Martin Schülein

Enzymatic properties of cellulases from Humicola insolens

We present the analysis of the activities towards soluble and insoluble substrates of seven cellulases cloned from the saprophytic fungus Humicola insolens. The activity on the soluble polymer substrate carboxymethylcellulose (CMC) was used to determine the pH activity profiles of the five endoglucanases (EG), whereas cellotriose and reduced cellohexaose were used to determine the pH activity profiles of cellobiohydrolase I (CBH) and CBH II. All the EGs show optimal activity between pH 7 and 8.5, while CBH I and CBH II peak around pH 5.5 and 9, respectively. The catalytic activities of five of these cellulases were investigated under neutral and alkaline conditions using reduced cellohexaose as a substrate in a cellobiose oxidase coupled assay. EG I and CBH I both belong to family (7) according to a recent classification of glycosyl hydrolases. They both have activity against cellotriose. Therefore, they were studied using a coupled assay involving glucose oxidase. The activity on insoluble substrate (phosphoric-acid swollen cellulose) was assessed by the formation of reducing groups. The presence of a cellulose binding domain (CBD) lowers the apparent KM. This can be explained by the dispersing action of CBD. However, the CBD also reduces the apparent k(cat) probably by slowing down the mobility. EG I, EG II and EG III show similar activity towards CMC and amorphous cellulose, while EG V, EG VI, CBH I and CBH II have the highest catalytic rate on amorphous cellulose. In summary, Humicola insolens possesses a battery of cellulose-degrading enzymes which cooperate in the efficient hydrolysis of cellulose.

Catalysis and specificity in enzymatic glycoside hydrolysis: a 2,5B conformation for the glycosyl-enzyme intermediate revealed by the structure of the Bacillus agaradhaerens family 11 xylanase

BACKGROUND The enzymatic hydrolysis of glycosides involves the formation and subsequent breakdown of a covalent glycosyl-enzyme intermediate via oxocarbenium-ion-like transition states. The covalent intermediate may be trapped on-enzyme using 2-fluoro-substituted glycosides, which provide details of the intermediate conformation and noncovalent interactions between enzyme and oligosaccharide. Xylanases are important in industrial applications - in the pulp and paper industry, pretreating wood with xylanases decreases the amount of chlorine-containing chemicals used. Xylanases are structurally similar to cellulases but differ in their specificity for xylose-based, versus glucose-based, substrates. RESULTS The structure of the family 11 xylanase, Xyl11, from Bacillus agaradhaerens has been solved using X-ray crystallography in both native and xylobiosyl-enzyme intermediate forms at 1.78 A and 2.0 A resolution, respectively. The covalent glycosyl-enzyme intermediate has been trapped using a 2-fluoro-2-deoxy substrate with a good leaving group. Unlike covalent intermediate structures for glycoside hydrolases from other families, the covalent glycosyl-enzyme intermediate in family 11 adopts an unusual 2,5B conformation. CONCLUSIONS The 2,5B conformation found for the alpha-linked xylobiosyl-enzyme intermediate of Xyl11, unlike the 4C1 chair conformation observed for other systems, is consistent with the stereochemical constraints required of the oxocarbenium-ion-like transition state. Comparison of the Xyl11 covalent glycosyl-enzyme intermediate with the equivalent structure for the related family 12 endoglucanase, CelB, from Streptomyces lividans reveals the likely determinants for substrate specificity in this clan of glycoside hydrolases.

The action of 1,4‐β‐D‐glucan cellobiohydrolase on Valonia cellulose microcrystals

The interaction between 1,4‐β‐D‐glucan‐cellobiohydrolase I (CBHI) from Trichoderma reesei and microcrystalline cellulose from Vallonia macrophysa was investigated by electron microscopy which allows to visualize the individual enzymes and their strong adsorption at the substrate surface. The microcrystals are slowly degraded and decrystallized by erosion and fibrillation while soluble products are released and characterized by HPLC. CBHI is thus able to break down Valonia microcrystals without the help of any endo‐β‐1,4‐glucanase activity.

Structural Basis for Ligand Binding and Processivity in Cellobiohydrolase Cel6A from Humicola Insolens

The enzymatic digestion of cellulose entails intimate involvement of cellobiohydrolases, whose characteristic active-center tunnel contributes to a processive degradation of the polysaccharide. The cellobiohydrolase Cel6A displays an active site within a tunnel formed by two extended loops, which are known to open and close in response to ligand binding. Here we present five structures of wild-type and mutant forms of Cel6A from Humicola insolens in complex with nonhydrolyzable thio-oligosaccharides, at resolutions from 1.7-1.1 A, dissecting the structural accommodation of a processing substrate chain through the active center during hydrolysis. Movement of ligand is facilitated by extensive solvent-mediated interactions and through flexibility in the hydrophobic surfaces provided by a sheath of tryptophan residues.

Comparison of structure and activities of peroxidases from Coprinus cinereus, Coprinus macrorhizus and Arthromyces ramosus

Initial structural and kinetic data suggested that peroxidases from Coprinus cinereus, Coprinus macrorhizus and Arthromyces ramosus were similar. Therefore they were characterized more fully. The three peroxidases were purified to RZ 2.5 and showed immunochemical identity as well as an identical M(r) of 38,000, pI about 3.5 and similar amino acid compositions. The N-termini were blocked for amino acid sequencing. The peroxidases had similar retention volumes by anion-exchange and gel-filtration chromatography. All peroxidases showed multiple peaks by Concanavalin A-Sepharose chromatography. The Concanavalin A-Sepharose profiles were different and depended furthermore on a fermentation batch. Tryptic peptide maps were very similar except for one peptide. This peptide contained an N-linked glycan composed of varying ratios of glucosamine and mannose for the three peroxidases. Rate constants and their pH dependence were the same for the three peroxidases using guaiacol or iodide as reducing substrates. We conclude that peroxidases from Coprinus cinereus, Coprinus macrorhizus and Arthromyces ramosus are most likely identical in their amino acid sequences, but deviate in glycosylation which, apparently, has no influence on the reaction rates of the enzyme. We suggest, that the Coprinus fungi express one peroxidase only in contrast to the lignin-degrading white-rot Basidiomycetes, which produce multiple peroxidase isozymes.

