Mutational analysis of a CBM family 5 chitin-binding domain of an alkaline chitinase from Bacillus sp. J813

Chitinase J from alkaliphilic Bacillus sp. J813 comprises a glycoside hydrolase (GH) family 18 catalytic domain (CatD), a fibronectin type III like domain, and a carbohydrate-binding module (CBM) family 5 chitin-binding domain (ChBD). It has been suggested that the ChBD binds to insoluble chitin and enhances its degradation by the CatD. To investigate the roles of two aromatic residues (Trp541 and Trp542), which are exposed on the surface of the ChBD, mutational analysis was performed. Single and double mutations of the two aromatic residues decreased binding and hydrolyzing abilities toward insoluble chitin. This result suggests that the ChBD binds to chitin by hydrophobic interactions via two surface-exposed aromatic residues. However, the double mutant, which has no such aromatic residue, bound to chitin at pH 5.2, probably by electrostatic interactions. Moreover, the ChBD bound to insoluble chitosan by electrostatic interactions.     

Functional analysis of the chitin-binding domain of a family 19 chitinase from Streptomyces griseus HUT6037: substrate-binding affinity and cis-dominant increase of antifungal function

Chitinase C (ChiC) is the first bacterial family 19 chitinase discovered in Streptomyces griseus HUT6037. While it shares significant similarity with the plant family 19 chitinases in the catalytic domain, its N-terminal chitin-binding domain (ChBD(ChiC)) differs from those of the plant enzymes. ChBD(ChiC) and the catalytic domain (CatD(ChiC)), as well as intact ChiC, were separately produced in E. coli and purified to homogeneity. Binding experiments and isothermal titration calorimetry assays demonstrated that ChBD(ChiC) binds to insoluble chitin, soluble chitin, cellulose, and N-acetylchitohexaose (roughly in that order). A deletion of ChBD(ChiC) resulted in moderate (about 50%) reduction of the hydrolyzing activity toward insoluble chitin substrates, but most (about 90%) of the antifungal activity against Trichoderma reesei was abolished by this deletion. Thus, this domain appears to contribute more importantly to antifungal properties than to catalytic activities. ChBD(ChiC) itself did not have antifungal activity or a synergistic effect on the antifungal activity of CatD(ChiC) in trans.     

Solution structure of the chitin-binding domain of Bacillus circulans WL-12 chitinase A1

The three-dimensional structure of the chitin-binding domain (ChBD) of chitinase A1 (ChiA1) from a Gram-positive bacterium, Bacillus circulans WL-12, was determined by means of multidimensional heteronuclear NMR methods. ChiA1 is a glycosidase that hydrolyzes chitin and is composed of an N-terminal catalytic domain, two fibronectin type III-like domains, and C-terminal ChBD(ChiA1) (45 residues, Ala(655)-Gln(699)), which binds specifically to insoluble chitin. ChBD(ChiA1) has a compact and globular structure with the topology of a twisted beta-sandwich. This domain contains two antiparallel beta-sheets, one composed of three strands and the other of two strands. The core region formed by the hydrophobic and aromatic residues makes the overall structure rigid and compact. The overall topology of ChBD(ChiA1) is similar to that of the cellulose-binding domain (CBD) of Erwinia chrysanthemi endoglucanase Z (CBD(EGZ)). However, ChBD(ChiA1) lacks the three aromatic residues aligned linearly and exposed to the solvent, which probably interact with cellulose in CBDs. Therefore, the binding mechanism of a group of ChBDs including ChBD(ChiA1) may be different from that proposed for CBDs.     

Importance of Trp59 and Trp60 in chitin-binding, hydrolytic, and antifungal activities of Streptomyces griseus chitinase C

The chitin-binding domain of Streptomyces griseus chitinase C (ChBD_ChiC) belongs to CBM family 5. Only two exposed aromatic residues, W59 and W60, were observed in ChBD_ChiC, in contrast to three such residues on CBD_Cel5 in the same CBM family. To study importance of these residues in binding activity and other functions of ChBD_ChiC, site-directed mutagenesis was carried out. Single (W59A and W60A) and double (W59A/W60A) mutations abolished the binding activity of ChiC to colloidal chitin and decreased the hydrolytic activity toward not only colloidal chitin but also a soluble high Mr substrate, glycol chitin. Interaction of ChBD_ChiC with oligosaccharide was eliminated by these mutations. The hydrolytic activity toward oligosaccharide was increased by deletion of ChBD but not affected by these mutations, indicating that ChBD interferes with oligosaccharide hydrolysis but not through its binding activity. The antifungal activity was drastically decreased by all mutations and significant difference was observed between single and double mutants. Taken together with the structural information, these results suggest that ChBD_ChiC binds to chitin via a mechanism significantly different from CBD_Cel5, where two aromatic residues play major role, and contributes to various functions of ChiC. Sequence comparison indicated that ChBD_ChiC-type CBMs are dominant in CBM family 5.     

