Roles of the Exposed Aromatic Residues in Crystalline Chitin Hydrolysis by Chitinase A from Serratia marcescens 2170

doi:10.1074/jbc.M103610200

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Roles of the Exposed Aromatic Residues in Crystalline Chitin Hydrolysis by Chitinase A from Serratia marcescens 2170^*

Taku Uchiyama, Fuminori Katouno, Naoki Nikaidou, Takamasa Nonaka^§, Junji Sugiyama^¶, and Takeshi Watanabe

From the Department of Applied Biological Chemistry, Faculty of Agriculture, Niigata University, 8050 Ikarashi-2, Niigata 950-2181, Japan, the ^§ Department of BioEngineering, Nagaoka University of Technology, Nagaoka, Niigata 940-2188, Japan, and ^¶ Wood Research Institute, Kyoto University, Uji, Kyoto, 611-0011, Japan

Received for publication, April 23, 2001, and in revised form, August 2, 2001

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Four exposed aromatic residues, two in the N-terminal domain (Trp-69 and Trp-33) and two in the catalytic domain (Trp-245and Phe-232) of Serratia marcescens chitinase A, are linearlyaligned with the deep catalytic cleft. To investigate the importanceof these residues in the binding activity and hydrolyzing activityagainst insoluble chitin, site-directed mutagenesis to alaninewas carried out. The substitution of Trp-69, Trp-33, or Trp-245significantly reduced the binding activity to both highly crystalline $beta$ -chitin and colloidal chitin. The substitution of Phe-232, whichis located closest to the catalytic cleft, did not affect thebinding activity. On the other hand, the hydrolyzing activityagainst $beta$ -chitin microfibrils was significantly reduced by thesubstitution of any one of the four aromatic residues includingPhe-232. None of the mutations reduced the hydrolyzing activityagainst soluble substrates. These results clearly demonstratethat the four exposed aromatic residues are essential determinantsfor crystalline chitin hydrolysis. Three of them, two in the N-terminaldomain and one in the catalytic domain, play vital roles in thechitin binding. Phe-232 appeared to be important for guiding thechitin chain into the catalytic cleft. Based on these observations,a model for processive hydrolysis of crystalline chitin by chitinaseA isproposed.

INTRODUCTION

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The chitinases sequenced so far are classified into two different families, families 18 and 19, in the classification systemof glycosyl hydrolases based on the amino acid sequence similarityof their catalytic domains (1-3). The catalytic domains of family18 chitinases have ( $beta$ / $alpha$ )₈ barrel folds (4-8), whereas those offamily 19 chitinases have a high $alpha$ -helical content and share astructural similarity with chitosanase and lysozyme (9, 10).

Chitinolytic bacteria generally produce multiple chitinases encoded by different genes. Many chitinolytic bacteria produceonly family 18 chitinases, whereas some other bacteria such asStreptomyces species produce family 19 chitinases in additionto family 18 chitinases (11). Bacterial family 18 chitinasesare further classified into three subfamilies, subfamilies A,B, and C (12). Chitinases in subfamily A have an insertion domainbetween the seventh and eighth $beta$ -strands of the ( $beta$ / $alpha$ )₈ barrelbasic structure, whereas chitinases in subfamilies B and C donot have such an insertion domain. The three-dimensional (3D)¹ structure of the three-bacterial family 18 chitinases, all belongingto subfamily A, has been determined including those of chitinaseA (ChiA) and chitinase B from Serratia marcescens QMB1466 andchitinase A1 (ChiA1) from Bacillus circulans WL-12 (5, 6,8). Serratia ChiA comprises three domains: an N-terminal domain,a catalytic ( $beta$ / $alpha$ )₈ barrel domain, and a small ( $alpha$ + $beta$ ) domain,which is inserted in the ( $beta$ / $alpha$ )₈ barrel domain. Serratia ChiB comprisesa catalytic ( $beta$ / $alpha$ )₈ barrel domain and a C-terminal chitin-bindingdomain (ChBD). B. circulans ChiA1 comprises the catalytic domain(CatD), two fibronectin type III-like domain, and the C-terminalChBD. The 3D structures of the entire molecules of the formertwo chitinases were determined by x-ray crystallography. On theother hand, the 3D structures of the domains constituting B. circulansChiA1 were determined separately. The structures of CatD weredetermined by x-ray crystallography, and those of ChBD and fibronectintype III-like domain were determined by NMR (8, 13).²

