Expression and Characterization of the Chitin-Binding Domain of Chitinase A1 from Bacillus circulans WL-12

doi:10.1128/JB.182.11.3045-3054.2000

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Journal of Bacteriology, June 2000, p. 3045-3054, Vol. 182, No. 11
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Expression and Characterization of the Chitin-Binding Domain of Chitinase A1 from Bacillus circulans WL-12

Masayuki Hashimoto,¹ Takahisa Ikegami,² Shizuka Seino,¹ Nobuhumi Ohuchi,³ Harumi Fukada,⁴ Junji Sugiyama,⁵ Masahiro Shirakawa,² and Takeshi Watanabe¹^,³^,^*

Department of Biosystem Science, Graduate School of Science and Technology,¹ and Department of Applied Biological Chemistry, Faculty of Agriculture,³ Niigata University, 8050 Ikarashi-2, Niigata 950-2181, Graduate School of Biological Sciences, Nara Institute of Science and Technology, 8916-5 Takayama, Ikoma, Nara 630-0101,² Laboratory of Biophysical Chemistry, College of Agriculture, Osaka Prefecture University, Sakai, Osaka 599-8531,⁴ and Wood Research Institute, Kyoto University, Uji, Kyoto, 611-0011,⁵ Japan

Received 12 July 1999/Accepted 5 March 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

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 studythe biochemical properties and structure of the ChBD, ChBD_ChiA1was produced in Escherichia coli using a pET expression systemand purified by chitin affinity column chromatography. PurifiedChBD_ChiA1 specifically bound to various forms of insoluble chitinbut not to other polysaccharides, including chitosan, cellulose,and starch. Interaction of soluble chitinous substrates with ChBD_ChiA1was not detected by means of nuclear magnetic resonance and isothermaltitration calorimetry. In addition, the presence of soluble substratesdid not interfere with the binding of ChBD_ChiA1 to regeneratedchitin. These observations suggest that ChBD_ChiA1 recognizes astructure which is present in insoluble or crystalline chitinbut not in chito-oligosaccharides or in soluble derivatives ofchitin. ChBD_ChiA1 exhibited binding activity over a wide rangeof pHs, and the binding activity was enhanced at pHs near itspI and by the presence of NaCl, suggesting that the binding ofChBD_ChiA1 is mediated mainly by hydrophobic interactions. Hydrolysisof $beta$ -chitin microcrystals by intact chitinase A1 and by a deletionderivative lacking the ChBD suggested that the ChBD is not absolutelyrequired for hydrolysis of $beta$ -chitin microcrystals but greatlyenhances the efficiency ofdegradation.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Chitin, an insoluble linear $beta$ -1,4-linked homopolymer of N-acetylglucosamine, is a common constituent of fungal cell walls,exoskeletons of insects, and shells of crustaceans and is oneof the most abundant polysaccharides in nature. Chitinase degradeschitin by hydrolyzing $beta$ -1,4-glycosidic-linkages, and the activityhas been found in a variety of organisms. Bacteria, which do notcontain chitin as a constituent, also produce chitinase, mainlyfor utilization of chitin as a carbon and energy source. Fromthe ecological point of view, bacterial chitinases play an importantrole in recycling chitin innature.

Bacillus circulans WL-12 was isolated as a yeast and fungal cell wall-lytic bacterium from soil (31). When the bacteriumwas grown in the presence of chitin, more than 10 chitinases weredetected in the culture supernatant (2, 39). These chitinasesare derived from three genes, chiA, chiC, and chiD (2), andthe primary products of these genes are designated chitinasesA1, C1, and D1, respectively. All of the three chitinases havemultidomain structures, and proteolytic modifications of thesechitinases give rise to the large variety of chitinases observedin the culture supernatant. Chitinase A1 binds to insoluble chitinand exhibits the highest degradative activity toward insolublechitin among the chitinases of this bacterium. The mature formof this enzyme consists of a catalytic domain, two fibronectintype III-like domains (FnIII domains), and a C-terminal domain,in order from its N terminus to its C terminus (38). As describedin a previous report, the roles of these domains were studiedby using deletion derivatives lacking one or both of the FnIIIdomains and/or the C-terminal domain (40). The isolated catalyticdomain hydrolyzed soluble substrates with an activity level comparableto that of intact chitinase A1. However, loss of the C-terminaldomain deprived the enzyme of the ability to bind to insolublechitin and significantly reduced the ability to hydrolyze colloidalchitin. Therefore, it appeared that the C-terminal domain is thechitin-binding domain (ChBD) and is important for efficient degradationof insoluble chitin. Chitinase D1 of this bacterium also possessesa ChBD that is very similar to that of chitinase A1, but at itsN-terminus, and has binding activity to insoluble chitin (2).On the other hand, chitinase C1 has a C-terminal domain with unknownfunction and lacks significant chitin-binding activity (1).

