The bglA Gene of Aspergillus kawachii Encodes Both Extracellular and Cell Wall-Bound beta -Glucosidases

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Applied and Environmental Microbiology, December 1999, p. 5546-5553, Vol. 65, No. 12
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

The bglA Gene of Aspergillus kawachii Encodes Both Extracellular and Cell Wall-Bound $beta$ -Glucosidases

Kazuhiro Iwashita,^* Tatsuya Nagahara, Hitoshi Kimura, Makoto Takano, Hitoshi Shimoi, and Kiyoshi Ito

National Research Institute of Brewing, 7-3-1, Kagamiyama, Higashihiroshima, Hiroshima 739-0046, Japan

Received 26 April 1999/Accepted 27 August 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

We cloned the genomic DNA and cDNA of bglA, which encodes $beta$ -glucosidase in Aspergillus kawachii, based on a partial aminoacid sequence of purified cell wall-bound $beta$ -glucosidase CB-1.The nucleotide sequence of the cloned bglA gene revealed a 2,933-bpopen reading frame with six introns that encodes an 860-amino-acidprotein. Based on the deduced amino acid sequence, we concludedthat the bglA gene encodes cell wall-bound $beta$ -glucosidase CB-1.The amino acid sequence exhibited high levels of homology withthe amino acid sequences of fungal $beta$ -glucosidases classified insubfamily B. We expressed the bglA cDNA in Saccharomyces cerevisiaeand detected the recombinant $beta$ -glucosidase in the periplasm fractionof the recombinant yeast. A. kawachii can produce two extracellular $beta$ -glucosidases (EX-1 and EX-2) in addition to the cell wall-bound $beta$ -glucosidase. A. kawachii in which the bglA gene was disruptedproduced none of the three $beta$ -glucosidases, as determined by enzymeassays and a Western blot analysis. Thus, we concluded that thebglA gene encodes both extracellular and cell wall-bound $beta$ -glucosidasesin A. kawachii.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Aspergillus kawachii, an industrial fungus, has been used to prepare shochu koji, which is used to make shochu, a traditionalJapanese alcoholic beverage. This species, like other Aspergillusspecies, secretes large amounts of various enzymes into the medium,and it can be a useful host for heterologous protein production.A. kawachii also releases large amounts of citric acid into theenvironment, causing it to become acidic. To adapt to this acidicenvironment, some of the enzymes of A. kawachii such as amylase,protease, cellulase, and hemicellulase, are more acid stable thanthe same enzymes secreted by other species (17, 18, 27,28, 42).

One of the acid-stable enzymes is $beta$ -glucosidase (1,4- $beta$ -D-glucosidase; EC 3.2.1.21). $beta$ -Glucosidase catalyzes the hydrolysisof compounds containing $beta$ -glucosidic links, such as p-nitrophenyl- $beta$ -D-glucopyranosideand cellobiose, and acts by splitting off the terminal nonreducing $beta$ -D-glucose residue and releasing $beta$ -D-glucose as the reactionproduct (3, 4). Because of this activity, $beta$ -glucosidaseplays an important role in the biological saccharification ofcellulosic materials. Hydrolysis of cellulose is accomplishedby the synergistic reactions of cellulase family enzymes. Exo-1,4- $beta$ -D-glucancellobiohydrolase (exocellulase or cellobiohydrolase; EC 3.2.1.91)and endo-1,4- $beta$ -D-glucan glucanohydrolase (endoglucanase; EC 3.2.1.4)can directly solubilize crystalline cellulose. This results mainlyin the generation of cellobiose, which is a product inhibitorfor these enzymes. $beta$ -Glucosidase is involved in the final stepof cellulose saccharification; in this step it degrades cellobioseto glucose and releases exocellulase and endoglucanase from cellobioseinhibition (11, 40).