The 3D structure of CatD_ChiA1 is basically very similar to that of Serratia ChiA. Two small insertion domains, $beta$ -domain 1and $beta$ -domain 2, located on top of the ( $beta$ / $alpha$ )₈ barrel provide adeep cleft for substrate binding (8). The crystal structureof inactivated CatD_ChiA1 complexed with (GlcNAc)₇ suggested thatthe cleavage of the chitin chain occurs at the second linkagefrom the reducing end. Seven subsites numbered from $-$ 5 to +2 inthe deep substrate-binding cleft were deduced. The oligomer chainbound to the cleft was bent and twisted at the third sugar ringat subsite $-$ 1. Four tryptophans, Trp-285, Trp-164, Trp-433, andTrp-53, in the substrate-binding cleft and one tyrosine, Tyr-56,at the edge of the substrate-binding cleft were identified asthe residues interacting with the GlcNAc units of the bound oligomerthrough stacking interactions. In addition, two exposed Trp residues,Trp-122 and Trp-134, were found outside of the catalytic cleftto be aligned on the extension of the oligomer chain bound tothe cleft. These two aromatic residues have been shown to be essentialfor crystalline chitin hydrolysis and have been proposed to playan important role in guiding a chitin chain into the catalyticcleft during crystalline chitin hydrolysis (14).

The two exposed aromatic residues and the four aromatic residues in the catalytic cleft of CatD_ChiA1 are all conserved inSerratia ChiA. In this study, the roles in chitin binding activityand hydrolyzing activity of the two exposed aromatic residuesin the catalytic domain and the two additional aromatic residuesfound on the surface of the N-terminal domain of Serratia ChiAwerestudied.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Bacterial Strains and Plasmids-- Escherichia coli XL1-Blue (Stratagene, La Jolla, CA) was the host strain used throughout the construction of plasmids carryingthe chiA genes with various mutations. E. coli DH5 $alpha$ was used asthe host strain for the production of the wild-type and mutantchitinase proteins. Plasmid pNCA112 carrying the wild-type chiAgene from S. marcescens 2170 was described previously (15).

Site-directed Mutagenesis-- Site-directed mutagenesis was carried out by polymerase chain reaction using a QuickChange site-directed mutagenesis kit (Stratagene)and pNCA112 as a template. The primers used for site-directedmutagenesis were 5'-CCGACCATCGCCGCGGGCAACACC-3' for Trp-33 $right-arrow$ Alamutation (W33A), 5'-CCTGGAATTTAGCGAATGGCGACAC-3' for Trp-69 $right-arrow$ Ala mutation (W69A), 5'-GATCCACGATCCGGCCGCCGCGCTGC-3' for Phe-232 $right-arrow$ Ala mutation (F232A), and 5'-GGGCGTGACCGCCGCGGATGACCCC-3' forTrp-245 $right-arrow$ Ala mutation (W245A). The mutant clones were selectedafter sequencing the entire open reading frame to ensure thatthe desired mutation was the only mutation in each mutated gene.Sequencing was done by using an automated laser fluorescence DNAsequencer (Model 4000L; LI-COR) and the ThermoSequenase fluorescent-labeledprimer cycle sequencing kit with 7-deaza-dGTP (Amersham PharmaciaBiotech) for sequencingreaction.

To create the gene encoding ChiA with a double mutation (W33A/W69A), the second mutation was introduced into the gene encodingW33A by using the primers for W69A mutation. The third mutationof triple mutant (W33A/W69A/W245A) was introduced into the geneencoding W33A/W69A by using the primers for W245Amutation.

Production and Purification of ChiA and Its Mutants-- ChiA and its mutants were produced in E. coli DH5 $alpha$ cells carrying the plasmid pNCA112 or its derivatives and purified fromculture supernatants. After collecting chitinase proteins by ammoniumsulfate precipitation (80% saturation), wild-type ChiA, W33A,W69A, W245A, and F232A were purified by chitin affinity columnchromatography (16) with some modifications as follows. Crudechitinase was applied to a chitin affinity column previously equilibratedwith 20 mM phosphate buffer. pH 6.0. The column was washed with3-column volumes of 20 mM phosphate buffer, pH 6.0, containing0.5 M NaCl and 1-column volume of 20 mM sodium acetate buffer,pH 5.0, containing 0.5 M NaCl. The chitinase protein then waseluted with 20 mM sodium acetate buffer, pH 4.0.

