An elaboration on the syn-anti proton donor concept of glycoside hydrolases: electrostatic stabilisation of the transition state as a general strategy.

An in silico survey of all known 3D-structures of glycoside hydrolases that contain a ligand in the -1 subsite is presented. A recurrent crucial positioning of active site residues indicates a common general strategy for electrostatic stabilisation directed to the carbohydrate's ring-oxygen at the transition state. This is substantially different depending on whether the enzyme's proton donor is syn or anti positioned versus the substrate. A comprehensive list of enzymes belonging to 42 different families is given and selected examples are described. An implication for an early evolution scenario of glycoside hydrolases is discussed.

Engineering of a glycosidase Family 7 cellobiohydrolase to more alkaline pH optimum: the pH behaviour of Trichoderma reesei Cel7A and its E223S/ A224H/L225V/T226A/D262G mutant.

The crystal structures of Family 7 glycohydrolases suggest that a histidine residue near the acid/base catalyst could account for the higher pH optimum of the Humicola insolens endoglucanase Cel7B, than the corresponding Trichoderma reesei enzymes. Modelling studies indicated that introduction of histidine at the homologous position in T. reesei Cel7A (Ala(224)) required additional changes to accommodate the bulkier histidine side chain. X-ray crystallography of the catalytic domain of the E223S/A224H/L225V/T226A/D262G mutant reveals that major differences from the wild-type are confined to the mutations themselves. The introduced histidine residue is in plane with its counterpart in H. insolens Cel7B, but is 1.0 A (=0.1 nm) closer to the acid/base Glu(217) residue, with a 3.1 A contact between N(epsilon2) and O(epsilon1). The pH variation of k(cat)/K(m) for 3,4-dinitrophenyl lactoside hydrolysis was accurately bell-shaped for both wild-type and mutant, with pK(1) shifting from 2.22+/-0.03 in the wild-type to 3.19+/-0.03 in the mutant, and pK(2) shifting from 5.99+/-0.02 to 6.78+/-0.02. With this poor substrate, the ionizations probably represent those of the free enzyme. The relative k(cat) for 2-chloro-4-nitrophenyl lactoside showed similar behaviour. The shift in the mutant pH optimum was associated with lower k(cat)/K(m) values for both lactosides and cellobiosides, and a marginally lower stability. However, k(cat) values for cellobiosides are higher for the mutant. This we attribute to reduced non-productive binding in the +1 and +2 subsites; inhibition by cellobiose is certainly relieved in the mutant. The weaker binding of cellobiose is due to the loss of two water-mediated hydrogen bonds.

Molecular cloning and enzymatic characterization of a Trichoderma reesei 1,2-alpha-D-mannosidase.

A cDNA encoding 1,2-alpha-D-mannosidase mds 1 from Trichoderma reesei was cloned. The largest open reading frame occupied 1571 bp. The predicted sequence contains 523 amino acid residues for a calculated molecular mass of 56,266 Da and shows high similarity to the amino acid sequences of 1,2-alpha-D-mannosidases from Aspergillus saitoi and Penicillium citrinum (51.6 and 51.0% identity, respectively). T. reesei mannosidase was produced as a recombinant enzyme in the yeast Pichia pastoris. Replacement of the N-terminal part with the prepro-signal peptide of the Saccharomyces cerevisiae alpha-mating factor resulted in high amounts of secreted enzyme. A three-step purification protocol was designed and the enzymatic properties were analyzed. The enzyme was characterized as a class-I mannosidase.

Active-site binding of glycosides by Thermomonospora fusca endocellulase E2.

The determination of the high-resolution structure of the Thermomonospora fusca endocellulase E2 catalytic domain makes it ideal for exploring cellulase structure-function relationships. Here we present binding parameters (Kd, DeltaH degrees, and DeltaS degrees) describing the interaction of E2 with 4-methylumbelliferyl glycosides, determined by titrating the quenching of ligand fluorescence in equilibrium binding experiments. Quenched MU(Glc)2/E2 complexes were used as indicators in displacement titrations to measure the binding of natural glycosides and also of a nonhydrolyzable cellotetraose analogue. Binding of MU(Glc)2 and cellotriose were also determined by titration calorimetry. The results show that E2 binds glycosides exclusively in its active-site cleft, with high affinity and specificity. The observed patterns of ligand hydrolysis and the results with MU(Glc)2 as a substrate indicated that ligands bound to E2 with their nonreducing ends in position -2, consistent with the position of cellobiose in the E2cd structure. Polymerase chain reaction (PCR) mutagenesis of the conserved residue Tyr 73 (in E2 binding subsite -1) to Phe and Ser produced enzymes with lower activity but higher binding affinities, indicating that the volume of the subsite -1 binding pocket is crucial for enzyme function. Similarly, MUXylGlc (with its xylosyl unit located in position -1) bound with 100-fold higher affinity than MU(Glc)2. These results are similar to those for the related Trichoderma reesei exocellulase CBH II. The binding data were compared with that previously reported for CBH II and interpreted in terms of the functional differences between endo- and exocellulases.

Flow cytometric measurement of neutrophil alkaline phosphatase before and during initiation of an induced Escherichia coli mastitis in cattle.