In addition to its role in cellulose saccharification, $beta$ -glucosidase plays other important biological roles. Some $beta$ -glucosidasescatalyze not only hydrolysis reactions but also transglycosylationreactions. This transglycosylation activity is believed to beimportant in the production of cellulase inducers in some fungi,but the details of this process are not clear (5, 37, 44,46). In plants, $beta$ -glucosidases are important in flavor formationin fruits. They are also important in the production of wine andsweet potato shochu. Some monoterpene alcohols (linalool, $alpha$ -terpineol,citronellol, nerol, and geranol) contribute to the flavor of sweetpotato shochu and wine. These monoterpene alcohols are presentin sweet potatoes and grape berries as nonvolatile glycosidesand are released by the action of $beta$ -glucosidase (13, 23, 29,30, 39, 45).

During production of sweet potato shochu, the $beta$ -glucosidases are supplied by A. kawachii (30). In a previous study we purifiedtwo extracellular $beta$ -glucosidases (EX-1 and EX-2) and one cellwall-bound $beta$ -glucosidase (CB-1) from A. kawachii (19). Thesethree enzymes were very unstable after purification, but theybecame stable when cell wall material from A. kawachii was added.The cell wall material adsorbed all of the purified $beta$ -glucosidases,but it did not inhibit the activities of the enzymes. Althoughthe N-terminal amino acid sequences of the enzymes were identical,the molecular masses were different, as follows: EX-1, 145 kDa;EX-2, 130 kDa; and CB-1, 120 kDa. Our data suggested that thesethree $beta$ -glucosidases are products of the same gene and are modifiedby different degrees of glycosylation (19).

In this study, we cloned the gene encoding $beta$ -glucosidase in A. kawachii and analyzed the sequence. We found that both of theextracellular $beta$ -glucosidases (EX-1 and EX-2) and the cell wall-bound $beta$ -glucosidase (CB-1) are encoded by a single gene, which we designatedbglA.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains, plasmids, and media. A. kawachii IFO4308 was used as a donor of genomic DNA and mRNA. Saccharomyces cerevisiae YPH499 (MATa ura3 lys2 ade2trp1 his3 leu2) was used as the host for expression of bglA cDNA.Escherichia coli JM109 and LE392 were used for DNA manipulation.Plasmid pUSC, which was a gift from O. Yamada, was used for transformationof A. kawachii and isolation of the Aspergillus nidulans sC gene(47). Basic medium (0.1% Bacto-Tryptone [Difco], 0.5% yeastextract, 0.1% NaNO₃, 0.1% K₂HPO₄, 0.05% MgSO₄ · 7H₂O, 0.001% FeSO₄· 7H₂O; pH 5.0) containing various carbon sources was used forcultivation of A. kawachii IFO4308. Solid cultivation was carriedout as described previously by using rice grain (19). Minimalmedium was used to select A. kawachii transformants (6). Foryeast cultures, we used YNBD medium supplemented with the appropriateamino acids (2). E. coli was grown in Luria-Bertani mediumsupplemented with 100 µg of ampicillin per ml (38).

Purification of cell wall-bound $beta$ -glucosidase CB-1. Cell wall-bound $beta$ -glucosidase CB-1 was purified from a lysate of 4-day-old mycelia as previously described (19).

Partial amino acid sequence of CB-1. Purified CB-1 (200 µg) was digested with lysyl endopeptidase (Achromobacter protease I; Wako Pure Chemicals) by using themethod of Kamei et al. (20). The resulting peptide fragmentswere separated by reverse-phase high-performance liquid chromatographyby using a µBondasphere C-8 100-Å column (Waters Corp.) and alinear 0 to 100% acetonitrile gradient in which the concentrationincreased at a rate of 1.5% per min. The peptide fragments inpeaks were sequenced with a gas phase protein sequencer (model491 Procise; AppliedBiosystems).

General DNA manipulation technique. All of the DNA manipulation procedures (subcloning, purification of plasmids, etc.) were carried out by using standard methods,as described by Sambrook et al. (38).

Cloning of genomic DNA. The genomic DNA of A. kawachii was amplified with a primer set (primer 1 [5'-GGTATTCAAGACGGAGGTGTTGTCGCGACTGCAAA-3'] and primer2 [5'-GGCAGCCCAGTCCGACATAACAAAGCC-3']) by performing PCR, andthen two DNA fragments (probes A and B) were isolated. The $lambda$ EMBL3A. kawachii genomic library was screened independently with theseprobes as previously described (16).

