Theoretical Studies for the Discovery of Potential Sucrase-Isomaltase Inhibitors from Maize Silk Phytochemicals: An Approach to Treatment of Type 2 Diabetes

A theoretical analysis of the potential inhibition of human sucrase-isomaltase (SI) by flavonoids was carried out with the aim of identifying potential candidates for an alternative treatment of type 2 diabetes. Two compounds from maize silks, maysin and luteolin, were selected to be studied with the structure-based density functional theory (DFT), molecular docking (MDock), and molecular dynamics (MD) approaches. The docking score and MD simulations suggested that the compounds maysin and luteolin presented higher binding affinities in N-terminal sucrase-isomaltase (NtSI) than in C-terminal sucrase-isomaltase (CtSI). The reactivity parameters, such as chemical hardness (η) and chemical potential (µ), of the ligands, as well as of the active site amino acids of the NtSI, were calculated by the meta-GGA M06 functional in combination with the 6-31G(d) basis set. The lower value of chemical hardness calculated for the maysin molecule indicated that this might interact more easily with the active site of NtSI, in comparison with the values of the acarbose and luteolin structures. Additionally, a possible oxidative process was proposed through the quantum chemical calculations of the electronic charge transfer values (∆N) between the active site amino acids of the NtSI and the ligands. In addition, maysin displayed a higher ability to generate more oxidative damage in the NtSI active site. Our results suggest that maysin and luteolin can be used to develop novel α-glucosidase inhibitors via NtSI inhibition.

Characterization of α-Glucosidase Inhibitors from Clinacanthus nutans Lindau Leaves by Gas Chromatography-Mass Spectrometry-Based Metabolomics and Molecular Docking Simulation

BACKGROUND

Clinacanthus nutans (C. nutans) is an Acanthaceae herbal shrub traditionally consumed to treat various diseases including diabetes in Malaysia. This study was designed to evaluate the α-glucosidase inhibitory activity of C. nutans leaves extracts, and to identify the metabolites responsible for the bioactivity.

METHODS

Crude extract obtained from the dried leaves using 80% methanolic solution was further partitioned using different polarity solvents. The resultant extracts were investigated for their α-glucosidase inhibitory potential followed by metabolites profiling using the gas chromatography tandem with mass spectrometry (GC-MS).

RESULTS

Multivariate data analysis was developed by correlating the bioactivity, and GC-MS data generated a suitable partial least square (PLS) model resulting in 11 bioactive compounds, namely, palmitic acid, phytol, hexadecanoic acid (methyl ester), 1-monopalmitin, stigmast-5-ene, pentadecanoic acid, heptadecanoic acid, 1-linolenoylglycerol, glycerol monostearate, alpha-tocospiro B, and stigmasterol. In-silico study via molecular docking was carried out using the crystal structure Saccharomyces cerevisiae isomaltase (PDB code: 3A4A). Interactions between the inhibitors and the protein were predicted involving residues, namely LYS156, THR310, PRO312, LEU313, GLU411, and ASN415 with hydrogen bond, while PHE314 and ARG315 with hydrophobic bonding.

CONCLUSION

The study provides informative data on the potential α-glucosidase inhibitors identified in C. nutans leaves, indicating the plant's therapeutic effect to manage hyperglycemia.

Dietary phenolic compounds selectively inhibit the individual subunits of maltase-glucoamylase and sucrase-isomaltase with the potential of modulating glucose release

In this study, it was hypothesized that dietary phenolic compounds selectively inhibit the individual C- and N-terminal (Ct, Nt) subunits of the two small intestinal α-glucosidases, maltase-glucoamylase (MGAM) and sucrase-isomaltase (SI), for a modulated glycemic carbohydrate digestion. The inhibition by chlorogenic acid, caffeic acid, gallic acid, (+)-catechin, and (-)-epigallocatechin gallate (EGCG) on individual recombinant human Nt-MGAM and Nt-SI and on mouse Ct-MGAM and Ct-SI was assayed using maltose as the substrate. Inhibition constants, inhibition mechanisms, and IC50 values for each combination of phenolic compound and enzymatic subunit were determined. EGCG and chlorogenic acid were found to be more potent inhibitors for selectively inhibiting the two subunits with highest activity, Ct-MGAM and Ct-SI. All compounds displayed noncompetitive type inhibition. Inhibition of fast-digesting Ct-MGAM and Ct-SI by EGCG and chlorogenic acid could lead to a slow, but complete, digestion of starch for improved glycemic response of starchy foods with potential health benefit.

