• Journal of Microbiology and Biotechnology
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• 제21권10호
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• pp.1057-1063
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• 2011

Herein, a novel ginsenosidase, named ginsenosidase type IV, hydrolyzing 6-O-multi-glycosides of protopanaxatriol-type ginsenosides (PPT), such as Re, R1, Rf, and Rg2, was isolated from the Aspergillus sp. 39g strain, purified, and characterized. Ginsenosidase type IV was able to hydrolyze the 6-O-${\alpha}$-L-($1{\rightarrow}2$)-rhamnoside of Re and the 6-O-${\beta}$-D-($1{\rightarrow}2$)-xyloside of R1 into ginsenoside Rg1. Subsequently, it could hydrolyze the 6-O-${\beta}$-D-glucoside of Rg1 into F1. Similarly, it was able to hydrolyze the 6-O-$_{\alpha}$-L-($1{\rightarrow}2$)-rhamnoside of Rg2 and the 6-O-${\beta}$-D-($1{\rightarrow}2$)-glucoside of Rf into Rh1, and then further hydrolyze Rh1 into its aglycone. However, ginsenosidase type IV could not hydrolyze the 3-O- or 20-O-glycosides of protopanaxadiol-type ginsenosides (PPD), such as Rb1, Rb2, Rb3, Rc, and Rd. These exhibited properties are significantly different from those of glycosidases described in Enzyme Nomenclature by the NC-IUBMB. The optimal temperature and pH for ginsenosidase type IV were $40^{\circ}C$ and 6.0, respectively. The activity of ginsenosidase type IV was slightly improved by the $Mg^{2+}$ ion, and inhibited by $Cu^{2+}$ and $Fe^{2+}$ ions. The molecular mass of the enzyme, based on SDS-PAGE, was noted as being approximately 56 kDa.

• 산업식품공학
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• 제14권1호
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• pp.7-13
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• 2010

호열성 미생물을 검토하기 위하여 전국 각지로부터 토양과 두엄을 채취하여 그로부터 호열성 미생물을 분리하였다. 토양과 두엄으로부터 분리된 호열성 미생물 1250여 균주를 선별하였고, 이들을 대상으로 미생물이 생산하는 효소 활성을 검토하여 호열성 전분 분해 효소를 생산하는 1주의 미생물을 확인하였다. 확인된 1주의 미생물을 strain 2719라 명명하였다. Strain 2719 균주는 형태학적으로 gram 양성 간균의 특징을 나타냈고, 균주의 표면은 매끄럽지 않았으며, 비교적 다양한 길이를 가지고 있었다. 또한 다른 gram 양성 간균들에 비해서 많은 수의 균사들이 각 균주들 사이에 복잡하게 얽혀있었다. 생화학적 특성을 확인한 결과 catalase 양성, glucose 발효, arabinose 발효, mannitol 발효, casein gelatin starch 가수분해의 특징을 가지고 있었으며, 이는 Bacillus sp.로 추정되었다. 생육 pH의 범위는 pH 6-pH 8범위에서 생육이 가능했으며, 생육 온도의 범위는 50-70${^{\circ}C}$였다. 16S rDNA sequence 분석결과 Bacillus thermoglucosidasius의 16S rDNA와 99.52%가 일치하였으나, sequence의 일부분이 다른 부분이 있고, 생육 특성에서 약간의 차이를 보였다. 또한 gene bank에 등록되어 있는 균주들의 16S rDNA sequence들과 비교하여도 일치하는 균주는 확인되지 않았다. 이와 같은 실험결과에 따라 2719 균주는 기존에 발표되지는 않았으나, Bacillus thermoglucosidasius와 매우 유사한 균주로 판단되어 Bacillus thermoglucosidasius 2719로 명명하였다.

• Journal of Microbiology and Biotechnology
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• 제22권3호
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• pp.343-351
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• 2012

In this paper, the kinetics of a cloned special glucosidase, named ginsenosidase type III hydrolyzing 3-O-glucoside of multi-protopanaxadiol (PPD)-type ginsenosides, were investigated. The gene (bgpA) encoding this enzyme was cloned from a Terrabacter ginsenosidimutans strain and then expressed in E. coli cells. Ginsenosidase type III was able to hydrolyze 3-O-glucoside of multi-PPD-type ginsenosides. For instance, it was able to hydrolyze the 3-O-${\beta}$-D-(1${\rightarrow}$2)-glucopyranosyl of Rb1 to gypenoside XVII, and then to further hydrolyze the 3-O-${\beta}$-D-glucopyranosyl of gypenoside XVII to gypenoside LXXV. Similarly, the enzyme could hydrolyze the glucopyranosyls linked to the 3-O-position of Rb2, Rc, Rd, Rb3, and Rg3. With a larger enzyme reaction $K_m$ value, there was a slower enzyme reaction speed; and the larger the enzyme reaction $V_{max}$ value, the faster the enzyme reaction speed was. The $K_m$ values from small to large were 3.85 mM for Rc, 4.08 mM for Rb1, 8.85 mM for Rb3, 9.09 mM for Rb2, 9.70 mM for Rg3(S), 11.4 mM for Rd and 12.9 mM for F2; and $V_{max}$ value from large to small was 23.2 mM/h for Rc, 16.6 mM/h for Rb1, 14.6 mM/h for Rb3, 14.3 mM/h for Rb2, 1.81mM/h for Rg3(S), 1.40 mM/h for Rd, and 0.41 mM/h for F2. According to the $V_{max}$ and $K_m$ values of the ginsenosidase type III, the hydrolysis speed of these substrates by the enzyme was Rc>Rb1>Rb3>Rb2>Rg3(S)>Rd>F2 in order.

