• Journal of Microbiology and Biotechnology
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• 제30권8호
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• pp.1261-1271
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• 2020

Cytochrome c_L (Cytc_L) is an essential protein in the process of methanol oxidation in methylotrophs. It receives an electron from the pyrroloquinoline quinone (PQQ) cofactor of methanol dehydrogenase (MDH) to produce formaldehyde. The direct electron transfer mechanism between Cytc_L and MDH remains unknown due to the lack of structural information. To help gain a better understanding of the mechanism, we determined the first crystal structure of heme c containing Cytc_L from the aquatic methylotrophic bacterium Methylophaga aminisulfidivorans MP^T at 2.13 Å resolution. The crystal structure of Ma-Cytc_L revealed its unique features compared to those of the terrestrial homologues. Apart from Fe in heme, three additional metal ion binding sites for Na⁺, Ca⁺, and Fe²⁺ were found, wherein the ions mostly formed coordination bonds with the amino acid residues on the loop (G93-Y111) that interacts with heme. Therefore, these ions seemed to enhance the stability of heme insertion by increasing the loop's steadiness. The basic N-terminal end, together with helix α4 and loop (G126 to Y136), contributed positive charge to the region. In contrast, the acidic C-terminal end provided a negatively charged surface, yielding several electrostatic contact points with partner proteins for electron transfer. These exceptional features of Ma-Cytc_L, along with the structural information of MDH, led us to hypothesize the need for an adapter protein bridging MDH to Cytc_L within appropriate proximity for electron transfer. With this knowledge in mind, the methanol oxidation complex reconstitution in vitro could be utilized to produce metabolic intermediates at the industry level.

• Archives of Pharmacal Research
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• 제14권4호
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• pp.325-329
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• 1991

Effects of Lycii Fructus on primary cultured chicken embryonic brain cells were studied by microscopic observation, determination of the activity of pyruvate dehydrogenase complex (PDHC), and syntheses of protein, RNA and DNA. The brain cells were prepared from the brains or 10-day-old chicken embryos and cultured with a deficient medium. The activity of PDHC in the brain cells cultured with a deficient medium was increased to 1.8 times by the addition of $30\;{\mu}g/ml$ of the total methanol extract of Lycii Fructus. To seek the active fraction, total methanol extract was further fractionated by the polarity. The survival rate of neuronal cells was significantly increased by the addition of $100\;{\mu}g/ml$ of the buthanol or aqueous fraction. At this concentration, the significant increase of the syntheses of protein and RNA, but not of DNA, indicates that the fractions may act on the neuronal cells which are known to be non-dividing cells.

• 미생물학회지
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• 제31권3호
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• pp.179-183
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• 1993

A restricted facultatively methanol-oxidizing bacterium, Methylovorus sp. strain SS1, was isolate dfrom soil samples from Kuala Lumpur, Malaysia, through methanol-enrichment culture technique. The isolate was nonmotile Gram-negative rod and did not have complex internal membrane system. The colonies were small, pale-yellow, and raised convex with entire margin. The cell did not produce any spores and capsular materials. The cell was obligately aerobic and exhibited catalase, but no oxidase, activity. Plasmid, carotenoid pigment, and poly-.betha.-hydroxybutyric acid were not found. The guanine plus cytosine content of the DNA was 55%. The isolate was found to grow only on methanol methylamine, or glucose. Growth factors were not required. Cells growing on methanol was found to produce extracellular polysaccharides containing glucose, lactose, and fructose. Growth was optimal (t$_{d}$= 1.7) with 0.5%(v/v) methanol at 40.deg.C and pH 6.5. No Growth was observed at over 60.deg.C. Cell-free extracts of the methanol grown cells exhibited the phenazine methosulfate-linked methanol dehydrogenase activity Methanol was found to be assimilate dthrough the ribulose monophosphate pathway.y.

• 약학회지
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• 제34권6호
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• pp.447-456
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• 1990

Various methods are available for the production of L-threonine. The microbial production of L-threonine has been achieved by breeding L-threonine analog-resistant auxotrophic mutants of various bacteria. The enzymatic production of L-threonine has been demonstrated by use of threonine metabolic enzymes such as threonine deaminase, threonine aldolase, or threonine dehydrogenase complex. Threonine synthesis from glycine and ethanol seems to be catalyzed by the enzymes Methanol dehydrogenase(MDH) and Serine hydroxymethyltransferase(SHMT), which was also found to catalyze the aldol condensation of glycine with acetaldehyde. The improved production of L-threonine has been achieved by amplifying the genes for the L-threonine biosynthetic enzymes using recombinant DNA techniques.

• 대한환경공학회지
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• 제33권9호
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• pp.662-669
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• 2011

본 연구에서는 메탄의 생물학적 메탄올 전환에 관한 연구를 수행하였다. 바이오가스 중의 메탄은 메탄산화균의 methane monooxygenase (MMO)의 생물학적 촉매반응에 의해 산화되었으며, 인산염, NaCl, $NH_4Cl$, EDTA와 같은 methanol dehydrogenase (MDH)의 활성 저해제를 이용하여 MDH의 활성도를 저해함으로써 메탄올의 전환이 이루어졌다. 메탄산화균은 $35^{\circ}C$, pH 7, 인공 바이오가스($CH_4$ 50%, $CO_2$ 50%) / Air의 부피비가 0.4인 조건에서 메탄 산화 정도가 0.56 mmol로 최대로 나타났다. 인산염 40 mM, NaCl 50 mM, $NH_4Cl$ 40 mM, EDTA $150{\mu}m$ 이하일 때 저해제의 종류에 상관없이 메탄 산화율은 80% 이상을 달성하였다. 한편, 인산염 40 mM, NaCl 100 mM, $NH_4Cl$ 40 mM, EDTA $50{\mu}m$ 주입 시 각각 1.30, 0.67, 0.74, 1.30 mmol의 메탄이 산화되는 동시에 각각 0.71, 0.60, 0.66, 0.66 mmol의 메탄올이 최대로 생성되었다. 이때의 메탄올 전환율은 각각 54.7, 89.9, 89.6 및 47.8%였으며 최대 메탄올 생성 속도는 $7.4{\mu}mol/mg{\cdot}h$였다. 이로부터 대상 저해제로 MDH 활성도를 일반적으로 35% 저해 시에 메탄올 생산량이 최대인 89.9%까지 나타남을 알 수 있었다.