Functional Analysis of Glu380 and Leu383 of Soybean β‐Amylase

Totsuka, Atsushi; Fukazawa, Chikafusa

doi:10.1111/j.1432-1033.1996.0655h.x

Cited by 22 publications

(15 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The structural analysis of the soybean maltose-␤-amylase complex indicated that Glu 186 and Glu 380 play important roles in the enzymatic reaction as general acid and base catalysts, respectively (16). This finding is supported by the results of site-directed mutagenesis (17,18) and affinity labeling (19). In addition, the structures of ␣-CD⅐␤-amylase and maltose⅐␤-amylase complexes revealed that a flexible loop plays a key role in the reaction.…”

mentioning

confidence: 80%

“…Leu 383 , which forms an inclusion complex, is one of the residues that contribute to the slipping mechanism (12). Totsuka et al (18) suggested by site-directed mutagenesis that Leu 383 may work to bind polymeric substrate as a winder (18). Probably, Leu 383 plays an important role in the single chain attack mechanism as well as in the binding of polymeric substrate, because the residue seems to block the cleaved substrate from release into the solvent (see Fig.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Crystal Structure of Recombinant Soybean β-Amylase Complexed with β-Cyclodextrin

Adachi

Mikami

Katšube³

et al. 1998

Journal of Biological Chemistry

View full text Add to dashboard Cite

In order to study the interaction of soybean ␤-amylase with substrate, we solved the crystal structure of ␤-cyclodextrin-enzyme complex and compared it with that of ␣-cyclodextrin-enzyme complex. The enzyme was expressed in Escherichia coli at a high level as a soluble and catalytically active protein. The purified recombinant enzyme had properties nearly identical to those of native soybean ␤-amylase and formed the same crystals as the native enzyme. The crystal structure of recombinant enzyme complexed with ␤-cyclodextrin was refined at 2.07-Å resolution with a final crystallographic R value of 15.8% (R free ‫؍‬ 21.1%). The root mean square deviation in the position of C-␣ atoms between this recombinant enzyme and the native enzyme was 0.22 Å. These results indicate that the expression system established here is suitable for studying structure-function relationships of ␤-amylase. The conformation of the bound ␤-cyclodextrin takes an ellipsoid shape in contrast to the circular shape of the bound ␣-cyclodextrin. The cyclodextrins shared mainly two glucose binding sites, 3 and 4. The glucose residue 4 was slightly shifted from the maltose binding site. This suggests that the binding site of the cyclodextrins is important for its holding of a cleaved substrate, which enables the multiple attack mechanism of ␤-amylase.␤-Amylase (␣-1,4-glucan maltohydrolase; EC 3.2.1.2) catalyzes the removal of ␤-anomeric maltose from the nonreducing ends of starch and glycogen. This enzyme is distributed in higher plants and in some microorganisms. The cDNAs from five kinds of plants (soybean (1), barley (2), rye (3), Arabidopsis thaliana (4), and sweet potato (5)) and those of three kinds of bacterium (Bacillus polymixa (6, 7), Bacillus circulans (8), and Clostridium thermosulfurogenes (9)) have been cloned and sequenced. Plant ␤-amylases are similar to each other in terms of their physicochemical properties, i.e. molecular mass (50 -60 kDa), optimum pH, amino acid sequence, and their subunit structure (with the exception of the homotetramer sweet potato ␤-amylase) (10 -12).cDNAs of ␤-amylase from barley, sweet potato, and soybean have been expressed in E. coli (1,5,13). Yoshigi et al. (14) tried to produce the thermostable barley ␤-amylase by random and site-directed mutagenesis using the E. coli expression system. The produced 7-fold mutant was more stable than the wild-type recombinant enzyme by 11.6°C (14). The soybean ␤-amylase was expressed using pKK233-2 expression vector (1). The catalytic efficiency of the recombinant enzyme, however, was lower than that of the native enzyme.The crystal structure of native soybean ␤-amylase complexed with ␣-cyclodextrin (␣-CD) 1 was solved at 2.0 Å (12) by the isomolphous replacement method. Cheong et al. (15) reported the crystal structure of tetrameric sweet potato ␤-amylase at 2.3-Å resolution. The structural analysis of the soybean maltose-␤-amylase complex indicated that Glu 186 and Glu 380 play important roles in the enzymatic reaction as general acid and base catalysts, respectiv...

