Cloning and sequencing of the gene coding for the large subunit of methylamine dehydrogenase from Thiobacillus versutus

Cloning, sequencing and mutagenesis of the genes for aromatic amine dehydrogenase from Alcaligenes faecalis and evolution of amine dehydrogenases

The nucleotide sequence of the aromatic amine utilization (aau) gene region from Alcaligenes faecalis contained nine genes (orf-1, aauBEDA, orf-2, orf-3, orf-4 and hemE) transcribed in the same direction. The aauB and aauA genes encode the periplasmic aromatic amine dehydrogenase (AADH) large and small subunit polypeptides, respectively, and were homologous to mauB and mauA, the genes for the large and small subunits of methylamine dehydrogenase (MADH). aauE and aauD are homologous to mauE and mauD and apparently carry out the same function of transport and folding of the small subunit polypeptide in the periplasm. No analogues of the mauF, mauG, mauL, mauM and mauN genes responsible for biosynthesis of tryptophan tryptophylquinone (the prosthetic group of amine dehydrogenases) were found in the aau cluster. orf-2 was predicted to encode a small periplasmic monohaem c-type cytochrome. No biological function can be assigned to polypeptides encoded by orf-1, orf-3 and orf-4 and mutations in these genes appeared to be lethal. Mutants generated by insertions into mauD were not able to use phenylethylamine, tyramine and tryptamine as a source of carbon and phenylethylamine, 3'-hydroxytyramine (dopamine) and tyramine as a source of nitrogen, indicating that AADH is the only enzyme involved in utilization of primary amines in A. faecalis. AADH genes are present in Alcaligenes xylosoxydans subsp. xylosoxydans, but not in other beta- and gamma-proteobacteria. Phylogenetic analysis of amine dehydrogenases (MADH and AADH) indicated that AADH and MADH evolutionarily diverged before separation of proteobacteria into existing subclasses.

Molecular genetics of the genus Paracoccus: metabolically versatile bacteria with bioenergetic flexibility

Paracoccus denitrificans and its near relative Paracoccus versutus (formerly known as Thiobacilllus versutus) have been attracting increasing attention because the aerobic respiratory system of P. denitrificans has long been regarded as a model for that of the mitochondrion, with which there are many components (e.g., cytochrome aa3 oxidase) in common. Members of the genus exhibit a great range of metabolic flexibility, particularly with respect to processes involving respiration. Prominent examples of flexibility are the use in denitrification of nitrate, nitrite, nitrous oxide, and nitric oxide as alternative electron acceptors to oxygen and the ability to use C1 compounds (e.g., methanol and methylamine) as electron donors to the respiratory chains. The proteins required for these respiratory processes are not constitutive, and the underlying complex regulatory systems that regulate their expression are beginning to be unraveled. There has been uncertainty about whether transcription in a member of the alpha-3 Proteobacteria such as P. denitrificans involves a conventional sigma70-type RNA polymerase, especially since canonical -35 and -10 DNA binding sites have not been readily identified. In this review, we argue that many genes, in particular those encoding constitutive proteins, may be under the control of a sigma70 RNA polymerase very closely related to that of Rhodobacter capsulatus. While the main focus is on the structure and regulation of genes coding for products involved in respiratory processes in Paracoccus, the current state of knowledge of the components of such respiratory pathways, and their biogenesis, is also reviewed.

Refined crystal structure of methylamine dehydrogenase from Paracoccus denitrificans at 1.75 A resolution

The three-dimensional structure of the quinoprotein methylamine dehydrogenase from Paracoccus denitrificans has been refined at 1.75 A resolution utilizing the DNA-based protein sequence. The final model incorporates 8034 atoms per molecule, including 552 molecules of solvent, and gives an R-factor of 0.163. The molecule is an H2L2 hetero-tetramer containing a non-crystallographic 2-fold axis of symmetry. The 373-residue H subunit is folded into seven repeats of a four-stranded antiparallel beta-sheet motif, arranged in a propeller-like pattern about a pseudo-7-fold rotational axis of symmetry. Each L subunit contains 131 residues folded in a tight structure composed of five beta-strands in two sheets and crosslinked by six disulfide bonds. In addition there is an intrasubunit covalent linkage between two tryptophan side-chains that form the unique redox center, tryptophan tryptophylquinone (TTQ). The active site contains the O-6 carbonyl of TTQ, the side-chains of Asp32L Asp76L, Tyr119L and Thr122L, and two solvent molecules. A potential "gate" (Phe55H) separates the closed active-site cavity from a channel containing a group of highly ordered water molecules to bulk solvent. Phe55H and Tyr119L, and a number of neighboring oxygen atoms, may also provide a binding site for monovalent cations that are known to affect the reactivity and spectral properties of TTQ as well as the oxidative half reaction. The overall reaction has been dissected into a number of discrete steps that may require participation by several individual amino acid residues in the active site acting as general acids and bases.