Biochemical characterization and site-directed mutational analysis of the double chitin-binding domain from chitinase 92 of Aeromonas hydrophila JP101

Chitinase 92 from Aeromonas hydrophila JP101 contains C-terminal repeated chitin-binding domains (ChBDs) which were named ChBD(CI) and ChBD(CII) and classified into family 5 carbohydrate-binding modules on the basis of sequence. In this work, we constructed single and double ChBD by use of the pET system, which expressed as isolated ChBD(CII) or ChBD(CICII). Polysaccharide-binding studies revealed that ChBD(CICII) not only bound to chitin, but also to other insoluble polysaccharides such as cellulose (Avicel) and xylan. In comparison with ChBD(CII), the binding affinities of ChBD(CICII) are about 10- and 12-fold greater toward colloidal and powdered chitin, indicating that a cooperative interaction exists between ChBD(CI) and ChBD(CII). In order to investigate the roles of the highly conserved aromatic amino acids in the interaction of ChBD(CICII) and chitin, we have performed site-directed mutagenesis. The data showed that W773A, W792A, Y796A and W797A mutant proteins exhibited a much weaker affinity for chitin than wild-type protein, suggesting that these residues play important roles in chitin binding.     

Tertiary structure and carbohydrate recognition by the chitin-binding domain of a hyperthermophilic chitinase from Pyrococcus furiosus

A chitinase is a hyperthermophilic glycosidase that effectively hydrolyzes both α and β crystalline chitins; that studied here was engineered from the genes PF1233 and PF1234 of Pyrococcus furiosus. This chitinase has unique structural features and contains two catalytic domains (AD1 and AD2) and two chitin-binding domains (ChBDs; ChBD1 and ChBD2). A partial enzyme carrying AD2 and ChBD2 also effectively hydrolyzes crystalline chitin. We determined the NMR and crystal structures of ChBD2, which significantly enhances the activity of the catalytic domain. There was no significant difference between the NMR and crystal structures. The overall structure of ChBD2, which consists of two four-stranded β-sheets, was composed of a typical β-sandwich architecture and was similar to that of other carbohydrate-binding module 2 family proteins, despite low sequence similarity. The chitin-binding surface identified by NMR was flat and contained a strip of three solvent-exposed Trp residues (Trp274, Trp308 and Trp326) flanked by acidic residues (Glu279 and Asp281). These acidic residues form a negatively charged patch and are a characteristic feature of ChBD2. Mutagenesis analysis indicated that hydrophobic interaction was dominant for the recognition of crystalline chitin and that the acidic residues were responsible for a higher substrate specificity of ChBD2 for chitin compared with that of cellulose. These results provide the first structure of a hyperthermostable ChBD and yield new insight into the mechanism of protein-carbohydrate recognition. This is important in the development of technology for the exploitation of biomass.     

X-Ray Crystal Structure of the Full Length Human Chitotriosidase (CHIT1) Reveals Features of Its Chitin Binding Domain

Chitinases are enzymes that catalyze the hydrolysis of chitin. Human chitotriosidase (CHIT1) is one of the two active human chitinases, involved in the innate immune response and highly expressed in a variety of diseases. CHIT1 is composed of a catalytic domain linked by a hinge to its chitin binding domain (ChBD). This latter domain belongs to the carbohydrate-binding module family 14 (CBM14 family) and facilitates binding to chitin. So far, the available crystal structures of the human chitinase CHIT1 and the Acidic Mammalian Chitinase (AMCase) comprise only their catalytic domain. Here, we report a crystallization strategy combining cross-seeding and micro-seeding cycles which allowed us to obtain the first crystal structure of the full length CHIT1 (CHIT1-FL) at 1.95 Å resolution. The CHIT1 chitin binding domain (ChBD_CHIT1) structure shows a distorted β-sandwich 3D fold, typical of CBM14 family members. Accordingly, ChBD_CHIT1 presents six conserved cysteine residues forming three disulfide bridges and several exposed aromatic residues that probably are involved in chitin binding, including the highly conserved Trp465 in a surface- exposed conformation. Furthermore, ChBD_CHIT1 presents a positively charged surface which may be involved in electrostatic interactions. Our data highlight the strong structural conservation of CBM14 family members and uncover the structural similarity between the human ChBD_CHIT1, tachycitin and house mite dust allergens. Overall, our new CHIT1-FL structure, determined with an adapted crystallization approach, is one of the few complete bi-modular chitinase structures available and reveals the structural features of a human CBM14 domain.     