A novel type of detergent-resistant membranes may contribute to an early protein sorting event in epithelial cells

One sorting mechanism of apical and basolateral proteins in epithelial cells is based on their solubility profiles with Triton X-100. Nevertheless, apical proteins themselves are also segregated beyond the trans-Golgi network by virtue of their association or nonassociation with cholesterol/sphingolipid-rich microdomains (Jacob, R., and Naim, H. Y. (2001) Curr. Biol. 11, 1444-1450). Therefore, extractability with Triton X-100 does not constitute an absolute criterion of protein sorting. Here, we investigate the solubility patterns of apical and basolateral proteins with other detergents and demonstrate that the mild detergent Tween 20 is adequate to discriminate between apical and basolateral proteins during early stages in their biosynthesis. Although the mannose-rich forms of the apical proteins sucrase-isomaltase, lactase-phlorizin hydrolase, aminopeptidase N, and dipeptidylpeptidase IV reveal similar solubility profiles comprising soluble and nonsoluble fractions, the basolateral proteins, vesicular stomatitis virus G protein, major histocompatibility complex class I, and CD46 are entirely soluble with this detergent. The insoluble Tween 20 membranes are enriched in phosphatidylinositol and phosphatidylglycerol compatible with their synthesis in the endoplasmic reticulum and the existence of a novel class of detergent-resistant membranes. The association of the mannose-rich biosynthetic forms of the apical proteins, sucraseisomaltase, lactase-phlorizin hydrolase, aminopeptidase N, and dipeptidylpeptidase IV with the Tween 20-resistant membranes suggests an early polarized sorting mechanism prior to maturation in the Golgi apparatus.

Crystal structure of Thermotoga maritima 4-alpha-glucanotransferase and its acarbose complex: implications for substrate specificity and catalysis

4-alpha-Glucanotransferase (GTase) is an essential enzyme in alpha-1,4-glucan metabolism in bacteria and plants. It catalyses the transfer of maltooligosaccharides from an 1,4-alpha-D-glucan molecule to the 4-hydroxyl group of an acceptor sugar molecule. The crystal structures of Thermotoga maritima GTase and its complex with the inhibitor acarbose have been determined at 2.6A and 2.5A resolution, respectively. The GTase structure consists of three domains, an N-terminal domain with the (beta/alpha)(8) barrel topology (domain A), a 65 residue domain, domain B, inserted between strand beta3 and helix alpha6 of the barrel, and a C-terminal domain, domain C, which forms an antiparallel beta-structure. Analysis of the complex of GTase with acarbose has revealed the locations of five sugar-binding subsites (-2 to +3) in the active-site cleft lying between domain B and the C-terminal end of the (beta/alpha)(8) barrel. The structure of GTase closely resembles the family 13 glycoside hydrolases and conservation of key catalytic residues previously identified for this family is consistent with a double-displacement catalytic mechanism for this enzyme. A distinguishing feature of GTase is a pair of tryptophan residues, W131 and W218, which, upon the carbohydrate inhibitor binding, form a remarkable aromatic "clamp" that captures the sugar rings at the acceptor-binding sites +1 and +2. Analysis of the structure of the complex shows that sugar residues occupying subsites from -2 to +2 engage in extensive interactions with the protein, whereas the +3 glucosyl residue makes relatively few contacts with the enzyme. Thus, the structure suggests that four subsites, from -2 to +2, play the dominant role in enzyme-substrate recognition, consistent with the observation that the smallest donor for T.maritima GTase is maltotetraose, the smallest chain transferred is a maltosyl unit and that the smallest residual fragment after transfer is maltose. A close similarity between the structures of GTase and oligo-1,6-glucosidase has allowed the structural features that determine differences in substrate specificity of these two enzymes to be analysed.