Cloning of cDNA. A. kawachii was grown in basic medium containing 1% glucose and 2% xylan as carbon sources for 3 days, and the total RNA wasisolated from mycelia as described by Hata et al. (14). Thepoly(A)⁺ mRNA was separated from the total RNA by chromatography on anoligo(dT)-cellulose column (Amersham Pharmacia Biotech). The full-lengthcDNA was isolated from the mRNA by using a Marathon cDNA amplificationkit (Clontech). On the basis of the genomic sequence of bglA,the following deoxyoligonucleotide primers were synthesized: Boligo5(primer for rapid amplification of cDNA 5' ends [5'-RACE]; 5'-CATGAGGTTCACTTTGATTGA-3')and Boligo3 (primer for 3'-RACE; 5'-CGTAGCTAGCATCCCCAGAAG-3').Using these primers and adapter primer 1 (5'-GTCAATGTCCCAAACGTCACCAGA-3'),we performed 5'- and 3'-RACE PCR. The amplified DNA fragmentswere cloned into pCR2 by using a TA cloning kit (Invitrogen),and 15 clones were isolated. We used one of longest of these clonesto obtain full-length cDNA. The 5'- and 3'-RACE products wereligated at the EcoRV site in order to isolate full-length bglAcDNA(pYbglA21).

DNA sequencing. Restriction enzyme fragments were subcloned into pUC118 by using E. coli JM109 as the host. The nucleotide sequence was determinedby the dideoxy chain termination method of Messing with an automatedDNA sequencer (model 371A; Applied Biosystems) (26). The completenucleotide sequences of both strands were determined by overlappingat everyjunction.

The deduced amino acid sequence was compared with the sequences of enzymes related to $beta$ -glucosidases in the SwissProt databaseby using the FASTA program (11a).

Construction of bglA expression vector in S. cerevisiae. The bglA expression vector pGBGA1 was synthesized as follows. Full-length $beta$ -glucosidase cDNA was isolated from pYbglA21 byEcoRI digestion and inserted into the SacI site of pG-1, whichyieldedpGBGA1.

The pYKBA1 vector, which contained the bglA gene with the exchanged signal sequence, was synthesized as follows. Full-lengthmature $beta$ -glucosidase cDNA was amplified by PCR by using the upperprimer (5'-CCGGAGCTCGGATGAATTGGCTTACTCCCCA-3') and the lower primer(5'-CCGGAGTCTAATTCATATACCACGGCCATCA-3'). The amplified DNA fragmentwas partially digested by SacI and then inserted into the SacIsite of pYEX-S1 (Nippon Gene), which yielded pYKBA1. This plasmidwas sequenced to confirm that the region encoding the mature proteinwas ligated in frame following the secretion signal from Kluyveromyceslactis.

Transformation of S. cerevisiae and A. kawachii. Transformation of S. cerevisiae was carried out as described by Becker and Guarente (2). Transformation of A. kawachiiwas carried out as described by Punt and van den Hondel (33).

$beta$ -Glucosidase assay. $beta$ -Glucosidase activity was measured by using p-nitrophenyl glycoside (PNPG) as a substrate, as previously described (19).A plate assay was performed by using 4-methylumbelliferyl- $beta$ -D-glucosideas a substrate. Transformants of S. cerevisiae were grown on minimalmedium plates at 30°C for 72 h. The plates were overlaid with0.75% top agarose containing 10 mM 4-methylumbelliferyl- $beta$ -D-glucosideand incubated for 5 min at room temperature. The fluorescenceof the methylumbelliferol that was released by the enzyme reactionwas observed under UV light (wavelength, 350nm).

