutant, accumulated formate upon substrate addition and had a 1 h lag in CO2 production under the experimental conditions. Determination of the kinetic properties of the purified enzyme showed a conversion capacity for both formaldehyde and methanol. The results suggest that XoxF is involved in one-carbon metabolism in M. extorquens AM1.

Analysis of the promoter activities of the genes encoding three quinoprotein alcohol dehydrogenases in Pseudomonas putida HK5

The transcriptional regulation of three distinct alcohol oxidation systems, alcohol dehydrogenase (ADH)-I, ADH-IIB and ADH-IIG, in Pseudomonas putida HK5 was investigated under various induction conditions. The promoter activities of the genes involved in alcohol oxidation were determined using a transcriptional lacZ fusion promoter-probe vector. Ethanol was the best inducer for the divergent promoters of qedA and qedC, encoding ADH-I and a cytochrome c, respectively. Primary and secondary C3 and C4 alcohols and butyraldehyde specifically induced the divergent promoters of qbdBA and aldA, encoding ADH-IIB and an NAD-dependent aldehyde dehydrogenase, respectively. The qgdA promoter of ADH-IIG responded well to (S)-(+)-1,2-propanediol induction. In addition, the roles of genes encoding the response regulators exaE and agmR, located downstream of qedA, were inferred from the properties of exaE- or agmR-disrupted mutants and gene complementation tests. The gene products of both exaE and agmR were strictly necessary for qedA transcription. The mutation and complementation studies also suggested a role for AgmR, but not ExaE, in the transcriptional regulation of qbdBA (ADH-IIB) and qgdA (AGH-IIG). A hypothetical scheme describing a regulatory network, which directs expression of the three distinct alcohol oxidation systems in P. putida HK5, was derived.

Identification of an upstream regulatory sequence that mediates the transcription of mox genes in Methylobacterium extorquens AM1

A multiple A-tract sequence has been identified in the promoter regions for the mxaF, pqqA, mxaW, mxbD and mxcQ genes involved in methanol oxidation in Methylobacterium extorquens AM1, a facultative methylotroph. Site-directed mutagenesis was exploited to delete or change this conserved sequence. Promoter-xylE transcriptional fusions were used to assess promoter activity in these mutants. A fiftyfold drop in the XylE activity was observed for the mxaF and pqqA promoters without this sequence, and a five- to sixfold drop in the XylE activity was observed for the mxbD and mxcQ promoters without this sequence. Mutants were generated in the chromosomal copies in which this sequence was either deleted or altered, and these mutants were unable to grow on methanol. When one of these sequences was added to Plac of Escherichia coli, which is a weak constitutive promoter in M. extorquens AM1, the activity increased two- to threefold. These results suggest that this sequence is essential for normal expression of these genes in M. extorquens AM1, and may serve as a general enhancer element for genetic constructs in this bacterium.

Promoters and transcripts for genes involved in methanol oxidation in Methylobacterium extorquens AM1

Twenty-five genes are involved in methanol oxidation to formaldehyde by the methanol dehydrogenase system in the facultative methylotroph Methylobacterium extorquens AM1 organized in five gene clusters. RT-PCR was used to assess the transcripts for the main gene clusters that encode methanol dehydrogenase and proteins required for its activity (mxaFGJIRSACKLDEHB), and the enzymes that are required for the synthesis of the methanol dehydrogenase prosthetic group, pyrroloquinoline quinone (pqqABC/DE and the pqqFG cluster). In both cases, positive bands were obtained corresponding to mRNA spanning each of the genes in the cluster, but not across the first and last genes and the gene immediately upstream or downstream of the cluster, respectively. These results suggest that these three gene clusters are each transcribed as a single operon. Confirmation was obtained by cloning a number of intergenic regions into a promoter probe vector. None of these regions showed significant promoter activity. Promoter regions were analysed for mxaF, pqqA, orf181 upstream of pqqFG, and mxaW, a gene located upstream of mxaF and divergently transcribed. The promoter regions for these genes were defined to within 100, 46, 124 and 146 bp, respectively, and the two unknown transcriptional start sites were determined, for mxaW and orf181. Alignment of these promoter regions suggests that they all may be transcribed by the sigma(70) orthologue in M. extorquens AM1.

PqqC/D, which converts a biosynthetic intermediate to pyrroloquinoline quinone

PqqC/D was purified from Escherichia coli transformant. The purified enzyme converted an intermediate that accumulated in a pqqC mutant of Methylobacterium extorquens AM1 to PQQ. The reaction did not show any dependence of NAD(P)H that was observed in the crude extract before purification. PqqC/D reacted with the intermediate stoichiometrically, but not catalytically. When partially purified proteins from the crude extract of E. coli were added to the reaction mixture, the rate of PQQ production increased dependent on the amount of NADPH added and the total amount of PQQ produced increased.

