Cellulose is the major polysaccharide of plants where it plays a predominantly structural role. A variety of highly specialized microorganisms have evolved to produce enzymes that either synergistically or in complexes can carry out the complete hydrolysis of cellulose. The structure of the major cellobiohydrolase, CBHI, of the potent cellulolytic fungus Trichoderma reesei has been determined and refined to 1.8 angstrom resolution. The molecule contains a 40 angstrom long active site tunnel that may account for many of the previously poorly understood macroscopic properties of the enzyme and its interaction with solid cellulose. The active site residues were identified by solving the structure of the enzyme complexed with an oligosaccharide, o-iodobenzyl-1-thio-beta-cellobioside. The three-dimensional structure is very similar to a family of bacterial beta-glucanases with the main-chain topology of the plant legume lectins.
The solution structure of a synthetic 36-residue polypeptide comprising the C-terminal cellulose binding domain of cellobiohydrolase I (CT-CBH I) from Trichoderma reesei was investigated by nuclear magnetic resonance (NMR) spectroscopy. The 1H NMR spectrum was completely assigned in a sequential manner by two-dimensional NMR techniques. A large number of stereospecific assignments for beta-methylene protons, as well as ranges for the phi, psi, and chi 1 torsion angles, were obtained on the basis of sequential and intraresidue nuclear Overhauser enhancement (NOE) and coupling constant data in combination with a conformational data base search. The structure calculations were carried out in an iterative manner by using the hybrid distance geometry-dynamical simulated annealing method. This involved computing a series of initial structures from a subset of the experimental data in order to resolve ambiguities in the assignments of some NOE cross-peaks arising from chemical shift degeneracy. Additionally, this permitted us to extend the stereospecific assignments to the alpha-methylene protons of glycine using information on phi torsion angles derived from the initial structure calculations. The final experimental data set consisted of 554 interproton distance restraints, 24 restraints for 12 hydrogen bonds, and 33 phi, 24 psi, and 25 chi 1 torsion angle restraints. CT-CBH I has two disulfide bridges whose pairing was previously unknown. Analysis of structures calculated with all three possible combinations of disulfide bonds, as well as without disulfide bonds, indicated that the correct disulfide bridge pairing was 8-25 and 19-35. Forty-one structures were computed with the 8-25 and 19-35 disulfide bridges, and the average atomic rms difference between the individual structures and the mean structure obtained by averaging their coordinates was 0.33 +/- 0.04 A for the backbone atoms and 0.52 +/- 0.06 A for all atoms. The protein has a wedgelike shape with an amphiphilic character, one face being predominantly hydrophilic and the other mainly hydrophobic. The principal element of secondary structure is made up of an irregular triple-stranded antiparallel beta-sheet composed of residues 5-9 (beta 1), 24-28 (beta 2), and 33-36 (beta 3) in which strand beta 3 is hydrogen bonded to the other two strands.(ABSTRACT TRUNCATED AT 400 WORDS)
Limited action of papain on the native forms of two cellobiohydrolases (CBH) from Trichoderma reesei (CBH I, 65 kDa, and CBH II,58 kDa) leads to the isolation of the respective core fragments (56 kDa and 45 kDa) which are fully active on small, soluble substrates, but have a strongly reduced activity (respectively 10% and 50% of the initial value) on microcrystalline cellulose (Avicel).By partial sequencing at the C terminus of the CBH I core and at the N terminus of the CBH I1 core the papain cleavage sites have been assigned in the primary structures (at about residue 431 and 82 respectively). This limited action of papain on the native enzymes indicates the presence of hinge regions linking the core to these terminal glycopeptides. The latter conserved sequences appear either at the C or N terminus of several cellulolytic enzymes from ~r~c~o d e r m a reesei [Teeri et al. (1987) Gene 51,43 -521. The specific activities of the intact enzymes and their cores on two forms of insoluble cellulose (crystalline, amorphous) differentiate the CBH I and CBH TI in terms of adsorption and catalytic properties, Distinct functions can be attributed to the terminal peptides: for intact CBH I1 the N-terminal region contributes in the binding onto both cellulose types; the homologous C-terminal peptide in CBH I, however, only affects the interaction with microcrystalline cellulose. It could be inferred that CBH I and its core bind preferentially to crystalline regions. This seems to be corroborated by the results of CBH I/CBH I1 synergism experiments.The filamentous fungus Trichoderma reesei presents an ideal system for the study of cellulose hydrolysis since it produces a variety of enzymes including endocellulase and exocellulase (cellobiohydrolases) and b-glucosidases (cellobiases) [l]. The primary structure of several of these proteins is presently known [2 -61 but no structure/function relationships have yet been established. The two cellobiohydrolases, CBH I and CBH I1 [7 -111, lack any apparent homology in their amino acid sequence except for a conserved region present at their C and N termini respectively [4].Their action is similar both with regard to their strong adsorption onto insoluble substrates and lack of carboxymethylcellulase activity. However, studies both with microcrystalline cellulose [9] and small, soluble substrates [I 21 reveal some differences in specificity. In addition, the two cellobiohydrolases interact synergistically both with each other and with endoglucanases on microcrystalline substrates In order to differentiate these enzymes further by their function and to investigate possible domain structure, proteolysis studies were performed. Preliminary results on the limited action of papain on native CBH I have been reported by us [16]. Two fragments were isolated: first, a heavily glycosylated peptide, tentatively identified with the C terminus; secondly, a core protein containing the active (hydrolytic) site. The terminal peptide was characterised as an independent structural and functional dom...
