Isolation of a cDNA Clone for α-Amylase in Mung Bean Cotyledons

Koizuka, Nobuya; Tanaka, Yoshiyuki; Morohashi, Yukio

doi:10.1104/pp.94.3.1488

Cited by 14 publications

(12 citation statements)

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“…The design of these primers was based on the following two criteria: (i) both primers correspond to highly conserved regions in the a-amylase genes and (ii) the PCR products for the AmyA and AmyB genes could be easily resolved by polyacrylamide gel electrophoresis. The two mung bean a-amylase gene primers were based on the previously published sequence information (30).…”

Section: Methodsmentioning

confidence: 99%

“…Since zymograms do not resolve the a-amylase isozymes of rice into distinct high and low pI groups (2,19), it has been difficult to relate these isozymes to those observed in barley and wheat. Subsequently, Huang et al (20) used DNA-DNA hybridization to classify 30 rice genomic clones into five hybridization groups. These five groups were eventually consolidated into three subfamilies (Amyl, Amy2, and Amy3) on the basis of protein comparisons to other wheat and barley a-amylase genes (8,(20)(21)(22).…”

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confidence: 99%

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Classification and evolution of alpha-amylase genes in plants.

Huang

Stebbins

Rodriguez

1992

Proc. Natl. Acad. Sci. U.S.A.

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The DNA sequences for 17 plant genes for a-amylase (EC 3.2.1.1) were analyzed to determine their phylogenetic relationship. A phylogeny for these genes was obtained using two separate approaches, one based on molecular clock assumptions and the other based on a comparison of sequence polymorphisms (i.e., small and localized insertions) in the a-amylase genes. These polymorphisms are called "ra-amylase signatures" because they are diagnostic of the gene subfamily to which a particular a-amylase gene belongs. Results indicate that the cereal a-amylase genes fall into two major classes: AmyA and AmyB. The AmyA class is subdivided into the Amyl and Amy2 subfamilies previously used to classify a-amylase genes in barley and wheat. The AmyB class includes the Amy3 subfamily to which most of the a-amylase genes of rice belong. Using polymerase chain reaction and oligonucleotide primers that flank one of the two signatu regions, we show that the AmyA and AmyB gene classes are present in approximately equal amounts in all grass species exined except barley. The AmyB (Amy3 subfamily) genes in the latter case are comparatively underrepresented. Additional evidence suggests that the AmyA genes appeared recently and may be confined to the grass family.a-Amylase (EC 3.2.1.1) plays a key role in the metabolism of the plant by hydrolyzing starch in the germinating seed and in other tissues. This is accomplished primarily through the 1,4-a endoglycolytic cleavage of amylose and amylopectin, the principal components of starch granules in plant cells. Because of its importance to cereal seed germination and malting, the genetic basis and biochemical mechanism of this process have been the subject of study for many years (1). More recent descriptions of the biology and biochemistry of plant a-amylases have been reviewed by Akazawa et al. (2) and Fincher (3).Protein sequence comparisons of a-amylases from plants, animals, and microbes reveal four highly conserved domains that correspond to sites necessary for enzyme structure and/or function (4). A subsequent comparison of 11 different cereal a-amylase proteins revealed the same four sites plus three additional sites (5). Two of these correspond to intron splice sites, whereas the third may represent a duplication of the calcium binding site, essential for enzyme stability. These results clearly indicate a common ancestry for the a-amylases and conservation of critical sequences over evolutionary time.Although three a-amylase isozymes have been detected in germinating rice seeds (6, 7), it is now known that a-amylase isozymes are encoded by a family of 10 genes located on five different chromosomes (8-10). Multiple a-amylase genes are also known to exist in barley (11) and wheat (12). In barley, 7 genes encoding a-amylase isozymes with high isoelectric

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Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

Classification and evolution of alpha-amylase genes in plants.

Huang

Stebbins

Rodriguez

1992

Proc. Natl. Acad. Sci. U.S.A.

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“…respectively (9,34,35,46,56 (6). Furthermore, NE2 of His 201 from the Lys-His-Z motif in PPA forms a hydrogen bond with sugar OH-2 in subsite ϩ1, i.e.…”

Section: Discussionmentioning

confidence: 99%

“…A conserved region in the ␤-␣ loop extending at the C terminus of the fourth ␤-strand of the (␤/␣) 8 -fold is interpreted to play an important role in the specificity (25, 27, 30 -32). Remarkably, Arg 183 -Gly 184 -Tyr 185 at this loop in AMY1 is distinctive to plant ␣-amylases; others have Lys-His-Z, where Z is hydrophobic (9,25,27,(33)(34)(35). Arg 183 in AMY1 aligns with Lys 182 in AMY2 (9), which in the crystal structure of AMY2-acarbose (71) forms a hydrogen bond to OH-3 of the sugar ring at subsite ϩ2 and in the crystal structure of AMY2-BASI (36) interacts with a glu-…”

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confidence: 99%

Improved Activity and Modulated Action Pattern Obtained by Random Mutagenesis at the Fourth β-α Loop Involved in Substrate Binding to the Catalytic (β/α)8-Barrel Domain of Barley α-Amylase 1