It has been reported that many insoluble-polysaccharide hydrolases contain discrete substrate-binding domains. Among them,cellulose-binding domains (CBDs) of some cellulases have beenstudied most extensively. The three-dimensional structures ofCBDs of Trichoderma reesei endoglucanase I (CBD_EGI), T. reeseicellobiohydrolase I (CBD_CBHI), Cellulomonas fimi $beta$ -1,4-glucanaseCex (CBD_Cex), Erwinia chrysanthemi endoglucanase Z (CBD_EGZ), C.fimi $beta$ -1,4-glucanase CenC (CBD_N1), and Clostridium thermocellumcellulosomal scaffolding subunit (Cip-CBD) have been determined(4, 14, 15, 19, 35, 42). From structural analyses,it has been suggested that CBDs which can bind to crystallinecellulose have a hydrophobic face constructed by linearly exposedaromatic amino acid residues, and these residues bind to sugarrings of the crystalline cellulose surface through hydrophobicinteractions (3, 6, 17). Although the role of CBDs inthe activity of cellulases is not completely clear, two hypotheseshave been proposed. One of them is that CBDs simply increase thelocal enzyme concentration on insoluble substrates (10, 33).The other is that disruption of the structure of the cellulosefiber occurs without hydrolysis for smooth degradation (8).

On the other hand, although the presence of ChBDs and putative ChBDs has been suggested for many chitinases, detailed analyseson the structures and biochemical properties of ChBDs have notyet been reported. In order to understand the mechanisms underlyingdegradation of insoluble chitin by chitinases, biochemical andstructural studies of ChBDs are indispensable. In the presentstudy, we constructed an expression system for ChBD of chitinaseA1 (ChBD_ChiA1), purified the ChBD_ChiA1, and studied its bindingproperties without interference from the catalytic domain andFnIIIdomains.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains, plasmids, and culture medium. Escherichia coli JM109 was the host strain used throughout the construction of various recombinant plasmids. Chitinase A1and A1 $Delta$ ChBD, a deletion derivative of chitinase A1 lacking theChBD, were produced in E. coli HB101 cells carrying recombinantplasmids pHT012 and pHTX013, respectively (37, 40). ChBD_ChiA1was produced in E. coli BL21(DE3) cells carrying pChBD, whichwas constructed by using expression vector pET3a (Novagen, Madison,Wis.).

E. coli HB101 and BL21(DE3) carrying the recombinant plasmid were generally grown in Luria-Bertani broth (LB) medium containing100 µg of ampicillin per ml. Bacto Tryptone (Difco, Detroit, Mich.)was used to prepare LB medium for cultivation of E. coli BL21(DE3)cells according to the instructions for the pET expression system.To prepare a uniformly ¹⁵N-labeled ChBD_ChiA1 for nuclear magnetic resonance (NMR) studies,E. coli BL21(DE3) carrying pChBD was grown in modified M9 minimalmedium (7.0 g of Na₂HPO₄ per liter, 3.0 g of KH₂PO₄ per liter,0.5 g of NaCl per liter, 20 mg of thymine per liter, 20 mg ofadenosine per liter, 20 mg of guanosine per liter, 20 mg of cytidineper liter, 20 mg of biotin per liter, 20 mg of thiamine per liter,1.0 mM MgSO₄, 3.3 µM FeCl₃, 50 µM MnCl₂, and 100 mM CaCl₂) containing100 µg of ampicillin per ml, 0.1% glycerol, 4.0 g of D-glucoseper liter, and 0.5 g of ¹⁵NH₄Cl per liter as the sole nitrogensource.

Construction of pChBD. The DNA region encoding the ChBD of chitinase A1 was amplified by PCR with synthetic oligonucleotides 5'-CCGGATCCGCTTGGCAGGTCAAC-3'and 5'-CCGGATCCCTATTGAAGCTGCCACAA-3' as the primers and pHT012carrying the chiA gene as the template. To determine the nucleotidesequence, the amplified fragment was blunt ended by using a DNAblunting kit (Takara Biochemical, Kyoto, Japan), inserted intothe SmaI site of pUC119, and sequenced using an automated laserfluorescence DNA sequencer (model 4000L; LI-COR). The insertedfragment was cut out using BamHI and ligated with BamHI-cut pET3ato construct the ChBD_ChiA1 expression plasmid,pChBD.

Production and purification of chitinase A1, A1 $Delta$ ChBD, and ChBD_ChiA1. Chitinase A1 was produced by E. coli HB101 cells carrying recombinant plasmid pHT012 and purified by chitin affinity columnchromatography as described previously (30, 39). A1 $Delta$ ChBD wasproduced by E. coli HB101 cells carrying recombinant plasmid pHTX013and purified by high-performance liquid chromatography as describedpreviously (40).

For production of ChBD_ChiA1, E. coli BL21(DE3) cells carrying pChBD were grown in 1 liter of LB medium containing 100 µg ofampicillin per ml at 30°C. When the optical density at 600 nm(OD₆₀₀) reached 0.6 (2.1 × 10⁸ cells/ml), 0.5 mM (final concentration) isopropyl- $beta$ -D-thiogalactopyranoside(IPTG) was added to the culture to induce expression of ChBD_ChiA1,and cultivation was continued for a further 12 h. Then cells werecollected by centrifugation, washed once with sonication buffer[10 mM (p-amidinophenyl)methanesulfonyl fluoride and 1 mM EDTAin 100 mM Tris-HCl (pH 8.0)], resuspended in the same buffer,and disrupted by sonication with a Tomy ultrasonic disruptor (modelUR-200P). The soluble fraction of disrupted cells was extractedby centrifugation (4°C, 20,000 × g, 15 min) and ultracentrifugation(4°C, 75,000 × g, 2 h). Proteins in the soluble fraction werecollected by ammonium sulfate precipitation (60% saturation),dissolved in a small volume of 5 mM sodium phosphate buffer (pH6.0), dialyzed against the same buffer, and lyophilized. ChBD_ChiA1in the collected proteins was purified by chitin affinity columnchromatography. Chitin affinity column chromatography was carriedout as described previously (30), except that 1 M NaCl was includedin the washing solution (20 mM sodium phosphate buffer, pH 6.0).The fractions containing purified ChBD_ChiA1 eluted with 20 mMacetic acid were collected, dialyzed against 5 mM sodium phosphatebuffer (pH 6.0), andlyophilized.