Oligo-1,6-glucosidase from a thermophile, Bacillus thermoglucosidasius KP1006, was efficiently produced by combinatorial expression of GroEL in Escherichia coli

To improve the production of oligo-1,6-glucosidase from the obligately thermophilic Bacillus thermoglucosidasius KP1006 in Escherichia coli, the combined expression of oligo-1,6-glucosidase with various chaperone proteins of Hsp (heat-shock protein) 60 team proteins (GroES and GroEL) or Hsp70 team proteins (GrpE, DnaK and DnaJ) from the same thermophile was examined. This attempt was based on the facts that, (i) among glycosyl hydrolases of Family 13, bacillary oligo-1,6-glucosidases share highest homology with yeast alpha-glucosidase, and (ii) this yeast enzyme interacts with GroEL. In B. thermoglucosidasius Hsp60 team proteins, in particular, GroEL brought about a remarkable rise in expression of B. thermoglucosidasius oligo-1,6-glucosidase, while Hsp70 team proteins had no significant effect. The effect of B. thermoglucosidasius GroEL on oligo-1,6-glucosidase expression was supported by the finding that thermally inactivated B. thermoglucosidasius oligo-1,6-glucosidase was revived by B. thermoglucosidasius GroEL. Although the molecular mass of B. thermoglucosidasius oligo-1,6-glucosidase (66 kDa) exceeds the major range of substrates for GroEL proteins, the GroEL molecules probably recognized the alpha/beta motifs contained in the N-terminal domain and the subdomain of the oligo-1,6-glucosidase. Here we show that (i) the production of B. thermoglucosidasius oligo-1,6-glucosidase in E. coli was improved 3.8-fold by Hsp60 team proteins, (ii) the system can function for the expression of other glycosyl hydrolases of Family 13 that have defects in expression and (iii) the combinatorial expression of thermostable proteins with GroEL from the same thermophile in E. coli can increase the production of thermostable enzymes, preventing problems derived from differences in protein biogenesis.

Identification of catalytic and substrate-binding site residues in Bacillus cereus ATCC7064 oligo-1,6-glucosidase

Three active site residues (Asp199, Glu255, Asp329) and two substrate-binding site residues (His103, His328) of oligo-1,6-glucosidase (EC 3.2.1.10) from Bacillus cereus ATCC7064 were identified by site-directed mutagenesis. These residues were deduced from the X-ray crystallographic analysis and the comparison of the primary structure of the oligo-1,6-glucosidase with those of Saccharomyces carlsbergensis alpha-glucosidase, Aspergillus oryzae alpha-amylase and pig pancreatic alpha-amylase which act on alpha-1,4-glucosidic linkages. The distances between these putative residues of B. cereus oligo-1,6-glucosidase calculated from the X-ray analysis data closely resemble those of A. oryzae alpha-amylase and pig pancreatic alpha-amylase. A single mutation of Asp199-->Asn, Glu255-->Gln, or Asp329-->Asn resulted in drastic reduction in activity, confirming that three residues are crucial for the reaction process of alpha-1,6-glucosidic bond cleavage. Thus, it is identified that the basic mechanism of oligo-1,6-glucosidase for the hydrolysis of alpha-1,6-glucosidic linkage is essentially the same as those of other amylolytic enzymes belonging to Family 13 (alpha-amylase family). On the other hand, mutations of histidine residues His103 and His328 resulted in pronounced dissimilarity in catalytic function. The mutation His328-->Asn caused the essential loss in activity, while the mutation His103-->Asn yielded a mutant enzyme that retained 59% of the k0/Km of that for the wild-type enzyme. Since mutants of other alpha-amylases acting on alpha-1,4-glucosidic bond linkage lost most of their activity by the site-directed mutagenesis at their equivalent residues to His103 and His328, the retaining of activity by His103-->Asn mutation in B. cereus oligo-1,6-glucosidase revealed the distinguished role of His103 for the hydrolysis of alpha-1,6-glucosidic bond linkage.

