Protein destabilization and loss of protein‐protein interaction are fundamental mechanisms in
            <i>cblA</i>
            ‐type methylmalonic aciduria

Plessl, Tanja; Bürer, Céline; Lutz, Seraina; Yue, Wyatt W.; Baumgartner, Matthias R.; Froese, D. Sean

doi:10.1002/humu.23251

Cited by 23 publications

(30 citation statements)

References 42 publications

(89 reference statements)

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“…45 This transfer, however, is gated by a third protein methylmalonic aciduria cblA type (MMAA), which additionally appears to protect the AdoCbl from oxidation during the MUT catalytic cycle in a guanosine triphosphate GTP dependent manner. 46,47 Mutation of MMAA in patients is described as the cblA defect, 43 and every patient mutation described to date either results in a complete loss of MMAA protein or interferes with the interaction between MMAA and MUT. 46 MUT itself catalyzes the rearrangement of L-methylmalonyl-CoA to succinyl-CoA in an AdoCbl dependent manner.…”

Section: The Mitochondrial Cobalamin Pathwaymentioning

confidence: 99%

“…46,47 Mutation of MMAA in patients is described as the cblA defect, 43 and every patient mutation described to date either results in a complete loss of MMAA protein or interferes with the interaction between MMAA and MUT. 46 MUT itself catalyzes the rearrangement of L-methylmalonyl-CoA to succinyl-CoA in an AdoCbl dependent manner. This pathway is an extension of the propionate catabolic pathway, which is required for the breakdown of the branched-chain amino acids valine, isoleucine, methionine and threonine, odd-chain fatty acids and the side chain of cholesterol, and whose product enters the tricarboxylic acid cycle as an anapleurotic substrate.…”

Section: The Mitochondrial Cobalamin Pathwaymentioning

confidence: 99%

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Vitamin B₁₂, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

Froese

Fowler

Baumgartner

2019

J of Inher Metab Disea

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284

187

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Vitamin B12 (cobalamin, Cbl) is a nutrient essential to human health. Due to its complex structure and dual cofactor forms, Cbl undergoes a complicated series of absorptive and processing steps before serving as cofactor for the enzymes methylmalonyl‐CoA mutase and methionine synthase. Methylmalonyl‐CoA mutase is required for the catabolism of certain (branched‐chain) amino acids into an anaplerotic substrate in the mitochondrion, and dysfunction of the enzyme itself or in production of its cofactor adenosyl‐Cbl result in an inability to successfully undergo protein catabolism with concomitant mitochondrial energy disruption. Methionine synthase catalyzes the methyl‐Cbl dependent (re)methylation of homocysteine to methionine within the methionine cycle; a reaction required to produce this essential amino acid and generate S‐adenosylmethionine, the most important cellular methyl‐donor. Disruption of methionine synthase has wide‐ranging implications for all methylation‐dependent reactions, including epigenetic modification, but also for the intracellular folate pathway, since methionine synthase uses 5‐methyltetrahydrofolate as a one‐carbon donor. Folate‐bound one‐carbon units are also required for deoxythymidine monophosphate and de novo purine synthesis; therefore, the flow of single carbon units to each of these pathways must be regulated based on cellular needs. This review provides an overview on Cbl metabolism with a brief description of absorption and intracellular metabolic pathways. It also provides a description of folate‐mediated one‐carbon metabolism and its intersection with Cbl at the methionine cycle. Finally, a summary of recent advances in understanding of how both pathways are regulated is presented.

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Section: The Mitochondrial Cobalamin Pathwaymentioning