Production and purification of ChBD_ChiA1 for NMR measurement. E. coli BL21(DE3) carrying pChBD was grown in LB medium containing 100 µg of ampicillin per ml at 30°C. When the OD₆₀₀ reached1.0 (3.5 × 10⁸ cells/ml), 3.0 ml of the culture was withdrawn and centrifuged.The pelleted cells were resuspended in a small volume of modifiedM9 minimal medium containing ¹⁵NH₄Cl and other supplements, inoculated into 1 liter of the samemedium, and incubated at 30°C with shaking. When the OD₆₀₀ reached0.5 (1.8 × 10⁸ cells/ml), IPTG was added to a final concentration of 0.5 mMand cultivation was continued for 24 h. Cells were then collectedby centrifugation, and ¹⁵N-labeled ChBD_ChiA1 accumulated in the cytoplasm was extractedand purified as describedabove.

Chemical shift perturbation experiments. Samples for NMR measurements consisted of 250 µl of 90% (vol/vol) H₂O-10% (vol/vol) ²H₂O solution containing 50 µM ¹⁵N-labeled ChBD_ChiA1, 50 mM KH₂PO₄-K₂HPO₄ (pH 6.0), and 10 mM deuterateddithiothreitol. The two-dimensional WATERGATE and water-flip-back¹⁵N-¹H-HSQC (21) spectra of ¹⁵N-labeled ChBD_ChiA1 in the absence and presence of each of thefollowing soluble chitinous substrates were acquired: hexa-N-acetylchitohexaose[(GlcNAc)₆], soluble chitin, carboxymethyl chitin (CM-chitin),and ethylene glycol chitin. The concentration of each added solublesubstrate corresponded to 500 µM, assuming the six monosaccharideunits to be one molecule. The spectrum in the presence of eachsubstrate was compared with that of the free ChBD_ChiA1.

NMR experiments were performed using a Bruker DRX500 or DRX800 spectrometer at 310 K. The spectral widths measured with theDRX500 or DRX800 spectrometer were 1,116.1 and 1,785.7 Hz forthe ¹⁵N dimension and 8,012.8 and 12,019.2 Hz for the ¹H dimension, respectively. The ¹H carrier was set to the frequency of the water resonance (4.69ppm), and the ¹⁵N carrier was set to 120.0 ppm. NMR data processing and analysiswere performed using the nmrPipe and nmrDraw software package(7).

ITC. Isothermal titration calorimetry (ITC) experiments were carried out using an OMEGA calorimeter (MicroCal Inc., Amherst, Mass.)(41). The reaction cell (ca. 1.4 ml in volume) was filled with0.1 mM ChBD_ChiA1 solution, and the injection syringe was filledwith 3 mM (GlcNAc)₆ or a 2.5-mg/ml soluble chitin solution. Ten-microliteraliquots of the substrate solutions were injected 12 times at5- to 7-min intervals. Control dilutions of these substrates intobuffer were also carried out in order to correct the observedheats of binding. Titration experiments were done at pH 6.0 with50 mM sodium phosphate buffer for (GlcNAc)₆ and 20 mM sodium cacodylatebuffer for soluble chitin and also at pH 9.0 with 20 mM pyrophosphatebuffer for (GlcNAc)₆. The substrates were dissolved in dialysatesolutions so that no pH difference existed between the proteinand the substratesolutions.

Electron microscopy. Enzyme-treated $beta$ -chitin microcrystals were deposited on carbon-coated grids and allowed to dry. All of the electron micrographswere taken with a JEOL 2000EXII electron microscope operated at100 kV and recorded on Mitsubishi MEM film. Diffraction contrastimaging in the bright-field mode was used to visualize the samplewithout further contrast enhancement. The images were taken atmagnifications of ×1,000 to ×6,000 under low-dose exposure withthe use of a Minimum Dose System(JEOL).

Protein assay. The protein concentration was estimated from absorbance at 280 nm using the molar extinction coefficients $varepsilon$ (chitinase A1)= 153,920, $varepsilon$ (A1 $Delta$ ChBD) = 138,450, and $varepsilon$ (ChBD_ChiA1) = 20,970, whichwere calculated from the amino acid compositions of each protein(24). To determine relative equilibrium association constants,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.

SDS-polyacrylamide gel electrophoresis. Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis in 16.5% polyacrylamide slabs was carried out according tothe manufacturer's instructions for SDS molecular weight markers(Sigma Chemical Co., St. Louis, Mo.).

Enzyme assay. Reducing sugar generated by the degradation of microcrystalline $beta$ -chitin from a vestimentiferan tube worm (Lamellibrachiasatsuma) was measured by a modification of Schales' procedureusing di-N-acetylchitobiose as the standard (12). Each assaymixture (total volume, 300 µl) contained 200 µg (dry weight) ofmicrocrystalline $beta$ -chitin and 240 nM enzyme in 0.1 M sodium phosphatebuffer (pH 6.0).