Double and triple mutants, W33A/W69A and W33A/W69A/W245A, were purified by hydroxyapatite column chromatography as follows.Crude chitinase obtained by ammonium sulfate precipitation wassubjected to hydroxypatite column (1.5 × 15 cm) previously washedwith 1 mM phosphate buffer, pH 6.0. After washing with an 8-columnvolume of the same buffer, chitinase was eluted with 100 mM sodiumphosphate buffer, pH 6.0. Peak fractions containing purified chitinasewere collected andlyophilized.

SDS-polyacrylamide gel electrophoresis of the purified chitinases in 12.5% slab gels was conducted by the method of Laemmli(17).

Enzyme and Protein Assays-- Reducing sugar generated by the degradation of various chitinous substrates was measured by a modification of Schales' procedureusing N-acetylglucosamine as a standard (18). The reaction mixture(total 750 µl) contained purified chitinase and 1 mg (dry weight)of each substrate in 0.1 M sodium phosphate buffer, pH 6.0.

The protein concentration was estimated from the absorbance at 280 nm using the molar extinction coefficients calculated fromthe amino acid compositions of each protein (19). For the chitinbinding assay, the protein concentration was estimated by spectrofluorometry(Hitachi F-3010 Spectrofluorometer) at an excitation wavelengthof 280 nm and an emission wavelength of 342 nm. A separate standardcurve was prepared for eachprotein.

Chitin Binding Assay-- Binding assay mixtures in 1-ml glass microtubes containing various concentrations of protein and 0.5 mg of binding assay substratein 500 µl of 20 mM sodium phosphate buffer, pH 6.0, were incubatedon ice with occasional mixing. Each mixture was centrifuged at4 °C for 20 min at 9500 × g to separate the supernatant from substratewith bound protein. The supernatant containing free protein wascollected, and the protein concentration was determined. The amountof bound protein was calculated from the difference between theinitial protein concentration and the free protein concentrationafterbinding.

Electron Microscopy-- Enzyme-treated $beta$ -chitin microfibrils were deposited on carbon-coated grids and were allowed to dry. All of the electron micrographswere taken with a JEOL 2000EXII electron microscope operated at100 kV and recorded on Mitsubishi electron microscope film. Diffractioncontrast imaging in the bright field mode was used to visualizethe sample without further contrast enhancement. The images weretaken at magnifications of × 1000 to × 6000 under low dose exposurewith the use of a minimum dose system(JEOL).

Chemicals-- Chitin EX (powdered prawn shell chitin) and carboxymethyl chitin were purchased from Funakoshi Chemical Co. (Tokyo, Japan).Soluble chitin and (GlcNAc)₅ were obtained from Yaizu Suisan ChemicalCo., Ltd. (Shizuoka, Japan). The degree of deacetylation was 38.8%,and approximate molecular weight of the soluble chitin was from200,000 to 300,000. Colloidal chitin and glycol chitin were preparedfrom powdered crab shell chitin purchased from Funakoshi ChemicalCo. by the methods described by Jeuniaux (20) and Yamada andImoto (21), respectively. Reduction of (GlcNAc)₅ was carriedout as described by Yanase et al. (22). Microcrystalline $beta$ -chitinfrom vestimentiferan (Lamellibrachia satsuma) was prepared asdescribed previously (23).

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Four Aromatic Residues Linearly Aligned on the Surface of ChiA Molecule-- ChiA from S. marcescens QMB1466 comprises three domains: an N-terminal domain with an immunoglobulin-like fold, a catalytic( $beta$ / $alpha$ )₈ barrel domain, and a small ( $alpha$ + $beta$ ) fold domain, which isinserted in the catalytic ( $beta$ / $alpha$ )₈ barrel domain (5). The roleof the N-terminal domain has not yet been clarified, althoughinvolvement in interactions with the chitin chain has been suggested(24). However, the following two observations strongly suggestedthat the N-terminal domain of Serratia ChiA participates in thechitin binding. First, ChiA from S. marcescens 2170, which has99.3% amino acid identity with ChiA from QMB1466, has significantchitin binding activity (15). Second, the catalytic domainsof B. circulans ChiA1 and Serratia ChiA are structurally verysimilar as shown in Fig. 1, and CatD_ChiA1 does not have significantchitin binding activity (25). The chitin binding activity ofB. circulans ChiA1 depends on the C-terminal ChBD (26).

