Improvement of cellulose-degrading ability of a yeast strain displaying Trichoderma reesei endoglucanase II by recombination of cellulose-binding domains

To improve the cellulolytic activity of a yeast strain displaying endoglucanase II (EGII) from the filamentous fungus Trichoderma reesei QM9414, the genes encoding the cellulose-binding domain (CBD) of EGII, cellobiohydrolase I (CBHI) and cellobiohydrolase II (CBHII) from T. reesei QM9414, were fused with the catalytic domain of EGII and expressed in Saccharomyces cerevisiae. Display of each of the recombinant EGIIs was confirmed using immunofluorescence microscopy. In the case of EGII-displaying yeast strains in which the CBD of EGII was replaced with the CBD of CBHI or CBHII, the binding affinity to Avicel and hydrolytic activity toward phosphoric acid swollen Avicel were similar to that of a yeast strain displaying wild-type EGII. On the other hand, the three yeast strains displaying EGII with two or three tandemly aligned CBDs showed binding affinity and hydrolytic activity higher than that of the yeast strain displaying wild-type EGII. This result indicates that the hydrolytic activity of yeast strains displaying recombinant EGII increases with increased binding ability to cellulose.     

Identification of functionally important amino acids in the cellulose-binding domain of Trichoderma reesei cellobiohydrolase I.

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.     

The 1,4-beta-D-glucan cellobiohydrolases from Phanerochaete chrysosporium. I. A system of synergistically acting enzymes homologous to Trichoderma reesei.

A physico-chemical and structural characterization of three 1,4-beta-D-glucan cellobiohydrolases (EC. 3.2.1.91), isolated from a culture filtrate of the white-rot fungus Phanerochaete chrysosporium, reveals that the cellulolytic enzyme secretion pattern and thus the general degradation strategy for P. chrysosporium is similar to that of Trichoderma reesei. Partial sequence data show that two of the isolated enzymes, i.e., CBHI, pI 3.82 and CBH62, pI 4.85, are homologous with CBHI and EGI from T. reesei; while, the third, i.e., CBH50, pI 4.87, is homologous to T. reesei CBHII. Limited proteolysis with papain cleaved each of the three enzymes into two domains: a core protein which retained full catalytic activity against low molecular weight substrates and a peptide fragment corresponding to the cellulose binding domain, in striking similarity to the structural organization of T. reesei. CBHI and CBH62 have their binding domain located at the C-terminus, whereas in CBH50 it is located at the N-terminus. It is evident that synergistically acting cellobiohydrolases is a general requirement for efficient hydrolysis of crystalline cellulose by cellulolytic fungi.     

Isolation and purification of isoenzymes of cellobiohydrolase I and II of trichoderma reesei using LPLC methods

Five cellulases were fractionated from a commercial cellulase preparation (Celluclast^TM) Two isoenzymes of cellobiohydrolase I (CBHI)(pI = 4.1) could be proved to be real exo-glucanases due to their activity towards MU (=methylumbelliferyl)-lactoside being inhibited by cellobiose (5 mM) and due to production of cellobiose from carboxymethylcellulose (CMC) as the sole final product.Two isoenzymes of CBHII (pI=6.15, 6.0) were shown to act as endo-glucanases because they produced glucose, cellobiose and cellotetraose from CMC and because they were not inhibited by cellobiose when decomposing MU-lactoside. Results confirm recent reports in the literature classifying CBHI and CBHII as exo-type and endo-type cellulases, respectively. Both the CBHI and the CBHII isoenzymes were shown to be active towards CMC and amorphous cellulose.CBHI and CBHII reactions could be differentiated from one another by the velocities of decomposition of CMC: CBHI acts slowly and linearly whereas CBHII acts strongly and exponentially.The fifth of the purified enzymes must be classed as a conventional endoglucanase which exhibits activity towards CMC but fails to be active towards MU-lactoside and amorphous cellulose.     

Investigation of the function of mutated cellulose-binding domains of Trichoderma reesei cellobiohydrolase I.