Binding assay. Binding assay mixtures in 1-ml glass microtubes containing various concentrations of protein and 1 mg of binding substratein 1 ml of 20 mM buffer were incubated on ice with occasionalmixing. Each mixture was centrifuged at 4°C for 20 min at 15,000× g to separate supernatant and substrate with bound protein,the supernatant containing free protein was collected, and theprotein concentration was determined. The amount of bound proteinwas calculated from the difference between the initial proteinconcentration and the free protein concentration after binding.The relative equilibrium association constants (K_r) was determinedfrom double-reciprocal plots of binding data by the method describedby Gilkes et al. (9).

Chemicals. Chitin EX (powdered prawn shell chitin), chitosans, and CM-chitin were purchased from Funakoshi Chemical Co. (Tokyo, Japan).(GlcNAc)₆ and soluble chitin were obtained from Yaizu Suisan ChemicalCo. Ltd. (Shizuoka, Japan). The degree of deacetylation and approximatemolecular weight of the soluble chitin were 38.8% and from 200,000to 300,000, respectively. Avicel and soluble starch were purchasedfrom Asahi Chemical Industry (Osaka, Japan) and Wako Pure ChemicalIndustries (Osaka, Japan), respectively. Regenerated chitin wasprepared from chitosan 8B (approximately 20% acetylated), purchasedfrom Funakoshi Chemical Co., as described by Molano et al. (20).Colloidal chitin and ethylene glycol chitin were prepared frompowdered crab shell chitin, purchased from Funakoshi ChemicalCo., by the methods described by Jeuniaux (13) and Yamada andImoto (43), respectively. Microcrystalline $beta$ -chitin from vestimentiferanwas prepared as described previously (29).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Production and purification of ChBD_ChiA1. The mature form of chitinase A1 from B. circulans WL-12 is composed of the N-terminal catalytic domain, two FnIII domainsand the C-terminal ChBD. In order to study the biochemical propertiesand structure of ChBD of chitinase A1, a high-level expressionsystem for ChBD_ChiA1 was constructed by using the pET expressionsystem. The DNA region of the chiA gene corresponding to the ChBD(Ala655 to Gln699 of chitinase A1) was amplified by PCR, and theamplified fragment was first inserted into the SmaI site of pUC119for sequencing to ensure that the amplified fragment had the expectedsequence. The inserted fragment was then cut out using BamHI andreinserted into the BamHI site of pET3a, resulting in the plasmidpChBD. E. coli BL21(DE3) cells carrying pChBD produced ChBD_ChiA1in soluble form when induced with IPTG and accumulated it in thecytoplasm. ChBD_ChiA1 in the cytoplasm was extracted from the cellsafter 12 h of induction with IPTG, fractionated by ammonium sulfateprecipitation, and purified by chitin affinity column chromatography.ChBD_ChiA1 was eluted from the chitin column with 20 mM aceticacid after the column was washed with 20 mM sodium phosphate buffer(pH 6.0) containing 1 M NaCl. The protein in the peak fractionexhibited a single band on an SDS-polyacrylamide gel, as shownin Fig. 1. From a 1-liter culture of E. coli BL21(DE3) cells carryingpChBD, over 50 mg of ChBD_ChiA1 was extracted and 20 to 40 mg ofpurified ChBD_ChiA1 was obtained. The ChBD_ChiA1 obtained includeda T7 tag at its N terminus consisting of 14 amino acid residuesderived from the expression vector.

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FIG. 1. Expression and purification of ChBD_ChiA1. ChBD_ChiA1 produced in E. coli BL21 cells was purified by chitin affinity column chromatography from the soluble protein fraction of disrupted cells. Lane 1, soluble protein fraction of E. coli BL21(DE3) cells carrying pET3a (control); lane 2, soluble protein fraction of induced E. coli BL21(DE3) cells carrying pChBD; lane 3, proteins obtained by ammonium sulfate precipitation from the soluble protein fraction; lane 4, flowthrough fraction of chitin affinity column chromatography; lane 5, proteins eluted from the chitin affinity column with 20 mM sodium acetate buffer (pH 5.5); lane 6, purified ChBD_ChiA1 obtained by elution with 20 mM acetic acid; lane MW, molecular mass standards. The arrowhead indicates the position of the ChBD_ChiA1 protein band.