A Bifunctionalized Fluorogenic Tetrasaccharide as a Substrate to Study Cellulases

Cellulases are usually classified as endoglucanases and cellobiohydrolases, but the heterogeneity of cellulose, in terms of particle size and crystallinity, has always represented a problem for the biochemical characterization of the enzymes. The synthesis of a bifunctionalized tetrasaccharide substrate suitable for measuring cellulase activity by resonance energy transfer is described. The substrate, which carries a 5-(2-aminoethylamino)-1-naphthalenesulfonate group on the non-reducing end and an indolethyl group on the reducing end, was prepared from β-lactosyl fluoride and indolethyl β-cellobioside by a chemoenzymatic approach using the transglycosylating activity of endoglucanase I of Humicola insolens as the key step. The bifunctionalized substrate has been used for the determination of the catalytic constants of H. insolens endoglucanase I and cellobiohydrolases I and II; this substrate could be of general use to measure the kinetic constants of cellulases able to act on oligomers of degree of polymerization <5. The data also provide evidence that cellobiohydrolases I and II are able to degrade an oligosaccharide substrate carrying non-carbohydrate substituents at both ends.

Electron microscopic investigation of the diffusion of Bacillus licheniformis α-amylase into corn starch granules

A method for the direct electron microscopic observation of amylases in interaction with starch granules is presented. The technique involves immuno-gold labeling of the enzymes and cross-sectioning of hydrated starch granules. This approach allows the analysis of the internal degradation of starch with a concomitant visualization of enzymes at the sites of hydrolysis. The visualization of enzymes at the surface, inside the channel and inside the core of the degraded granules shows that the alpha-amylase molecules first proceed from the surface toward the center (centripetal hydrolysis). Then the core is completely degraded from within by erosion of its periphery (centrifugal hydrolysis). In the first case (centripetal hydrolysis), the enzymes act by progressing along the polysaccharide chains. By contrast, the centrifugal hydrolysis leads to even erosion, indicative of a more diffusive motion of the enzymes.

Structure of the endoglucanase I from Fusarium oxysporum: native, cellobiose, and 3,4-epoxybutyl beta-D-cellobioside-inhibited forms, at 2.3 A resolution.

The mechanisms involved in the enzymatic degradation of cellulose are of great ecological and commercial importance. The breakdown of cellulose by fungal species is performed by a consortium of free enzymes, known as cellobiohydrolases and endoglucanases, which are found in many of the 57 glycosyl hydrolase families. The structure of the endoglucanase I (EG I), found in glycosyl hydrolase family 7, from the thermophilic fungus Fusarium oxysporum has been solved at 2.3 A resolution. In addition to the native enzyme, structures have also been determined with both the affinity label, 3,4-epoxybutyl beta-D-cellobioside, and the reaction product cellobiose. The affinity label is covalently bound, as expected, to the catalytic nucleophile, Glu197, with clear evidence for binding of both the R and S stereoisomers. Cellobiose is found bound to the -2 and -1 subsites of the enzyme. In marked contrast to the structure of EG I with a nonhydrolyzable thiosaccharide analog, which spanned the -2, -1, and +1 subsites and which had a skew-boat conformation for the -1 subsite sugar [Sulzenbacher, G., et al. (1996) Biochemistry 35, 15280-15287], the cellobiose complex shows no pyranoside ring distortion in the -1 subsite, implying that strain is induced primarily by the additional +1 subsite interactions and that the product is found, as expected, in its unstrained conformation.

Direct electron transfer of cellobiose dehydrogenase from various biological origins at gold and graphite electrodes

Direct electron transfer was observed for cellobiose dehydrogenases (CDH) from three different fungi, viz. CDH from Phanerochaete chrysosporium, Sclerotium rolfsii and Humicola insolens, in the presence of cellobiose when the enzymes were adsorbed on graphite electrodes. The redox wave of the heme cofactor of CDH could be demonstrated on thiol modified gold electrodes using cyclic voltammetry for Phanerochaete CDH and Humicola CDH; however, the electrocatalytic current for cellobiose oxidation could only be registered for Phanerochaete CDH.

Oligosaccharide binding to family 11 xylanases: both covalent intermediate and mutant product complexes display 2,5B conformations at the active centre

The glycoside hydrolase sequence-based classification reveals two families of enzymes which hydrolyse the beta-1,4-linked backbone of xylan, xylanases, termed families GH-10 and GH-11. Family GH-11 xylanases are intriguing in that catalysis is performed via a covalent intermediate adopting an unusual (2,5)B (boat) conformation, a conformation which also fulfils the stereochemical constraints of the oxocarbenium ion-like transition state. Here, the 1.9 A structure of a nucleophile, E94A, mutant of the Xyn11 from Bacillus agaradhaerens in complex with xylotriose is presented. Intriguingly, this complex also adopts the (2,5)B conformation in the -1 subsite, with the vacant space provided by the Glu-->Ala mutation allowing the sugar to adopt the alpha-configuration at C1. The structure of the covalent 2-deoxy-2-fluoroxylobiosyl-enzyme intermediate has been extended to atomic (1.1 A) resolution.