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Fig. 1. Positions of aromatic residues in Serratia ChiA and CatD_ChiA1 from B. circulans. A, $alpha$ -carbon chain (green) of Serratia ChiA with the side chains of aromatic residues (red). Four linearly aligned aromatic residues outside of the catalytic cleft are labeled with orange letters. B, $alpha$ -carbon chain (purple) of CatD_ChiA1 inactivated by E204Q mutation with the side chains of aromatic residues (pink). Bound oligomer chain is shown in yellow. C, superimposed A and B.

To examine chitin binding activity of the N-terminal domain itself, the N-terminal domain of ChiA from S. marcescens 2170was produced by using an E. coli expression system. However, isolatedN-terminal domain did not show significant chitin binding activity.³ Therefore, we examined the 3D structure of ChiA reported by Perrakiset al. (5, 24) and found that Trp-33 and Trp-69 in the N-terminaldomain and Trp-245 in the catalytic domain are linearly alignedon the surface of the ChiA molecule (Fig. 1A). These three aromaticresidues are assumed to be involved in the chitin binding of ChiAbased on the analogy to the cellulose-binding domains of severalcellulases. It is well known that three aromatic residues linearlyaligned on the surface of cellulose-binding domains play majorroles in cellulose binding (27-30). In addition, when the 3D structureof CatD_ChiA1 complexed with (GlcNAc)₇ was superimposed on thestructure of Serratia ChiA, two exposed aromatic residues, Phe-232and Trp-245, corresponding to Trp-122 and Trp-134 of B. circulansCatD_ChiA1 (Fig. 1B) that are exclusively required for crystallinechitin hydrolysis, were identified (Fig. 1C). In summary, a totalof four linearly aligned aromatic amino acids, two in the N-terminaldomain and two in the catalytic domain of Serratia ChiA, thuswere identified. Some of these residues must be identical to theresidues in the N-terminal domain, which were proposed by Perrakiset al. (24) to be in ideal positions to facilitate an interactionwith an extended sugarchain.

From the above observations and the structural implication described by Perrakis et al. (24), it is hypothesized that SerratiaChiA binds chitin mainly through the interaction between GlcNAcresidues in the chitin chain and the exposed aromatic residuesin both the N-terminal and catalytic domains, and that this chitinchain is introduced into the catalytic cleft to be hydrolyzedat the catalytic site located at the bottom of the deep substrate-bindingcleft.

Production and Purification of the Enzymes-- To investigate the possible importance of the Trp-69, Trp-33, Trp-245, and Phe-232 in the binding activity and hydrolyzingactivity against insoluble chitin, site-directed mutagenesis ofthe four aromatic residues to alanine was carried out. The wild-typeand six mutant chitinases, W69A, W33A, W245A, F232A, W33A/W69A,and W33A/W69A/W245A, were produced in E. coli cells carrying aplasmid encoding either a wild-type or mutated chiA gene and purifiedfrom the culture supernatants. All mutant chitinases were producedat a level similar to that at which wild-type ChiA was produced.Purification of chitinase proteins was carried out either by chitinaffinity column chromatography or by hydroxyapatite column chromatography.F232A behaved like ChiA did on the chitin column; i.e. the twoproteins were eluted from the column with 20 mM sodium acetatebuffer, pH 4.0, after the column was washed with the same bufferat pH 5.0. On the other hand, W69A, W33A, and W245A appeared tobind more weakly than wild-type ChiA did and were eluted fromthe chitin column at the washing step with 20 mM sodium acetatebuffer, pH 5.0, along with many other contaminating proteins.Therefore, 0.5 M NaCl was included in the buffer to prevent elutionof these mutant chitinases at the washing step, and purificationwas finally achieved by elution with 20 mM sodium acetate buffer,pH 4.0. Double and triple mutants of ChiA, W33A/W69A and W33A/W69A/W245A,did not bind chitin column even in the presence of 0.5 M NaCland, therefore, were purified by hydroxyapatite columnchromatography.

The purified chitinases were essentially homogeneous as judged by SDS-polyacrylamide gel electrophoresis analysis (Fig. 2).Approximately 14 mg of purified chitinase was obtained from a1-liter culture of E. coli cells carrying each chitinase gene.

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Fig. 2. SDS-polyacrylamide gel electrophoresis analysis of the wild-type and mutant chitinases. Chitinase proteins produced in E. coli DH5 $alpha$ cells were purified from the culture supernatant. Protein staining of the polyacrylamide gel with Coomassie Brilliant Blue R-250 is shown. Lanes 1 and 10, molecular mass standards; lane 2, partially purified ChiA obtained by ammonium sulfate precipitation; lanes 3-9, purified chitinases (20 µg each). Lane 3, ChiA; lane 4, W33A; lane 5, W69A; lane 6, F232A; lane 7, W245A; lane 8, W33A/W69A; lane 9, W33A/W69A/W245A.