Cellobiohydrolase I (CBHI) of Trichoderma reesei has two functional domains, a catalytic core domain and a cellulose binding domain (CBD). The structure of the CBD reveals two distinct faces, one of which is flat and the other rough. Several other fungal cellulolytic enzymes have similar two-domain structures, in which the CBDs show a conserved primary structure. Here we have evaluated the contributions of conserved amino acids in CBHI CBD to its binding to cellulose. Binding isotherms were determined for a set of six synthetic analogues in which conserved amino acids were substituted. Two-dimensional NMR spectroscopy was used to assess the structural effects of the substitutions by comparing chemical shifts, coupling constants, and NOES of the backbone protons between the wild-type CBD and the analogues. In general, the structural effects of the substitutions were minor, although in some cases decreased binding could clearly be ascribed to conformational perturbations. We found that at least two tyrosine residues and a glutamine residue on the flat face were essential for tight binding of the CBD to cellulose. A change on the rough face had only a small effect on the binding and it is unlikely that this face interacts with cellulose directly.
Limited proteolysis of the cellobiohydrolase I (CBH I, 65 kDa) from Trichoderma reesei by papain yields a core protein (56 kDa) which is fully active against small, soluble substrates such as the chromophoric glycosides derived from the cellodextrins and lactose. Activity against an insoluble substrate, such as Avicel, is however completely lost and concomitantly decreased adsorption onto this microcrystalline cellulose is observed. The peptide (10 kDa), initially split off during proteolysis, is identified as the heavily glycosylated carboxy‐terminal of the native CBH I. Depending on the experimental conditions the core protein is further nicked in between disulfide bonds, but its properties and stability do not appreciably differ from those of intact CBH I. These results lead to the proposal of a bifunctional organisation of the CBH I: one domain, corresponding to the carboxyterminal, acts as a binding site for insoluble cellulose and the other, localised in the core protein, contains the active (hydrolytic) site.
The inhibition effect of cellobiose on the initial stage of hydrolysis when cellobiohydrolase Cel 7A and endoglucanases Cel 7B, Cel 5A, and Cel 12A from Trichoderma reesei were acting on bacterial cellulose and amorphous cellulose that were [(3)H]- labeled at the reducing end was quantified. The apparent competitive inhibition constant (K(i)) for Cel 7A on [(3)H]-bacterial cellulose was found to be 1.6 +/- 0.5 mM, 100-fold higher than that for Cel 7A acting on low-molecular-weight model substrates. The hydrolysis of [(3)H]-amorphous cellulose by endoglucanases was even less affected by cellobiose inhibition with apparent K(i) values of 11 +/- 3 mM and 34 +/- 6 mM for Cel 7B and Cel 5A, respectively. Contrary to the case for the other enzymes studied, the release of radioactive label by Cel 12A was stimulated by cellobiose, possibly due to a more pronounced transglycosylating activity. Theoretical analysis of the inhibition of Cel 7A by cellobiose predicted an inhibition analogous to that of mixed type with two limiting cases, competitive inhibition if the prevalent enzyme-substrate complex without inhibitor is productive and conventional mixed type when the prevalent enzyme-substrate complex is nonproductive.
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