A soluble two-component regulatory system controls expression of quinoprotein ethanol dehydrogenase (QEDH) but not expression of cytochrome c(550) of the ethanol-oxidation system in Pseudomonas aeruginosa

The regulation of the divergent promoters of the exaAB genes in Pseudomonas aeruginosa ATCC 17933, in which exaA encodes a quinoprotein ethanol dehydrogenase and exaB codes for a cytochrome c(550), was studied. Using transcriptional lacZ fusions, promoter activity during growth on several substrates was measured. These promoter-probe vectors were also used to identify regulatory mutants defective in exaAB induction. Transcription from both exaA and exaB was reduced significantly in four mutants. Two other mutants showed transcription from exaA that was reduced, but higher than wild-type transcription from exaB. The genes that are needed for exaA promoter induction were sequenced and found to encode a two-component regulatory system: a histidine sensor kinase, which lacks a transmembrane helical N-terminus and is presumably located in the cytoplasm, and a response regulator. The phenotypic characterization and restoration of the wild-type behaviour of the different regulatory mutants produced by different cosmids and subclones indicate that six different genes may be involved in regulating ethanol oxidation in P. aeruginosa.

Two-component system that regulates methanol and formaldehyde oxidation in Paracoccus denitrificans

A chromosomal region encoding a two-component regulatory system, FlhRS, has been isolated from Paracoccus denitrificans. FlhRS-deficient mutants were unable to grow on methanol, methylamine, or choline as the carbon and energy source. Expression of the gene encoding glutathione-dependent formaldehyde dehydrogenase (fhlA) was undetectable in the mutant, and expression of the S-formylglutathione hydrolase gene (fghA) was reduced in the mutant background. In addition, methanol dehydrogenase was immunologically undetectable in cell extracts of FhlRS mutants. These results indicate that the FlhRS sensor-regulator pair is involved in the regulation of formaldehyde, methanol, and methylamine oxidation. The effect that the FlhRS proteins exert on the regulation of C(1) metabolism might be essential to maintain the internal concentration of formaldehyde below toxic levels.

The biochemistry, physiology and genetics of PQQ and PQQ-containing enzymes

Pyrrolo-quinoline quinone (PQQ) is the non-covalently bound prosthetic group of many quinoproteins catalysing reactions in the periplasm of Gram-negative bacteria. Most of these involve the oxidation of alcohols or aldose sugars. PQQ is formed by fusion of glutamate and tyrosine, but details of the biosynthetic pathway are not known; a polypeptide precursor in the cytoplasm is probably involved, the completed PQQ being transported into the periplasm. In addition to the soluble methanol dehydrogenase of methylotrophs, there are three classes of alcohol dehydrogenases; type I is similar to methanol dehydrogenase; type II is a soluble quinohaemoprotein, having a C-terminal extension containing haem C; type III is similar but it has two additional subunits (one of which is a multihaem cytochrome c), bound in an unusual way to the periplasmic membrane. There are two types of glucose dehydrogenase; one is an atypical soluble quinoprotein which is probably not involved in energy transduction. The more widely distributed glucose dehydrogenases are integral membrane proteins, bound to the membrane by transmembrane helices at the N-terminus. The structures of the catalytic domains of type III alcohol dehydrogenase and membrane glucose dehydrogenase have been modelled successfully on the methanol dehydrogenase structure (determined by X-ray crystallography). Their mechanisms are likely to be similar in many ways and probably always involve a calcium ion (or other divalent cation) at the active site. The electron transport chains involving the soluble alcohol dehydrogenases usually consist only of soluble c-type cytochromes and the appropriate terminal oxidases. The membrane-bound quinohaemoprotein alcohol dehydrogenases pass electrons to membrane ubiquinone which is then oxidized directly by ubiquinol oxidases. The electron acceptor for membrane glucose dehydrogenase is ubiquinone which is subsequently oxidized directly by ubiquinol oxidases or by electron transfer chains involving cytochrome bc1, cytochrome c and cytochrome c oxidases. The function of most of these systems is to produce energy for growth on alcohol or aldose substrates, but there is some debate about the function of glucose dehydrogenases in those bacteria which contain one or more alternative pathways for glucose utilization. Synthesis of the quinoprotein respiratory systems requires production of PQQ, haem and the dehydrogenase subunits, transport of these into the periplasm, and incorporation together with divalent cations, into active quinoproteins and quinohaemoproteins. Six genes required for regulation of synthesis of methanol dehydrogenase have been identified in Methylobacterium, and there is evidence that two, two-component regulatory systems are involved.