Effect of the Mutations on the Chitin Binding Activity-- The chitin binding activities of wild-type and mutant ChiAs were studied using colloidal chitin and highly crystalline $beta$ -chitinmicrofibrils isolated from L. satsuma. The binding assay was carriedout at pH 6.0 since the optimum pH for the hydrolysis reactionof ChiA is 6.0 (31). To minimize hydrolysis of the binding substrates,the binding assay mixture was maintained below 4 °C. The bindingreaction times were 3 h for $beta$ -chitin microfibrils and 1 h forcolloidal chitin since preliminary experiments indicated thatthe binding to $beta$ -chitin microfibrils requires approximately 3h, and that binding to colloidal chitin requires less than 1 hto reach equilibrium (data notshown).

Fig. 3 shows binding isotherms of the wild-type and mutant ChiAs to $beta$ -chitin microfibrils and colloidal chitin. Wild-typeChiA exhibited significant binding activity to both colloidalchitin and $beta$ -chitin microfibrils. Substitution of any of the threearomatic residues, Trp-69, Trp-33, or Trp-245 with alanine, reducedthe binding activity to $beta$ -chitin microfibrils drastically (Fig.3A). On the other hand, mutation of Phe-232 did not affect thebinding activity significantly. The mutations of Trp-69, Trp-33,and Trp-245 also reduced the binding activity to colloidal chitinbut less significantly than the cases of $beta$ -chitin microfibrils.The effect of mutation of Trp-69, which is located in the N-terminaldomain and is most distal to the catalytic cleft among the fouraromatic residues, was more severe than the effects of the othertwo mutations, suggesting special importance of this residuesin the binding activity (Fig. 3B). Double and triple mutationsof the three residues deprived binding activity to colloidal chitinalmost completely. Mutation of Phe-232 did not affect the bindingactivity to colloidal chitin and to $beta$ -chitin microfibrils.

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Fig. 3. Adsorption isotherms of wild-type and mutant ChiAs to $beta$ -chitin microfibrils (A) and colloidal chitin (B). $black-diamond$ , wild-type ChiA;

, W33A; $black-triangle$ , W69A; $open circle$ , F232A;

, W245A; $black-square$ , W33A/W69A; $triangle$ , W33A/W69A/W245A. The enzyme concentration used was 0.07-1.7 µM.

These results clearly demonstrated that Trp-69 and Trp-33 in the N-terminal domain and Trp-245 in the catalytic domain areessential for the chitin binding activity of ChiA. Therefore,the chitin binding activity of this enzyme depends not only onthe N-terminal domain but also on the catalytic domain. The N-terminaldomain is important for the chitin binding activity of this enzyme,but the N-terminal domain alone is not sufficient to confer fullbindingactivity.

Effect of the Mutations on the Hydrolyzing Activity-- The effect of the mutations on the hydrolyzing activity against colloidal chitin and $beta$ -chitin microfibrils was examined. Thehydrolysis of $beta$ -chitin microfibrils by 50 pmol of wild-type ormutant ChiA was monitored by measuring the amount of reducingsugar released from the substrates. As shown in Fig. 4A, the hydrolyzingactivity against $beta$ -chitin microfibrils was significantly reducedby all four single mutations including F232A, which did not affectthe binding activity, although some hydrolysis was still observed.The effect of F232A was even more severe than that caused by W33A.This observation suggests that the defect in hydrolyzing activityof F232A is not attributed to a defect in chitin binding activity,whereas the defect in the hydrolyzing activity of W69A, W33A,and W245A may be due to, at least in part, a defect in chitinbinding activity. Double and triple mutations of the three residuescompletely impaired hydrolyzing activity against $beta$ -chitin microfibrils.

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Fig. 4. Hydrolysis of $beta$ -chitin microfibrils (A) and colloidal chitin (B) by wild-type and mutant ChiAs. $black-diamond$ , wild-type ChiA;

, W33A; $black-triangle$ , W69A; $open circle$ , F232A;

, W245A; $black-square$ , W33A/W69A; $triangle$ , W33A/W69A/W245A. Reaction mixtures contained 1 mg (dry weight) of substrate and either 50 pmol (A) or 10 pmol (B) of each chitinase. Reactions were performed at 37 °C, and the amount of reducing sugar generated was monitored.

