• 한국미생물·생명공학회지
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• 제19권5호
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• pp.444-449
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• 1991

Pullulanase의 역반응능을 이용하여 maltose와 $\beta$-cyclodextrin으로부터 maltosyl-$\beta$-cyclodextrin을 중합합성하기 위한 최적효소반응조건을 검토하였다. Maltose와 $\beta$-CD를 기질로 maltosyl-$\beta$-CD을 합성하였을 경우, 기질의 농도 70( w/w, 70g/100ml $H2_O$ ), malto-loigo당 /$\beta$-CD의 혼합비 12.7, 그리고 사용효소량 350 units/100ml일 때 최대전융인 43(w/w, g branched-CD/g CD)를 얻었고, 생성량은 2.31g/100ml였다. Maltosyl-$\beta$-CD의 효소합성의 적정 pH 및 온도는 각각 4.9와 $60^{\circ}C$ 였다. 또한 maltose와 $\alpha ,\beta$-그리고 $\gamma$-CD 각각을 기질로하여 maltosyl $\Alpha, \beta$ 그리고 $\gamma$-CD를 합성하였을 경우 전환율은 51.8, 42.6, 그리고 48.1로써, 생성량은 각각 2.8, 2.3 그리고 2.6g/100ml였다.

• 한국미생물·생명공학회지
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• 제19권4호
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• pp.362-367
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• 1991

Pullulanase 생산균으로서 토양으로부터 분리한 Aeromonas caviae No.S-76을 진탕배양하여 얻은 조효소액을 ammonium sulfate 침전, DAEA Sephadex A-50 column chromatoraphy, Sephadex G-150 column chromatography에 의하여 정제하였다. 이때 수율은 21이었고 50배의 정제도를 가진 효소단백질을 얻었다. 정제효소는 SDS-polyacrylamide slab gel 정기영동에 의하여 분자량 118,000의 단일단백질이었고, 등전점은 4.3, 작용 최적온도는 $50^{\circ}C$, 작용 최적 pH는 8.0이었다. 또한 이효소는 $45^{\circ}C$ 이하, pH 6.0-90. 범위에서 안정성을 나타내었다. 이 효소를 $\beta$-cyclodextrin과 maltose의 고농도 혼합액에서 작용시켜 maltosyl-$\beta$-cyclodextrin을 합성하였다.

• Journal of Microbiology and Biotechnology
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• 제17권9호
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• pp.1521-1526
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• 2007

A maltogenic amylase gene from Lactobacillus gasseri ATCC33323 (LGMA) was expressed in Lactococcus lactis MG1363 using the P170 expression system. The successful production of recombinant LGMA (rLGMA) was confirmed by the catalytic activity of the enzyme in liquid and solid media. The N-terminal amino acid sequencing analysis of the rLGMA showed that it was Met-Gln-Leu-Ala-Ala-Leu-, which was the same as that of genuine protein, meaning the signal peptide was efficiently cleaved during secretion to the extracellular milieu. The optimal reaction temperature and pH of rLGMA ($55^{\circ}C$ and pH 5, respectively) and enzymatic hydrolysis patterns on various substrates (${\beta}$-cyclodextrin, starch, and pullulan) supported that rLGMA was not only efficiently secreted from the Lactococcus lactis MG1363 but was also functionally active. Finally, the branched maltooligosaccharides were effectively produced from liquefied com starch, by using rLGMA secreted from Lactococcus lactis, with a yield of 53.1%.

• 한국미생물·생명공학회지
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• 제19권4호
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• pp.315-318
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• 1991

Pullulanase 생산력이 높은 세균 No.S-76을 토양으로부터 분리하였다. 분리된 균은 0.4~$0.6\times 0.8$~1.4 $\mu\textrm{m}$의 크기의 gram음성, 간균으로서 운동성이 있으며, 여러가지 특성을 조사한 결과 Bergey의 세균분류 동종법에 따라 Aeromonas caviae로 동정되었다. 본 균의 pullulanase 생산배지로서는 탄소원은 1 pullulan, soluble strach 또는 corn starch가, 질소원으로는 0.5% yeast extract 또는 peptone이 적당하였으며 initial pH는 9.0의 배지가 가장 좋았으며 $32^{\circ}C$에서 2일간 배양이 적당하였다.

• Journal of Microbiology and Biotechnology
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• 제23권8호
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• pp.1060-1069
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• 2013

Genome organization near cyclomaltodextrinases (CDases) was analyzed and compared for four different hyperthermophilic archaea: Thermococcus, Pyrococcus, Staphylothermus, and Thermofilum. A gene (CL1_0884) encoding a putative CDase from Thermococcus sp. CL1 (tccd) was cloned and expressed in Escherichia coli. TcCD was confirmed to be highly thermostable, with optimal activity at $85^{\circ}C$. The melting temperature of TcCD was determined to be $93^{\circ}C$ by both differential scanning calorimetry and differential scanning fluorimetry. A size-exclusion chromatography experiment showed that TcCD exists as a monomer. TcCD preferentially hydrolyzed ${\alpha}$-cyclodextrin (${\alpha}$-CD), and at the initial stage catalyzed a ring-opening reaction by cleaving one ${\alpha}$-1,4-glycosidic linkage of the CD ring to produce the corresponding single maltooligosaccharide. Furthermore, TcCD could hydrolyze branched CDs (G1-${\alpha}$-CD, G1-${\beta}$-CD, and G2-${\beta}$-CD) to yield significant amounts (45%, 40%, and 46%) of isomaltooligosaccharides (panose and $6^2$-${\alpha}$-maltosylmaltose) in addition to glucose and maltose. This enzyme is one of the most thermostable maltogenic amylases reported, and might be of potential value in the production of isomaltooligosaccharides in the food industry.

