• 제목/요약/키워드: starch-binding domain

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Structure of the Starch-Binding Domain of Bacillus cereus $\beta-Amylase$

  • Yoon, Hye-Jin;Akira, Hirata;Motoyasu, Adachi;Atsushi, Sekine;Shigeru, Utsumi;Bunzo, Mikami
    • Journal of Microbiology and Biotechnology
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    • 제9권5호
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    • pp.619-623
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    • 1999
  • The C-terminal starch-binding domain of Bacillus cereus $\beta$-amylase expressed in Escherichia coli was purified and crystallized using the vapor diffusion method. The crystals obtained belong to a space group of $P3_2$ 21 with cell dimensions, a=b=60.20${\AA},\; c=64.92{\AA},\; and \; \gamma = 120^{\circ}$ The structure was determined by the molecular replacement method and refined at 1.95 ${\AA}$, with R-factors of 0.181. The final model of the starch-binding domain comprised 99 amino acid residues and 108 water molecules. The starch-binding domain had a secondary structure of two 4-stranded antiparallel p-sheets similar to domain E of cyclodextrin glucanotransferase and the C-terminal starch-binding domain of glucoamylase. A comparison of the structures of these starch-binding domains revealed that the separated starch-binding domain of Bacillus cereus $\beta-Amylase$had only one starch-binding site (site 1) in contrast to two sites (site 1 and site 2) reported in the domains of cyclodextrin glucanotransferase and glucoamylase.

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Raw Starch-digesting Amylase is Comprised of two Distinct Domains of Catalytic and Substrate-Adsorbable Domain: Role of the C- Terminal Region in Raw-Starch-Binding

  • Kim, Cheorl-Ho
    • 한국미생물생명공학회:학술대회논문집
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    • 한국미생물생명공학회 2001년도 Proceedings of 2001 International Symposium
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    • pp.40-45
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    • 2001
  • Raw starch-digesting amylase (BF-2A, M.W. 93, 000 Da) from Bacillus circulans F-2 was converted to two components during digestion with subtilisin. Two components were separated and designated as BF-2A' (63, 000 Da) and BF-2B (30, 000 Da), respectively. BF-2A' exhibited the same hydrolysis curve for soluble starch as the original amylase (BF-2A). Moreover, the catalytic activities of original and modified enzymes were indistinguishable in $K_{m}$, Vmax for, and in their specific activity for soluble starch hydrolysis. However, its adsorbability and digestibility on raw starch was greatly decreased. Furthermore, the enzymatic action pattern on soluble starch was greatly different from that of the BF-2A. A smaller peptide (BF-2B) showed adsorb ability onto raw starch. By these results, it is suggested that the larger peptide (BF-2A') has a region responsible for the expression of the enzyme activity to hydrolyze soluble substrate, and the smaller peptide (BF-2B) plays a role on raw starch adsorption. A similar phenomenon is observed during limited proteinase K, thermolysin, and endopeptidase Glu-C proteolysis of the enzyme. Fragments resulting from proteolysis were characterized by immunoblotting with anti-RSDA. The proteolytic patterns resulting from proteinase K and subtilisin were the same, producing 63- and 30-kDa fragments. Similar patterns were obtained with endopeptidase Glu-C or thermolysin. All proteolytic digests contained a common, major 63-kDa fragment. Inactivation of RSDA activity results from splitting off the C-terminal domain. Hence, it seems probable that the protease sensitive locus is in a hinge region susceptible to cleavage. Extracellular enzymes immunoreactive toward anti-RSDA were detected through whole bacterial cultivation. Proteins of sizes 93-, 75-, 63-, 55-, 38-, and 31-kDa were immunologically identical to RSDA. Of these, the 75-kDa and 63-kDa proteins correspond to the major products of proteolysis with Glu-C and thermolysin. These results postulated that enzyme heterogeneity of the raw starch-hydrolysis system might arise from the endogeneous proteolytic activity of the bacterium. Truncated forms of rsda, in which the gene sequence encoding the conserved domain had been deleted, directed the synthesis of a functional amylase that did not bind to raw starch. This indicates that the conserved region of RSDA constitutes a raw starch-binding domain, which is distinct from the active centre. The possible role of this substrate-binding region is discussed.d.