Comparison of sucrase-free isomaltase with sucrase-isomaltase purified from the house musk shrew Suncus murinus

We purified sucrase-isomaltase and sucrase-free isomaltase from a normal and a sucrase-deficient line, respectively, of the house musk shrew Suncus murinus and examined the effects of mutation on enzyme structure and activities. Recent cDNA cloning studies have predicted that sucrase-free mutant isomaltase lacks the C-terminal 69 amino acids of normal isomaltase, as well as the entire sucrase. On SDS-polyacrylamide gel electrophoresis purified sucrase-free isomaltase gave a single protein band of 103 kDa, while sucrase-isomaltase gave two major protein bands of 106 and 115 kDa. The 115, but not 106, kDa band was quite similar to the 103 kDa band on Western blotting with Aleuria aurantia lectin and antibody against shrew sucrase-isomaltase, suggesting that the 115 and 103 kDa bands are due to normal and mutant isomaltases, respectively, in accordance with the above prediction. Purified isomaltase and sucrase-isomaltase were similar in Km and Vmax (based on isomaltase mass) values for isomaltose hydrolysis and in inhibition of isomaltase activity by antibody against rabbit sucrase-isomaltase, suggesting that the enzymatic properties of isomaltase are mostly unaffected by mutation.

Clustered proline residues around the active-site cleft in thermostable oligo-1,6-glucosidase of Bacillus flavocaldarius KP1228

The gene that coded for a cellular oligo-1,6-glucosidase (dextrin 6-alpha-D-glucanohydrolase, EC 3.2.1.10) in Bacillus flavocaldarius KP1228 (FERM-P9542) cells growing at 51-82 degrees C was expressed in Escherichia coli JM109. The enzyme had a half-life of 10 min at 89.2 degrees C. Purification of the enzyme and its characterization showed that the enzyme was identical with the native one. Its primary structure of 529 residues with a molecular weight of 61,469 deduced from the gene was 40-42% identical to the sequences of less thermostable oligo-1,6-glucosidases from Bacillus cereus ATCC 7064, Bacillus coagulans ATCC 7050, and Bacillus thermoglucosidasius KP1006. Sequence analysis showed that the B. flavocaldarius enzyme shared 14 proline residues at the same positions as in the three other enzymes, and that the B. flavocaldarius enzyme had 22 of 33 additional proline residues (cf. 1/5, 5/10, and 9/18 in the respective counterparts) in three long polypeptides constituting the active-site cleft, which connected the third, fourth, and eighth beta-strands to the corresponding third, fourth, and eighth alpha-helices in the (beta/alpha)8-barrel.

The refined crystal structure of Bacillus cereus oligo-1,6-glucosidase at 2.0 A resolution: structural characterization of proline-substitution sites for protein thermostabilization

The crystal structure of oligo-1,6-glucosidase (dextrin 6-alpha-glucanohydrolase, EC 3.2.1.10) from Bacillus cereus ATCC7064 has been refined to 2.0 A resolution with an R-factor of 19.6% for 43,328 reflections. The final model contains 4646 protein atoms and 221 ordered water molecules with respective root-mean-square deviations of 0.015 A for bond lengths and of 3.166 degrees for bond angles from the ideal values. The structure consists of three domains: the N-terminal domain (residues 1 to 104 and 175 to 480), the subdomain (residues 105 to 174) and the C-terminal domain (residues 481 to 558). The N-terminal domain takes a (beta/alpha)8-barrel structure with additions of an alpha-helix (N alpha6') between the sixth strand Nbeta6 and the sixth helix N alpha6, an alpha-helix (N alpha7') between the seventh strand Nbeta7 and the seventh helix N alpha7 and three alpha-helices (N alpha8', N alpha8" and N alpha8'" between the eighth strand Nbeta8 and the eighth helix N alpha8. The subdomain is composed of an alpha-helix, a three-stranded antiparallel beta-sheet, and long intervening loops. The C-terminal domain has a beta-barrel structure of eight antiparallel beta-strands folded in double Greek key motifs, which is distorted in the sixth strand Cbeta6. Three catalytic residues, Asp199, Glu255 and Asp329, are located at the bottom of a deep cleft formed by the subdomain and a cluster of the two additional alpha-helices N alpha8' and N alpha8" in the (beta/alpha)8-barrel. The refined structure reveals the locations of 21 proline-substitution sites that are expected to be critical to protein thermostabilization from a sequence comparison among three Bacillus oligo-1,6-glucosidases with different thermostability. These sites lie in loops, beta-turns and alpha-helices, in order of frequency, except for Cys515 in the fourth beta-strand Cbeta4 of the C-terminal domain. The residues in beta-turns (Lys121, Glu208, Pro257, Glu290, Pro443, Lys457 and Glu487) are all found at their second positions, and those in alpha-helices (Asn109, Glu175, Thr261 and Ile403) are present at their N1 positions of the first helical turns. Those residues in both secondary structures adopt phi and phi values favorable for proline substitution. Residues preceding the 21 sites are mostly conserved upon proline occurrence at these 21 sites in more thermostable Bacillus oligo-1,6-glucosidases. These structural features with respect to the 21 sites indicate that the sites in beta-turns and alpha-helices have more essential prerequisites for proline substitution to thermostabilize the protein than those in loops. This well supports the previous finding that the replacement at the appropriate positions in beta-turns or alpha-helices is the most effective for protein thermostabilization by proline substitution.