The function of the cellulose-binding domain (CBD) of the cellobiohydrolase I of Trichoderma reesei was studied by site-directed mutagenesis of two amino acid residues identified by analyzing the 3D structure of this domain. The mutant enzymes were produced in yeast and tested for binding and activity on crystalline cellulose. Mutagenesis of the tyrosine residue (Y492) located at the tip of the wedge-shaped domain to alanine or aspartate reduced the binding and activity on crystalline cellulose to the level of the core protein lacking the CBD. However, there was no effect on the activity toward small oligosaccharide (4-methylumbelliferyl beta-D-lactoside). The mutation tyrosine to histidine (Y492H) lowered but did not destroy the cellulose binding, suggesting that the interaction of the pyranose ring of the substrate with an aromatic side chain is important. However, the catalytic activity of this mutant on crystalline cellulose was identical to the other two mutants. The mutation P477R on the edge of the other face of the domain reduces both binding and activity of CBHI. These results support the hypothesis that both surfaces of the CBD are involved in the interaction of the binding domain with crystalline cellulose.     

Effects of pH and high ionic strength on the adsorption and activity of native and mutated cellobiohydrolase I from Trichoderma reesei

Cellobiohydrolase I (CBHI) is the major cellulase of Trichoderma reesei. The enzyme contains a discrete cellulose-binding domain (CBD), which increases its binding and activity on crystalline cellulose. We studied cellulase-cellulose interactions using site-directed mutagenesis on the basis of the three-dimensional structure of the CBD of CBHI. Three mutant proteins which have earlier been produced in Saccharomyces cerevisiae were expressed in the native host organism. The data presented here support the hypothesis that a conserved tyrosine (Y492) located on the flat and more hydrophilic surface of the CBD is essential for the functionality. The data also suggest that the more hydrophobic surface is not directly involved in the CBD function. The pH dependence of the adsorption revealed that electrostatic repulsion between the bound proteins may also control the adsorption. The binding of CBHI to cellulose was significantly affected by high ionic strength suggesting that the interaction with cellulose includes a hydrophobic effect. High ionic strength increased the activity of the isolated core and of mutant proteins on crystalline cellulose, indicating that once productively bound, the enzymes are capable of solubilizing cellulose even with a mutagenized or with no CBD. © 1995 Wiley-Liss, Inc.     

Efficient secretion of two fungal cellobiohydrolases by Saccharomyces cerevisiae

Two different cellobiohydrolases, CBHI and CBHII, of the filamentous fungus Trichoderma reesei both hydrolyse highly crystalline cellulose. Cellulolytic strains of the yeast Saccharomyces cerevisiae were constructed by transferring cDNAs coding for these enzymes into yeast on an expression plasmid. These cellulolytic yeasts were able to secrete efficiently the large, heterologous proteins to the culture medium. The recombinant cellulases were observed to be heterogeneous in Mr due, at least partly, to variable N-glycosylation. Recombinant CBHII was able to bind to crystalline cellulose, although slightly less efficiently than the native enzyme. Both of the two recombinant cellulases were able to degrade amorphous cellulose. In a fermenter cultivation, around 100 micrograms/ml of CBHII was secreted into the yeast growth medium.     

Cloning of two cellobiohydrolase genes from <Emphasis Type="Italic">Trichoderma</Emphasis><Emphasis Type="Italic">viride</Emphasis> and heterogenous expression in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Cellobiohydrolase genes cbhI and cbhII were isolated from Trichoderma viride AS3.3711 and T. viride CICC 13038, respectively, using RT-PCR technique. The cbhI gene from T. viride AS3.3711 contains 1,542 nucleotides and encodes a 514-amino acid protein with a molecular weight of approximately 53.96 kDa. The cbhII gene from T. viride CICC 13038 was 1,413 bp in length encoding 471 amino acid residues with a molecular weight of approximately 49.55 kDa. The CBHI protein showed high homology with enzymes belonging to glycoside hydrolase family 7 and CBHII is a member of Glycoside hydrolase family 6. CBHI and CBHII play a role in the conversion of cellulose to glucose by cutting the disaccharide cellobiose from the non-reducing end of the cellulose polymer chain. The two cellobiohydrolase (CBHI, CBHII) genes were successfully expressed in Saccharomyces cerevisiae H158. Maximal activities of transformants Sc-cbhI and Sc-cbhII were 0.03 and 0.089 units ml⁻¹ under galactose induction, respectively. The optimal temperatures of the recombinant enzymes (CBHI, CBHII) were 60 and 70°C, respectively. The optimal pHs of recombinant enzymes CBHI and CBHII were at pH 5.8 and 5.0, respectively.     

