Unusual active site location and catalytic apparatus in a glycoside hydrolase family

Significance The location of the active site of enzymes with the same fold is invariably conserved. The β-propeller fold exemplifies this feature with all functions located at what is termed their anterior surface. Herein, however, we show that the active site of a glycoside hydrolase that adopts the β-propeller fold is located to the posterior surface of the α-l-rhamnosidase. The enzyme also displays a catalytic apparatus that utilizes a single histidine instead of the canonical pair of carboxylate residues deployed by the vast majority of glycoside hydrolases. The capacity to engineer catalytic functionality into the posterior surface of other family members provides insight into the evolution of this enzyme family. The human gut microbiota use complex carbohydrates as major nutrients. The requirement for an efficient glycan degrading systems exerts a major selection pressure on this microbial community. Thus, we propose that these bacteria represent a substantial resource for discovering novel carbohydrate active enzymes. To test this hypothesis, we focused on enzymes that hydrolyze rhamnosidic bonds, as cleavage of these linkages is chemically challenging and there is a paucity of information on l-rhamnosidases. Here we screened the activity of enzymes derived from the human gut microbiota bacterium Bacteroides thetaiotaomicron, which are up-regulated in response to rhamnose-containing glycans. We identified an α-l-rhamnosidase, BT3686, which is the founding member of a glycoside hydrolase (GH) family, GH145. In contrast to other rhamnosidases, BT3686 cleaved l-Rha-α1,4–d-GlcA linkages through a retaining double-displacement mechanism. The crystal structure of BT3686 showed that the enzyme displayed a type A seven-bladed β-propeller fold. Mutagenesis and crystallographic studies, including the structure of BT3686 in complex with the reaction product GlcA, revealed a location for the active site among β-propeller enzymes cited on the posterior surface of the rhamnosidase. In contrast to the vast majority of GH, the catalytic apparatus of BT3686 does not comprise a pair of carboxylic acid residues but, uniquely, a single histidine functions as the only discernable catalytic amino acid. Intriguingly, the histidine, His48, is not invariant in GH145; however, when engineered into structural homologs lacking the imidazole residue, α-l-rhamnosidase activity was established. The potential contribution of His48 to the catalytic activity of BT3686 is discussed.

[1]  N. Botting,et al.  Studies on the Mechanism of Myrosinase , 1995, The Journal of Biological Chemistry.

[2]  Kevin Cowtan,et al.  research papers Acta Crystallographica Section D Biological , 2005 .

[3]  S. Withers,et al.  The mechanism of cellulose hydrolysis by a two-step, retaining cellobiohydrolase elucidated by structural and transition path sampling studies. , 2014, Journal of the American Chemical Society.

[4]  Pedro M. Coutinho,et al.  The carbohydrate-active enzymes database (CAZy) in 2013 , 2013, Nucleic Acids Res..

[5]  P. Bork,et al.  Enterotypes of the human gut microbiome , 2011, Nature.

[6]  Bernard Henrissat,et al.  Recognition and Degradation of Plant Cell Wall Polysaccharides by Two Human Gut Symbionts , 2011, PLoS biology.

[7]  Spencer J. Williams,et al.  Dissecting conformational contributions to glycosidase catalysis and inhibition , 2014, Current opinion in structural biology.

[8]  Temple F. Smith,et al.  G Protein Heterodimers: New Structures Propel New Questions , 1996, Cell.

[9]  A. Voragen,et al.  Stereochemical course of hydrolysis catalysed by alpha-L-rhamnosyl and alpha-D-galacturonosyl hydrolases from Aspergillus aculeatus. , 1998, Biochemical and biophysical research communications.

[10]  Collaborative Computational,et al.  The CCP4 suite: programs for protein crystallography. , 1994, Acta crystallographica. Section D, Biological crystallography.

[11]  Eric C. Martens,et al.  Complex Glycan Catabolism by the Human Gut Microbiota: The Bacteroidetes Sus-like Paradigm , 2009, The Journal of Biological Chemistry.

[12]  S. Steinbacher,et al.  Crystal structure of phage P22 tailspike protein complexed with Salmonella sp. O-antigen receptors. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[13]  N. Pannu,et al.  REFMAC5 for the refinement of macromolecular crystal structures , 2011, Acta crystallographica. Section D, Biological crystallography.