Binding activity of purified ChBD_ChiA1. To study the contribution of ChBD to the binding of chitinase A1 to chitin, the binding activity of purified ChBD_ChiA1 wascompared with those of the intact chitinase A1 and A1 $Delta$ ChBD, adeletion derivative of chitinase A1 lacking ChBD. The relativeequilibrium association constants (K_r) of intact chitinase A1,A1 $Delta$ ChBD, and ChBD_ChiA1 toward regenerated chitin were determinedas shown in Table 1 from the double-reciprocal plots of bindingdata shown in Fig. 2. The binding assay for these experimentswas carried out at pH 6.0, since the pH optimum of chitinase A1for the hydrolysis reaction is 6.0. The binding reaction timeswere 3 h for ChBD_ChiA1 and 1 h for chitinase A1 and A1 $Delta$ ChBD, sincepreliminary experiments indicated that the binding of ChBD_ChiA1required approximately 3 h and those of chitinase A1 and A1 $Delta$ ChBDrequired less than 1 h to reach equilibrium (data not shown).The regenerated chitin used in this experiment was prepared byacetylation of chitosan, and the degree of acetylation was morethan 95%. The a/[N₀] values, indicating the relative space ofsubstrate surface occupied by a single ligand molecule, are almostconsistent with the ligands' molecular weights (a is the numberof lattice units occupied by a single ligand molecule, and N₀is the concentration of binding sites on the chitin surface).The K_r of ChBD_ChiA1 was significantly smaller than that of chitinaseA1, and A1 $Delta$ ChBD exhibited a much smaller K_r than the other twoproteins. The K_r of ChBD_ChiA1 could be an underestimate, sincebinding assays with ChBD_ChiA1 in the lower range of protein concentrationwere difficult to carry out. This small protein is not as sensitiveas chitinase A1 and A1 $Delta$ ChBD in protein concentration measurement.However, the results strongly suggested that the binding activityof intact chitinase A1 depends mostly on the binding activityof ChBD_ChiA1 and that the catalytic domain is involved in thebinding of chitinase A1 to a certain extent. The weak bindingactivity of A1 $Delta$ ChBD was considered to be due to the affinity ofthe catalytic domain for chitin, since the isolated catalyticdomain and A1 $Delta$ ChBD exhibited the same level of affinity towardregenerated chitin, as described previously (40).

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TABLE 1. Adsorption parameters

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FIG. 2. Double-reciprocal plots of binding data for chitinase A1 (a), A1 $Delta$ ChBD (b), and ChBD_ChiA1 (c). The binding assay mixture contained 1 mg (dry weight) of regenerated chitin and from 1 to 70 µg of each protein (14 to 1,000 pmol of chitinase A1, 15 to 1,050 pmol of A1 $Delta$ ChBD, and 154 to 10,770 pmol of ChBD_ChiA1) in 1 ml of 20 mM sodium phosphate buffer (pH 6.0). The binding assay was performed by keeping the binding assay mixtures on ice for 1 h for chitinase A1 and A1 $Delta$ ChBD and 3 h for ChBD_ChiA1. [B], bound protein concentration; [F], free protein concentration.

Effect of pH and salt concentration on binding. The effect of pH on the binding of chitinase A1 and ChBD_ChiA1 to regenerated chitin was investigated. As shown in Fig. 3,both chitinase A1 and ChBD_ChiA1 showed binding activity over awide range of pH. The highest binding activity of ChBD_ChiA1 wasobserved at pH 9.0. The binding of both chitinase A1 and ChBD_ChiA1significantly decreased at pHs below 3. This may explain the observationthat these proteins were eluted from a chitin affinity columnby 20 mM acetic acid. ChBD_ChiA1 exhibited higher percentages ofbound protein than chitinase A1 did at all tested pHs under thisreaction condition, in contrast to the lower K_r value comparedto chitinase A1. The conflict may be explained by the possibleunderestimate of the K_r of ChBD_ChiA1 described above and the factthat the relative binding of chitinase A1 decreases much fasterthan that of ChBD_ChiA1 with the increase in the amount of addedproteins in the binding assay mixture, probably due to its highera/[N₀] value.

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FIG. 3. Effect of pH on the binding of chitinase A1 and ChBD_ChiA1 to regenerated chitin. Assay mixtures contained 1 mg (dry weight) of regenerated chitin and 1 nmol of either chitinase A1 (70 µg) or ChBD_ChiA1 (6.5 µg) in 1 ml of buffers with various pHs. The buffers used in this experiment were 20 mM sodium citrate (pH 2.0 to 6.0), sodium phosphate (pH 7.0), Tris-HCl (pH 8.0), glycine-NaOH (pH 9.0 and 10.0), and disodium hydrogen phosphate-NaOH (pH 11 and 12). Assay mixtures were incubated on ice for 1 h for chitinase A1 and 3 h for ChBD_ChiA1.

, chitinase A1; ×, ChBD_ChiA1.

Figure 4 shows the kinetics of binding of ChBD_ChiA1 over 60 min of incubation at pH 9.0 and in the presence of 0.5 M NaClat pH 6.0. ChBD_ChiA1 bound better at pH 9.0 than that at pH 6.0.The isoelectric points (pIs) calculated from the amino acid sequencesof ChBD_ChiA1 with and without a T7 tag are 9.3 and 8.8, respectively.Therefore, the electric charge of ChBD_ChiA1 was almost minimizedat pH 9.0. In the presence of 0.5 M NaCl at pH 6.0, ChBD_ChiA1also bound better than it did without NaCl. These results suggestthat the binding of ChBD_ChiA1 to chitin is mediated mainly byhydrophobic interactions.

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FIG. 4. Time courses of binding of ChBD_ChiA1 at pH 9.0 and in the presence of NaCl. Assay mixtures contained 6 mg (dry weight) of regenerated chitin and 2.3 nmol (15 µg) of ChBD_ChiA1 in 1 ml of 20 mM sodium phosphate buffer (pH 6.0) (

), 20 mM sodium phosphate buffer (pH 6.0) containing 0.5 M NaCl (

), or 20 mM Tris-HCl buffer (pH 9.0) (+).