纤维二糖水解酶I基因的系统进化分析

纤维二糖水解酶I（CBHI）是生物降解纤维素的一种重要的外切酶,它作用于纤维素分子末端,水解β-1,4-糖苷键。纤维二糖水解酶由3个部分组成：具有催化活性的催化结构域,作用为锚定纤维素的纤维素结合域以及连接这两个结构域的一段短肽。已知催化结构域属于糖基水解酶家族7（GH7）,纤维素结合域属于糖类结合模块家族1（CBMl）。为进一步探索CBHI编码基因之间的进化关系,本研究依据CBHI的结构域在GenBank数据库中搜索并鉴定CBHI编码基因并据此构建系统发育树。序列的平均长度为1776bp,平均GC含量为57．64％,平均转换颠换比为0．71,平均遗传距离为0．424。得出结论CBHI编码基因只存在于真菌中,是一个相对活跃的基因,它的进化与物种的进化有着密切的关系。     

Dynamic interaction of Trichoderma reesei cellobiohydrolases Cel6A and Cel7A and cellulose at equilibrium and during hydrolysis

The binding of cellobiohydrolases to cellulose is a crucial initial step in cellulose hydrolysis. In the search for a detailed understanding of the function of cellobiohydrolases, much information concerning how the enzymes and their constituent catalytic and cellulose-binding domains interact with cellulose and with each other and how binding changes during hydrolysis is still needed. In this study we used tritium labeling by reductive methylation to monitor binding of the two Trichoderma reesei cellobiohydrolases, Cel6A and Cel7A (formerly CBHII and CBHI), and their catalytic domains. Measuring hydrolysis by high-performance liquid chromatography and measuring binding by scintillation counting allowed us to correlate activity and binding as a function of the extent of degradation. These experiments showed that the density of bound protein increased with both Cel6A and Cel7A as hydrolysis proceeded, in such a way that the adsorption points moved off the initial binding isotherms. We also compared the affinities of the cellulose-binding domains and the catalytic domains to the affinities of the intact proteins and found that in each case the affinity of the enzyme was determined by the linkage between the catalytic and cellulose-binding domains. Desorption of Cel6A by dilution of the sample showed hysteresis (60 to 70% reversible); in contrast, desorption of Cel7A did not show hysteresis and was more than 90% reversible. These findings showed that the two enzymes differ with respect to the reversibility of binding.     

Monoclonal antibodies against core and cellulose-binding domains of Trichoderma reesei cellobiohydrolases I and II and endoglucanase I.

Cellulases from Trichoderma reesei form an enzyme group with a common structural organization. Each cellulase enzyme is composed of two functional domains, the core region containing the active site and the cellulose-binding domain (CBD). To facilitate the specific detection of each domain, monoclonal antibodies (mAb) against cellobiohydrolase I (CBHI), cellobiohydrolase II (CBHII) and endoglucanase I (EGI) were produced. Five mAb were obtained against CBHI, ten against CBHII and eight against EGI. The location of the antigenic epitope for each antibody was mapped by allowing the antibodies to react with truncated cellulases, synthesized from deleted cDNA in Saccharomyces cerevisiae. Proteolytic fragments of Trichoderma cellulases, obtained by papain digestion, were used to confirm the results. Specific antibodies were detected against the core and the CBD epitopes for all three cellulases. Using the truncated enzymes, it was possible to locate the epitopes to a reasonably short region within the protein. To obtain a quantitative assay for each enzyme, a specific mAb against each antigen was chosen, based on the affinity to the corresponding antigen on Western-blot staining and on filter blots of the cellulolytic yeasts. The mAb were used to quantitative the corresponding enzymes in T. reesei culture medium. Specific quantitation of each cellulase enzyme has not been possible by biochemical assays or using polyclonal antibodies, due to their cross-reactions. Now, these mAb can be specifically used to recognize and quantitate different domains of these three important cellulolytic enzymes.     