• Journal of Microbiology and Biotechnology
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• 제29권3호
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• pp.357-366
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• 2019

We first confirmed the involvement of MalQ (4-${\alpha}$-glucanotransferase) in Escherichia coli glycogen breakdown by both in vitro and in vivo assays. In vivo tests of the knock-out mutant, ${\Delta}malQ$, showed that glycogen slowly decreased after the stationary phase compared to the wild-type strain, indicating the involvement of MalQ in glycogen degradation. In vitro assays incubated glycogen-mimic substrate, branched cyclodextrin (maltotetraosyl-${\beta}$-CD: G4-${\beta}$-CD) and glycogen phosphorylase (GlgP)-limit dextrin with a set of variable combinations of E. coli enzymes, including GlgX (debranching enzyme), MalP (maltodextrin phosphorylase), GlgP and MalQ. In the absence of GlgP, the reaction of MalP, GlgX and MalQ on substrates produced glucose-1-P (glc-1-P) 3-fold faster than without MalQ. The results revealed that MalQ led to disproportionate G4 released from GlgP-limit dextrin to another acceptor, G4, which is phosphorylated by MalP. In contrast, in the absence of MalP, the reaction of GlgX, GlgP and MalQ resulted in a 1.6-fold increased production of glc-1-P than without MalQ. The result indicated that the G4-branch chains of GlgP-limit dextrin are released by GlgX hydrolysis, and then MalQ transfers the resultant G4 either to another branch chain or another G4 that can immediately be phosphorylated into glc-1-P by GlgP. Thus, we propose a model of two possible MalQ-involved pathways in glycogen degradation. The operon structure of MalP-defecting enterobacteria strongly supports the involvement of MalQ and GlgP as alternative pathways in glycogen degradation.

• 한국미생물학회:학술대회논문집
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• 한국미생물학회 1991년도 춘계학술발표대회 논문집
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• pp.225-236
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• 1991

The genes encoding the thermostable $\alpha$-amylase and maltogenic amylase from Bacillus lichenciformis were cloned and expressed in E. coli. The recombinant plasmid pTA322 was found to contain a 3.1kb EcoRI genomic DNA fragment of the thermostable $\alpha$-amylase. The cloned $\alpha$-amylase was compared with the B. licheniformis native $\alpha$-amylase. Both $\alpha$-amylase have the same optimal temperature of $70^{\circ}C$ and are stable in the pH range of 6 and 9. The complete nucleotide sequences of the thermostable $\alpha$-amylase gene were determined. It was composed of one open reading rame of 1,536 bp. Start and stop codons are ATG and TAG. From the amino acid sequence deduced from the nucleotide sequence, the cloned thermostable $\alpha$-amylase is composed of 483 amino acid residues and its molecular weight is 55,200 daltons. The content of guanine and cytosine is $47.46mol\%$ and that of third base codon was $53_41mol\%$. The recombinant plasmid, pIJ322 encoding the maltogenic amylase contains a 3.5kb EcoRI-BamHI genomic DNA fragment. The optimal reaction temperature and pH of the maltogenci amylase were $50^{\circ}C$ and 7, respectively. The maltogenic amylase was capable of hydrolysing pullulan, starch and cyclodextrin to produce maltose from starch and panose from pullulan. The maltogenic amylase also showed the transferring activity. The maltogenic amylase gene is composed of one open reading frame of 1,734bp. Start and stop codons are ATG and ATG. At 2bp upstream from start codon, the nucleotide sequence AAAGGGGGAA seems to be the ribosome-binding site(RBS, Shine-Dalgarno sequence). A putative promoter(-35 and-10 regions) was found to be GTTAACA and TGATAAT. From deduced amino acid sequence from the nucleotide srquence, this enzyme was comosed of 578 amino acid residues and its molecular weight was 77,233 daltons. The content of guanine and cytosine was $48.1mol\%$. The new recombinant plasmid, pTMA322 constructed by inserting the thermostable $\alpha$-amylase gene in the EcoRI site of pIJ322 to produce both the thermostable $\alpha$-amylase and the maltogenic amylase were expressed in the E. coli. The two enzymes expressed from E. coli containing pTMA322 was reacted with the $15\%$ starch slurry at $40^{\circ}C$ for 24hours. The distribution of the branched oligosaccharides produced by the single-step process was of the ratio 50 : 50 between small oligosaccharide up DP3 and large oligosaccharide above DP3.