Specificity of binding to insoluble polysaccharides. Figure 5 shows the specificities of binding of intact chitinase A1, A1 $Delta$ ChBD, and ChBD_ChiA1 to various insoluble polysaccharides.Chitinase A1 preferentially bound to various forms of insolublechitin, but it also bound, although weakly, to other insolublepolysaccharides such as avicel and soluble starch. On the otherhand, ChBD_ChiA1 bound highly specifically to chitin. It boundto colloidal chitin, regenerated chitin, chitin powder (chitinEX), and microcrystalline $beta$ -chitin from L. satsuma and did notshow significant binding to chitosan, starch, or avicel. A1 $Delta$ ChBDexhibited weak affinity to all insoluble $beta$ -1,4-polysaccharidesexamined in this experiment, and thus, the affinity was not restrictedto chitin, although the binding activity to colloidal chitin wasthe highest among the tested polysaccharides. Therefore, the weakbinding activity of the intact chitinase A1 observed with polysaccharidesother than chitin is suggested to be due to the affinity of thecatalytic domain for these polysaccharides.

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FIG. 5. Binding specificities of chitinase A1, A1 $Delta$ ChBD, and ChBD_ChiA1. Binding assay mixtures contained 1 mg (dry weight) of various insoluble polysaccharides and 25 µg of protein in 1 ml of 20 mM Tris-HCl (pH 9.0). Assay mixtures were kept on ice for 24 h for binding.

Interaction with soluble substrates. Interactions of ChBD_ChiA1 with soluble substrates, including (GlcNAc)₆, ethylene glycol chitin, CM-chitin, and soluble chitin,were examined by NMR andITC.

The simplest approach for detecting interactions between proteins and substrates by NMR is the chemical shift perturbationexperiment (25), where changes of amide chemical shifts of aprotein are monitored by ¹⁵N-¹H-HSQC spectra upon the addition of a substrate. The spectra ofthe ¹⁵N-labeled ChBD_ChiA1 in the presence and absence of one of thefour soluble substrates were compared. These comparisons revealedno changes of the chemical shifts of the NMR peaks, although slightoverall increases in the peak widths were observed, probably dueto the increase in the solution viscosity caused by the additionaloligosaccharide (data not shown). Thus, we concluded that ChBD_ChiA1does not interact specifically with any of the four solublesubstrates.

Interaction between ChBD_ChiA1 and either (GlcNAc)₆ or soluble chitin was also studied by means of ITC. Titration of 0.1 mMChBD_ChiA1 solution with either 2.5 mg of soluble chitin per mlor 3 mM (GlcNAc)₆ was carried out, but no heat change was observedfor either titration with the two substrates within the sensitivityrange of the calorimeter. These results indicated that no specificinteraction occurred between the protein and the substrates. Thiswas also confirmed by differential scanning calorimetry measurementsconducted on the protein solutions in both the presence and absenceof each of three substrates, (GlcNAc)₆, soluble chitin, and CM-chitin,at pH 6.0. The denaturation temperature of ChBD_ChiA1 was not shiftedto a higher temperature range by the presence of these substrates,indicating that there was no complex formation, as judged usingthe Le Chaterier principle (28).

In addition, the effect of the presence of (GlcNAc)₆ and CM-chitin on the binding of ChBD_ChiA1 to regenerated chitin was examined.Equal amounts of either (GlcNAc)₆ or CM-chitin and regeneratedchitin, the binding substrate, were included in the assay mixture,and binding of ChBD_ChiA1 was carried out for 24 h at 4°C. Theprotein concentration in the supernatant was measured after centrifugation,and the amount of bound protein was estimated. However, no significantdecrease in the amount of bound protein was observed even in thepresence of soluble substrates, and therefore, these soluble substratesdo not interfere with the binding of ChBD_ChiA1 to regeneratedchitin.

From all of these data, it was concluded that ChBD_ChiA1 does not interact with either chito-oligosaccharide or soluble derivativesofchitin.

Degradation of microcrystalline $beta$ -chitin. Since ChBD_ChiA1 was shown not to interact with either soluble chitin or chito-oligosaccharide, the effect of the absence ofthe ChBD from chitinase A1 on the hydrolysis of highly crystalline $beta$ -chitin was examined. $beta$ -Chitin microcrystals isolated from protectivetubes of L. satsuma were treated with intact chitinase A1 andA1 $Delta$ ChBD, and the amount of reducing sugar generated was measured.As shown in Fig. 6, degradation of microcrystalline $beta$ -chitin byA1 $Delta$ ChBD was much less efficient than degradation by intact chitinaseA1. Hydrolysis by chitinase A1 continued and reducing sugar increasedduring 60 min of incubation, although the rate of hydrolysis decreasedgradually with incubation time. Since approximately 30% of thesubstrate was hydrolyzed at the end of the incubation period,the decrease in the rate of hydrolysis was probably due to thesubstrate shortage and/or product inhibition of the hydrolysisreaction. On the other hand, significant degradation of microcrystalline $beta$ -chitin by A1 $Delta$ ChBD was observed only at the beginning of theincubation period, and soon hydrolysis slowed down and nearlystopped. The effects of substrate consumption and/or product inhibitionmust therefore be much smaller than in the case of chitinase A1.Therefore, it is clear that ChBD plays a vital role in the degradationof $beta$ -chitin microcrystals.