Analysis of the critical sites for protein thermostabilization by proline substitution in oligo-1,6-glucosidase from Bacillus coagulans ATCC 7050 and the evolutionary consideration of proline residues

To identify the critical sites for protein thermostabilization by proline substitution, the gene for oligo-1,6- glucosidase from a thermophilic Bacillus coagulans strain, ATCC 7050, was cloned as a 2.4-kb DNA fragment and sequenced. In spite of a big difference in their thermostabilities, B. coagulans oligo-1,6-glucosidase had a large number of points in its primary structure identical to respective points in the same enzymes from a mesophilic Bacillus cereus strain, ATCC 7064 (57%), and an obligately thermophilic Bacillus thermoglucosidasius strain, KP1006 (59%). The number of prolines (19 for B. cereus oligo-1,6-glucosidase, 24 for B. coagulans enzyme, and 32 for B. thermoglucosidasius enzyme) was observed to increase with the rise in thermostabilities of the oligo-1,6-glucosidases. Classification of proline residues in light of the amino acid sequence alignment and the protein structure revealed by X-ray crystallographic analysis also supported this tendency. Judging from proline residues occurring in B. coagulans oligo-1,6-glucosidase and the structural requirement for proline substitution (second site of the beta turn and first turn of the alpha helix) (K. Watanabe, T. Masuda, H. Ohashi, H. Mihara, and Y. Suzuki, Eur. J. Biochem. 226:277-283, 1994), the critical sites for thermostabilization were found to be Lys-121, Glu-290, Lys-457, and Glu-487 in B. cereus oligo-1,6-glucosidase. With regard to protein evolution, the oligo-1,6-glucosidases very likely follow the neutral theory. The adaptive mutations of the oligo-1,6-glucosidases that appear to increase thermostability are consistent with the substitution of proline residues for neutrally occurring residues. It is concluded that proline substitution is an important factor for the selection of thermostability in oligo-1,6-glucosidases.

Similarity of different beta-strands flanked in loops by glycines and prolines from distinct (alpha/beta)8-barrel enzymes: chance or a homology?

Many (alpha/beta)8-barrel enzymes contain their conserved sequence regions at or around the beta-strand segments that are often preceded and succeeded by glycines and prolines, respectively. alpha-Amylase is one of these enzymes. Its sequences exhibit a very low degree of similarity, but strong conservation is seen around its beta-strands. These conserved regions were used in the search for similarities with beta-strands of other (alpha/beta)8-barrel enzymes. The analysis revealed an interesting similarity between the segment around the beta 2-strand of alpha-amylase and the one around the beta 4-strand of glycolate oxidase that are flanked in loops by glycines and prolines. The similarity can be further extended on other members of the alpha-amylase and glycolate oxidase subfamilies, i.e., cyclodextrin glycosyltransferase and oligo-1,6-glucosidase, and flavocytochrome b2, respectively. Moreover, the alpha-subunit of tryptophan synthase, the (alpha/beta)8-barrel enzyme belonging to the other subfamily of (alpha/beta)8-barrels, has both investigated strands, beta 2 and beta 4, similar to beta 2 of alpha-amylase and beta 4 of glycolate oxidase. The possibilities of whether this similarity exists only by chance or is a consequence of some processes during the evolution of (alpha/beta)8-barrel proteins are briefly discussed.

