Sucrase-isomaltase

sucrase-isomaltase (alpha-glucosidase)
Identifiers
Symbol	SI
Entrez	6476
HUGO	10856
OMIM	609845
PDB	3LPO
RefSeq	NM_001041
UniProt	P14410
Other data
EC number	3.2.1.10
Locus	Chr. 3 q25.2-26.2

Sucrase-isomaltase (EC 3.2.1.10, oligo-1,6-glucosidase, limit dextrinase, isomaltase, exo-oligo-1,6-glucosidase, dextrin 6alpha-glucanohydrolase, alpha-limit dextrinase, dextrin 6-glucanohydrolase, oligosaccharide alpha-1,6-glucohydrolase) is a glucosidase enzyme located in on the brush border of the small intestine with systematic name oligosaccharide 6-alpha-glucohydrolase.^[1]^[2]^[3] Sucrase-isomaltase is a type II transmembrane glycoprotein located in the brush border of the small intestine. It has preferential expression in the apical membranes of enterocytes.^[4] The enzyme’s purpose is to digest dietary carbohydrates such as starch, glucose, and isomaltose. By further processing the broken-down products, energy in the form of ATP can be generated.^[5]

Enzyme Mechanism

This enzyme catalyses the following chemical reaction

Hydrolysis of (1->6)-alpha-D-glucosidic linkages in some oligosaccharides produced from starch and glycogen by enzyme EC 3.2.1.1.

Hydrolysis uses water to cleave chemical bonds. Sucrase-isomaltase’s mechanism results in a net retention of configuration at the anomeric center.^[6]

Mechanism for how sucrase-isomaltase catalyzes the conversion of isomaltose to two glucose molecules

Enzyme Structure

Sucrase-isomaltase consists of two enzymatic subunits: sucrase and isomaltase. The subunits originate from a polypeptide precursor, pro-SI. By heterodimerizing the two subunits, the sucrase-isomaltase complex is formed.^[7] The enzyme is anchored in the intestinal brush border membrane by a hydrophobic segment located near the N-terminal of the isomaltase subunit.^[8] Before the enzyme is anchored to the membrane, pro-SI is mannose-rich and glycosylated; it moves from the ER to the Golgi, where it becomes a protein complex that is N- and O- glycosylated. The O-linked glycosylation is necessary to target the protein to the apical membrane.^[9]^[10] In addition, there is a segment that is both O-linked glycosylated and Ser/Thr-rich.^[11]

Sucrase-isomaltase is composed of duplicated catalytic domains, N- and C-terminal. Each domain displays overlapping specificities. Scientists have discovered the crystal structure for N-terminal human sucrase-isomaltase (ntSI) in apo form to 3.2 Å and in complex with the inhibitor kotalanol to 2.15 Å resolution.^[6]

The crystal structure shows that sucrase-isomaltase exists as a monomer. The researchers claim that the observance of SI dimers is dependent on experimental conditions.^[6] ntSI’s four monomers, A, B, C, and D are included in the crystal asymmetric unit and have identical active sites. The active site is composed of a shallow-substrate binding pocket including -1 and +1 subsites. The non-reducing end of substrates binds to the pocket. While the non-reducing sugar ring has interactions with the buried -1 subsite, the reducing ring has interactions with the surface exposed +1 subsite.^[6]

Sim et al. describes the interactions between the active site of sucrase-isomaltase and the following compounds:

Man2GlcNAc2 glycan: Within the active site, Man2GlcNAc2 hydrogen bonds with hydroxyl side chains of Asp231 and Asp571. Furthermore, hydrophobic interactions with Leu233, Trp327, Trp435, Phe479, Val605, and Tyr634 provide additional stabilization for Man2GlcNAc2.^[6]
Kotalonal, the inhibitor: It interacts with the catalytic nucleophile Asp472 and acid base catalyst Asp571. In addition, ntSI residues His629, Asp355, Arg555, Asp231, Trp435, and Phe479 bind to the substrate.^[6]

Key residues that interact with substrate where turquoise residues correspond to interactions with Man2GlcNAc2, pink residues correspond to interactions with kotalonal, and magenta residues corresponds to interactions with both Man2GlcNAc2 and kotalonal. Generated from 3LPO^[6]

Currently, there are no crystal structures of ntSI in complex with an α-1,6-linked substrate or inhibitor analogue. In order to predict isomaltose binding in sucrase-isomaltase structure, a model was produced by hand. Within the -1 subsite, isomaltose’s non-reducing glucose ring was aligned to that of acarbose.^[6]

