• Journal of Microbiology and Biotechnology
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• 제14권3호
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• pp.540-546
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• 2004

We deviced a new graphite-Mn(II) electrode and found that the modified electrode with Mn(II) can catalyze NADH oxidation and $NAD^+$ reduction coupled to electricity production and consumption as oxidizing agent and reducing power, respectively. In fuel cell with graphite-Mn(II) anode and graphite-Fe(III) cathode, the electricity of 1.5 coulomb (A x s) was produced from NADH which was electrochemically reduced by the graphite-Mn(II) electrode. When the initial concentrations of pyruvate and acetaldehyde were adjusted to 40 mM and 200 mM, respectively, about 25 mM lactate and 35 mM ethanol were produced from 40 mM pyruvate and 200 mM acetaldehyde, respectively, by catalysis of ADH and LDH in the electrochemical reactor with $NAD^+$ as cofactor and electricity as reducing power. By using this new electrode with catalytic function, the bioelectrocatalysts are engineered; namely, oxidoreductase (e.g., lactate dehydrogenase) and $NAD^+$ can function for biotransformation without electron mediator and second oxidoreductase for $NAD^+$/NADH recycling.

• Journal of Microbiology and Biotechnology
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• 제14권6호
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• pp.1120-1128
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• 2004

The SCBFC was composed of bilayered cathode, the outside of which was modified with $Fe^{3+}$ (graphite-Fe(III) cathode) and the inside of which was porcelain membrane, and of an anode which was modified with $Mn^{4+}$ (graphite­Mn(lV) anode). The graphite-Fe(III), graphite-Mn(IV), and porcelain membrane were designed to have micropores. The outside of the cathode was exposed to the atmosphere and the inside was contacted with porcelain membrane. In all SCBFCS the graphite-Fe(III) was used as a cathode, and graphite-Mn(IV) and normal graphite were used as anodes, for comparison of the function between normal graphite and graphite-Mn(IV) anode. The potential difference between graphite-Mn(IV) anode and graphite-Fe(III) cathode was about 0.3 volt, which is the source for the electron driving force from anode to cathode. In chemical fuel cells composed of the graphite-Mn(IV) anode and graphite-Fe(III) cathode, a current of maximal 13 mA was produced coupled to oxidation of NADH to $NAD^{+}$ the current was not produced in SCBFC with normal graphite anode. When growing and resting cells of E. coli were applied to the SCBFC with graphite-Mn(IV) anode, the electricity production and substrate consumption were 6 to 7 times higher than in the SCBFC with normal graphite anode, and when we applied anaerobic sewage sludge to SCBFC with graphite-Mn(IV) anode, the electricity production and substrate consumption were 3 to 5 times higher than in the SCBFC with normal graphite anode. These results suggest that useful electric energy might possibly be produced from SCBFC without electron mediators, electrode-active bacteria, and extra energy consumption for the aeration of catholyte, but with wastewater as a fuel.

• KSBB Journal
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• 제8권4호
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• pp.341-350
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• 1993

본 연구에서는 sMMO를 갖는 메탄 자화균인 M. triclwsporium OB3b를 이용하여 메탄올 생산을 위한 기초실험을 수행하였다. 중요한 결과를 요약하면 다음과 같다(Table 2). 1. 세포 내 NADH의 재생을 위해 개미산을 첨가 할 때 whole-cell의 sMMO 활성은 pH 7.0 및 $30^{\circ}C$ 에서 최대값을 보이며 propylene을 기질로 할 경우 약 130nmol/mg cell min 정도이다. 2. 인산은 MMO와 MDH 활성을 모두 저해하나 M MDH에 대한 저해 정도가 훨씬 크므로 메탄올 합성 에 사용이 가능하다. Noncompetitive mode를 가정 할 때 저해상수는 각각 185mM(MMO) 및 42mM ( (MDH)이었다. 3. 메탄올은 MMO 활성을 저해하며 noncompeti­t tive mode를 가정할 때 propylene기질의 경우 2 21mM 이었다. 4. 균체 내 sMMO 활성은 성장이 멈춰진 상태에 셔 비교적 때}른 속도로 감소하며 고농도 인산용액에 서 그 속도가 더 빨라진다. 5. 인산농도 91mM에서 메탄은 메탄올로 산화되 어 축적되며 4.5시간 동안 에탄올의 생성속도는 평 균 79nmol/mg min이었다.