[14]  Spencer J. Williams,et al.  Structural and mechanistic insight into N-glycan processing by endo-α-mannosidase , 2012, Proceedings of the National Academy of Sciences.

[15]  Kenji Yamamoto,et al.  Structural Basis of the Catalytic Reaction Mechanism of Novel 1,2-α-L-Fucosidase from Bifidobacterium bifidum* , 2007, Journal of Biological Chemistry.

[16]  Tasuku Ito,et al.  Crystal structure of glycoside hydrolase family 127 β-l-arabinofuranosidase from Bifidobacterium longum. , 2014, Biochemical and biophysical research communications.

[17]  Jianfeng Liu,et al.  Crystal structure of 1,3Gal43A, an exo-β-1,3-galactanase from Clostridium thermocellum. , 2012, Journal of structural biology.

[18]  G. Murshudov,et al.  Refinement of macromolecular structures by the maximum-likelihood method. , 1997, Acta crystallographica. Section D, Biological crystallography.

[19]  Randy J. Read,et al.  Phaser crystallographic software , 2007, Journal of applied crystallography.

[20]  B. Henrissat,et al.  Complex pectin metabolism by gut bacteria reveals novel catalytic functions , 2017, Nature.

[21]  J. Hermoso,et al.  Structure and Cell Wall Cleavage by Modular Lytic Transglycosylase MltC of Escherichia coli , 2014, ACS chemical biology.

[22]  G. Davies,et al.  Mechanistic insights into glycosidase chemistry. , 2008, Current opinion in chemical biology.

[23]  S. Withers,et al.  N-Acetylglucosaminidases from CAZy Family GH3 Are Really Glycoside Phosphorylases, Thereby Explaining Their Use of Histidine as an Acid/Base Catalyst in Place of Glutamic Acid* , 2014, The Journal of Biological Chemistry.

[24]  Vincent B. Chen,et al.  Correspondence e-mail: , 2000 .

[25]  D. Jakeman,et al.  On the phosphorylase activity of GH3 enzymes: A β-N-acetylglucosaminidase from Herbaspirillum seropedicae SmR1 and a glucosidase from Saccharopolyspora erythraea. , 2016, Carbohydrate research.

[26]  S. Withers,et al.  Glycosidase mechanisms: anatomy of a finely tuned catalyst. , 1999, Accounts of chemical research.

[27]  B. Henrissat,et al.  Divergence of Catalytic Mechanism within a Glycosidase Family Provides Insight into Evolution of Carbohydrate Metabolism by Human Gut Flora , 2008, Chemistry & biology.

[28]  K. Diederichs,et al.  Structural and Kinetic Analysis of Bacillus subtilis N-Acetylglucosaminidase Reveals a Unique Asp-His Dyad Mechanism* , 2010, The Journal of Biological Chemistry.

[29]  B. Henrissat,et al.  The Structure of a Streptomyces avermitilis α-l-Rhamnosidase Reveals a Novel Carbohydrate-binding Module CBM67 within the Six-domain Arrangement* , 2013, The Journal of Biological Chemistry.

[30]  A. Boraston,et al.  Analysis of Keystone Enzyme in Agar Hydrolysis Provides Insight into the Degradation (of a Polysaccharide from) Red Seaweeds* , 2012, The Journal of Biological Chemistry.

[31]  G. Phillips,et al.  The core carbohydrate structure of Acacia seyal var. seyal (Gum arabic) , 2013 .

[32]  Miroslaw Cygler,et al.  New Ulvan-Degrading Polysaccharide Lyase Family: Structure and Catalytic Mechanism Suggests Convergent Evolution of Active Site Architecture. , 2017, ACS chemical biology.

[33]  D. Bolam,et al.  Evidence That GH115 α-Glucuronidase Activity, Which Is Required to Degrade Plant Biomass, Is Dependent on Conformational Flexibility* , 2013, The Journal of Biological Chemistry.

[34]  M. Anteunis,et al.  1H-N.m.r. study of l-rhamnose, methyl α-l-rhamnopyranoside, and 4-O-β-d-galactopyranosyl-l-rhamnose in deuterium oxide , 1976 .

[35]  B. Clantin,et al.  Crystal structure of papaya glutaminyl cyclase, an archetype for plant and bacterial glutaminyl cyclases. , 2006, Journal of molecular biology.

[36]  H. Flint,et al.  Microbial degradation of complex carbohydrates in the gut , 2012, Gut microbes.