Expression and characterization of the chitin-binding domain of chitinase A1 from Bacillus circulans WL-12

Chitinase A1 from Bacillus circulans WL-12 comprises an N-terminal catalytic domain, two fibronectin type III-like domains, and a C-terminal chitin-binding domain (ChBD). In order to study the biochemical properties and structure of the ChBD, ChBD(ChiA1) was produced in Escherichia coli using a pET expression system and purified by chitin affinity column chromatography. Purified ChBD(ChiA1) specifically bound to various forms of insoluble chitin but not to other polysaccharides, including chitosan, cellulose, and starch. Interaction of soluble chitinous substrates with ChBD(ChiA1) was not detected by means of nuclear magnetic resonance and isothermal titration calorimetry. In addition, the presence of soluble substrates did not interfere with the binding of ChBD(ChiA1) to regenerated chitin. These observations suggest that ChBD(ChiA1) recognizes a structure which is present in insoluble or crystalline chitin but not in chito-oligosaccharides or in soluble derivatives of chitin. ChBD(ChiA1) exhibited binding activity over a wide range of pHs, and the binding activity was enhanced at pHs near its pI and by the presence of NaCl, suggesting that the binding of ChBD(ChiA1) is mediated mainly by hydrophobic interactions. Hydrolysis of beta-chitin microcrystals by intact chitinase A1 and by a deletion derivative lacking the ChBD suggested that the ChBD is not absolutely required for hydrolysis of beta-chitin microcrystals but greatly enhances the efficiency of degradation.     

Unique GH18 chitinase from Euglena gracilis: full-length cDNA cloning and characterization of its catalytic domain

A cDNA of putative chitinase from Euglena gracilis, designated EgChiA, encoded 960 amino acid residues, which is arranged from N-terminus in the order of signal peptide, glycoside hydrolase family 18 (GH18) domain, carbohydrate binding module family 18 (CBM18) domain, GH18 domain, CBM18 domain, and transmembrane helix. It is likely that EgChiA is anchored on the cell surface. The recombinant second GH18 domain of EgChiA, designated as CatD2, displayed optimal catalytic activity at pH 3.0 and 50 °C. The lower the polymerization degree of the chitin oligosaccharides [(GlcNAc)_4–6] used as the substrates, the higher was the rate of degradation by CatD2. CatD2 degraded chitin nanofibers as an insoluble substrate, and it produced only (GlcNAc)₂ and GlcNAc. Therefore, we speculated that EgChiA localizes to the cell surface of E. gracilis and is involved in degradation of chitin polymers into (GlcNAc)₂ or GlcNAc, which are easily taken up by the cells.     

A single surface tryptophan in the chitin-binding domain from Bacillus circulans chitinase A1 plays a pivotal role in binding chitin and can be modified to create an elutable affinity tag

Site-directed mutagenesis was carried out to investigate the roles of a number of highly conserved residues of the chitin-binding domain (ChBD) of Bacillus circulans chitinase A1 (ChiA1) in the binding of chitin. Analysis of single alanine replacement mutants showed that mutation of an exposed tryptophan residue (Trp(687)) impaired the binding to chitin, while mutation of other highly conserved residues, most carrying aromatic or hydrophobic side chains, did not significantly affect the binding activity. Interestingly, replacement of Trp(687) with phenylalanine significantly reduced chitin-binding activity at lower salt concentrations (0-1 M NaCl) but allowed strong binding to chitin at 2 M NaCl. Since Trp(687) is conserved among the ChBDs belonging to the bacterial ChiA1 subfamily, the data presented suggest a general mechanism in which this exposed tryptophan, which is located in the cleft formed between two beta-sheets as revealed by the solution structure [J. Biol. Chem. 275 (2000) 13654], makes a major contribution to ligand binding presumably through hydrophobic interactions. Furthermore, modulation of the chitin-binding activity by the conserved amino acid replacement (W687F) and a shift in the ionic strength of buffer has led to the development of an elutable affinity tag for single column purification of recombinant proteins.     

