Catalytic mechanism of quinoprotein methanol dehydrogenase: A theoretical and x-ray crystallographic investigation

Zheng, Y.-J.

doi:10.1073/pnas.021547498

Cited by 22 publications

(39 citation statements)

References 5 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…(a) Structure of the PQQ prosthetic group. (b) Hydride transfer mechanism for methanol oxidation in PQQ-dependent MDH enzymes [49]. Asp297 is located in the large, catalytic a subunit.…”

Section: Mdh Genes For Synthetic Methylotrophy In the Patent Literaturementioning

confidence: 99%

Synthetic methylotrophy: engineering the production of biofuels and chemicals based on the biology of aerobic methanol utilization

Whitaker

Sandoval

Bennett

et al. 2015

Current Opinion in Biotechnology

153

135

View full text Add to dashboard Cite

Synthetic methylotrophy is the development of non-native methylotrophs that can utilize methane and methanol as sole carbon and energy sources or as co-substrates with carbohydrates to produce metabolites as biofuels and chemicals. The availability of methane (from natural gas) and its oxidation product, methanol, has been increasing, while prices have been decreasing, thus rendering them as attractive fermentation substrates. As they are more reduced than most carbohydrates, methane and methanol, as co-substrates, can enhance the yields of biologically produced metabolites. Here we discuss synthetic biology and metabolic engineering strategies based on the native biology of aerobic methylotrophs for developing synthetic strains grown on methanol, with Escherichia coli as the prototype.

show abstract

“…(a) Structure of the PQQ prosthetic group. (b) Hydride transfer mechanism for methanol oxidation in PQQ-dependent MDH enzymes [49]. Asp297 is located in the large, catalytic a subunit.…”

Section: Mdh Genes For Synthetic Methylotrophy In the Patent Literaturementioning

confidence: 99%

Synthetic methylotrophy: engineering the production of biofuels and chemicals based on the biology of aerobic methanol utilization

Whitaker

Sandoval

Bennett

et al. 2015

Current Opinion in Biotechnology

153

135

View full text Add to dashboard Cite

show abstract

“…In addition, the structure used in the cryoEM model is that of MDH from the methylotroph Methylophilus methylotrophus W3A1. 34 , 35 The structure of the cognate M. capsulatus (Bath) MDH has not been determined, hindering further consideration of the structural model. Moreover, the enhancement of pMMO propylene epoxidation activity by the presence of MDH could not be reconstituted by combining purified pMMO and MDH, and formation of a complex between purified pMMO and MDH has not been reported.…”

mentioning

confidence: 99%

Structure and Protein–Protein Interactions of Methanol Dehydrogenase from Methylococcus capsulatus (Bath)

Culpepper

Rosenzweig

2014

Biochemistry

View full text Add to dashboard Cite

In the initial steps of their metabolic pathway, methanotrophic bacteria oxidize methane to methanol with methane monooxygenases (MMOs) and methanol to formaldehyde with methanol dehydrogenases (MDHs). Several lines of evidence suggest that the membrane-bound or particulate MMO (pMMO) and MDH interact to form a metabolic supercomplex. To further investigate the possible existence of such a supercomplex, native MDH from Methylococcus capsulatus (Bath) has been purified and characterized by size exclusion chromatography with multi-angle light scattering and X-ray crystallography. M. capsulatus (Bath) MDH is primarily a dimer in solution, although an oligomeric species with a molecular mass of ∼450–560 kDa forms at higher protein concentrations. The 2.57 Å resolution crystal structure reveals an overall fold and α2β2 dimeric architecture similar to those of other MDH structures. In addition, biolayer interferometry studies demonstrate specific protein–protein interactions between MDH and M. capsulatus (Bath) pMMO as well as between MDH and the truncated recombinant periplasmic domains of M. capsulatus (Bath) pMMO (spmoB). These interactions exhibit KD values of 833 ± 409 nM and 9.0 ± 7.7 μM, respectively. The biochemical data combined with analysis of the crystal lattice interactions observed in the MDH structure suggest a model in which MDH and pMMO associate not as a discrete, stoichiometric complex but as a larger assembly scaffolded by the intracytoplasmic membranes.

show abstract

“…The methanol dehydrogenase in methylotrophic bacteria is MXAF-type MDH, which is a quinone protein with PQQ as a prosthetic group (21). It serves as the vital enzyme for the methylotrophic bacteria, which facilitates methanol utilization to generate energy for bacterial growth (22).…”

Section: Discussionmentioning

confidence: 99%

Mechanism of PQQ and CoQ10 overproduction in Methylobacterium as revealed by comparative genomic analysis between mutant and wild-type strains

Zhao¹,

Wan²,

Cao³

et al. 2020

Preprint

View full text Add to dashboard Cite

Background The microbial synthesis of pyrroloquinoline quinone (PQQ) and Coenzyme Q10 (CoQ10) remains the most promising industrial production route. Methylobacterium has been used to generate PQQ and other value-added chemicals from cheap carbon feedstocks.However, the low PQQ and CoQ10 production capacity of the Methylobacterium strains is a major limitation The regulation mechanism for PQQ and CoQ10 biosynthesis in this strain has also not been fully elucidated. Results Methylobacterium sp. CLZ strain was isolated from soil contaminated with chemical wastewater, which can simultaneously produce PQQ, CoQ10, and carotenoids by using cheap methanol as carbon source. We investigated a mutant strain NI91, which increased the PQQ and CoQ10 yield by 72.44% and 59.80%, respectively. Whole-genome sequencing of NI91 and wild-type strain CLZ revealed that both contain a 5.28 Mb chromosome. The comparative genomic analysis and validation study revealed that a significant increase in biomass and PQQ production was associated with the base mutations in the methanol dehydrogenase (MDH) synthesis genes, mxaD and mxaJ. The significant increase in CoQ10 production may be associated with the base mutations in dxs gene, a key gene in the MEP/DOXP pathway. Conclusions A PQQ producing strain that simultaneously produces CoQ10 and carotenoids was selected and after ANI analysis, named as Methylobacterium sp. CLZ. After random mutagenesis of this strain, we obtained NI91 strain, which showed increased production of PQQ and CoQ10. Based on comparative genomic analysis of the whole genome of mutant strain NI91 and wild-type strain CLZ, a total of 270 SNPs and InDels events were detected, which provided a reference for subsequent research. The mutations in mxaD, mxaJ and dxs genes may be related to the high yield of PQQ and CoQ10. These findings will enhance our understanding of the PQQ and CoQ10 over-production mechanism in Methylobacterium sp. NI91 at the genomic level. It will also provide useful clues for strain engineering in order to improve the PQQ and CoQ10 production.

show abstract

Catalytic mechanism of quinoprotein methanol dehydrogenase: A theoretical and x-ray crystallographic investigation

Cited by 22 publications

References 5 publications

Synthetic methylotrophy: engineering the production of biofuels and chemicals based on the biology of aerobic methanol utilization

Synthetic methylotrophy: engineering the production of biofuels and chemicals based on the biology of aerobic methanol utilization

Structure and Protein–Protein Interactions of Methanol Dehydrogenase from Methylococcus capsulatus (Bath)

Mechanism of PQQ and CoQ10 overproduction in Methylobacterium as revealed by comparative genomic analysis between mutant and wild-type strains

Contact Info

Product

Resources

About