Effect of substrate structure on the activity of Man9‐mannosidase from pig liver involved in N‐linked oligosaccharide processing

Man9‐mannosidase, an α1,2‐specific enzyme located in the endoplasmic reticulum and involved in N‐linked‐oligosaccharide processing, has been isolated from crude pig‐liver microsomes and its substrate specificity studied using a variety of free and peptide‐bound high‐mannose oligosaccharide derivativ...

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Published in	European journal of biochemistry Vol. 208; no. 2; pp. 451 - 457
Main Authors	BAUSE, Ernst, BREUER, Wilhelm, SCHWEDEN, Jürgen, ROESER, Rainer, GEYER, Rudolf
Format	Journal Article
Language	English
Published	Oxford, UK Blackwell Publishing Ltd 01.09.1992 Blackwell
Subjects	Amino Acid Sequence Analytical, structural and metabolic biochemistry Animals Biological and medical sciences Carbohydrate Conformation Carbohydrate Sequence Cattle Enzymes and enzyme inhibitors Fundamental and applied biological sciences. Psychology Hydrolases Hydrolysis Kinetics Mannose - chemistry Mannose - metabolism Mannosidases - metabolism Microsomes, Liver - enzymology Molecular Sequence Data Molecular Structure Oligosaccharides - chemistry Oligosaccharides - metabolism Structure-Activity Relationship Substrate Specificity Swine Vertebrata Mammalia Enzymatic activity Enzyme Liver Substrate specificity Artiodactyla Ungulata α-D-Mannosidase Pig
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Abstract	Man9‐mannosidase, an α1,2‐specific enzyme located in the endoplasmic reticulum and involved in N‐linked‐oligosaccharide processing, has been isolated from crude pig‐liver microsomes and its substrate specificity studied using a variety of free and peptide‐bound high‐mannose oligosaccharide derivatives. The purified enzyme displays no activity towards synthetic α‐mannosides, but removes three α1,2‐mannose residues from the natural Man9‐(GlcNAc)2 substrate (M9). The α1,2‐mannosidic linkage remaining in the M6 intermediate is cleaved about 40‐fold more slowly. Similar kinetics of hydrolysis were determined with Man9‐(GlcNAc)2 N‐glycosidically attached to the hexapeptide Tyr‐Asn‐Lys‐Thr‐Ser‐Val (GP‐M9), indicating that the specificity of the enzyme is not influenced by the peptide moiety of the substrate. The α1,2‐mannose residue which is largely resistant to hydrolysis, was found to be attached in both the M6 and GP‐M6 intermediate to the α1,3‐mannose of the peripheral α1,3/α1,6‐branch of the glycan chain. Studies with glycopeptides varying in the size and branching pattern of the sugar chains, revealed that the relative rates at which the various α1,2‐mannosidic linkages were cleaved, differed depending on their structural complexity. This suggests that distinct sugar residues in the aglycon moiety may be functional in substrate recognition and binding. Reduction or removal of the terminal GlcNAc residue of the chitobiose unit in M9 increased the hydrolytic susceptibility of the fourth (previously resistant) α1,2‐mannosidic linkage significantly. We conclude from this observation that, in addition to peripheral mannose residues, the intact chitobiose core represents a structural element affecting Man9‐mannosidase specificity. A possible biological role of the enzyme during N‐linked‐oligosaccharide processing is discussed.