Identification of the substrate interaction region of the chitin-binding domain of Streptomyces griseus chitinase C

Chitinase C from Streptomyces griseus HUT6037 was discovered as the first bacterial chitinase in family 19 other than chitinases found in higher plants. Chitinase C comprises two domains: a chitin-binding domain (ChBD(ChiC)) for attachment to chitin and a chitin-catalytic domain for digesting chitin. The structure of ChBD(ChiC) was determined by means of 13C-, 15N-, and 1H-resonance nuclear magnetic resonance (NMR) spectroscopy. The conformation of its backbone comprised two beta-sheets composed of two and three antiparallel beta-strands, respectively, this being very similar to the backbone conformations of the cellulose-binding domain of endoglucanase Z from Erwinia chrysanthemi (CBD(EGZ)) and the chitin-binding domain of chitinase A1 from Bacillus circulans WL-12 (ChBD(ChiA1)). The interaction between ChBD(ChiC) and hexa-N-acetyl-chitohexaose was monitored through chemical shift perturbations, which showed that ChBD(ChiC) interacted with the substrate through two aromatic rings exposed to the solvent as CBD(EGZ) interacts with cellulose through three characteristic aromatic rings. Comparison of the conformations of ChBD(ChiA1), ChBD(ChiC), and other typical chitin- and cellulose-binding domains, which have three solvent-exposed aromatic residues responsible for binding to polysaccharides, has suggested that they have adopted versatile binding site conformations depending on the substrates, with almost the same backbone conformations being retained.     

Structure of full‐length class I chitinase from rice revealed by X‐ray crystallography and small‐angle X‐ray scattering

The rice class I chitinase OsChia1b, also referred to as RCC2 or Cht‐2, is composed of an N‐terminal chitin‐binding domain (ChBD) and a C‐terminal catalytic domain (CatD), which are connected by a proline‐ and threonine‐rich linker peptide. Because of the ability to inhibit fungal growth, the OsChia1b gene has been used to produce transgenic plants with enhanced disease resistance. As an initial step toward elucidating the mechanism of hydrolytic action and antifungal activity, the full‐length structure of OsChia1b was analyzed by X‐ray crystallography and small‐angle X‐ray scattering (SAXS). We determined the crystal structure of full‐length OsChia1b at 2.00‐Å resolution, but there are two possibilities for a biological molecule with and without interdomain contacts. The SAXS data showed an extended structure of OsChia1b in solution compared to that in the crystal form. This extension could be caused by the conformational flexibility of the linker. A docking simulation of ChBD with tri‐N‐acetylchitotriose exhibited a similar binding mode to the one observed in the crystal structure of a two‐domain plant lectin complexed with a chitooligosaccharide. A hypothetical model based on the binding mode suggested that ChBD is unsuitable for binding to crystalline α‐chitin, which is a major component of fungal cell walls because of its collisions with the chitin chains on the flat surface of α‐chitin. This model also indicates the difference in the binding specificity of plant and bacterial ChBDs of GH19 chitinases, which contribute to antifungal activity. Proteins 2010. © 2010 Wiley‐Liss,Inc.     

Structural studies of a two-domain chitinase from Streptomyces griseus HUT6037

Chitinase C (ChiC) from Streptomyces griseus HUT6037 was the first glycoside hydrolase family 19 chitinase that was found in an organism other than higher plants. An N-terminal chitin-binding domain and a C-terminal catalytic domain connected by a linker peptide constitute ChiC. We determined the crystal structure of full-length ChiC, which is the only representative of the two-domain chitinases in the family. The catalytic domain has an alpha-helix-rich fold with a deep cleft containing a catalytic site, and lacks three loops on the domain surface compared with the catalytic domain of plant chitinases. The chitin-binding domain is an all-beta protein with two tryptophan residues (Trp59 and Trp60) aligned on the surface. We suggest the binding mechanism of tri-N-acetylchitotriose onto the chitin-binding domain on the basis of molecular dynamics (MD) simulations. In this mechanism, the ligand molecule binds well on the surface-exposed binding site through two stacking interactions and two hydrogen bonds and only Trp59 and Trp60 are involved in the binding. Furthermore, the flexibility of the Trp60 side-chain, which may be involved in adjusting the binding surface to fit the surface of crystalline chitin by the rotation of chi2 angle, is shown.     

