Crystal Structure of Rice α-Galactosidase Complexed with D-Galactose

Fujimoto, Zui; Kaneko, Satoshi; Momma, Mitsuru; Kobayashi, Hideyuki; Mizuno, Hiroshi

doi:10.1074/jbc.m302292200

Cited by 106 publications

(137 citation statements)

References 34 publications

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“…The active site of family 27 acid a-Gals was predicted to contain two carboxyl groups (Mathew and Balasubramaniam, 1987), one serving as the catalytic nucleophile and the other one as the general acid/base catalyst. Recently, crystallization of a rice a-Gal confirmed the identity of Asp in the conserved motif LKYDNC after the fourth b-sheet as the catalytic nucleophile as shown previously for green coffee bean a-Gal (Ly et al, 2000;Fujimoto et al, 2002Fujimoto et al, , 2003. Further, Asp in the motif DIXD was shown to be the acid/base catalyst, and Trp in the conserved motif TPPMGWNSWN is discussed to function in hydrophobic substrate binding of the glycosyl oligosaccharids (Fujimoto et al, 2003).…”

Section: Discussionmentioning

confidence: 76%

“…Recently, crystallization of a rice a-Gal confirmed the identity of Asp in the conserved motif LKYDNC after the fourth b-sheet as the catalytic nucleophile as shown previously for green coffee bean a-Gal (Ly et al, 2000;Fujimoto et al, 2002Fujimoto et al, , 2003. Further, Asp in the motif DIXD was shown to be the acid/base catalyst, and Trp in the conserved motif TPPMGWNSWN is discussed to function in hydrophobic substrate binding of the glycosyl oligosaccharids (Fujimoto et al, 2003). When GGT was modeled in the known structure of rice a-Gal (SWISS-MODEL; http://swissmodel.expasy.org/), Asp-162 and Asp-217 as well as Trp-45 of GGT precisely superimposed over the respective Asp and Trp residues of rice a-Gal mentioned above (Fig.…”

Section: Discussionmentioning

confidence: 88%

“…This classification not only reflects substrate specificities and molecular mechanisms but also structural features of these enzymes. Hydrophobic cluster analysis of the GGT peptide sequence revealed that the catalytic domain of GGT comprised of an (a/b) 8 -barrel and a C-terminal domain made up of eight b-strands containing a Greek key motif, just like the plant acid a-Gal from rice (Fujimoto et al, 2003). The active site of family 27 acid a-Gals was predicted to contain two carboxyl groups (Mathew and Balasubramaniam, 1987), one serving as the catalytic nucleophile and the other one as the general acid/base catalyst.…”

Section: Discussionmentioning

confidence: 99%

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Cloning, Functional Expression, and Characterization of the Raffinose Oligosaccharide Chain Elongation Enzyme, Galactan:Galactan Galactosyltransferase, from Common Bugle Leaves

2004

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Galactan:galactan galactosyltransferase (GGT) is a unique enzyme of the raffinose family oligosaccharide (RFO) biosynthetic pathway. It catalyzes the chain elongation of RFOs without using galactinol (a-galactosyl-myoinositol) by simply transferring a terminal a-galactosyl residue from one RFO molecule to another one. Here, we report the cloning and functional expression of a cDNA encoding GGT from leaves of the common bugle (Ajuga reptans), a winter-hardy long-chain RFO-storing Lamiaceae. The cDNA comprises an open reading frame of 1215 bp. Expression in tobacco (Nicotiana plumbaginifolia) protoplasts resulted in a functional recombinant protein, which showed GGT activity like the previously described purified, native GGT enzyme. At the amino acid level, GGT shows high homologies ([60%) to acid plant a-galactosidases of the family 27 of glycosylhydrolases. It is clearly distinct from the family 36 of glycosylhydrolases, which harbor galactinol-dependent raffinose and stachyose synthases as well as alkaline a-galactosidases. Physiological studies on the role of GGT confirmed that GGT plays a key role in RFO chain elongation and carbon storage. When excised leaves were exposed to chilling temperatures, levels of GGT transcripts, enzyme activities, and long-chain RFO concentrations increased concomitantly. On a whole-plant level, chilling temperatures induced GGT expression mainly in the roots and fully developed leaves, both known RFO storage organs of the common bugle, indicating an adaptation of the metabolism from active growth to transient storage in the cold.

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Section: Discussionmentioning

confidence: 76%

Section: Discussionmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 99%

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Cloning, Functional Expression, and Characterization of the Raffinose Oligosaccharide Chain Elongation Enzyme, Galactan:Galactan Galactosyltransferase, from Common Bugle Leaves

2004

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“…Homology models of the first two domains and the C-terminal carbohydrate-binding module family 13 (CBM13) of SaArap27A were built with the MODELER program (Accelrys Software Inc., San Diego, CA) using the known crystal structures of rice ␣-galactosidase and CBM13 of Streptomyces olivaceoviridis ␤-xylanase (SoCBM13), respectively, as reference models (25,26). The first run of the MOLREP program (27) in the CCP4 program suite (28) using the ␣-galactosidase-derived model as the reference against the native data resulted in two prominent solutions yielding an R factor of 0.553.…”

Section: Methodsmentioning

confidence: 99%

“…Enzymatic Properties-␤-L-Arabinopyranosidase activity was determined using a mixture containing 25 . One unit of enzyme activity is defined as the amount of enzyme that released 1 mol of PNP per minute.…”

Section: Methodsmentioning

confidence: 99%

A β-l-Arabinopyranosidase from Streptomyces avermitilis Is a Novel Member of Glycoside Hydrolase Family 27