AbstractList	Man9-mannosidase, an alpha 1,2-specific enzyme located in the endoplasmic reticulum and involved in N-linked-oligosaccharide processing, has been isolated from crude pig-liver microsomes and its substrate specificity studied using a variety of free and peptide-bound high-mannose oligosaccharide derivatives. The purified enzyme displays no activity towards synthetic alpha-mannosides, but removes three alpha 1,2-mannose residues from the natural Man9-(GlcNAc)2 substrate (M9). The alpha 1,2-mannosidic linkage remaining in the M6 intermediate is cleaved about 40-fold more slowly. Similar kinetics of hydrolysis were determined with Man9-(GlcNAc)2 N-glycosidically attached to the hexapeptide Tyr-Asn-Lys-Thr-Ser-Val (GP-M9), indicating that the specificity of the enzyme is not influenced by the peptide moiety of the substrate. The alpha 1,2-mannose residue which is largely resistant to hydrolysis, was found to be attached in both the M6 and GP-M6 intermediate to the alpha 1,3-mannose of the peripheral alpha 1,3/alpha 1,6-branch of the glycan chain. Studies with glycopeptides varying in the size and branching pattern of the sugar chains, revealed that the relative rates at which the various alpha 1,2-mannosidic linkages were cleaved, differed depending on their structural complexity. This suggests that distinct sugar residues in the aglycon moiety may be functional in substrate recognition and binding. Reduction or removal of the terminal GlcNAc residue of the chitobiose unit in M9 increased the hydrolytic susceptibility of the fourth (previously resistant) alpha 1,2-mannosidic linkage significantly. We conclude from this observation that, in addition to peripheral mannose residues, the intact chitobiose core represents a structural element affecting Man9-mannosidase specificity. A possible biological role of the enzyme during N-linked-oligosaccharide processing is discussed. Man9‐mannosidase, an α1,2‐specific enzyme located in the endoplasmic reticulum and involved in N‐linked‐oligosaccharide processing, has been isolated from crude pig‐liver microsomes and its substrate specificity studied using a variety of free and peptide‐bound high‐mannose oligosaccharide derivatives. The purified enzyme displays no activity towards synthetic α‐mannosides, but removes three α1,2‐mannose residues from the natural Man9‐(GlcNAc)2 substrate (M9). The α1,2‐mannosidic linkage remaining in the M6 intermediate is cleaved about 40‐fold more slowly. Similar kinetics of hydrolysis were determined with Man9‐(GlcNAc)2 N‐glycosidically attached to the hexapeptide Tyr‐Asn‐Lys‐Thr‐Ser‐Val (GP‐M9), indicating that the specificity of the enzyme is not influenced by the peptide moiety of the substrate. The α1,2‐mannose residue which is largely resistant to hydrolysis, was found to be attached in both the M6 and GP‐M6 intermediate to the α1,3‐mannose of the peripheral α1,3/α1,6‐branch of the glycan chain. Studies with glycopeptides varying in the size and branching pattern of the sugar chains, revealed that the relative rates at which the various α1,2‐mannosidic linkages were cleaved, differed depending on their structural complexity. This suggests that distinct sugar residues in the aglycon moiety may be functional in substrate recognition and binding. Reduction or removal of the terminal GlcNAc residue of the chitobiose unit in M9 increased the hydrolytic susceptibility of the fourth (previously resistant) α1,2‐mannosidic linkage significantly. We conclude from this observation that, in addition to peripheral mannose residues, the intact chitobiose core represents a structural element affecting Man9‐mannosidase specificity. A possible biological role of the enzyme during N‐linked‐oligosaccharide processing is discussed.
Author	ROESER, Rainer GEYER, Rudolf BAUSE, Ernst BREUER, Wilhelm SCHWEDEN, Jürgen
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SubjectTerms	Amino Acid Sequence Analytical, structural and metabolic biochemistry Animals Biological and medical sciences Carbohydrate Conformation Carbohydrate Sequence Cattle Enzymes and enzyme inhibitors Fundamental and applied biological sciences. Psychology Hydrolases Hydrolysis Kinetics Mannose - chemistry Mannose - metabolism Mannosidases - metabolism Microsomes, Liver - enzymology Molecular Sequence Data Molecular Structure Oligosaccharides - chemistry Oligosaccharides - metabolism Structure-Activity Relationship Substrate Specificity Swine
Title	Effect of substrate structure on the activity of Man9‐mannosidase from pig liver involved in N‐linked oligosaccharide processing
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