Alpha-amylase inhibitors selected from a combinatorial library of a cellulose binding domain scaffold

A disulfide bridge-constrained cellulose binding domain (CBD(WT)) derived from the cellobiohydrolase Cel7A from Trichoderma reesei has been investigated for use in scaffold engineering to obtain novel binding proteins. The gene encoding the wild-type 36 aa CBD(WT) domain was first inserted into a phagemid vector and shown to be functionally displayed on M13 filamentous phage as a protein III fusion protein with retained cellulose binding activity. A combinatorial library comprising 46 million variants of the CBD domain was constructed through randomization of 11 positions located at the domain surface and distributed over three separate beta-sheets of the domain. Using the enzyme porcine alpha-amylase (PPA) as target in biopannings, two CBD variants showing selective binding to the enzyme were characterized. Reduction and iodoacetamide blocking of cysteine residues in selected CBD variants resulted in a loss of binding activity, indicating a conformation dependent binding. Interestingly, further studies showed that the selected CBD variants were capable of competing with the binding of the amylase inhibitor acarbose to the enzyme. In addition, the enzyme activity could be partially inhibited by addition of soluble protein, suggesting that the selected CBD variants bind to the active site of the enzyme.     

The 1,4-beta-D-glucan glucanohydrolases from Phanerochaete chrysosporium. Re-assessment of their significance in cellulose degradation mechanisms.

A physico-chemical, functional and structural characterization, including partial sequence data, of three major 1,4-beta-D-glucan glucanohydrolases (EC. 3.2.1.4) isolated from the culture filtrate of the white-rot fungus Phanerochaete chrysosporium, shows that all three enzymes belong to a single family of cellulases. EG44, pI 4.3, (named after its apparent molecular mass in kDa), shows a clear homology with Schizopyllum commune Endoglucanase I (EGI); whereas EG38, pI 4.9, (named in the same manner) is related more closely to Trichoderma reesei (Trichoderma longibrachiatum) Endoglucanase III (EGIII). EG36, pI 5.6-5.7, is probably an EG38 protein lacking its cellulose binding domain. Strong synergistic action is induced by the enzymes acting in concert with cellobiohydrolases (CBHI and CBHII) from the same organism, indicating a highly effective enzymatic system for cellulose degradation. Controlled proteolysis with papain has allowed a so far unique cleavage of endoglucanases EG44 and EG38 into two domains: a core protein, which virtually lacks the capacity to absorb onto microcrystal-line cellulose but retains full catalytic activity against carboxymethyl cellulose and low molecular weight soluble substrates; and a peptide fragment corresponding to the cellulose binding domain. The latter appears to be of paramount significance in the mechanisms involved in the hydrolysis of microcrystalline cellulose.     

Dynamic Interaction of Trichoderma reesei Cellobiohydrolases Cel6A and Cel7A and Cellulose at Equilibrium and during Hydrolysis

The binding of cellobiohydrolases to cellulose is a crucial initial step in cellulose hydrolysis. In the search for a detailed understanding of the function of cellobiohydrolases, much information concerning how the enzymes and their constituent catalytic and cellulose-binding domains interact with cellulose and with each other and how binding changes during hydrolysis is still needed. In this study we used tritium labeling by reductive methylation to monitor binding of the two Trichoderma reesei cellobiohydrolases, Cel6A and Cel7A (formerly CBHII and CBHI), and their catalytic domains. Measuring hydrolysis by high-performance liquid chromatography and measuring binding by scintillation counting allowed us to correlate activity and binding as a function of the extent of degradation. These experiments showed that the density of bound protein increased with both Cel6A and Cel7A as hydrolysis proceeded, in such a way that the adsorption points moved off the initial binding isotherms. We also compared the affinities of the cellulose-binding domains and the catalytic domains to the affinities of the intact proteins and found that in each case the affinity of the enzyme was determined by the linkage between the catalytic and cellulose-binding domains. Desorption of Cel6A by dilution of the sample showed hysteresis (60 to 70% reversible); in contrast, desorption of Cel7A did not show hysteresis and was more than 90% reversible. These findings showed that the two enzymes differ with respect to the reversibility of binding.     