Fig. 4B shows the time course of hydrolysis of colloidal chitin by 10 pmol of ChiA and its mutants. Because ChiA hydrolyzescolloidal chitin much faster than $beta$ -chitin microfibrils, smalleramounts of the enzymes were used in these experiments. The effectsof four single mutations were much less than those observed inthe hydrolysis of $beta$ -chitin microfibrils. Interestingly, W69A,which caused the most severe defect among four single mutantsin the binding activity to colloidal chitin, did not reduce thehydrolyzing activity at all. W33A and W245A, which also reducedthe binding activity to colloidal chitin, only slightly reducedthe hydrolyzing activity. F232A, which had the same level of bindingactivity as wild-type ChiA, exhibited the lowest hydrolyzing activityamong the four mutant chitinases. On the other hand, double andtriple mutations again reduced hydrolyzing activity drastically,although a slight hydrolysis was stillobserved.

The effects of mutations on the hydrolyzing activity against various soluble substrates were also examined. The substratestested include reduced (GlcNAc)₅, soluble chitin, carboxymethylchitin, and glycol chitin. As shown in Table I, none of the mutationsincluding double and triple mutations reduced the activities againstall soluble substrates. The hydrolyzing activities of the sixmutant chitinases were essentially the same as that of wild-typeChiA against reduced (GlcNAc)₅, soluble chitin and carboxymethylchitin. Interestingly, F232A exhibited increased activity againstthe glycol chitin. The specific hydrolyzing activity of F232Aagainst glycol chitin was 2.5-fold higher than that of wild-typeChiA. Both glycol chitin and carboxymethyl chitin are derivativesof chitin chemically modified at the C6 position of GlcNAc residues.In this sense, the two soluble substrates are structurally similar;however, the hydrolyzing activity against carboxymethyl chitinwas not affected by the F232A mutation. The reason for this differenceis unclear.

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Table I
Specific hydrolyzing activities of mutant and wild-type ChiA measured on soluble substrates

Unidirectional Processive Action of ChiA on $beta$ -chitin Microfibrils-- The $beta$ -chitin microfibrils isolated from the protective tubes of L. satsuma are highly crystalline $beta$ -chitin as demonstratedby electron microdiffraction (23). The microfibrils were treatedwith intact ChiA and its mutants, and the morphological changewas examined by electron microscopy. As shown in Fig. 5A, theinitial microfibrils displayed a uniform and well defined microfibrillarform. On the other hand, after treatment with ChiA, the microfibrilswere primarily shortened, and the tips of the microfibrils weregradually narrowed and sharpened at one end very similar to needles(Fig. 5B). The morphology of the microfibriles treated with ChiAare compatible with the notion that the hydrolysis of $beta$ -chitinmicrofibrils by ChiA occurs unidirectionally and processively. $beta$ -chitin microfibrils treated with W33A and F232A are shown inFig. 5C and D. W33A and F232A also formed needle tips at one endof the microfibrils clearly demonstrating that the two mutantchitinases are able to hydrolyze crystalline microfibril in partby a manner similar to intact ChiA. The needle tips formed byF232A appeared to be sharpest among three chitinases. This observationsseems to be consistent with the idea that this mutant chitinasehas a significant defect in introducing chitin chain into thecatalytic cleft, and thus the starting of processive hydrolysisof chitin chains occurs less efficiently than do the other chitinases.

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Fig. 5. Bright-field diffraction contrast micrographs of L. satsuma $beta$ -chitin microfibrils. A, no enzyme treatment (control). B, after treatment with ChiA. C, after treatment with W33A. D, after treatment with F232A.

The shape of the needle tips generated by ChiA is very similar to those observed after treatment with ChiA1 from B. circulansWL-12 (23, 26). Hydrolysis of the $beta$ -chitin microfibrils byB. circulans ChiA1 was experimentally demonstrated very recentlyto occur from the reducing end side of the microfibrils as suggestedfrom the structural study of CatD_ChiA1.⁴ Because the catalytic domains of the two chitinases are verysimilar as mentioned already, the pointed tips formed by the ChiAmust be at the reducing end side of themicrofibrils.