Subcellular fractionation. Fractionation of yeast cells was carried out as described by Pines and London (32), with the following modifications. Agrowth medium fraction and a periplasm fraction were obtainedfrom 100 ml of a yeast culture (100 ml containing 6 × 10⁷ cells/ml), and protoplasts were recovered as described by Pinesand London. The recovered protoplasts were resuspended in 15 mlof buffer B and were vortexed for 5 min with 0.33 volume of glassbeads (diameter, 0.4 to 0.45 mm). The homogenate was assayed asthe cytoplasm and membranefraction.

Immunoblot analysis and DEAE chromatography. Yeast strains were cultivated in YNBD medium supplemented with the appropriate amino acids for 1 day. The yeast cells wereharvested by centrifugation and washed twice with H₂O. The washedcells were extracted by boiling them for 5 min in extraction buffer(125 mM Tris-HCl [pH 6.0], 1 mM phenylmethylsulfonyl fluoride,1× protease inhibitor cocktail [Boehringer Mannheim], 5% 2-mercaptoethanol,2% sodium dodecyl sulfate [SDS], 5% sucrose) and then centrifugingthem at 12,000 × g for 5 min. The culture medium was concentratedby ultrafiltration (type UFC3 TGC 00 filter; Millipore), and appropriateamounts were used for an immunoblotanalysis.

Aspergillus strains were cultivated in basal medium containing 1% glucose and 2% xylan at 30°C for 3 days. The mycelia wereharvested, washed, and then lysed in an isoosmotic solution (0.8N NaCl, 50 mM sodium acetate buffer [pH 5.0]) containing 3 mgof Yatalase (Takara) per ml. The lysate was centrifuged at 5,000rpm for 10 min, and the supernatant was used for the immunoblotanalysis. The immunoblot analysis was performed with $beta$ -glucosidaseantiserum as previously described (19).

DEAE chromatography was performed as described below. The cell wall lysate was placed on an anion-exchange column containingTSK gel DEAE-5PW (Tosoh Co., Ltd.) and equilibrated with 20 mMsodium acetate buffer (pH 5.0), and the column was eluted witha linear gradient consisting of 20 mM sodium acetate buffer (pH5.0) containing 0 to 0.4 N NaCl. The $beta$ -glucosidase activity wasmeasured by using PNPG as thesubstrate.

Mutagenesis and selection of sC strains of A. kawachii. Mutagenesis and isolation of sC strains were carried out as described by Buxton et al. (6), and 11 sC strains were isolated. The growth rates, morphological features,and enzyme production characteristics of selected sC strains were investigated in order to eliminate unnecessary mutations.Three of the strains selected were transformed by pUSC, whichcontained the A. nidulans sC gene. This transformation restoredthe abilities of all three strains to grow on sulfate as the solesulfur source. One of these three sC strains was used for subsequent experiments and was designatedstrainSC60.

Disruption of bglA gene. The SacI-SacI region of the bglA gene was replaced with the A. nidulans sC gene as follows. The genomic DNA of the bglA genewas subcloned into pYUM201 (Nippon Gene) by using the BamHI andKpnI sites (pYBA201). This plasmid was digested with SacI to removea 2.8-kbp SacI-SacI fragment. The sC gene, which was isolatedfrom pUSC by BamHI-SphI digestion, was inserted into the SacIsite. The resulting plasmid (pDbglA) was used as the disruptionvector.

The disruption vector was digested with BamHI and KpnI to recover the DNA fragment, which was bglA genomic DNA in which theSacI-SacI fragment of bglA was replaced by the sC gene. The A.kawachii sC strain was transformed with this DNA fragment, and transformantswere isolated by using minimal medium. The transformants wereincubated in the basic medium containing 3% glucose, and the genomicDNAs were purified from the transformants as described by Iimuraet al. and then were used for a Southern blot analysis to isolatethe bglA disruptant (15).

Nucleotide sequence accession number. The nucleotide sequence of the bglA gene and the deduced amino acid sequence have been deposited in the DDBJ database underaccession no. AB003470 (8a).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Partial amino acid sequence of A. kawachii $beta$ -glucosidase CB-1. After $beta$ -glucosidase CB-1 was purified from the cell wall lysate of A. kawachii, it produced a single band on SDS-polyacrylamidegel electrophoresis gels corresponding to a molecular weight of120,000. This protein was digested with lysyl endopeptidase andwas applied to a reverse-phase chromatography gel. Three fragments(P1, P2, and P3) were sequenced. The N-terminal amino acid sequencesof these peptides were as follows: P1, GIQDAGVVATAK; P2, NDGALPLTGK;and P3,TREAYQDYLVLEPNNG.