A mechanistic model for rational design of optimal cellulase mixtures

A model‐based framework is described that permits the optimal composition of cellulase enzyme mixtures to be found for lignocellulose hydrolysis. The rates of hydrolysis are shown to be dependent on the nature of the substrate. For bacterial microcrystalline cellulose (BMCC) hydrolyzed by a ternary cellulase mixture of EG2, CBHI, and CBHII, the optimal predicted mixture was 1:0:1 EG2:CBHI:CBHII at 24 h and 1:1:0 at 72 h, at loadings of 10 mg enzyme per g substrate. The model was validated with measurements of soluble cello‐oligosaccharide production from BMCC during both single enzyme and mixed enzyme hydrolysis. Three‐dimensional diagrams illustrating cellulose conversion were developed for mixtures of EG2, CBHI, CBHII acting on BMCC and predicted for other substrates with a range of substrate properties. Model predictions agreed well with experimental values of conversion after 24 h for a variety of enzyme mixtures. The predicted mixture performances for substrates with varying properties demonstrated the effects of initial degree of polymerization (DP) and surface area on the performance of cellulase mixtures. For substrates with a higher initial DP, endoglucanase enzymes accounted for a larger fraction of the optimal mixture. Substrates with low surface areas showed significantly reduced hydrolysis rates regardless of mixture composition. These insights, along with the quantitative predictions, demonstrate the utility of this model‐based framework for optimizing cellulase mixtures. Biotechnol. Bioeng. 2011;108: 2561–2570. © 2011 Wiley Periodicals, Inc.     

CelG from Clostridium cellulolyticum: a multidomain endoglucanase acting efficiently on crystalline cellulose.

The gene coding for CelG, a family 9 cellulase from Clostridium cellulolyticum, was cloned and overexpressed in Escherichia coli. Four different forms of the protein were genetically engineered, purified, and studied: CelGL (the entire form of CelG), CelGcat1 (the catalytic domain of CelG alone), CelGcat2 (CelGcat1 plus 91 amino acids at the beginning of the cellulose binding domain [CBD]), and GST-CBD(CelG) (the CBD of CelG fused to glutathione S-transferase). The biochemical properties of CelG were compared with those of CelA, an endoglucanase from C. cellulolyticum which was previously studied. CelG, like CelA, was found to have an endo cutting mode of activity on carboxymethyl cellulose (CMC) but exhibited greater activity on crystalline substrates (bacterial microcrystalline cellulose and Avicel) than CelA. As observed with CelA, the presence of the nonhydrolytic miniscaffolding protein (miniCipC1) enhanced the activity of CelG on phosphoric acid swollen cellulose (PASC), but to a lesser extent. The absence of the CBD led to the complete inactivation of the enzyme. The abilities of CelG and GST-CBD(CelG) to bind various substrates were also studied. Although the entire enzyme is able to bind to crystalline cellulose at a limited number of sites, the chimeric protein GST-CBD(CelG) does not bind to either of the tested substrates (Avicel and PASC). The lack of independence between the two domains and the weak binding to cellulose suggest that this CBD-like domain may play a special role and be either directly or indirectly involved in the catalytic reaction.     

Fusion of cellulose binding domain from Trichoderma reesei CBHI to Cryptococcus sp. S-2 cellulase enhances its binding affinity and its cellulolytic activity to insoluble cellulosic substrates

Cryptococcus sp. S-2 carboxymethyl cellulase (CSCMCase) is active in the acidic pH and lacks a binding domain. The absence of the binding domain makes the enzyme inefficient against insoluble cellulosic substrates. To enhance its binding affinity and its cellulolytic activity to insoluble cellulosic substrates, cellulose binding domain (CBD) of cellobiohydrolase I (CBHI) from Trichoderma reesei belonging to carbohydrate binding module (CBM) family 1 was fused at the C-terminus of CSCMCase. The constructed fusion enzymes (CSCMCase-CBD and CSCMCase-2CBD) were expressed in a newly recombinant expression system of Cryptococcus sp. S-2, purified to homogeneity, and then subject to detailed characterization. The recombinant fusion enzymes displayed optimal pH similar to those of the native enzyme. Compared with rCSCMCase, the recombinant fusion enzymes had acquired an increased binding affinity to insoluble cellulose and the cellulolytic activity toward insoluble cellulosic substrates (SIGMACELL^® and Avicel) was higher than that of native enzyme, confirming the presence of CBDs improve the binding and the cellulolytic activity of CSCMCase on insoluble substrates. This attribute should make CSCMCase an attractive applicant for various application.     