Matsui

Svensson

1997

Journal of Biological Chemistry

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␣-Amylase (␣-1,4-D-glucan glucanohydrolase, EC 3.2.1.1) hydrolyzes internal ␣-1,4-glucosidic bonds in starch and related oligo-and polysaccharides. High resolution x-ray structures are known for Taka-amylase A (TAA) 1 from Aspergillus oryzae(1), acid ␣-amylase from Aspergillus niger (2), isozyme I of porcine pancreatic ␣-amylase (PPA; Ref.3), the AMY2-2 isoform from barley malt (4), and an inactive, protease-cleaved form of ␣-amylase from Bacillus licheniformis (5). These enzymes are organized in three domains, an N-terminal catalytic (␤/␣) 8 -barrel fold (domain A) having a long ␤-␣ loop (domain B) protruding at the third ␤-strand and a C-terminal either fiveor eight-stranded ␤-sheet (domain C). Oligosaccharide inhibitor complexes are determined of TAA (1), PPA (6), and AMY2-2 (71). The structure of Saccharomycopsis fibuligera ␣-amylase (Sfamy) was modelled on that of TAA (7). Barley ␣-amylases occur in two isozyme families (8), a low pI (AMY1) and a high pI (AMY2), of 80% sequence identity (9) but significantly different substrate affinity, turnover rate (10 -12), Ca 2ϩ dependence of activity (13-15), and stability (13, 15, 16). Only AMY2 is inhibited by the endogenous ␣-amylase/subtilisin inhibitor (BASI) present in barley seeds (17, 18). The subsite maps of binding affinities for substrate glucosyl residues are very similar for AMY1 and AMY2 and comprise ten subsites, six toward the nonreducing and four toward the reducing end relative to the cleavage point in linear maltooligosaccharides (19). They moreover possess, like subsite maps from Bacillus subtilis (20) and Bacillus amyloliquefaciens ␣-amylases (21), TAA (22), and Sfamy (23), a large negative affinity, indicating distortion of the glucose residue at the catalytic site, flanked by two subsites of large positive affinity.Sequence alignment and prediction of secondary structures indicated that different starch hydrolases and related enzymes contain a catalytic (␤/␣) 8 -barrel similar to the ␣-amylases (24,25). In a recent structure-based classification of glycosylases, these amylolytic enzymes belong to family 13 (26), currently including 18 EC classes, representing variations in substrate/ product specificity (27). Seven short conserved sequences characterize family 13 members, but only seven amino acid residues are invariant (28, 29). Although ␣-amylases strictly hydrolyze the ␣-1,4, related enzymes can act on either ␣-1,4 or ␣-1,6 glucosidic bonds or have dual bond-type specificity. A conserved region in the ␤-␣ loop extending at the C terminus of the fourth ␤-strand of the (␤/␣) 8 -fold is interpreted to play an important role in the specificity (25, 27, 30 -32). Remarkably, Arg 183 -Gly 184 -Tyr 185 at this loop in AMY1 is distinctive to plant ␣-amylases; others have Lys-His-Z, where Z is hydrophobic (9,25,27,(33)(34)(35). Arg 183 in AMY1 aligns with Lys 182 in AMY2 (9), which in the crystal structure of AMY2-acarbose (71) forms a hydrogen bond to OH-3 of the sugar ring at subsite ϩ2 and in the crystal structure of AMY2-BASI (36) interacts with a ...

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“…7) In leguminous plants, a-amylase is expressed in cotyledons during seed germination, where its mRNA was isolated. [8][9][10] The a-amylase is localized in lytic vacuoles in cotyledon cells, and starch granules are transported into the vacuoles via an autophagic process, and hydrolyzed there. 11) An Arabidopsis mutant suggested that one of the a-amylases in the plant is responsible for degradation of transitory starch in chloroplasts.…”

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confidence: 99%

Purification, Characterization, and Sequence Analysis of Two α-Amylase Isoforms from Azuki Bean,Vigna angularis, Showing Different Affinity towards β-Cyclodextrin Sepharose

Mar

Mori

Lee

et al. 2003

Bioscience, Biotechnology, and Biochemistry

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Two alpha-amylase isoforms designated VAAmy1 and VAAmy2 were purified from cotyledons of germinating seedlings of azuki bean (Vigna angularis). VAAmy1 apparently had lower affinity towards a beta-cyclodextrin Sepharose column than VAAmy2. Molecular weights of VAAmy1 and VAAmy2 were estimated to be 47,000 and 44,000, respectively. However, no considerable difference was found between them in effects of pH, temperature, CaCl2, and EDTA, as well as the kinetic parameters for amylose (average degree of polymerization 17): kcat, 71.8 and 55.5 s(-1), Km, 0.113 and 0.097 mg/ml; for blocked 4-nitrophenyl alpha-D-maltoheptaoside: kcat, 62.4 and 85.3 s(-1), Km, 0.22 and 0.37 mM, respectively. Primary structures of the two enzymes were analyzed by N-terminal sequencing, cDNA cloning, and MALDI-TOF mass spectrometry, implying that the two enzymes have the same peptide. The results indicated that the low affinity of VAAmy1 towards beta-cyclodextrin Sepharose was due to some modification on/near carbohydrate binding site in the limited sequence regions, resulting in higher molecular weight.

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Isolation of a cDNA Clone for α-Amylase in Mung Bean Cotyledons

Cited by 14 publications

References 9 publications

Classification and evolution of alpha-amylase genes in plants.

Classification and evolution of alpha-amylase genes in plants.

Improved Activity and Modulated Action Pattern Obtained by Random Mutagenesis at the Fourth β-α Loop Involved in Substrate Binding to the Catalytic (β/α)8-Barrel Domain of Barley α-Amylase 1

Purification, Characterization, and Sequence Analysis of Two α-Amylase Isoforms from Azuki Bean,Vigna angularis, Showing Different Affinity towards β-Cyclodextrin Sepharose

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