Protein Engineering of Chit42 Towards Improvement of Chitinase and Antifungal Activities

The antagonism of Trichoderma strains usually correlates with the secretion of fungal cell wall degrading enzymes such as chitinases. Chitinase Chit42 is believed to play an important role in the biocontrol activity of Trichoderma strains as a biocontrol agent against phytopathogenic fungi. Chit42 lacks a chitin-binding domain (ChBD) which is involved in its binding activity to insoluble chitin. In this study, a chimeric chitinase with improved enzyme activity was produced by fusing a ChBD from T. atroviride chitinase 18–10 to Chit42. The improved chitinase containing a ChBD displayed a 1.7-fold higher specific activity than chit42. This increase suggests that the ChBD provides a strong binding capacity to insoluble chitin. Moreover, Chit42-ChBD transformants showed higher antifungal activity towards seven phytopathogenic fungal species.     

Identification and characterization of the three chitin-binding domains within the multidomain chitinase Chi92 from Aeromonas hydrophila JP101.

The gene (chi92) encoding the extracellular chitinase of Aeromonas hydrophila JP101 has been cloned and expressed in Escherichia coli. The mature form of Chi92 is an 842-amino-acid (89.830-kDa) modular enzyme comprised of a family 18 catalytic domain, an unknown-function region (the A region), and three chitin-binding domains (ChBDs; Chi92-N, ChBD(CI), and ChBD(CII)). The C-terminally repeated ChBDs, ChBD(CI) and ChBD(CII), were grouped into family V of cellulose-binding domains on the basis of sequence homology. Chitin binding and enzyme activity studies with C-terminally truncated Chi92 derivatives lacking ChBDs demonstrated that the ChBDs are responsible for its adhesion to unprocessed and colloidal chitins. Further adsorption experiments with glutathione S-transferase (GST) fusion proteins (GST-CI and GST-CICII) demonstrated that a single ChBD (ChBD(CI)) could promote efficient chitin and cellulose binding. In contrast to the two C-terminal ChBDs, the Chi92-N domain is similar to ChiN of Serratia marcescens ChiA, which has been proposed to participate in chitin binding. A truncated derivative of Chi92 that contained only a catalytic domain and Chi92-N still exhibited insoluble-chitin-binding and hydrolytic activities. Thus, it appears that Chi92 contains Chi92-N as the third ChBD in addition to two ChBDs (ChBD(CI) and ChBD(CII)).     

Removal of tightly bound ADP induces distinct structural changes of the two tryptophan-containing regions of the ncd motor domain

ncd is a molecular motor belonging to the kinesin superfamily. In solution, it is a homo-dimer of a 700 amino acid polypeptide. The C-terminus of each polypeptide forms a globular domain of about 40 kDa, the motor domain with ATPase activity. The ATPase site of the motor domain of kinesin family members, including ncd, binds ADP tightly, the release of which is facilitated by microtubules during the mechanochemical ATPase cycle. Previously, we studied the spectroscopic characteristics of the ncd motor domain, focusing on interactions of the transition-moment-dipoles between ADP and aromatic amino acid side chains using circular dichroism (CD) spectroscopy. In the present study, we generated several ncd motor domain mutants. In each, a tryptophanyl or specific tyrosyl residue was mutated. We found that Trp370 and Tyr442, the latter of which stacks directly with the adenine moiety of bound ADP, caused the bound ADP to exhibit peculiar CD signals. In addition, fluorescence measurements revealed that Trp370, but not Trp473, was responsible for the emission intensity change depending on the presence or absence of bound ADP. This fluorescence result implies that the structural change induced at the ADP-binding site (on the release of the ADP) is transmitted to the region that includes Trp370, which is relatively close to the ADP-binding site but not in direct contact with the ADP-binding region. In contrast, Trp473 in the region that is in contact with the alpha-helical coiled coil stalk did not experience the structural changes caused on removal of ADP. The distinct behavior of these two tryptophanyl residues suggests that the ncd motor domain has a bifacial architecture made up of a relatively deformable side including the nucleotide binding site and a more rigid one.     