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FIG. 6. Hydrolysis of $beta$ -chitin microfibrils by intact chitinase A1 and A1 $Delta$ ChBD. Reaction mixtures contained 200 µg (dry weight) of microcrystalline $beta$ -chitin from L. satsuma and 71 pmol of each chitinase. Reactions were performed at 37°C, and the amount of reducing sugar generated was monitored by the modified Schales procedure.

, chitinase A1; ×, A1 $Delta$ ChBD.

However, since significant degradation by A1 $Delta$ ChBD was observed only at the beginning of incubation, it is possible that degradationby A1 $Delta$ ChBD occurred at less-crystalline regions of the substrate.To see whether A1 $Delta$ ChBD can truly hydrolyze $beta$ -chitin microcrystals, $beta$ -chitin microfibrils were treated with intact chitinase A1 andA1 $Delta$ ChBD and then examined by electron microscopy. As demonstratedpreviously, intact chitinase A1 shortened $beta$ -chitin microcrystalsand formed a pointed tip at one end of the microcrystal (29).As shown in Fig. 7c, A1 $Delta$ ChBD also shortened $beta$ -chitin microcrystalsand formed a pointed tip at one end of the microcrystal, justas chitinase A1 did. The shape of the $beta$ -chitin microcrystals treatedwith A1 $Delta$ ChBD was indistinguishable from the shape of those treatedwith chitinase A1. The means that without ChBD, the enzyme isstill able to hydrolyze the crystalline part of the substrate.Therefore, it appeared that ChBD_ChiA1 is not absolutely requiredfor hydrolysis of $beta$ -chitin microcrystals but that it greatly improvesthe efficiency of degradation.

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FIG. 7. Bright-field diffraction contrast micrographs of L. satsuma $beta$ -chitin microfibrils. (a) no enzyme treatment (control); (b) after treatment with chitinase A1; (c) after treatment with A1 $Delta$ ChBD.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

ChBD_ChiA1 was successfully expressed separately from the catalytic domain and FnIII domains by using a pET expression system.This made it possible to study the properties of ChBD withoutinfluence from the other domains, and we found two important andunexpected features of the ChBD of chitinase A1. One is that theChBD_ChiA1 interacted only with insoluble chitin, and the otheris that binding of ChBD_ChiA1 was highly specific for chitin. Asmentioned above, no interactions between ChBD_ChiA1 and a chito-oligosaccharide,(GlcNAc)₆, was detected. Interactions between ChBD_ChiA1 and solublesubstrates were also studied with ITC. Titration of ChBD_ChiA1solution with either (GlcNAc)₆ or soluble derivatives of chitindid not give significant reaction heat, which indicates a lackof interaction between ChBD_ChiA1 and the tested substrates. Inaddition, (GlcNAc)₆ and CM-chitin did not interfere with the bindingof ChBD_ChiA1 to regenerated chitin. Thus, no interaction was observedusing three different approaches attempting to detect interactionwith soluble chitinoussubstrates.

Since chitinase A1 exhibited weak but significant binding to cellulose in addition to various forms of insoluble chitin, wefirst expected that ChBD would also have some binding activityto cellulose. However, it appeared that ChBD_ChiA1 bound only tochitin, and there was no significant binding to cellulose or otherpolysaccharides. These observations suggest that ChBD_ChiA1 recognizesa structure that is present only in insoluble or crystalline chitinand not in chito-oligosaccharides, soluble derivatives of chitin,or other insolublepolysaccharides.

As far as we know, the three-dimensional structures of six CBDs from five families, five from cellulases and one from cellulosome,have been reported (4, 14, 15, 19, 35, 42). Amongthem, the CBD of CenC from C. fimi binds to amorphous cellulosebut not to crystalline cellulose, and the others can bind bothamorphous and crystalline celluloses. CBDs that can bind to crystallinecellulose share the common surface feature of a planar array ofthree aromatic residues. The three aromatic residues have beenproposed to make a major contribution to the binding of CBDs tothe cellulose surface (3, 17). Interactions of CBDs and cello-oligosaccharideshave been demonstrated with CBDs of exoglucanase from C. fimi,endoglucanase I from T. reesei, and xylanase A from Pseudomonasfluorescens subsp. cellulosa by NMR spectroscopy (18, 23,42) and titration calorimetry (6). Binding to chitin in additionto cellulose has been demonstrated with CBD_CBHII, CBD_Cex, CBD_CenA,and Cip-CBD, while CBD_CBHI did not bind to chitin (11, 16,32, 34). On the other hand, ChBD bound specifically to chitinand not to cellulose and did not interact with chito-oligosaccharide,as mentioned above. These observations suggest that there mustbe significant differences in the mechanisms of binding betweenChBD_ChiA1 and these CBDs. In fact, the solution structure determinedvery recently revealed that ChBD_ChiA1 does not have a planar arrayof aromatic residues on its surface (unpublisheddata).