Ichinose

Fujimoto

Honda

et al. 2009

Journal of Biological Chemistry

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Arabinogalactan proteins (AGPs) are a family of plant cell surface proteoglycans and are considered to be involved in plant growth and development. Because AGPs are very complex molecules, glycoside hydrolases capable of degrading AGPs are powerful tools for analyses of the AGPs. We previously reported such enzymes from Streptomyces avermitilis. Recently, a ␤-Larabinopyranosidase was purified from the culture supernatant of the bacterium, and its corresponding gene was identified. The primary structure of the protein revealed that the catalytic module was highly similar to that of glycoside hydrolase family 27 (GH27) ␣-D-galactosidases. The recombinant protein was successfully expressed as a secreted 64-kDa protein using a Streptomyces expression system. The specific activity toward p-nitrophenyl-␤-L-arabinopyranoside was 18 mol of arabinose/min/mg, which was 67 times higher than that toward pnitrophenyl-␣-D-galactopyranoside. The enzyme could remove 0.1 and 45% L-arabinose from gum arabic or larch arabinogalactan, respectively. X-ray crystallographic analysis reveals that the protein had a GH27 catalytic domain, an antiparallel ␤-domain containing Greek key motifs, another antiparallel ␤-domain forming a jellyroll structure, and a carbohydrate-binding module family 13 domain. Comparison of the structure of this protein with that of ␣-D-galactosidase showed a single amino acid substitution (aspartic acid to glutamic acid) in the catalytic pocket of ␤-L-arabinopyranosidase, and a space for the hydroxymethyl group on the C-5 carbon of D-galactose bound to ␣-galactosidase was changed in ␤-L-arabinopyranosidase. Mutagenesis study revealed that the residue is critical for modulating the enzyme activity. This is the first report in which ␤-L-arabinopyranosidase is classified as a new member of the GH27 family.Arabinogalactan proteins (AGPs) 3 are a family of complex proteoglycans widely distributed in plants (1, 2). AGPs are also found in tree exudate gums and coniferous woods (3) and are characterized by the presence of large amounts of carbohydrate components rich in galactose (all the sugars in the present study are in the D-configuration unless otherwise specified) and L-arabinose and by protein components rich in hydroxyproline, serine, threonine, alanine, and glycine (4). Type II arabinogalactans and short oligosaccharides are the two types of carbohydrates attached to the AGP backbone. Type II arabinogalactans have ␤-1,3-linked galactosyl backbones in mono-or oligo-␤-1,6-galactosyl and/or L-arabinosyl side chains (2, 5). L-Arabinose and lesser amounts of other auxiliary sugars such as glucuronic acid, L-rhamnose, and L-fucose are attached to the side chains primarily at nonreducing termini (2). Molecular and biochemical evidence indicates that AGPs have specific functions during root formation, promotion of somatic embryogenesis, and attraction of pollen tubes to the style (6). However, because many putative protein cores exist and the structures of the carbohydrate moieties are complex, it has been difficult...

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Increasing the transglycosylation activity of α‐galactosidase from Bifidobacterium adolescentis DSM 20083 by site‐directed mutagenesis

Hinz¹,

Doeswijk-Voragen²,

Schipperus³

et al. 2005

Biotech & Bioengineering

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The alpha-galactosidase (AGA) from Bifidobacterium adolescentis DSM 20083 has a high transglycosylation activity. The optimal conditions for this activity are pH 8, and 37 degrees C. At high melibiose concentration (600 mM), approximately 64% of the enzyme-substrate encounters resulted in transglycosylation. Examination of the acceptor specificity showed that AGA required a hydroxyl group at C-6 for transglycosylation. Pentoses, hexuronic acids, deoxyhexoses, and alditols did not serve as acceptor molecules. Disaccharides were found to be good acceptors. A putative 3D-structure of the catalytic site of AGA was obtained by homology modeling. Based on this structure and amino acid sequence alignments, site-directed mutagenesis was performed to increase the transglycosylation efficiency of the enzyme, which resulted in four positive mutants. The positive single mutations were combined, resulting in six double mutants. The mutant H497M had an increase in transglycosylation of 16%, whereas most of the single mutations showed an increase of 2%-5% compared to the wild-type AGA. The double mutants G382C-Y500L, and H497M-Y500L had an increase in transglycosylation activity of 10%-16%, compared to the wild-type enzyme, whereas the increase for the other double mutants was low (4%-7%). The results show that with a single mutation (H497M) the transglycosylation efficiency can be increased from 64% to 75% of all enzyme-substrate encounters. Combining successful single mutants in double mutations did not necessarily result in an extra increase in transglycosylation efficiency. The donor and acceptor specificity did not change in the mutants, whereas the thermostability of the mutants with G382C decreased drastically.

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Crystal Structure of Rice α-Galactosidase Complexed with D-Galactose

Cited by 106 publications

References 34 publications

Cloning, Functional Expression, and Characterization of the Raffinose Oligosaccharide Chain Elongation Enzyme, Galactan:Galactan Galactosyltransferase, from Common Bugle Leaves

Cloning, Functional Expression, and Characterization of the Raffinose Oligosaccharide Chain Elongation Enzyme, Galactan:Galactan Galactosyltransferase, from Common Bugle Leaves

A β-l-Arabinopyranosidase from Streptomyces avermitilis Is a Novel Member of Glycoside Hydrolase Family 27

Increasing the transglycosylation activity of α‐galactosidase from Bifidobacterium adolescentis DSM 20083 by site‐directed mutagenesis

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