Multiple proline substitutions cumulatively thermostabilize Bacillus cereus ATCC7064 oligo-1,6-glucosidase. Irrefragable proof supporting the proline rule

Nine residues of Bacillus cereus ATCC7064 oligo-1,6-glucosidase were replaced stepwise with proline residues. Of the nine residues, Lys121, Glu208 and Glu290 were at second sites of beta turns; Asn109, Glu175 and Thr261 were at N-caps of alpha helices; Glu216, Glu270 and Glu378 were in coils within loops. The replacements were carried out in the order, Lys121-->Pro, Glu175-->Pro, Glu290-->Pro, Glu208-->Pro, Glu270-->Pro, Glu378-->Pro, Thr261-->Pro, Glu216-->Pro and Asn109-->Pro. The resultant nine active mutant enzymes contained 1-9 more proline residues than B. cereus oligo-1,6-glucosidase. The thermostability of these mutants was additively enhanced with the increase in the number of proline residues introduced. The increase in the thermostability was most remarkable when proline residues were introduced at second sites of beta turns or at N-caps of alpha helices. The above results afforded irrefragable proof for the proline rule as an effective principle for increasing protein thermostability [Suzuki, Y., Oishi, K., Nakano, H. & Nagayama, T. (1987) Appl. Microbiol. Biotechnol. 26, 546-551].

Parallel beta/alpha-barrels of alpha-amylase, cyclodextrin glycosyltransferase and oligo-1,6-glucosidase versus the barrel of beta-amylase: evolutionary distance is a reflection of unrelated sequences

The structures of functionally related beta/alpha-barrel starch hydrolases, alpha-amylase, beta-amylase, cyclodextrin glycosyltransferase and oligo-1,6-glucosidase, are discussed, their mutual sequence similarities being emphasized. Since these enzymes (except for beta-amylase) along with the predicted set of more than ten beta/alpha-barrels from the alpha-amylase enzyme superfamily fulfil the criteria characteristic of the products of divergent evolution, their unrooted distance tree is presented.

Polypeptide folding of Bacillus cereus ATCC7064 oligo-1,6-glucosidase revealed by 3.0 A resolution X-ray analysis

The crystal structure of an oligo-1,6-glucosidase from Bacillus cereus ATCC7064 was determined by the X-ray diffraction method at 3.0 A resolution. The structure was solved by the multiple isomorphous replacement method and refined to a crystallographic R-factor of 0.208, using the molecular dynamics refinement program, X-PLOR. The electron density map revealed the folding of a polypeptide chain consisting of 558 amino acid residues. The molecule can be subdivided into three domains (N-terminal domain, subdomain, and C-terminal domain). The N-terminal domain has an (alpha/beta)8-barrel structure called the TIM-barrel structure. The C-terminal domain is characterized by a beta-barrel structure composed of eight antiparallel beta-strands, while the subdomain has a loop-rich structure with a small alpha-helix and a beta-sheet. The enzyme has a large cleft between the N-terminal domain and the subdomain. The cleft leads from the molecular surface to the molecular center. The bottom of the cleft is at the C-terminal end of the parallel beta-strands of the (alpha/beta)8-barrel. These structural features closely resemble those of alpha-amylases from Aspergillus oryzae and pig pancreas.

Assignment of Bacillus thermoamyloliquefaciens KP1071 alpha-glucosidase I to an exo-alpha-1,4-glucosidase, and its striking similarity to bacillary oligo-1,6-glucosidases in N-terminal sequence and in structural parameters calculated from the amino acid composition

alpha-Glucosidase I of Bacillus thermoamyloliquefaciens KP1071 (FERM P8477, facultative thermophile) was purified to homogeneity. The relative molecular mass was estimated to be 62,000 Da. From its catalytic properties, the enzyme has been assigned to an exo-alpha-1,4-glucosidase. The enzyme shares its antigenic groups in part with Bacillus stearothermophilus ATCC12016 (obligate thermophile) exo-alpha-1,4-glucosidase. These exo-alpha-1,4-glucosidases strikingly resemble oligo-1,6-glucosidases from B. thermoamyloliquefaciens KP1071 and from Bacillus cereus ATCC7064 in the molecular properties tested, including relative molecular mass, N-terminal sequence of 15 residues, amino acid composition and structural parameters calculated from amino acid composition. We have suggested that bacillary exo-alpha-1,4-glucosidases take the same folded conformation, i.e. an (alpha/beta)8-barrel super-secondary structure in its N-terminal domain, as bacillary oligo-1,6-glucosidases.