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Sequencing of the RSDA Gene Encoding Raw Starch-Digesting $\alpha$-Amylase of Bacillus circulans F-2: Identification of Possible Two Domains for Raw Substrate-Adsorption and Substrate-Hydrolysis

  • Kim, Cheorl-Ho
    • Journal of Microbiology and Biotechnology
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    • 제2권1호
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    • pp.56-65
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    • 1992
  • The complete nucleotide sequence of the Bacillus circulans F-2 RSDA gene, coding for raw starch digesting a-amylase (RSDA), has been determined. The RSDA structure gene consists of an open reading frame of 2508 bp. Six bp upstream of the translational start codon of the RSDA is a typical gram-positive Shine-Dalgarno sequence and the RSDA encodes a preprotein of 836 amino acids with an Mr of 96, 727. The gene was expressed from its own regulatory region in E. coli and two putative consensus promoter sequences were identified upstream of a ribosome binding site and an ATG start codon. Confirmation of the nucleotide sequence was obtained and the signal peptide cleavage site was identified by comparing the predicted amino acid sequence with that derived by N-terminal analysis of the purified RSDA. The deduced N-terminal region of the RSDA conforms to the general pattern for the signal peptides of secreted prokaryotic proteins. The complete amino acid sequence was deduced and homology with other enzymes was compared. The results suggested that the Thr-Ser-rich hinge region and the non-catalytic domain are necessary for efficient adsorption onto raw substrates, and the catalytic domain (60 kDa) is necessary for the hydrolysis of substrates, as suggested in previous studies (8, 9).

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Screening, Gene Cloning, and Characterizations of an Acid-Stable α-Amylase

  • Liu, Xinyu;Jia, Wei;An, Yi;Cheng, Kun;Wang, Mingdao;Yang, Sen;Chen, Hongge
    • Journal of Microbiology and Biotechnology
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    • 제25권6호
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    • pp.828-836
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    • 2015
  • Based on its α-amylase activity at pH 5.0 and optimal pH of the crude enzyme, a strain (named B-5) with acid α-amylase production was screened. The B-5 strain was identified as Bacillus amyloliquefaciens through morphological, physiological, and biochemical characteristics analysis, as well as 16S rDNA phylogenetic analysis. Its α-amylase gene of GenBank Accession No. GU318401 was cloned and expressed in Escherichia coli. The purified recombinant α-amylase AMY-Ba showed the optimal pH of 5.0, and was stable at a pH range of 4.0-6.0. When hydrolyzing soluble starch, amylose, and amylopectin, AMY-Ba released glucose and maltose as major end products. The α-amylase AMY-Ba in this work was different from the well-investigated J01542-type α-amylase which also came from B. amyloliquefaciens. AMY-Ba exhibited notable adsorption and hydrolysis ability towards various raw starches. Structure analysis of AMY-Ba suggested the presence of a new starch-binding domain at its C-terminal region.

Cellulosimicrobium sp. YB-43의 mannanase B 유전자 클로닝과 특성 분석 (Molecular cloning and characterization of β-mannanase B from Cellulosimicrobium sp. YB-43)

  • 윤기홍
    • 미생물학회지
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    • 제52권3호
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    • pp.336-343
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    • 2016
  • 두 종류의 mannanases를 생산하는 Cellulosimicrobium sp. YB-43로부터 mannanase 유전자를 클로닝하고 그 염기서열을 결정하였다. Mannanase 유전자는 manB로 명명되었으며, 427 아미노 잔기로 구성된 단백질을 코드하는 1,284개 염기로 구성되었다. ManB는 추론된 아미노산 배열에 근거해서 glycosyl hydrolase family 5에 속하는 mannanase와 상동성이 높은 활성영역과 함께 2개의 탄수화물 결합영역을 포함하고 있는 다영역 효소로 확인되었다. Cellulosimicrobium sp. YB-43의 manB 유전자를 함유한 재조합 대장균의 균체 파쇄상등액으로부터 정제된 ManB의 아미노 말단 배열이 QGASAASDG로 결정되었으며 이는 SignalP4.1 server로 그람 음성균을 기준으로 예측된 signal peptide의 결과와 정확하기 일치하였다. 정제된 ManB의 최적 반응조건은 $55^{\circ}C$와 pH 6.5-7.0이며 locust bean gum (LBG), konjac과 guar gum을 가수분해 하였으며, 셀룰로스, 자일란, 전분과 para-nitrophenyl-${\beta}$-mannopyranoside에 대해서는 분해활성이 없었다. ManB의 활성은 $Mg^{2+}$, $K^+$$Na^+$에 의해 약간 저해되었으며 $Cu^{2+}$, $Zn^{2+}$, $Mn^{2+}$과 SDS에 의해서는 크게 저해되었다. 또한 이 효소는 mannobiose 보다 큰 중합도를 갖는 만노올리고당을 가수분해하였으며, LBG와 만노올리고당을 가수분해하였을 때 mannobiose가 가장 많은 양으로 생성되었다.