3t0d Citations

Ser-796 of β-galactosidase (Escherichia coli) plays a key role in maintaining a balance between the opened and closed conformations of the catalytically important active site loop.

Arch Biochem Biophys 517 111-22 (2012)
Related entries: 3sep, 3t08, 3t09, 3t0a, 3t0b, 3t2o, 3t2p, 3t2q

Cited: 9 times
EuropePMC logo PMID: 22155115

Abstract

A loop (residues 794-803) at the active site of β-galactosidase (Escherichia coli) opens and closes during catalysis. The α and β carbons of Ser-796 form a hydrophobic connection to Phe-601 when the loop is closed while a connection via two H-bonds with the Ser hydroxyl occurs with the loop open. β-Galactosidases with substitutions for Ser-796 were investigated. Replacement by Ala strongly stabilizes the closed conformation because of greater hydrophobicity and loss of H-bonding ability while replacement with Thr stabilizes the open form through hydrophobic interactions with its methyl group. Upon substitution with Asp much of the defined loop structure is lost. The different open-closed equilibria cause differences in the stabilities of the enzyme·substrate and enzyme·transition state complexes and of the covalent intermediate that affect the activation thermodynamics. With Ala, large changes of both the galactosylation (k(2)) and degalactosylation (k(3)) rates occur. With Thr and Asp, the k(2) and k(3) were not changed as much but large ΔH(‡) and TΔS(‡) changes showed that the substitutions caused mechanistic changes. Overall, the hydrophobic and H-bonding properties of Ser-796 result in interactions strong enough to stabilize the open or closed conformations of the loop but weak enough to allow loop movement during the reaction.

Reviews citing this publication (1)

Articles citing this publication (8)

  1. Potent Glycosidase Inhibition with Heterovalent Fullerenes: Unveiling the Binding Modes Triggering Multivalent Inhibition. Abellán Flos M, García Moreno MI, Ortiz Mellet C, García Fernández JM, Nierengarten JF, Vincent SP. Chemistry 22 11450-11460 (2016)
  2. Structural explanation for allolactose (lac operon inducer) synthesis by lacZ β-galactosidase and the evolutionary relationship between allolactose synthesis and the lac repressor. Wheatley RW, Lo S, Jancewicz LJ, Dugdale ML, Huber RE. J Biol Chem 288 12993-13005 (2013)
  3. Giant Glycosidase Inhibitors: First- and Second-Generation Fullerodendrimers with a Dense Iminosugar Shell. Nierengarten JF, Schneider JP, Trinh TMN, Joosten A, Holler M, Lepage ML, Bodlenner A, García-Moreno MI, Ortiz Mellet C, Compain P. Chemistry 24 2483-2492 (2018)
  4. Structural studies of a cold-adapted dimeric β-D-galactosidase from Paracoccus sp. 32d. Rutkiewicz-Krotewicz M, Pietrzyk-Brzezinska AJ, Sekula B, Cieśliński H, Wierzbicka-Woś A, Kur J, Bujacz A. Acta Crystallogr D Struct Biol 72 1049-1061 (2016)
  5. Isothermal titration calorimetry determination of individual rate constants of trypsin catalytic activity. Aguirre C, Condado-Morales I, Olguin LF, Costas M. Anal Biochem 479 18-27 (2015)
  6. An allolactose trapped at the lacZ β-galactosidase active site with its galactosyl moiety in a (4)H3 conformation provides insights into the formation, conformation, and stabilization of the transition state. Wheatley RW, Huber RE. Biochem Cell Biol 93 531-540 (2015)
  7. Synthesis of phenylazonaphtol-β-D-O-glycosides, evaluation as substrates for beta-glycosidase activity and molecular studies. Brito-Arias M, Aguilar-Lemus C, Hurtado-Ponce PB, Martínez-Barrón G, Ibañez-Hernandez M. Org Med Chem Lett 4 2 (2014)
  8. The functional mutational landscape of the lacZ gene. Beal MA, Meier MJ, Dykes A, Yauk CL, Lambert IB, Marchetti F. iScience 26 108407 (2023)