Proline residues responsible for thermostability occur with high frequency in the loop regions of an extremely thermostable oligo-1,6-glucosidase from Bacillus thermoglucosidasius KP1006

The gene encoding for an extremely thermostable oligo-1,6-glucosidase from Bacillus thermoglucosidasius KP1006 (DSM2542, obligate thermophile) was sequenced. The amino acid sequence deduced from the nucleotide sequence of the gene (1686 base pairs) corresponded to a protein of 562 amino acid residues with a Mr of 66,502. Its predicted amino acid composition, Mr, and N-terminal sequence of 12 residues were consistent with those determined for B. thermoglucosidasius oligo-1,6-glucosidase. The deduced sequence of the enzyme was 72% homologous to that of a thermolabile oligo-1,6-glucosidase (558 residues) from Bacillus cereus ATCC7064 (mesophile). B. cereus oligo-1,6-glucosidase contained 19 prolines. Eighteen of these were conserved at the equivalent positions of B. thermoglucosidasius oligo-1,6-glucosidase. This enzyme contained 14 extra prolines besides the conservative prolines. The majority of extra prolines was replaced by polar or charged residues (Glu, Thr, or Lys) in B. cereus oligo-1,6-glucosidase. The extra prolines were responsible for the difference in thermostability between these two enzymes. We suggested that 11 of the extra prolines in B. thermoglucosidasius oligo-1,6-glucosidase occur in beta-turns or in coils within the loops binding adjacent secondary structures.

Overproduction, purification and crystallization of Bacillus cereus oligo-1,6-glucosidase

The gene coding for oligo-1,6-glucosidase from Bacillus cereus ATCC7064 has been overexpressed in Escherichia coli MV1184 cells under the control of the lac promoter in the genetically engineered plasmid pBCE4-2. Oligo-1,6-glucosidase was purified in large quantities and was crystallized at 25 degrees C by using a hanging drop vapor diffusion method with 53% saturated ammonium sulfate. The crystals have the shape of hexagonal bipyramids and belong to the space group P6(2) or P6(4) with lattice constants of a = b = 106.1 A, c = 120.0 A and gamma = 120 degrees.

Primary structure of the oligo-1,6-glucosidase of Bacillus cereus ATCC7064 deduced from the nucleotide sequence of the cloned gene

The gene coding for Bacillus cereus ATCC7064 (mesophile) oligo-1,6-glucosidase was cloned within a 2.8-kb SalI-EcoRI fragment of DNA, using the plasmid pUC19 as a vector and Escherichia coli C600 as a host. E. coli C600 bearing the hybrid plasmid pBCE4 accumulated oligo-1,6-glucosidase in the cytoplasm. The cloned enzyme coincided absolutely with B. cereus oligo-1,6-glucosidase in its Mr (65,000), in its electrophoretic behavior on a polyacrylamide gel with or without sodium dodecyl sulfate, in its isoelectric point (4.5), in the temperature dependence of its stability and activity, and in its antigenic determinants. The nucleotide sequence of B. cereus oligo-1,6-glucosidase gene and its flanking regions was determined with both complementary strands of DNA (each 2838 nucleotides). The gene consisted of an open reading frame of 1674 bp commencing with a ATG start codon and followed by a TAA stop codon. The amino acid sequence deduced from the nucleotide sequence predicted a protein of 558 amino acid residues with a Mr of 66,010. The amino acid composition and Mr were comparable with those of B. cereus oligo-1,6-glucosidase. The predicted N-terminal sequence of 10 amino acid residues agreed completely with that of the cloned ligo-1,6-glucosidase. The deduced amino acid sequence of B. cereus oligo-1,6-glucosidase was 72% and 42% similar to those from Bacillus thermoglucosidasius KP1006 (DSM2542, obligate thermophile) oligo-1,6-glucosidase and from Saccharomyces carlsbergensis CB11 alpha-glucosidase, respectively. Predictions of protein secondary structures along with amino acid sequence alignments demonstrated that B. cereus oligo-1,6-glucosidase may take the similar (alpha/beta)8-barrel super-secondary structure, a barrel of eight parallel beta-strands surrounded by eight alpha-helices, in its N-terminal active site domain as S. carlsbergensis alpha-glucosidase and Aspergillus oryzae alpha-amylase.