• Journal of Ginseng Research
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• 제23권1호
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• pp.50-54
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• 1999

In this paper, the saponin enzymatic hydrolysis of ginsenoside Rg3 was studied. The $ginsenoside-{\beta}-glucosidase$ from FFCDL-48 strain mainly hydrolyzed the ginsenoside Rg3 to Rh2, the enzyme from FFCDL-00 strain hydrolyzed Rg3 to the mixture of Rh2 and protopanaxadiol (aglycon). The $ginsenoside-{\beta}-glucosidase$ from FFCDL-48 strain was purified with a column of DEAE-Cellulose to one spot in the SDS polyacrylamide gel electrophoresis. During the purification, the enzyme specific acitvity was increased about 10 times. The purified $ginsenoside-{\beta}-glucosidase$ can hydrolyze the Rg3 to Rh2, but do not hydrolyze the $p-nitrophenyl-{\beta}-glucoside$ which is a substrate of original exocellulase such as ${\beta}-glucosidase$ of cellulose. The molecular weight of $ginsenoside-{\beta}-glucosidase$ was 34,000, the optimal temperature of enzyme reaction was $50^{\circ}C,$ and the optimal pH was 5.0.

• Journal of Microbiology and Biotechnology
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• 제27권1호
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• pp.77-83
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• 2017

Lignocellulosic biomass represents a potentially large resource to supply the world's fuel and chemical feedstocks. Enzymatic bioconversion of this substrate offers a reliable strategy for accessing this material under mild reaction conditions. Owing to the complex nature of lignocellulose, many different enzymatic activities are required to function in concert to perform efficient transformation. In nature, large multienzyme complexes are known to effectively hydrolyze lignocellulose into constituent monomeric sugars. We created artificial complexes of enzymes, called rosettazymes, in order to hydrolyze glucuronoxylan, a common lignocellulose component, into its cognate sugar ${\small{D}}$-xylose and then further convert the ${\small{D}}$-xylose into ${\small{D}}$-xylonic acid, a Department of Energy top-30 platform chemical. Four different types of enzymes (endoxylanase, ${\alpha}$-glucuronidase, ${\beta}$-xylosidase, and xylose dehydrogenase) were incorporated into the artificial complexes. We demonstrated that tethering our enzymes in a complex resulted in significantly more activity (up to 71%) than the same amount of enzymes free in solution. We also determined that varying the enzyme composition affected the level of complex-related activity enhancement as well as overall yield.

• Asian-Australasian Journal of Animal Sciences
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• 제20권6호
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• pp.989-993
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• 2007

A lactose-hydrolyzed milk with low sweetness was developed using nanofiltration. Raw milk was treated with 0.03% ${\beta}$-galactosidase at $4^{\circ}C$ for 24 h to hydrolyze lactose partially. The resultant lactose-hydrolyzed milk containing 0.43% lactose was then concentrated using a nanofiltration membrane to reach concentration factor of 2.13. The concentration factors and coefficients of retention of milk components in nanofiltration were determined. The concentration factor of milk fat was 2.20 which was the highest of the milk components. The coefficient of retention of calcium and riboflavin was 0.96 and 0.76, respectively. However, the coefficient of retention of glucose, galactose, and sodium was 0.21, 0.15, and 0.22, respectively. Raw milk was treated with 0.1% ${\beta}$-galactosidase at $4^{\circ}C$ for 40 h to hydrolyze lactose fully and then concentrated to reach a concentration factor of 1.6 by using nanofiltration. The concentrated milk was reconstituted with water. The lactose-hydrolyzed milk had sweetness similar to milk. The compositional ratios of crude protein, calcium, sodium, and riboflavin of lactose-hydrolyzed nanofiltrated milk to those of raw milk were 99%, 97%, 77%, and 80%, respectively. This study showed that nanofiltration of lactose-hydrolyzed milk to remove galactose and glucose did not cause significant loss of calcium. The lactose-hydrolyzed nanofiltrated milk contained 0.06% lactose and had sweetness similar to milk.