show abstract

mentioning

confidence: 80%

Section: Discussionmentioning

confidence: 99%

Crystal Structure of Recombinant Soybean β-Amylase Complexed with β-Cyclodextrin

Adachi

Mikami

Katšube³

et al. 1998

Journal of Biological Chemistry

View full text Add to dashboard Cite

show abstract

“…The structural analysis of the soybean ␤-amylase (SBA) 1 -maltose complex indicated that Glu 186 and Glu 380 play important roles in the enzymatic reaction as a general acid and a base catalyst, respectively (16). This finding is supported by the results of site-directed mutagenesis (22) and affinity labeling (23). In the case of B. cereus ␤-amylase (BCB), Glu 172 and Glu 367 act as the general acid and base catalyst, respectively, corresponding to Glu 186 and Glu 380 in soybean ␤-amylase (20,21).…”

mentioning

confidence: 84%

Structural and Enzymatic Analysis of Soybean β-Amylase Mutants with Increased pH Optimum

Hirata

Adachi

Sekine

et al. 2004

Journal of Biological Chemistry

View full text Add to dashboard Cite

Comparison of the architecture around the active site of soybean ␤-amylase and Bacillus cereus ␤-amylase showed that the hydrogen bond networks (Glu 380 -(Lys 295 -Met 51 ) and Glu 380 -Asn 340 -Glu 178 ) in soybean ␤-amylase around the base catalytic residue, Glu 380 , seem to contribute to the lower pH optimum of soybean ␤-amylase. To convert the pH optimum of soybean ␤-amylase (pH 5.4) to that of the bacterial type enzyme (pH 6.7), three mutants of soybean ␤-amylase, M51T, E178Y, and N340T, were constructed such that the hydrogen bond networks were removed by site-directed mutagenesis. The kinetic analysis showed that the pH optimum of all mutants shifted dramatically to a neutral pH (range, from 5.4 to 6.0 -6.6). The K m values of the mutants were almost the same as that of soybean ␤-amylase except in the case of M51T, while the V max values of all mutants were low compared with that of soybean ␤-amylase. The crystal structure analysis of the wild typemaltose and mutant-maltose complexes showed that the direct hydrogen bond between Glu 380 and Asn 340 was completely disrupted in the mutants M51T, E178Y, and N340T. In the case of M51T, the hydrogen bond between Glu 380 and Lys 295 was also disrupted. These results indicated that the reduced pK a value of Glu 380 is stabilized by the hydrogen bond network and is responsible for the lower pH optimum of soybean ␤-amylase compared with that of the bacterial ␤-amylase.

show abstract

“…The three‐dimensional model of the C. sepium β‐amylase strongly resembles that of the soybean [33,39] and sweet potato [38]β‐amylases and shares the typical (α/β) 8 barrel core which is common to all other β‐amylases of different origins [44]. According to both structural [33,39] and functional data [45–47], four amino‐acid residues (Asp101, Glu186, Glu345 and Glu380) located in a cleft occurring between the (α/β) 8 barrel core and the smaller globular region play a key role in the catalytic activity of the soybean β‐amylase. These four residues are conserved in all other plant β‐amylases including the C. sepium β‐amylase.…”

Section: Discussionmentioning

confidence: 99%

“…origins [44]. According to both structural [33,39] and functional data [45][46][47], four amino-acid residues (Asp101, Glu186, Glu345 and Glu380) located in a cleft occurring between the (a/b) 8 barrel core and the smaller globular region play a key role in the catalytic activity of the soybean b-amylase. These four residues are conserved in all other plant b-amylases including the C. sepium b-amylase.…”

