1mfu Citations

Probing the role of a mobile loop in substrate binding and enzyme activity of human salivary amylase.

Ramasubbu N, Ragunath C, Mishra PJ
J Mol Biol 325 1061-76 (2003)
Related entries: 1jxk, 1mfv

Cited: 49 times
EuropePMC logo PMID: 12527308

Abstract

Mammalian amylases harbor a flexible, glycine-rich loop 304GHGAGGA(310), which becomes ordered upon oligosaccharide binding and moves in toward the substrate. In order to probe the role of this loop in catalysis, a deletion mutant lacking residues 306-310 (Delta306) was generated. Kinetic studies showed that Delta306 exhibited: (1) a reduction (>200-fold) in the specific activity using starch as a substrate; (2) a reduction in k(cat) for maltopentaose and maltoheptaose as substrates; and (3) a twofold increase in K(m) (maltopentaose as substrate) compared to the wild-type (rHSAmy). More cleavage sites were observed for the mutant than for rHSAmy, suggesting that the mutant exhibits additional productive binding modes. Further insight into its role is obtained from the crystal structures of the two enzymes soaked with acarbose, a transition-state analog. Both enzymes modify acarbose upon binding through hydrolysis, condensation or transglycosylation reactions. Electron density corresponding to six and seven fully occupied subsites in the active site of rHSAmy and Delta306, respectively, were observed. Comparison of the crystal structures showed that: (1) the hydrophobic cover provided by the mobile loop for the subsites at the reducing end of the rHSAmy complex is notably absent in the mutant; (2) minimal changes in the protein-ligand interactions around subsites S1 and S1', where the cleavage would occur; (3) a well-positioned water molecule in the mutant provides a hydrogen bond interaction similar to that provided by the His305 in rHSAmy complex; (4) the active site-bound oligosaccharides exhibit minimal conformational differences between the two enzymes. Collectively, while the kinetic data suggest that the mobile loop may be involved in assisting the catalysis during the transition state, crystallographic data suggest that the loop may play a role in the release of the product(s) from the active site.

Articles - 1mfu mentioned but not cited (3)

  1. Probing the role of aromatic residues at the secondary saccharide-binding sites of human salivary alpha-amylase in substrate hydrolysis and bacterial binding. Ragunath C, Manuel SG, Venkataraman V, Sait HB, Kasinathan C, Ramasubbu N. J Mol Biol 384 1232-1248 (2008)
  2. Action Observation Plus Sonification. A Novel Therapeutic Protocol for Parkinson's Patient with Freezing of Gait. Mezzarobba S, Grassi M, Pellegrini L, Catalan M, Kruger B, Furlanis G, Manganotti P, Bernardis P. Front Neurol 8 723 (2017)
  3. Early effect of fractional CO2 laser treatment in Post-menopausal women with vaginal atrophy. Eder SE. Laser Ther 27 41-47 (2018)


Reviews citing this publication (2)

  1. α-Amylase: an enzyme specificity found in various families of glycoside hydrolases. Janeček Š, Svensson B, MacGregor EA. Cell Mol Life Sci 71 1149-1170 (2014)
  2. Occurrence and functional significance of secondary carbohydrate binding sites in glycoside hydrolases. Cuyvers S, Dornez E, Delcour JA, Courtin CM. Crit Rev Biotechnol 32 93-107 (2012)

Articles citing this publication (44)

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  14. Crystal structure of α-amylase from Oryza sativa: molecular insights into enzyme activity and thermostability. Ochiai A, Sugai H, Harada K, Tanaka S, Ishiyama Y, Ito K, Tanaka T, Uchiumi T, Taniguchi M, Mitsui T. Biosci Biotechnol Biochem 78 989-997 (2014)
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  16. Putative salivary protein biomarkers for the diagnosis of oral lichen planus: a case-control study. Talungchit S, Buajeeb W, Lerdtripop C, Surarit R, Chairatvit K, Roytrakul S, Kobayashi H, Izumi Y, Khovidhunkit SP. BMC Oral Health 18 42 (2018)
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  18. Modeling and biochemical analysis of the activity of antibiofilm agent Dispersin B. Kerrigan JE, Ragunath C, Kandra L, Gyémánt G, Lipták A, Jánossy L, Kaplan JB, Ramasubbu N. Acta Biol Hung 59 439-451 (2008)
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  22. Molecular cloning of soluble trehalase from Chironomus riparius larvae, its heterologous expression in Escherichia coli and bioinformatic analysis. Forcella M, Mozzi A, Bigi A, Parenti P, Fusi P. Arch Insect Biochem Physiol 81 77-89 (2012)
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  25. Molecular cloning and in silico studies of physiologically significant trehalase from Drosophila melanogaster. Shukla E, Thorat L, Bhavnani V, Bendre AD, Pal JK, Nath BB, Gaikwad SM. Int J Biol Macromol 92 282-292 (2016)
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  28. Functional roles of H98 and W99 and β2α2 loop dynamics in the α-l-arabinofuranosidase from Thermobacillus xylanilyticus. Arab-Jaziri F, Bissaro B, Barbe S, Saurel O, Débat H, Dumon C, Gervais V, Milon A, André I, Fauré R, O'Donohue MJ. FEBS J 279 3598-3611 (2012)
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  40. Novel cold-adapted raw-starch digesting α-amylases from Eisenia fetida: Gene cloning, expression, and characterization. Tsukamoto K, Ariki S, Nakazawa M, Sakamoto T, Ueda M. Biotechnol Rep (Amst) 31 e00662 (2021)
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  43. The Role of a Loop in the Non-catalytic Domain B on the Hydrolysis/Transglycosylation Specificity of the 4-α-Glucanotransferase from Thermotoga maritima. Llopiz A, Ramírez-Martínez MA, Olvera L, Xolalpa-Villanueva W, Pastor N, Saab-Rincon G. Protein J 42 502-518 (2023)
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