Sequence and characterization of mxaB, a response regulator involved in regulation of methanol oxidation, and of mxaW, a methanol-regulated gene in Methylobacterium extorquens AM1

In the facultative serine cycle methylotroph Methylobacterium extorquens AM1, mxaB is required for regulation of methanol oxidation and is located at the end of a large cluster of methylotrophy genes that begins with mxaF. The sequence of mxaB has been obtained and indicates that the gene product is a member of the response regulator family. None of the open reading frames near mxaB showed sequence identity to sensor kinases. Complementation studies suggest a promoter may be located adjacent to mxaB. Another gene (mxaW) is present immediately upstream of mxaF, divergently transcribed from a methanol-inducible promoter. The sequence in the region of mxaW was also obtained. MxaW showed no identity to known proteins. Mutations in mxaW and in an adjacent open reading frame, OrfR, had no effect on growth of M. extorquens AM1 on methanol or other substrates. The MxaW mutant had normal methanol dehydrogenase activity and normal transcription of the mxaF promoter. Therefore, the function of mxaW is unknown.

pqqA is not required for biosynthesis of pyrroloquinoline quinone in Methylobacterium extorquens AM1

Methylobacterium extorquens AM1 is a facultative methylotroph that oxidizes methanol via the pyrroloquinoline quinone (PQQ)-linked enzyme methanol dehydrogenase. In M. extorquens AM1 and other PQQ-synthesizing bacteria, several genes are involved in the synthesis of PQQ and one of these, pqqA, has been proposed to encode a peptide precursor of PQQ. In other PQQ-synthesizing bacteria, pqqA is required for PQQ production. In this study, it is shown that both deletion and insertion mutants of pqqA in M. extorquens AM1 grow normally on methanol and produce PQQ. The level of PQQ production is reduced in the insertion mutant, but it is sufficient to allow normal growth on methanol. These results suggest either that a different peptide in M. extorquens AM1 can substitute for PqqA in pqqA mutants, or that PqqA-like peptides may not be obligatory precursors of PQQ. In addition, it is shown that the methanol oxidation transcriptional regulator gene, mxbM, is required for normal methanol induction of PQQ synthesis.

An RNA polymerase preparation from Methylobacterium extorquens AM1 capable of transcribing from a methylotrophic promoter

RNA polymerase (RNAP) was purified from Methylobacterium extorquens AM1 cells grown on methanol or on succinate. The beta, beta', alpha and omega subunits were approximately the same size as those of Escherichia coli, and the identity of the omega subunit was confirmed by N-terminal sequence analysis. N-terminal sequence analysis suggested that two other polypeptides in the purified RNAP preparation might be sigma factors, a 40 kDa polypeptide that shared identity with sigma 32 homologues, and a 97 kDa polypeptide that shared identity with sigma 70 homologues in other bacteria. The 97 kDa polypeptide did not cross-react with antibody to E. coli sigma 70. The same complement of putative sigma factors was found in RNAP purified from M. extorquens AM1 grown on succinate and those grown on methanol, indicating that no major methanol-inducible sigma factor is present in this strain. Run-off assays showed that the purified RNAP was capable of initiating transcription specifically at the transcriptional start site of a methylotrophic gene, mxaF, which encodes the large subunit of methanol dehydrogenase and is found only in methylotrophic bacteria.

Molecular analysis of mxbD and mxbM, a putative sensor-regulator pair required for oxidation of methanol in Methylobacterium extorquens AM1

Five genes are thought to be required for transcription of methanol oxidation genes in Methylobacterium strains. These putative regulatory genes include mxcQE, which encode a putative sensor-regulator pair, and mxbDM and mxaB, whose functions are less well-understood. In this study, mxbDM in Methylobacterium extorquens AM1 were shown to be required for expression of a xylE transcriptional fusion to the structural gene for the large subunit of methanol dehydrogenase (mxaF), confirming the role of these genes in transcriptional regulation of mxaF. The nucleotide sequence suggests that mxbD encodes a histidine protein kinase with two transmembrane domains and that mxbM encodes a DNA-binding response regulator. A xylE transcriptional fusion to the putative mxbD promoter showed low-level expression in wild-type cells grown on one-carbon (C1) compounds and no detectable expression in cells grown on succinate. Deletion analysis of this promoter construct showed that the region 229-129 bp upstream of the start of mxbD is required for expression. The expression of the mxbD-xylE fusion was examined in each of the five known regulatory mutant classes. xylE expression was reduced to non-detectable levels in MxcQ and MxcE mutants, but was not affected in the other regulatory mutants or in non-regulatory mutants defective in methanol oxidation. These results suggest a regulatory hierarchy in which the sensor-regulator pair MxcQE control expression of the sensor-regulator pair MxbDM, and MxbDM in turn control expression of a number of genes involved in methanol oxidation.