The ChBD of chitinase A1 exhibits amino acid sequence similarity with many sequence segments in other chitinases, cellulases,and a protease, as shown in Fig. 8. These sequences can be dividedinto two groups: one is represented by the ChBD of chitinase A1(upper group in Fig. 8) and the other is represented by a familyV CBD from E. chrysanthemi endoglucanase (CBDZ_EGZ). As seen inthe alignment, the N-terminal halves of the sequences are relativelyconserved between the two groups of sequences, but the C-terminalhalves are very different between the two groups of sequences.It is most striking that the upper group does not have the AKWWTQGmotif, which is well conserved in the lower-group sequences, andthe upper group contains solely known or proposed ChBDs. The C-terminaldomain of protease C from Streptomyces griseus is a member ofthe upper group. The homology of this domain with ChBDs of B.circulans chitinases A1 and D1 was described by Sidhu et al. (27),and they suggested that the enzyme is specialized for the degradationof chitin-linked proteins. On the other hand, the lower groupcontains both CBDs and ChBDs, including those of chitinase B fromClostridium paraputrificum (22), chitinase 85 from Altermonassp. strain O-7 (36), and chitinases from Aeromonas sp. strain10S-24 (26). CBD_EGZ exhibits a ski-boot shape, and three aromaticresidues (Trp382, Trp407, and Tyr408) are localized on one face(4). These aromatic residues are proposed to play a major rolein the binding of this CBD to the cellulose surface, as mentionedabove. Trp407 and Tyr408 of CBD_EGZ correspond to the two aromaticresidues in this motif.

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FIG. 8. Alignment of amino acid sequences that have similarity to ChBD of chitinase A1. Rows: 1, ChBD of B. circulans WL-12 chitinase A1; 2, N-terminal domain (ChBD) of B. circulans WL-12 chitinase D1; 3, C-terminal region of S. griseus proteinase C; 4, C-terminal region of Serratia marcescens 2170 chitinase CI; 5, C-terminal region of Aeromonas sp. strain 10S chitinase II; 6, C-terminal region of Janthinobacterium lividum chitinase 69a; 7 to 9, Bacillus sp. (strain N-4) cellulase A, cellulase B1, and cellulase B, respectively; 10, Alteromonas sp. (strain O-7) chitinase 85; 11-12, Aeromonas caviae chitinase A; 13, Vibrio harveyi chitinase A; 14 to 18, Aeromonas sp. strain 10S ORF1, chitinase II, ORF3, ORF4, and ORF2, respectively; 19, J. lividum chitinase 69b; 20 to 24, repeating units found in E. coli hypothetical 97.1-kDa protein YheB; 25, S. griseus chitinase C; 26, S. marcescens 2170 chitinase B; 27, E. chrysanthemi endglucasase Z. Highly conserved amino acid sequences in the upper and lower groups are indicated by a black background. The starting and ending amino acid positions, based on the translational start methionine being residue 1, are shown on both sides of each protein segment. The CLUSTAL X program was used to make the alignment.

Brun et al. suggested that the sequence regions shown in the lower group form individual functional domains structurally relatedto CBD_EGZ, and they proposed the possibility that CBD_EGZ and someChBDs might form a new family of functionally and structurallyrelated protein modules (4). They also noted that the ChBDsof B. circulans chitinases A1 and D1 are presumably not includedin this family, since they do not exhibit the highly conservedstWWst motif (AKWWTQG motif), where s and t represent small residuesand turn-like residues, respectively. Unique features of ChBD_ChiA1with respect to its binding properties and striking differencesin the surface structure between ChBD_ChiA1 and CBD_EGZ may indicatethe relevance of their suggestion. Therefore, presumably, theupper group forms a new family of functionally and structurallyrelated protein modules distinct from the family of the lowergroup. The family may share common features with the ChBD of chitinaseA1 characterized by chitin-specific binding activity and interactiononly with insolublechitin.

Isolated ChBD_ChiA1 has a tightly packed structure and remarkable stability in spite of its small size (45 amino acids) andthe absence of disulfide bonds, as demonstrated by NMR and differentialscanning calorimetry (unpublished data). The binding activityof ChBD_ChiA1 is highly specific for insoluble chitin, and it canbe controlled by changing the pH, as shown above. The ChBD ofchitinase A1 has been successfully used for purification of targetproteins in foreign protein expression systems as described byChong et al. (5). In addition to the remarkable stability andsmall size of ChBD_ChiA1, its specific binding to insoluble chitinand easy desorption by controlling the pH demonstrated in thisstudy may open new aspects regarding applications of the ChBDof chitinaseA1.

	ACKNOWLEDGMENTS

We thank 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.

This work was partly supported by a grant-in-aid for scientific research (10660077) from the Ministry of Education, Scienceand Culture ofJapan.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Applied Biological Chemistry, Faculty of Agriculture, Niigata University,8050 Ikarashi-2, Niigata 950-2181, Japan. Phone: (81)252626647.Fax: (81)252626854. E-mail: wata{at}agr.niigata-u.ac.jp.

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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Alam, M. M., N. Nikaidou, H. Tanaka, and T. Watanabe. 1995. Cloning and sequencing of chiC gene of Bacillus circulans WL-12 and relationship of its product to some other chitinases and chitinase-like proteins. J. Ferment. Bioeng. 80:454-461[CrossRef].
2.	Alam, M. M., T. Mizutani, M. Isono, N. Nikaidou, and T. Watanabe. 1996. Three chitinase genes (chiA, chiC, and chiD) comprise the chitinase system of Bacillus circulans WL-12. J. Ferment. Bioeng. 82:28-36[CrossRef].
3.	Bray, M. R., P. E. Johnson, N. R. Gilkes, L. P. McIntosh, D. G. Kilburn, and R. A. Warren. 1996. Probing the role of tryptophan residues in a cellulose-binding domain by chemical modification. Protein Sci. 5:2311-2318[Medline].
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