DISCUSSION

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Studies on the chitin binding activities of mutant ChiAs that have substitutions of the four exposed aromatic residues demonstratedthat the three of them, Trp-69, Trp-33, and Trp-245, are essentialfor the binding activity of ChiA to insoluble chitin substrates.On the other hand, F232A, which is closest to the catalytic cleftamong the four mutated aromatic residues, did not affect the bindingactivity. Because the substitution of any one of the three residuesreduced the chitin binding activity, all three residues are indispensableto express full binding activity and, therefore, act cooperativelyin the chitin binding of this enzyme. Trp-69 and Trp-33 are locatedin the N-terminal domain, whereas on the other hand Trp-245 islocated in the catalytic domain. This may be the first exampleof an identification of a site in the catalytic domain of a glycosylhydrolase required for specific binding to an insoluble substrate.As mentioned already, the N-terminal domain of ChiA has been consideredto be the chitin-binding domain (5). However, the results obtainedin this study clearly demonstrated that this domain is not sufficientfor the expression of the full binding activity of this enzymeand does not have significant binding activity by itself alone,although it is indispensable for the binding activity. In thissense, the N-terminal domain could be referred to as an incompletechitin-binding domain. This is very different from the case ofChBD of B. circulans ChiA1, which was the first ChBD characterizedin form isolated from the other domains. Trp-134 in CatD of B.circulans ChiA1, corresponding to Trp-245 of Serratia ChiA, enhancedthe binding activity of ChiA1 (14). However, isolated ChBD exhibitedsignificant chitin binding activity by itself, and this domainplayed a major role in the chitin binding activity of this enzyme(26).

In contrast to the contribution to chitin binding activity, all four aromatic amino acids replaced in this study appearedto be essential for efficient hydrolysis of highly crystalline $beta$ -chitin microfibrils. Substitution of any one of the four aromaticresidues decreased the hydrolyzing activity significantly. Thedefect in crystalline chitin hydrolysis of W69A, W33A, and W245Amay be explained, at least in part, by the defect in the bindingactivity of these mutant chitinases. On the other hand, the reducedhydrolyzing activity of F232A is not related to its binding activitysince F232A retained full binding activity. These results clearlydemonstrated that the Phe-232 exposed on the surface of the catalyticdomain is essential for the hydrolysis of crystalline chitin ina manner not related to chitin binding activity. Koivula et al.(32) reported that Trp-272 of Trichoderma reesei Cel6A is anessential determinant of crystalline cellulose hydrolysis. Mutagenesisof this residue selectively impaired crystalline cellulose hydrolysisbut not hydrolysis of soluble or amorphous substrates. BecauseTrp-272 is located close to the entrance of the enclosed catalytictunnel, the situation of Trp-272 seems to be rather similar tothat of Tyr-170 of ChiA, which is located at the edge of the entranceof the substrate-binding cleft. However, although Phe-232 is locatedoutside of the substrate-binding cleft, the effect of the substitutionof Phe-232 is similar to that caused by the substitution of Trp-272of Cel6A. Koivula et al. (32) suggested that Trp-272 has a specializedrole in crystalline cellulose hydrolysis, possibly in guidingthe glucan chain into the catalytic tunnel of Cel6A. These observationsand the relative location of Phe-232 to the substrate-bindingcleft strongly suggest that Phe-232 plays an important role inguiding and introducing the chitin chain into the catalyticcleft.

We suppose that the other aromatic residues, W69A, W33A, and W245A, are also involved in part in guiding the chitin chaininto the catalytic cleft, although the extent of their participationis different depending on the position of each aromatic residue.This means that Trp-69, Trp-33, and Trp-245 may have dual rolesin crystalline (or insoluble) chitin hydrolysis. Mutations ofany one of these three residues reduced the binding activity tocolloidal chitin, and W69A affected this binding most severely.On the other hand, hydrolyzing activity of W69A was indistinguishablefrom that of wild-type ChiA, whereas W33A and W245A exhibitedslightly lower activity than W69A, and F232A was the lowest amongfour single mutants. Although the difference in the hydrolyzingactivities between W69A and either W33A or W245A is very small,W33A and W245A always gave slightly lower activities than W69Ain several independent experiments. The slightly lower hydrolyzingactivities of W33A and W245A as compared with W69A and wild-typeChiA could be explained by the involvement of these residues inguiding a chitin chain into the catalytic cleft since the bindingactivities of W33A and W245A were significantly higher than thatof W69A. In addition, the possible involvement of three residuesin guiding the chitin chain may be partly responsible for thedrastic reduction in the hydrolyzing activity against both $beta$ -chitinmicrofibrils and colloidal chitin by double and triple mutations.Of course, a complete loss of the binding activity must be anotherreason for the drastic reduction of hydrolyzing activity by thesemutations.

