Active-site Mapping of a Populus Xyloglucan endo-Transglycosylase with a Library of Xylogluco-oligosaccharides

Marc Saura-Valls,Régis Fauré,Harry Brumer,Tuula T Teeri,Sylvain Cottaz,Hugues Driguez,Antoni Planas

doi:10.1074/jbc.m803058200

Abstract

Restructuring the network of xyloglucan (XG) and cellulose during plant cell wall morphogenesis involves the action of xyloglucan endo-transglycosylases (XETs). They cleave the XG chains and transfer the enzyme-bound XG fragment to another XG molecule, thus allowing transient loosening of the cell wall and also incorporation of nascent XG during expansion. The substrate specificity of a XET from Populus (PttXET16-34) has been analyzed by mapping the enzyme binding site with a library of xylogluco-oligosaccharides as donor substrates using a labeled heptasaccharide as acceptor. The extended binding cleft of the enzyme is composed of four negative and three positive subsites (with the catalytic residues between subsites -1 and +1). Donor binding is dominated by the higher affinity of the XXXG moiety (G=Glcbeta(1-->4) and X=Xylalpha(1-->6)Glcbeta(1-->4)) of the substrate for positive subsites, whereas negative subsites have a more relaxed specificity, able to bind (and transfer to the acceptor) a cello-oligosaccharyl moiety of hybrid substrates such as GGGGXXXG. Subsite mapping with k(cat)/K(m) values for the donor substrates showed that a GG-unit on negative and -XXG on positive subsites are the minimal requirements for activity. Subsites -2 and -3 (for backbone Glc residues) and +2' (for Xyl substitution at Glc in subsite +2) have the largest contribution to transition state stabilization. GalGXXXGXXXG (Gal=Galbeta(1-->4)) is the best donor substrate with a "blocked" nonreducing end that prevents polymerization reactions and yields a single transglycosylation product. Its kinetics have unambiguously established that the enzyme operates by a ping-pong mechanism with competitive inhibition by the acceptor.

Highlights

The plant cell wall, a composite structure of cellulose, hemicelluloses, pectin, lignin, and structural proteins, is continually modified during cell growth and differentiation
All of these compounds were assayed as donor substrates for PttXET16 –34 using a heptasaccharide derivatized with ANTS as acceptor (XXXG-ANTS)
Early work by Fanutti et al (28, 29) analyzed the transglycosylation and hydrolytic activities of a mixed-function XG endo-transglycosylase/endo-hydrolase from germinated nasturtium seeds with different oligosaccharides from xyloglucan hydrolysis, concluding that (a) transfer occurs from an unsubstituted Glc residue in subsite Ϫ1; (b) because GXXGXXXG underwent transglycosylation acting as a donor and an acceptor, Xyl substitutions at subsites Ϫ4 and ϩ1 are not required; (c) Xyl substitution at subsite Ϫ2 is not required because donor GXXGGXXGXXXG was hydrolyzed at the underlined Glc residue; (d) Xyl substitutions at subsites ϩ2 and/or ϩ3

Summary

Introduction

The plant cell wall, a composite structure of cellulose, hemicelluloses, pectin, lignin, and structural proteins, is continually modified during cell growth and differentiation. Xyloglucan (XG) is one of the key structural polysaccharides in dicot and certain monocot cell walls and sometimes serves as a plant energy reserve (1–3) It forms hydrogen bonds with cellulose microfibrils and provides a molecular tether between adjacent microfibrils by forming a three-dimensional cellulose-XG network (4). The main XGOs from tamarind seed XG depolymerization are XXXG, XXLG, XLXG, and XLLG (using the established one-letter code nomenclature) (9): G ϭ D-Glc, X ϭ ␣-D-Xyl(136)-␤-D-Glc, and L ϭ ␤-D-Gal(132)-␣-D-Xyl(136)-␤-D-Glc. Xyloglucan endo-transglycosylases (XETs; EC 2.4.1.207) are key enzymes involved in the restructuring of the cell wall during morphogenesis (10 –14). XETs and a few XEHs belong to glycoside hydrolase family GH16 (18, 19), acting by the canonical double-displacement mechanism of retaining glycosidases (20, 21) It involves the participation of two catalytic carboxylic amino acid residues, a general acid/base, and a nucleophile. I donors share the XXXG- substructure on the nonreducing end and were designed to map the positive subsites, whereas Family II donors have the opposite structural distribution to map negative subsites

Results

Discussion

Conclusion