Not only has the structure of human sucrase-isomaltase been studied, but also sucrase-isomaltase’s structure in sea lions and pigs have also been analyzed.^[2]^[12]^[13]

Disease Relevance

A deficiency is responsible for sucrose intolerance. Congenital sucrase-isomaltase deficiency (CSID), also called sucrose intolerance, is an autosomal-recessive intestinal disorder that is caused by a reduction or absence of sucrase and isomaltase activities.^[10] Explanations for CSID include:

Mutations C1229Y and F1745C, which are present in the sucrase domain of SI, block SI path to anchor in the cell’s aprical membrane but does not impact protein folding or isomaltase activity.^[10]
Substitution of a cysteine by an arginine at amino acid residue 635 in the isomaltase subunit of SI was present in the cDNA encoding for a patient with CSID. SIC635R had an altered folding pattern, which influenced the sorting profile and increased the turnover rate.^[14]
A factor that can be attributed to congenital sucrase-isomaltase deficiency is the retention of SI in the cis-Golgi. This inability to transport is a result of a glutamine to proline substitution at amino acid residue 1098 of the sucrase subunit.^[15]^[16]

Furthermore, scientists have identified a relationship between mutations in sucrase-isomaltase and chronic lymphocytic leukemia (CLL) patients. These mutations cause a loss of enzyme function by blocking the biosynthesis of SI at the cell surface.^[4]

References

↑ Hauri, H.-P., Quaroni, A. and Isselbacher, K.J. (1979). "Biogenesis of intestinal plasma membrane: posttranslational route and cleavage of sucrase-isomaltase". Proc. Natl. Acad. Sci. USA 76: 5183–5186. doi:10.1073/pnas.76.10.5183. PMID 291933.
1 2 Sjöström, H., Norén, O., Christiansen, L., Wacker, H. and Semenza, G. (1980). "A fully active, two-active-site, single-chain sucrase-isomaltase from pig small intestine. Implications for the biosynthesis of a mammalian integral stalked membrane protein". J. Biol. Chem. 255: 11332–11338. PMID 7002920.
↑ Rodriguez, I.R., Taravel, F.R. and Whelan, W.J. (1984). "Characterization and function of pig intestinal sucrase-isomaltase and its separate subunits". Eur. J. Biochem. 143: 575–582. doi:10.1111/j.1432-1033.1984.tb08408.x. PMID 6479163.
1 2 Rodríguez D, Ramsay AJ, Quesada V, Garabaya C, Campo E, Freije JM, López-Otín C (2013). "Functional analysis of sucrase-isomaltase mutations from chronic lymphocytic leukemia patients". Hum. Mol. Genet. 22 (11): 2273–82. doi:10.1093/hmg/ddt078. PMID 23418305.
↑ Berg, J. M. et al. Biochemistry, 7th Ed. W.H. Freeman and Company: New York, 2012.
1 2 3 4 5 6 7 8 Sim L, Willemsma C, Mohan S, Naim HY, Pinto BM, Rose DR (2010). "Structural basis for substrate selectivity in human maltase-glucoamylase and sucrase-isomaltase N-terminal domains". J. Biol. Chem. 285 (23): 17763–70. doi:10.1074/jbc.M109.078980. PMC 2878540. PMID 20356844.
↑ "SI sucrase-isomaltase (alpha-glucosidase) [Homo sapiens (human)] - Gene - NCBI".
↑ "www.jbc.org" (PDF).
↑ Naim HY, Sterchi EE, Lentze MJ (1988). "Biosynthesis of the human sucrase-isomaltase complex. Differential O-glycosylation of the sucrase subunit correlates with its position within the enzyme complex". J. Biol. Chem. 263 (15): 7242–53. PMID 3366777.
1 2 3 Alfalah M, Keiser M, Leeb T, Zimmer KP, Naim HY (2009). "Compound heterozygous mutations affect protein folding and function in patients with congenital sucrase-isomaltase deficiency". Gastroenterology 136 (3): 883–92. doi:10.1053/j.gastro.2008.11.038. PMID 19121318.
↑ Hunziker W, Spiess M, Semenza G, Lodish HF (1986). "The sucrase-isomaltase complex: primary structure, membrane-orientation, and evolution of a stalked, intrinsic brush border protein". Cell 46 (2): 227–34. doi:10.1016/0092-8674(86)90739-7. PMID 3755079.
↑ Wacker H, Aggeler R, Kretchmer N, O'Neill B, Takesue Y, Semenza G (1984). "A two-active site one-polypeptide enzyme: the isomaltase from sea lion small intestinal brush-border membrane. Its possible phylogenetic relationship with sucrase-isomaltase". J. Biol. Chem. 259 (8): 4878–84. PMID 6715326.
↑ Galand G (1989). "Brush border membrane sucrase-isomaltase, maltase-glucoamylase and trehalase in mammals. Comparative development, effects of glucocorticoids, molecular mechanisms, and phylogenetic implications". Comp. Biochem. Physiol., B 94 (1): 1–11. doi:10.1016/0305-0491(89)90002-3. PMID 2513162.
↑ Keiser M, Alfalah M, Pröpsting MJ, Castelletti D, Naim HY (2006). "Altered folding, turnover, and polarized sorting act in concert to define a novel pathomechanism of congenital sucrase-isomaltase deficiency". J. Biol. Chem. 281 (20): 14393–9. doi:10.1074/jbc.M513631200. PMID 16543230.
↑ Pröpsting MJ, Kanapin H, Jacob R, Naim HY (2005). "A phenylalanine-based folding determinant in intestinal sucrase-isomaltase that functions in the context of a quality control mechanism beyond the endoplasmic reticulum". J. Cell. Sci. 118 (Pt 12): 2775–84. doi:10.1242/jcs.02364. PMID 15944403.
↑ Pröpsting MJ, Jacob R, Naim HY (2003). "A glutamine to proline exchange at amino acid residue 1098 in sucrase causes a temperature-sensitive arrest of sucrase-isomaltase in the endoplasmic reticulum and cis-Golgi". J. Biol. Chem. 278 (18): 16310–4. doi:10.1074/jbc.C300093200. PMID 12624106.