confidence: 99%

Section: The Mitochondrial Cobalamin Pathwaymentioning

confidence: 99%

Vitamin B₁₂, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

Froese

Fowler

Baumgartner

2019

J of Inher Metab Disea

Self Cite

284

187

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“…FoldX calculation were performed 5 times and averaged for each mutation. 8 6 Highest destabilization (−ΔT m = −8.8 °C) 1.55 Å [ 114 ] Protein stabilization Growth factor 2 ( Homo sapiens ) Cut off (ΔΔG < −1 kcal mol − 1) 5 2 Stabilization ΔT m = 3.7 °C 1.6 Å [ 115 ] Flavin mononucleotide based fluorescent Protein ( Bacillus subtilis ) Cut off (ΔΔG < −1 kcal mol −1 ) performed additionally further pre-selections 22 15 Stabilization ΔT m = 11.4 °C Resolution under 2.2 Å [ 116 ] Endolysin PlyC ( Bacteriophage ) Cut off (ΔΔG < −1 kcal mol −1 ) 92 mutants were determined by FoldX and reduced by visual inspection and by Rosetta 12 3 Stabilization ΔT m = 2.2 °C 3.3 Å refined using Rosetta Relax [ 117 ] Database (known mutations) Cut off value ΔΔG < −1.0 kcal mol −1 30 20 n.d. 1.5 to 2.25 Å [ 87 ] Protein destabilization Repair protein MSH2 ( Homo sapiens ) Cut off value (ΔΔG > 5 kcal mol −1 ) 24 22 Destabilization of >3 kcal mol −1 3.3 Å [ 85 ] cblA -Type methylmalonic aciduria ( Homo sapiens ) Cut off value ΔΔG between 3.48 and 11.15 kcal mol −1 22 22 – 2.64 Å [ 118 ] Investigation of proline influence on stability Fungal chimeric cellobiohydrolase Cel6A ( Humicola insolens ) ΔΔG of exchanges of wild type amino acid against Pro exchange was calculated ...…”

Section: Un/folding Energy Algorithmsmentioning

confidence: 99%

FoldX as Protein Engineering Tool: Better Than Random Based Approaches?

Buß

Rudat

Ochsenreither

2018

Computational and Structural Biotechnology Journal

200

125

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Improving protein stability is an important goal for basic research as well as for clinical and industrial applications but no commonly accepted and widely used strategy for efficient engineering is known. Beside random approaches like error prone PCR or physical techniques to stabilize proteins, e.g. by immobilization, in silico approaches are gaining more attention to apply target-oriented mutagenesis. In this review different algorithms for the prediction of beneficial mutation sites to enhance protein stability are summarized and the advantages and disadvantages of FoldX are highlighted. The question whether the prediction of mutation sites by the algorithm FoldX is more accurate than random based approaches is addressed.

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“…MCM, an adenosylcobalamin-dependent enzyme, have a function in isomerization of L-methylmalonyl-CoA to succinyl-CoA, for entry into the tricarboxylic acid cycle for energy production. All mutations of MMAA strongly decreased functional association with MUT and interfered with gating the transfer of AdoCbl from MMAB to MUT, which is a disease-causing mechanism of cblA type MMA (6). The MMAB gene encodes the mitochondrial enzyme ATP: cobalamin adenosyl transferase (ATR), which catalyzes transfer of an adenosyl group from ATP to cobalamin (I) to form AdoCbl.…”

Section: Etiology and Pathogenesismentioning

confidence: 99%

Methylmalonic acidemia: Current status and research priorities

Zhou

Cui

Han

2018

IRDR

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Methylmalonic acidemia (MMA) is a lethal, severe heterogeneous disorder of methylmalonate and cobalamin (cbl; vitamin B12) metabolism with poor prognosis. Two main forms of the disease have been identified, isolated methylmalonic acidurias and combined methylmalonic aciduria and homocystinuria, which is respectively caused by different gene mutations. Here, we review the improvement of pathogenesis, diagnosis and treatment in MMA. Importantly, the reported epidemiological data of MMA patients in China and the hot mutation sites in Chinese patients are listed, which will aid in improving healthcare of Chinese patients in the future. c.729_730insTT was the most common mutation in Chinese isolated MMA patients, while c.609G>A and c.658_660delAAG were in Chinese cblC type patients according to unrelated studies. The estimated newborn screening incidence was reported to be 1:26,000, 1:3,920, 1:11,160, 1:6,032 respectively in Beijing and Shanghai, Shandong province, Taian district, and Henan province of China. Alternatively, when patients with suspected inherited metabolic diseases were used as the screened sample, the relatively high incidence 0.3% and 1.32% were respectively obtained in southern China and throughout all the provinces of mainland China and Macao with the exception of five provinces (Hainan, Neimenggu, Tibet, Ningxia, and Hong Kong).

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Protein destabilization and loss of protein‐protein interaction are fundamental mechanisms in cblA ‐type methylmalonic aciduria

Cited by 23 publications

References 42 publications

Vitamin B₁₂, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

Vitamin B₁₂, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

FoldX as Protein Engineering Tool: Better Than Random Based Approaches?

Methylmalonic acidemia: Current status and research priorities

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Protein destabilization and loss of protein‐protein interaction are fundamental mechanisms in cblA ‐type methylmalonic aciduria

Cited by 23 publications

References 42 publications

Vitamin B12, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

Vitamin B12, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

FoldX as Protein Engineering Tool: Better Than Random Based Approaches?

Methylmalonic acidemia: Current status and research priorities

Contact Info

Product

Resources

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Vitamin B₁₂, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation

Vitamin B₁₂, folate, and the methionine remethylation cycle—biochemistry, pathways, and regulation