• Asian-Australasian Journal of Animal Sciences
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• 제13권3호
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• pp.376-380
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• 2000

This study was conducted to investigate protein and carbohydrate utilization of Micrococcus varians, Staphylococcus carnosus and Staphylococcus xylosus. Sensitivity to pH, sodium chloride, potassium sorbate and sodium nitrite of these strains was also determined. In Chinese-style beaker sausage manufacturing, the growth rate of these strains during the curing period ($20^{\circ}C$ and $30^{\circ}C$) was evaluated. The results indicated that no strains could hydrolyze azo-casein and sarcoplasmic protein and only S. xylosus could hydrolyze gelatin at $30^{\circ}C$. All of these strains could oxidize and ferment fructose and mannitol. S. carnosus and S. xylosus could slightly oxidize lactose and utilize citrate. Arabinose was oxidized by S. xylosus and sorbitol was oxidized by S. carnosus. Growth of M. varians was restricted at pH 5.0 and S. carnosus and S. xylosus were restricted at pH 4.5. S. xylosus and S. carnosus were able to grow with 0.1~0.5% potassium sorbate, 50~200 ppm sodium nitrite or 1~15% sodium chloride. S. xylosus had a higher growth rate than the other strains. Staphylococcus species grew well during curing period of Chinese-style beaker sausage then followed by Micrococcaceae.

• 미생물학회지
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• 제22권4호
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• pp.215-222
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• 1984

Rhodotorula gl$\varkappa$tinis 세포벽에 작용하는 용해 효소 생산곰팡이를 토양으로부터 분리하였고, Aspergillus f'||'&'||'micro;mig$\alpha$tus에 속하는 species로 동정되었다. 이 세포벽 용해효소는 세표외 유도효소였으며 lytic polysaccharidase 와 protease로 구성되어 생세포 용해에 공동으로 착용하였다. 이 lytic polysaccharidase는 Ascomycetous 효모에서의 주 구성 결합인 ${\beta}-1,3-$와 ${\beta}-1$, 6-glucan에는 작용치 않았다. 이 효소는 생세포에는 역가가 낮았지만 R. glutinis의 분획된 세포액에는 protease의 도움없이 작용할 수 있었다.

• Journal of Microbiology and Biotechnology
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• 제32권2호
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• pp.187-194
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• 2022

Two α-ʟ-arabinofuranosidases (BfdABF1 and BfdABF3) and a β-ᴅ-xylosidase (BfdXYL2) genes were cloned from Bifidobacterium dentium ATCC 27679, and functionally expressed in E. coli BL21(DE3). BfdABF1 showed the highest activity in 50 mM sodium acetate buffer at pH 5.0 and 25℃. This exo-enzyme could hydrolyze p-nitrophenyl arabinofuranoside, arabino-oligosaccharides (AOS), arabinoxylo-oligosaccharides (AXOS) such as 3²-α-ʟ-arabinofuranosyl-xylobiose (A³X), and 2³-α-ʟ-arabinofuranosyl-xylotriose (A²XX), whereas hardly hydrolyzed polymeric substrates such as debranched arabinan and arabinoxylans. BfdABF1 is a typical exo-ABF with the higher specific activity on the oligomeric substrates than the polymers. It prefers to α-(1,2)-ʟ-arabinofuranosidic linkages compared to α-(1,3)-linkages. Especially, BfdABF1 could slowly hydrolyze 2³,3³-di-α-ʟ-arabinofuranosyl-xylotriose (A²⁺³XX). Meanwhile, BfdABF3 showed the highest activity in sodium acetate at pH 6.0 and 50℃, and it has the exclusively high activities on AXOS such as A³X and A²XX. BfdABF3 mainly catalyzes the removal of ʟ-arabinose side chains from various AXOS. BfdXYL2 exhibited the highest activity in sodium citrate at pH 5.0 and 55℃, and it specifically hydrolyzed p-nitrophenyl xylopyranoside and xylo-oligosaccharides (XOS). Also, BfdXYL2 could slowly hydrolyze AOS and AXOS such as A³X. Based on the detailed hydrolytic modes of action of three exo-hydrolases (BfdABF1, BfdABF3, and BfdXYL2) from Bf. dentium, their probable roles in the hemiceullose-utilization system of Bf. dentium are proposed in the present study. These intracellular exo-hydrolases can synergistically produce ʟ-arabinose and ᴅ-xylose from various AOS, XOS, and AXOS.

• 한국미생물생명공학회:학술대회논문집
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• 한국미생물생명공학회 1986년도 추계학술대회
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• pp.524.1-524
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• 1986

CMCase, a member of cellulose decomposing enzymes, hydrolyze cellulose up to cellobiose. Cellobiase splits cellobiose to glucose units. Therefore, a linkage of the twogenes coding for CMCase and cellobiase on the same plasmid is needed to produce a cellulase complex which can produce glucose from cellulose. A genetic operon in which the two structural genes are under the control of a single promoter would be ideal for this purpose. The present report is on the linking of the two cellulase genes in one plasmid as a preliminary step of the operon construction.