A search of the SwissProt database revealed no sequences homologous to P2 or P3, while part of one protein, the $beta$ -glucosidaseprecursor in Candida pelliculosa, was found to exhibit 75% identitywithP1.

Cloning of the genomic DNA (bglA) encoding $beta$ -glucosidase. Barnett et al. reported that the amino acid sequence around the known active site of the $beta$ -glucosidase gene of Aspergilluswentii is highly conserved in other fungal $beta$ -glucosidase genes,such as Tricoderma reesei bgl1, Saccharomycopsis fibuligera bgl1and bgl2, and the $beta$ -glucosidase gene of C. pelliculosa (1).Thus, we expected that this region around the active site wouldalso be conserved in the $beta$ -glucosidase of A. kawachii. On thebasis of the amino acid sequence of the PI region of $beta$ -glucosidaseCB-1 and the conserved region around the active center in theC. pelliculosa enzyme (GFVMTDWGA), we attempted to clone the genomicDNA which encoded $beta$ -glucosidase CB-1. In this study, we isolatedtwo phage clones, one obtained with probe 1 (designated bglA)and the other obtained with probe 2 (bglB), from the $lambda$ EMBL3 A.kawachii genomiclibrary.

After A. kawachii was grown for 3 days in basic medium containing 1% glucose and 2% xylan, total RNA was isolated from themycelia and subjected to a Northern analysis in which bglA andbglB were used as probes. A signal was detected with bglA DNAbut not with bglB (data not shown). Moreover, both strands ofbglA and bglB genomic DNAs were sequenced. On the basis of theNorthern blot analysis and DNA sequencing results, we concludedthat bglA is the gene that encodes $beta$ -glucosidase CB-1.

Cloning of bglA cDNA. Following the cloning of genomic bglA, we performed a Northern blot analysis to examine expression of the bglA gene (Fig.1). Expression of bglA was not observed in a 1-day-old culturebut was observed in 2- to 4-day-old cultures (Fig. 1, lanes 2through 4). Since the greatest intensity was observed in the 3-day-oldculture, we purified mRNA from mycelia in this culture and clonedbglA cDNA by the 5'- and 3'-RACE method. Fifteen clones of 5'-and 3'-RACE products were isolated. All of the 5'- and 3'-RACEproducts isolated were sequenced in order to verify the cDNA sequence,and no errors were detected in any of the 5'- and 3'-RACE products.The longest 5'-RACE product and the longest 3'-RACE product wereligated to isolate full-length bglA cDNA.

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FIG. 1. Northern blot analysis of bglA of A. kawachii IFO4308. Total RNA was isolated from mycelia after growth for 1 day (lane 1), 2 days (lane 2), 3 days (lane 3), and 4 days (lane 4) (5 µg per lane). Hybridization was performed by using a ³²P-labeled SalI-SalI fragment of genomic bglA. The positions of rRNAs are indicated on the right.

Southern blot analysis. Figure 2 shows the results of a Southern blot analysis of A. kawachii genomic DNA. In all of the samples digested with BamHI,EcoRI, or HindIII, one strong band was observed. This result indicatedthat the A. kawachii genomic DNA did not contain any genes thatwere homologous to the bglA gene of A. kawachii.

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FIG. 2. Southern blot analysis of A. kawachii genomic DNA. Genomic DNA was digested with BamHI (lane 1), EcoRI (lane 2), or HindIII (lane 3). Hybridization was performed overnight at 65°C by using a ³²P-labeled SalI-SalI fragment of genomic bglA as a probe, and the membrane was washed three times for 30 min in 2× SSC-1% SDS at 65°C (1× SSC is 0.15 M NaCl plus 0.015 M sodium citrate).