Roles of the Catalytic Domain and Two Cellulose Binding Domains of Thermomonospora fusca E4 in Cellulose Hydrolysis

Thermomonospora fusca E4 is an unusual 90.4-kDa endocellulase comprised of a catalytic domain (CD), an internal family IIIc cellulose binding domain (CBD), a fibronectinlike domain, and a family II CBD. Constructs containing the CD alone (E4-51), the CD plus the family IIIc CBD (E4-68), and the CD plus the fibronectinlike domain plus the family II CBD (E4-74) were made by using recombinant DNA techniques. The activities of each purified protein on bacterial microcrystalline cellulose (BMCC), filter paper, swollen cellulose, and carboxymethyl cellulose were measured. Only the whole enzyme, E4-90, could reach the target digestion of 4.5% on filter paper. Removal of the internal family IIIc CBD (E4-51 and E4-74) decreased activity markedly on every substrate. E4-74 did bind to BMCC but had almost no hydrolytic activity, while E4-68 retained 32% of the activity on BMCC even though it did not bind. A low-activity mutant of one of the catalytic bases, E4-68 (Asp55Cys), did bind to BMCC, although E4-51 (Asp55Cys) did not. The ratios of soluble to insoluble reducing sugar produced after filter paper hydrolysis by E4-90, E4-68, E4-74, and E4-51 were 6.9, 3.5, 1.3, and 0.6, respectively, indicating that the family IIIc CBD is important for E4 processivity.     

Biochemistry and genetics of actinomycete cellulases.

The order Actinomycetales includes a number of genera that contain species that actively degrade cellulose and these include both mesophilic and facultative thermophilic species. Cellulases produced by strains from two of the genera containing thermophilic organisms have been studied extensively: Microbispora bispora and Thermomonospora fusca. Fractionation of M. bispora cellulases has identified six different enzymes, all of which were purified to near homogeneity and partially characterized. Two of these enzymes appear to be exocellulases and gave synergism with each other and with the endocellulases. The structural genes of five M. bispora cellulases have been cloned and one was sequenced. Fractionation of T. fusca cellulases has identified five different enzymes, all of which were purified to near homogeneity and partially characterized. One of the T. fusca enzymes gives synergism in the hydrolysis of crystalline cellulose with several T. fusca endocellulases and with Trichoderma reesei CBHI but not with T. reesei CBHII. Each T. fusca cellulase contains distinct catalytic and cellulose binding domains. The structural genes of four of the T. fusca endoglucanases have been cloned and sequenced, while three cellulase genes have been cloned from "T. curvata". The T. fusca cellulase genes are expressed at a low level in Escherichia soli, but at a high level in Streptomyces lividans. Sequence comparisons have shown that there are no significant amino acid homologies between any of the catalytic domains of the four T. fusca cellulases, but each of them shows extensive homology to several other cellulases and fits in one of the five existing cellulase gene families. There have been extensive studies of the regulation of the synthesis of these cellulases and a number of regulatory mutants have been isolated. This work has shown that the different T. fusca cellulases are coordinately regulated over a 100-fold range by two independent controls; induction by cellobiose and repression by any good carbon source.     

Three-dimensional structures of three engineered cellulose-binding domains of cellobiohydrolase I from Trichoderma reesei.

Three-dimensional solution structures for three engineered, synthetic CBDs (Y5A, Y31A, and Y32A) of cellobiohydrolase I (CBHI) from Trichoderma reesei were studied with nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. According to CD measurements the antiparallel beta-sheet structure of the CBD fold was preserved in all engineered peptides. The three-dimensional NMR-based structures of Y31A and Y32A revealed only small local changes due to mutations in the flat face of CBD, which is expected to bind to crystalline cellulose. Therefore, the structural roles of Y31 and Y32 are minor, but their functional importance is obvious because these mutants do not bind strongly to cellulose. In the case of Y5A, the disruption of the structural framework at the N-terminus and the complete loss of binding affinity implies that Y5 has both structural and functional significance. The number of aromatic residues and their precise spatial arrangement in the flat face of the type I CBD fold appears to be critical for specific binding. A model for the CBD binding in which the three aligned aromatic rings stack onto every other glucose ring of the cellulose polymer is discussed.