Organization of methylamine utilization genes (mau) in 'Methylobacillus flagellatum ' KT and analysis of mau mutants

The organization of genes involved in utilization of methylamine (mau genes) was studied in the obligate methylotroph 'Methylobacillus flagellatum' KT. Nine open reading frames were identified as corresponding to the genes mauFBEDAGLMN. In addition, an open reading frame (orf-1 encoding a polypeptide with unknown function was identified upstream of the mau gene cluster. Subclones of the 'M. flagellatum' KT gene cluster were used for complementation of a series of chemically induced mau mutants of 'M. flagellatum' KT. Mutants in mauF, mauB, mauE/D, mauA, mauG, mauL and mauM were identified. Two mutants (mau-18 and mau-19) were not complemented by the known mau genes. Since none of the chemically induced mutants studies had a defect of orf-1 or mauN, inserting mutants in these genes were constructed. Phenotypically the mutants fell into three groups. The mauF, mauB, mauE/D, mauA, mauG, mauL and mauM mutants do not grow on methylamine as a source of carbon and lack methylamine dehydrogenase activity, but they synthesize both the large and the small subunit polypeptides albeit at different ratios. The mau-18 and mau-19 mutants do not grow on methylamine as a source of carbon, and lack both methylamine dehydrogenase activity and the methylamine dehydrogenase subunits. The orf-1 and mauN mutants grow on methylamine as a source of carbon and synthesize wild-type levels of methylamine dehydrogenase. It has been shown earlier that the product of the mauM gene is not required for synthesis of active methylamine dehydrogenase in Methylobacterium extorquens AM1 and Paracoccus denitrificans. However, MauM is required for synthesis of functional methylamine dehydrogenase in 'M. flagellatum'.

Expression of the mau gene cluster of Paracoccus denitrificans is controlled by MauR and a second transcription regulator

The mau gene cluster of Paracoccus denitrificans constitutes 11 genes (10 are located in the transcriptional order mauFBEDACJGMN; the 11th, mauR, is located upstream and divergently transcribed from these genes) that encode a functional methylamine-oxidizing electron transport branch. The mauR gene encodes a LysR-type transcriptional activator essential for induction of the mau operon. In this study, the characteristics of that process were established. By using lacZ transcriptional fusions integrated into the genome of P. denitrificans, it was found that the expression of the mauR gene during growth on methylamine and/or succinate was not autoregulated, but proceeded at a low and constant level. The mauF promoter activity was shown to be controlled by MauR and a second transcriptional regulator. This activity was very high during growth on methylamine, low on succinate plus methylamine, and absent on succinate alone. MauR was overexpressed in Escherichia coli by using a T7 RNA polymerase expression system. Gel shift assays indicated that MauR binds to a 403 bp DNA fragment spanning the mauR-mauF promoter region. It is concluded from these results that the expression of the structural mau genes is dependent on MauR and its inducer, methylamine, as well as on another transcription factor. Both activators are required for high-level transcription from the mauF promoter. It is hypothesized that the two activators act synergistically to activate transcription: the effects of the two activators are not additive and either one alone activates the mauF promoter rather weakly.

Mutational analysis of mau genes involved in methylamine metabolism in Paracoccus denitrificans