External links

Structure and evolution of the mammalian maltase-glucoamylase and sucrase-isomaltase
Sucrase-isomaltase complex at the US National Library of Medicine Medical Subject Headings (MeSH)

Enzymes: multienzyme complexes

Photosynthesis	Photosynthetic reaction center complex proteins Photosystem I II

Dehydrogenase	Pyruvate dehydrogenase complex E1 E2 E3 Oxoglutarate dehydrogenase OGDH DLST DLD Branched-chain alpha-keto acid dehydrogenase complex BCKDHA BCKDHB DBT DLD

Other	CAD Carbamoyl phosphate synthase II Aspartate carbamoyltransferase Dihydroorotase Cholesterol side-chain cleavage enzyme Cytochrome b6f complex Electron transport chain Fatty acid synthetase complex Glycine decarboxylase complex Mitochondrial trifunctional protein HADHA HADHB Phosphoenolpyruvate sugar phosphotransferase system Polyketide synthase Sucrase-isomaltase complex Tryptophan synthase

Hydrolase: sugar hydrolases (EC 3.2)

3.2.1: Glycoside hydrolases

Disaccharidase	Sucrase/Sucrase-isomaltase/Invertase Maltase Trehalase Lactase

Glucosidases	Cellulase Alpha-glucosidase Acid Neutral AB Neutral C Beta-glucosidase cytosolic Debranching enzyme

Other	Amylase Alpha-amylase Chitinase Lysozyme Neuraminidase NEU1 NEU2 NEU3 NEU4 Bacterial neuraminidase Viral neuraminidase Galactosidases Alpha Beta alpha-Mannosidase Glucuronidase Hyaluronidase Pullulanase Glucosylceramidase lysosomal non-lysosomal Galactosylceramidase Alpha-N-acetylgalactosaminidase NAGA Alpha-N-acetylglucosaminidase Fucosidase Hexosaminidase HEXA HEXB Iduronidase Maltase-glucoamylase Heparanase HPSE2

3.2.2: Hydrolysing
N-Glycosyl compounds

DNA glycosylases: Oxoguanine glycosylase

Enzymes

Activity	Active site Binding site Catalytic triad Oxyanion hole Enzyme promiscuity Catalytically perfect enzyme Coenzyme Cofactor Enzyme catalysis Enzyme kinetics Lineweaver–Burk plot Michaelis–Menten kinetics

Regulation	Allosteric regulation Cooperativity Enzyme inhibitor

Classification	EC number Enzyme superfamily Enzyme family List of enzymes

Types	EC1 Oxidoreductases(list) EC2 Transferases(list) EC3 Hydrolases(list) EC4 Lyases(list) EC5 Isomerases(list) EC6 Ligases(list)

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