Section: Discussionmentioning

confidence: 99%

Purification, characterization, immunolocalization and structural analysis of the abundant cytoplasmic β‐amylase from Calystegia sepium (hedge bindweed) rhizomes

Damme

Barre

et al. 2001

European Journal of Biochemistry

View full text Add to dashboard Cite

An abundant catalytically active b-amylase (EC 3.2.1.2) was isolated from resting rhizomes of hedge bindweed (Calystegia sepium ). Biochemical analysis of the purified protein, molecular modeling, and cloning of the corresponding gene indicated that this enzyme resembles previously characterized plant b-amylases with regard to its amino-acid sequence, molecular structure and catalytic activities.Immunolocalization demonstrated that the b-amylase is exclusively located in the cytoplasm. It is suggested that the hedge bindweed rhizome b-amylase is a cytoplasmic vegetative storage protein.Keywords: b-amylase; Calystegia sepium; hedge bindweed; immunolocalization; vegetative storage protein.Exo-hydrolases catalyzing the release of b-maltose from the nonreducing ends of a-1,4-linked oligo-and polyglucans (also so-called b-or exo-amylases) (EC 3.2.1.2) have been studied for several decades because they are possibly involved in starch metabolism in plants, and play an important role in biotechnological processes whereby starch is converted into simple sugars. In the past, research on b-amylases has been focussed on the abundant b-amylases found in the endosperm of barley (Hordeum vulgare ) and some other cereals [1], soybean (Glycine max ) seeds [2] and sweet potato (Ipomoea batatas ) tubers [3]. During the last decade, evidence has accumulated that b-amylases are ubiquitous in flowering plants. Cereals such as barley, wheat (Triticum aestivum ), rye (Secale cereale ) and maize (Zea mays ) also contain, besides the classical abundant and highly active endosperm b-amylases, low levels of another so-called 'tissue-ubiquitous' form in leaves and roots [1]. b-Amylases have also been identified in roots of alfalfa (Medicago sativa ) and several other forage legumes including sweetclover (Melilotus officinalis ), red clover (Trifolium pratense ), birdsfoot trefoil (Lotus corniculatus )[4], and in pea (Pisum sativum ) epicotyls [5]. In addition, b-amylases have been identified in species of the families Solanaceae (potato, Solanum tuberosum ) [6] and Brassicaceae (Arabidopsis thaliana and Streptanthus tortuosus ) [7,8].Extensive enzymatic studies of several b-amylases unambiguously demonstrated that these enzymes exclusively catalyze the release of b-maltose from the nonreducing ends of a-1,4-linked oligo-and polyglucans. Accordingly, b-amylases are believed to be involved in the degradation of starch in the plant and/or a-1,4-linked oligoglucans. Though this presumed role might hold true for some b-amylases, it certainly cannot be extrapolated to all plant b-amylases because (a) some b-amylases occur in tissues that are devoid of starch, (b) many plant b-amylases are spatially separated from their presumed substrate (i.e. starch), and (c) inbred lines of rye lacking the abundant endosperm b-amylase germinate normally [9]. This implies that some b-amylases are not required and even not involved in starch degradation but fulfil another role [10]. It has been proposed, for example, that the abundant b-amylases from cereal endos...

show abstract

Functional Analysis of Glu380 and Leu383 of Soybean β‐Amylase

Cited by 22 publications

References 34 publications

Crystal Structure of Recombinant Soybean β-Amylase Complexed with β-Cyclodextrin

Crystal Structure of Recombinant Soybean β-Amylase Complexed with β-Cyclodextrin

Structural and Enzymatic Analysis of Soybean β-Amylase Mutants with Increased pH Optimum

Purification, characterization, immunolocalization and structural analysis of the abundant cytoplasmic β‐amylase from Calystegia sepium (hedge bindweed) rhizomes

Contact Info

Product

Resources

About