The C-terminal module of Chi1 from Aeromonas caviae CB101 has a function in substrate binding and hydrolysis

The chitinase gene chi1 of Aeromonas caviae CB101 encodes an 865-amino-acid protein (with signal peptide) composed of four domains named from the N-terminal as an all-beta-sheet domain ChiN, a triosephosphate isomerase (TIM) catalytic domain, a function-unknown A region, and a putative chitin-binding domain (ChBD) composed of two repeated sequences. The N-terminal 563-amino-acid segment of Chi1 (Chi1DeltaADeltaChBD) shares 74% identity with ChiA of Serratia marcescens. By the homology modeling method, the three-dimensional (3D) structure of Chi1DeltaADeltaChBD was constructed. It fit the structure of ChiA very well. To understand fully the function of the C-terminal module of Chi1 (from 564 to 865 amino acids), two different C-terminal truncates, Chi1DeltaChBD and Chi1DeltaADeltaChBD, were constructed, based on polymerase chain reaction (PCR). Comparison studies of the substrate binding, hydrolysis capacity, and specificity among Chi1 and its two truncates showed that the C-terminal putative ChBD contributed to the insoluble substrate-protein binding and hydrolysis; the A region did not have any function in the insoluble substrate-protein binding, but it did have a role in the chitin hydrolysis: Deletion of the A region caused the enzyme to lose 30-40% of its activity toward amorphous colloidal chitin and soluble chitin, and around 50% toward p-nitrophenyl (pNP)-chitobiose pNP-chitotriose, and its activity toward low-molecular-weight chitooligomers (GlcNAc)3-6 also dropped, as shown by analysis of its digestion processes. This is the first clear demonstration that a domain or segment without a function in insoluble substrate-chitinase binding has a role in the digestion of a broad range of chitin substrates, including low-molecular-weight chitin oligomers. The reaction mode of Chi1 is also described and discussed.     

Comparison of cooperative and isolated site binding of T4 gene 32 protein to ssDNA by 1H NMR

Deuteriation of all aromatic protons of gene 32 protein (g32P) from phage T4, followed by selective introduction of specific protons, has allowed the precise identification of the number and magnitude of the chemical shift changes induced in the aromatic protons when g32P binds noncooperatively or cooperatively to nucleotides. Signals from five Tyr residues are shifted by binding of g32P to d(pA)8 or d(pA)40-60; however, the change from noncooperative, d(pA)8, to cooperative, d(pA)40-60, binding causes significant increases in the magnitudes of the shifts for only two of these Tyr signals. These two Tyr residues may interact directly with the nucleotide bases, while the shifts associated with the other three Tyr may be due to conformational changes in g32P upon ssDNA binding. Similar conclusions can be drawn for two of the six Phe residues whose protons undergo shifts upon nucleotide binding. Observation of selected proton signals allows for the first time detection by 1H NMR of changes in the proton signals from two Trp residues upon nucleotide binding. The side chains of two Tyr, one or two Phe, and one Trp are probably directly involved in nucleotide base-protein interactions. As assayed by the signals from the H2 and H8 protons of adenine, the bases of a bound nucleotide are undergoing a fast chemical exchange in the noncooperative mode of binding, but shift to slow exchange upon assuming the cooperative mode of ssDNA interaction. When bound to a polynucleotide, the A domain of g32P (residues 254-301) becomes more mobile, as reflected in sharpening of the 1H NMR signals from the A domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Roles of the exposed aromatic residues in crystalline chitin hydrolysis by chitinase A from Serratia marcescens 2170

Four exposed aromatic residues, two in the N-terminal domain (Trp-69 and Trp-33) and two in the catalytic domain (Trp-245 and Phe-232) of Serratia marcescens chitinase A, are linearly aligned with the deep catalytic cleft. To investigate the importance of these residues in the binding activity and hydrolyzing activity against insoluble chitin, site-directed mutagenesis to alanine was carried out. The substitution of Trp-69, Trp-33, or Trp-245 significantly reduced the binding activity to both highly crystalline beta-chitin and colloidal chitin. The substitution of Phe-232, which is located closest to the catalytic cleft, did not affect the binding activity. On the other hand, the hydrolyzing activity against beta-chitin microfibrils was significantly reduced by the substitution of any one of the four aromatic residues including Phe-232. None of the mutations reduced the hydrolyzing activity against soluble substrates. These results clearly demonstrate that the four exposed aromatic residues are essential determinants for crystalline chitin hydrolysis. Three of them, two in the N-terminal domain and one in the catalytic domain, play vital roles in the chitin binding. Phe-232 appeared to be important for guiding the chitin chain into the catalytic cleft. Based on these observations, a model for processive hydrolysis of crystalline chitin by chitinase A is proposed.