In 12 healthy cows, neutrophil alkaline phosphatase (NAP) activity was measured by flow cytometer before and during an experimentally induced Escherichia coli mastitis, to study the role and increase of NAP in Gram-negative bacterial infections. Percentage of neutrophils containing alkaline phosphatase and intensity of NAP activity were measured. Preinfection percentage of neutrophils with enzyme activity varied between 64.0% and 84.4% and the intensity of enzyme activity was low in all cows. After induction of infection, percentage of neutrophils with enzyme activity showed a significant decrease on day 1 followed by an significant increase on day 3. NAP intensity increased significantly on the second and third day after infection. This increase of intensity was significantly, positively correlated with the severity of infection. From this study we may conclude that variation in susceptibility to E. coli mastitis could not be explained by preinfection NAP levels. The post-infection increase of NAP activity, that was found following an induced infection was more a result of increased enzyme intensity per neutrophil, then from an increase of percentage neutrophils with enzyme activity. Furthermore, a strong correlation was found between NAP intensity and severity of inflammation. There was evidence that the more severely diseased animals showed stronger NAP intensity increase.

In vitro conversion of the carbohydrate moiety of fungal glycoproteins to mammalian-type oligosaccharides--evidence for N-acetylglucosaminyltransferase-I-accepting glycans from Trichoderma reesei.

To investigate the potential of filamentous fungi to synthesize N-glycans that are convertible to a mammalian type, in vitro glycosylation assays were performed. Recombinant human N-acetylglucosaminyltransferase I, human beta-1,4-galactosyltransferase and rat alpha-2,6-sialyltransferase were successively used to mimic part of the mammalian glycosylation synthesis pathway. High-mannose carbohydrates on Trichoderma reesei cellobiohydrolase I were converted to a hybrid mammalian-type structure. Successful modification varied markedly with the strain of T. reesei used to produce cellobiohydrolase I. In vitro pretreatment of fungal glycoproteins with Aspergillus saitoi alpha-1,2-mannosidase improved subsequent hybrid formation. It was, however, not possible to trim all fungal oligosaccharides to an acceptor substrate for mammalian glycosyltransferases. With T. reesei RUTC 30, capping glucose residues and phosphate groups were shown to be responsible for this lack of trimming. N-glycan processing in T. reesei apparently involves different steps, including alpha-1,2-mannosidase trimmings, and thus resembles the first mammalian glycosylation processes. The alpha-1,2-mannosidase trimming steps can be exploited for further in vitro and/or in vivo synthesis of complex oligosaccharides on (heterologous) glycoproteins from filamentous fungi.

Cellobiohydrolase I from Trichoderma reesei: identification of an active-site nucleophile and additional information on sequence including the glycosylation pattern of the core protein.

(R,S)-3,4-Epoxybutyl beta-cellobioside, but not the corresponding propyl and pentyl derivatives, inactivates specifically and irreversibly cellobiohydrolase I from Trichoderma reesei by covalent modification of Glu212, the putative active-site nucleophile. The position and identity of the modified amino acid residue were determined using a combination of comparative liquid chromatography coupled on-line to electrospray ionization mass spectrometry, tandem mass spectrometry and microsequencing. It was found that the core protein corresponds to the N-terminal sequence pyrGlu1-Gly434 (Gly435) of intact cellobiohydrolase I. In the particular enzyme samples investigated, the asparagine residues in positions 45, 270 and 384 are each linked to a single 2-acetamido-2-deoxy-D-glucopyranose residue.

Activity studies and crystal structures of catalytically deficient mutants of cellobiohydrolase I from Trichoderma reesei.

The roles of the residues in the catalytic trio Glu212-Asp214-Glu217 in cellobiohydrolase I (CBHI) from Trichoderma reesei have been investigated by changing these residues to their isosteric amide counterparts. Three mutants, E212Q, D214N and E217Q, were constructed and expressed in T. reesei. All three point mutations significantly impair the catalytic activity of the enzyme, although all retain some residual activity. On the small chromophoric substrate CNP-Lac, the kcat values were reduced to 1/2000, 1/85 and 1/370 of the wild-type activity, respectively, whereas the KM values remained essentially unchanged. On insoluble crystalline cellulose, BMCC, no significant activity was detected for the E212Q and E217Q mutants, whereas the D214N mutant retained residual activity. The consequences of the individual mutations on the active-site structure were assessed for two of the mutants, E212Q and D214N, by X-ray crystallography at 2.0 A and 2.2 A resolution, respectively. In addition, the structure of E212Q CBHI in complex with the natural product, cellobiose, was determined at 2.0 A resolution. The active-site structure of each mutant is very similar to that of the wild-type enzyme. In the absence of ligand, the active site of the D214N mutant contains a calcium ion firmly bound to Glu212, whereas that of E212Q does not. This supports our hypothesis that Glu212 is the charged species during catalysis. As in the complex of wild-type CBHI with bound o-iodobenzyl-1-thio-beta-D-glucoside, cellobiose is bound to the two product sites in the complex with E212Q. However, the binding of cellobiose differs from that of the glucoside in that the cellobiose is shifted away from the trio of catalytic residues to interact more intimately with a loop that is part of the outer wall of the active site.