Molecular and mutational analysis of a DNA region separating two methylotrophy gene clusters in Methylobacterium extorquens AM1

A region of 14.2 kb has been analysed that is a part of a locus on the Methylobacterium extorquens AM1 chromosome containing a number of genes involved in one-carbon (C1) metabolism, including serine cycle genes, pqq genes, regulatory methanol oxidation genes and the gene for N5,N10-methylene tetrahydrofolate dehydrogenase (mtdA). Fifteen new ORFs have been identified within the new region, and their sequences suggest that they encode the following polypeptides: the C-terminal part of phosphoenolpyruvate carboxylase, malyl-CoA lyase, polypeptides of 9.4 and 31 kDa of unknown function, three putative subunits of an ABC-type transporter, two polypeptides similar to the products of mxaF and mxaJ from M. extorquens AM1 and other methylotrophs, a cytochrome c, three enzymes of folate metabolism, and polypeptides of 13 and 20.5 kDa with no homologues in the protein database. Ten insertion mutations have been generated in the region to determine if the newly identified genes are associated with C1 metabolism. A mutation in mclA, encoding malyl-CoA lyase, resulted in a C1-minus phenotype, while mutations in the other genes all showed a C1-plus phenotype. It was not possible to obtain null mutants in a putative folate metabolism gene, folC, implying the necessity of these folate synthesis genes for metabolism of C1 and multicarbon compounds. Mutations in the putative ABC transporter genes, the genes similar to mxaG and mxaJ, and other unidentified ORFs produced double-crossover recombinants with a C1-positive phenotype. Promoter regions have been investigated upstream of orf3 and orf4 using the promoter probe vector pHX200. Transcription from these promoters was weak in wild-type M. extorquens AM1 but increased in regulatory mox mutants.

Sequence analysis of pqq genes required for biosynthesis of pyrroloquinoline quinone in Methylobacterium extorquens AM1 and the purification of a biosynthetic intermediate

Methylobacterium extorquens AM1 produces pyrroloquinoline quinone (PQQ), the prosthetic group of methanol dehydrogenase. Two genes clusters have been shown to be required for PQQ biosynthesis in this micro-organism and complementation analysis has identified seven pqq genes, pqqDGCBA and pqqEF. The DNA sequence of pqqDGC' was reported previously. This paper reports the sequence of the genomic region corresponding to pqqC'BA. For consistency, the nomenclature of pqq genes in Klebsiella pneumoniae will be followed. The new nomenclature for pqq genes of M. extorquens AM1 is pqqABCDE and pqqFG. In the genomic region sequenced in this study, two open reading frames were found. One of these encodes pqqE, which showed high identity to analogous pqq genes in other bacteria. PqqE also showed identity to MoaA and NifB in the N-terminal region, where a conserved CxxxCxYC sequence was identified. The sequence of the second open reading frame covered both the pqqC and pqqD regions, suggesting that both functions were encoded by this gene. It is proposed to designate this gene pqqC/D. The deduced amino acid sequence of the pqqC/D products showed identity to PqqC of K. pneumoniae and Pqql of Acinetobacter calcoaceticus in the N-terminal region, and to PqqD of K. pneumoniae and Pqql of A. calcoaceticus in the C-terminal region. A fragment of M. extorquens AM1 DNA containing only pqqC/D produced a protein of 42 kDa in Escherichia coli, which corresponds to the size of the deduced amino acid sequence of PqqC/D, confirming the absence of a separate pqqD. This genomic region complemented the growth of pqqC mutants of M. extorquens AM1 and Methylobacterium organophilum DSM 760 on methanol. As previously reported for pqq genes of K. pneumoniae, a pqqC mutant of M. extorquens AM1 produced an intermediate of PQQ biosynthesis, which was converted to PQQ by incubation with a crude extract from E.coli cells expressing PqqC/D. The intermediate was found in both crude extract and culture supernatant, and it was purified from the crude extract. The PqqC/D enzyme reaction appeared to require molecular oxygen and reduced nicotinamide adenine dinucleotides.

Characterization and nucleotide sequence of pqqE and pqqF in Methylobacterium extorquens AM1

Methylobacterium extorquens AM1 pqqEF are genes required for synthesis of pyrroloquinoline quinone (PQQ). The nucleotide sequence of these genes indicates PqqE belongs to an endopeptidase family, including PqqF of Klebsiella pneumoniae, and M. extorquens AM1 PqqF has low identity with the same endopeptidase family. M. extorquens AM1 pqqE complemented a K. pneumoniae pqqF mutant.