A chromosomal fragment containing DNA downstream from mauC was isolated from Paracoccus denitrificans. Sequence analysis of this fragment revealed the presence of four open reading frames, all transcribed in the same direction. The products of the putative genes were found to be highly similar to MauJ, MauG, MauM and MauN of Methylobacterium extorquens AM1. Using these four mau genes, 11 mau genes have been cloned from P. denitrificans to date. The gene order is mauRFBEDACJGMN, which is similar to that in M. extorquens AM1. mauL, present in M. extorquens AM1, seems to be absent in P. denitrificans. MauJ is predicted to be a cytoplasmic protein, and MauG a periplasmic protein. The latter protein contains two putative heme-binding sites, and has some sequence resemblance to the cytochrome c peroxidase from Pseudomonas aeruginosa. MauM is also predicted to be located in the periplasm, but MauN appears to be membrane associated. Both resemble ferredoxin-like proteins and contain four and two motifs, respectively, characteristic for [4Fe-4S] clusters. Inactivation of mauA, mauJ, mauG, mauM and mauN was carried out by introduction of unmarked mutations in the chromosomal copies of these genes. mauA and mauG mutant strains were unable to grow on methylamine. The mauJ mutant strain had an impaired growth rate and showed a lower dye-linked methylamine dehydrogenase (MADH) activity than the parent strain. Mutations in mauM and mauN had no effect on methylamine metabolism. The mauA mutant strain specifically lacked the beta subunit of MADH, but the alpha subunit and amicyanin, the natural electron acceptors of MADH, were still produced. The mauG mutant strain synthesized the alpha and beta subunits of MADH as well as amicyanin. However, no dye-linked MADH activity was found in this mutant strain. In addition, as the wild-type enzyme displays a characteristic fluorescence emission spectrum upon addition of methylamine, this property was lost in the mauG mutant strain. These results clearly show that MauG is essential for the maturation of the beta subunit of MADH, presumably via a step in the biosynthesis of tryptophan tryptophylquinone, the cofactor of MADH. The mau gene cluster mauRFBEDACJGMN was cloned on the broad-host vector pEG400. Transfer of this construct to mutant strains which were unable to grow on methylamine fully restored their ability to grow on this compound. A similar result was achieved for the closely related bacterium Thiosphaera pantotropha, which is unable to utilize methylamine as the sole sources of carbon and energy.

Expression of the mau genes involved in methylamine metabolism in Paracoccus denitrificans is under control of a LysR-type transcriptional activator

Expression of methylamine dehydrogenase in Paracoccus denitrificans and its concomitant ability to grow on methylamine is regulated by a substrate-induction mechanism as well as by a catabolite-repression-like mechanism. Methylamine dehydrogenase is synthesized in cells growing on either methylamine or ethylamine, but not during growth on succinate, methanol or choline as sole sources of carbon and energy. The synthesis of methylamine dehydrogenase is repressed when succinate is added to the growth medium in addition to methylamine. Repression is not observed when the growth medium contains methylamine and either choline or methanol. Induction of the mau genes encoding methylamine dehydrogenase is under control of the mauR gene. This regulatory gene is located directly in front of, but with the transcription direction opposite to that of, the structural genes in the mau cluster. The mauR gene encodes a LysR-type transcriptional activator. Inactivation of the gene results in loss of the ability to synthesize methylamine dehydrogenase and amicyanin, and loss of the ability to grow on methylamine. The mutation is completely restored when the mauR gene is supplied in trans. The first gene of the cluster of mau genes that is under control of MauR is mauF, which encodes a putative membrane-embedded protein. Inactivation of the gene results in the inability of cells to grow on methylamine. Downstream from mauF and in the same transcription direction, mauB is located. This gene encodes the large subunit of methylamine dehydrogenase.

Genetic organization of the mau gene cluster in Methylobacterium extorquens AM1: complete nucleotide sequence and generation and characteristics of mau mutants

The nucleotide sequence of the methylamine utilization (mau) gene region from Methylobacterium extorquens AM1 was determined. Open reading frames for 11 genes (mauFBEDACJGLMN) were found, all transcribed in the same orientation. The mauB, mauA, and mauC genes encode the periplasmic methylamine dehydrogenase (MADH) large and small subunit polypeptides and amicyanin, respectively. The products of mauD, mauG, mauL, and mauM were also predicted to be periplasmic. The products of mauF, mauE, and mauN were predicted to be membrane associated. The mauJ product is the only polypeptide encoded by the mau gene cluster which is predicted to be cytoplasmic. Computer analysis showed that the MauG polypeptide contains two putative heme binding sites and that the MauM and MauN polypeptides have four and two FeS cluster signatures, respectively. Mutants generated by insertions in mauF, mauB, mauE, mauD, mauA, mauG, and mauL were not able to grow on methylamine or any other primary amine as carbon sources, while a mutant generated from an insertion in mauC was not able to utilize methylamine as a source of carbon but utilized C2 to C4 n-alkylamines as carbon sources. Insertion mutations in mauJ, mauM, and mauN did not impair the ability of the mutants to utilize primary n-alkylamines as carbon sources. All mau mutants were able to utilize methylamine as a nitrogen source, implying the existence of an alternative (methyl)amine oxidation system, and a low activity of N-methylglutamate dehydrogenase was detected. The mauD, mauE, and mauF mutants were found to lack the MADH small subunit polypeptide and have a decreased amount of the MADH large subunit polypeptide. In the mauG and mauL mutants, the MADH large and small subunit polypeptides were present at wild-type levels, although the MADHs in these strains were not functional. In addition, MauG has sequence similarity to cytochrome c peroxidase from Pseudomonas sp. The mauA, mauD, and mauE genes from Paracoccus denitrificans and the mauD and mauG genes from Methylophilus methylotrophus W3A1 were able to complement corresponding mutants of M. extorquens AM1, confirming their functional equivalence. Comparison of amino acid sequences of polypeptides encoded by mau genes from M. extorquens AM1, P. denitrificans, and Thiobacillus versutus shows that they have considerable similarity.