Processive hydrolysis of crystalline chitin was suggested by electron microscopy of the $beta$ -chitin microfibrils treated withChiA and its mutants. Processive hydrolysis by polysaccharide-degradingenzymes has been most extensively studied with Cel6A and Cel7Afrom T. reesei (33, 34). The term "processivity" is used toindicate that an enzyme degrades a polymer chain without dissociatingfrom it between successive catalytic events. Both Cel6A and Cel7Ahave an active site cleft with tunnel morphology. According toa recent hypothesis, a single glucan chain is introduced at thetunnel entrance and threads through the entire tunnel with eventualrelease of the product, cellobiose, from the end of the tunnel(32). The mechanisms of crystalline chitin hydrolysis that wereproposed based on the structure of ChiA, especially from the positionsof the aromatic residues, and the results obtained in this study,are consistent with the processive action of this enzyme, althoughChiA does not have a tunnel-shaped catalytic cleft (see Fig. 6).Binding of ChiA to the crystalline chitin surface is achievedthrough the interaction among three aromatic residues (Trp-69,Trp-33, and Trp-245) and the GlcNAc residues in a single chitinchain on the crystalline chitin surface. The chitin chain interactingwith the three aromatic residues is introduced into the catalyticcleft from the reducing end side of the chain through the interactionwith Phe-232. In the catalytic cleft, the introduced chitin chainslides through the cleft to the catalytic site, and the secondlinkages from the reducing end are progressively cleaved, releasing(GlcNAc)₂ units continuously. Tyr-170 at subsite $-$ 5, Trp-167 atsubsite $-$ 3, Trp-539 at subsite $-$ 1, Trp-275 at subsite +1, andPhe-396 at subsite +2 in the catalytic cleft play major rolesin holding and also in sliding the chitin chain. The Trp residuesaround the catalytic site, such as Trp-167, Trp-539, Trp-275,and Phe-396, may be mainly responsible for bending and twistingthe chitin chain at the subsite $-$ 1. The interaction with thesemultiple aromatic residues, which are located not only withinthe catalytic cleft but also on the surface of the ChiA molecule,must result in a tight holding of a chitin chain by the enzymeduring a number of hydrolyzing reactions, which occurs at thesecond linkage from the reducing end, thus resulting in the processiveaction of this enzyme. As a result of the processive hydrolysisof a single chitin chain in the crystalline $beta$ -chitin microfibrils,the ChiA molecule proceeds on the crystalline chitin surface towardthe non-reducing end side of the microfibrils with the N-terminaldomain at the head, releasing (GlcNAc)₂ units from the reducingend of the chitin chain.

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Fig. 6. Model for crystalline $beta$ -chitin hydrolysis by ChiA.

	ACKNOWLEDGEMENTS

We acknowledge Kazuo Sakai (Yaizu Suisan Chemical Co., Ltd.) for supplying soluble chitin. We thank Jun Hashimoto (Japan MarineScience and Technology Center, Yokosuka, Japan) for the kind giftof tubes from the vestimentiferan tubeworm, Lamellibrachia satsuma.

	FOOTNOTES

^* This work was supported in part by Grant-in-aid for Scientific Research 12660070 from the Ministry of Education, Science,and Culture of Japan.The costs of publication of this articlewere defrayed in part by the payment of page charges. The articlemust therefore be hereby marked "advertisement" in accordancewith 18 U.S.C. Section 1734 solely to indicate thisfact.

To whom correspondence should be addressed. Tel.: 81-25-262-6647; Fax: 81-25-262-6854; E-mail: wata@agr.niigata-u.ac.jp.

Published, JBC Papers in Press, August 24, 2001, DOI 10.1074/jbc.M103610200

² M. Shirakawa, unpublisheddata.

³ T. Uchiyama, M. Yamagishi, and T. Watanabe, unpublishedresults.

⁴ T. Imai, T. Watanabe, T. Yui, and J. Sugiyama, submitted forpublication.

ABBREVIATIONS

The abbreviations used are: 3D, three-dimensional; ChiA, S. marcescens chitinase A; ChiA1, B circulans WL-12 chitinase A1; ChBD, chitin-binding domain; CatD, catalytic domain; CatD_ChiA1, catalytic domain of B circulans ChiA1; Cel6A, cellobiohydrolase II; Cel7A, cellobiohydrolase I.

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