Organization of the methylamine utilization (mau) genes in Methylophilus methylotrophus W3A1-NS

The organization of genes involved in utilization of methylamine (mau genes) was studied in Methylophilus methylotrophus W3A1. The strain used was a nonmucoid variant termed NS (nonslimy). The original mucoid strain was shown to be identical to the NS strains on the basis of chromosomal digest and hybridization patterns. An 8-kb PstI fragment of the chromosome from M. methylotrophus W3A1-NS encoding the mau genes was cloned and a 6,533-bp region was sequenced. Eight open reading frames were found inside the sequenced area. On the basis of a high level of sequence identity with the Mau polypeptides from Methylobacterium extorquens AM1, the eight open reading frames were identified as mauFBEDAGLM. The mau gene cluster from M. methylotrophus W3A1 is missing two genes, mauC (amicyanin) and mauJ (whose function is unknown), which have been found between mauA and mauG in all studied mau gene clusters. Mau polypeptides sequenced so far from five different bacteria show considerable identity. A mauA mutant of M. methylotrophus W3A1-NS that was constructed lost the ability to grow on all amines as sources of nitrogen but still retained the ability to grow on trimethylamine as a source of carbon. Thus, unlike M. extorquens AM1 and Methylobacillus flagellatum KT, M. methylotrophus W3A1-NS does not have an additional methylamine dehydrogenase system for amine oxidation. Using a promoter-probe vector, we identified a promoter upstream of mauF and used it to construct a potential expression vector, pAYC229.

Kinetics of the reduction of wild-type and mutant cytochrome c-550 by methylamine dehydrogenase and amicyanin from Thiobacillus versutus

To elucidate the kinetic properties of the methylamine dehydrogenase (MADH) redox chain of Thiobacillus versutus the reduction of cytochrome c-550 by MADH and amicyanin has been studied. Under steady state conditions, the rate constants of the reactions have been determined as a function of the ionic strength, both for wild type cytochrome c-550 and for mutants in which the conserved residue Lys14 has been replaced as follows: Lys14-->Gln (mutant [K14Q]cytochrome c-550) and Lys14-->Glu (mutant [K14E]cytochrome c-550). The second-order rate constant of the reduction of cytochrome c-550 by MADH shows a biphasic ionic-strength dependence. At low ionic strength the rate constant remains unchanged (wild type) or increases ([K14Q]cytochrome c-550) with increasing ionic strength, while at high salt concentrations the rate constant decreases monotonically as the ionic strength increases. It is suggested that conformational freedom exists in the association complex and that this is favourable for electron transfer. [K14Q]cytochrome c-550 and [K14E]cytochrome c-550 are reduced at rates 20-fold and 500-fold slower than wild-type cytochrome c-550 by MADH, due to a lower association constant. It is concluded that MADH possesses a negative patch with which cytochrome c-550 associates. Lys14 plays an important role in the formation of the reaction complex. The midpoint potentials of wild-type and mutant cytochrome c-550 have been determined by using cyclic voltammetry. [K14Q]cytochrome c-550 and [K14E]cytochrome c-550 show an increase in E0 of only 2 mV and 8 mV, respectively, compared to wild-type cytochrome c-550 (241 mV at pH 8.1). [K14Q]cytochrome c-550 and [K14E]cytochrome c-550 cytochrome c-550 are reduced by amicyanin at rates that are only slightly faster than for wild-type cytochrome c-550. The difference is partly attributable to the change in E0. High ionic strength results in a threefold increase in the rate in all three cases. These results indicate that charge interactions do not play a major role in the formation of the amicyanin/cytochrome c-550 reaction complex, suggesting an interaction at the hydrophobic patch of amicyanin. The reduction of cytochrome c-550 by MADH can be inhibited by Zn(2+)-substituted amicyanin. Ag(+)-amicyanin, however, has little effect on the reduction rate. These results suggest that MADH has a much higher affinity for Cu(2+)-amicyanin (substrate) than for Cu(+)-amicyanin (product). On the basis of these findings the roles of the components of the MADH redox chain are discussed.