Nucleotide sequence analysis. The bglA nucleotide sequence contained a 2,933-bp open reading frame (ORF) which encoded 860 amino acids and was interruptedby six introns. The bglA product had a predicted molecular weightof 91,000 and 14 possible N-glycosylationsites.

Partial amino acid sequences P1, P2, and P3 were recognized from Gly-178 to Lys-189, from Asn-405 to Lys-414, and from Thr-603to Gly-618, respectively. The N-terminal amino acid sequence wasrecognized from Asp-20 to Pro-32. Consequently, we hypothesizedthat the 19-amino-acid peptide from Met-1 to Ala-19 is a signalpeptide.

The bglA gene was interrupted by six introns. All of the introns started with GT and ended with AG; these sequences are knownto be general features ofintrons.

In the upstream region, a TATAA-like sequence was present at position $-$ 137; this sequence is known to be required for transcriptioninitiation by RNA polymerase II in higher eukaryotes. Three CCAATsequences were present at positions $-$ 341, $-$ 655, and $-$ 668. We isolated15 5'-RACE products, 3 of which had longer 5'-end-flanking regionsthan the others. The 5'-end-flanking regions of these three clonesstarted 85 bases upstream of the initiation codon. Five CREA bindingsites (5'-[G/C][C/T]GG[G/A]G-3') were present at positions $-$ 226, $-$ 526, $-$ 609, $-$ 687, and $-$ 752 (9, 10, 41, 43). This sequenceis known to be required for CREA to mediate carbon cataboliterepression.

In the 3'-end-flanking region of bglA, a putative polyadenylation signal, AATAAA, was present at position 2,978. The poly(A)tail started 11 bases downstream of the polyadenylationsignal.

Comparison of amino acid sequences. We searched the SwissProt database for sequences similar to the deduced amino acid sequence of bglA. Significant levels ofsimilarity were found with $beta$ -glucosidases from Aspergillus aculeatus(21), S. fibuligera (bgl1 and bgl2) (25), C. pelliculosa (22),Kluyveromyces fragilis (34), Agrobacterium tumefaciens (8),Clostridum thermocellum (12), and T. reesei (1). A. aculeatusbgl1 exhibited the highest level of homology (81%) with A. kawachiibglA. All of these enzymes have been classified in the same family, $beta$ -glucosidase subfamily B, according to Rojas et al. (this subfamilyincludes yeast and fungal $beta$ -glucosidases, while subfamily A includesvegetal and prokaryotic $beta$ -glucosidases) (35).

The amino acid sequences of the $beta$ -glucosidases of A. kawachii, A. aculeatus, C. pelliculosa, S. fibuligera (bgl1) and T. reeseiare aligned in Fig. 3. Rojas et al. identified the following eightconserved sequences in subfamily B $beta$ -glucosidases: DGP, GRNFE,DPYL, KHF, SDW, GLD, VLLKN, and FGYLSY (Fig. 3) (36). Each ofthese sequences was found in the $beta$ -glucosidase of A. kawachii.We designed the DNA sequence of primer 2 on the basis of the conservedsequence of C. pelliculosa $beta$ -glucosidases. This region was theregion from Gly-275 to Ala-283, and it was conserved in otherfungal $beta$ -glucosidases. The SDW motif was included in this region.Legler et al. reported that the Asp residue of the SDW motif inthe $beta$ -glucosidase of A. wentii is the active site (24). Thisregion, including the SDW motif, is used as a signature regionfor the active site of glycosyl hydrolase family 3 enzymes (accessionno. PS00775) by the PROSITE data bank (42a). Based on these results,we concluded that the A. kawachii $beta$ -glucosidase is a subfamilyB $beta$ -glucosidase.

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FIG. 3. Alignment of the amino acid sequence of A. kawachii $beta$ -glucosidase with the amino acid sequences of other fungal $beta$ -glucosidases. Amino acid residues are indicated by single-letter codes. Alignment was maximized by introducing gaps, which are indicated by dashes. The numbers indicate the multiple alignment positions from the N terminus. Conserved residues are shaded. The solid bars indicate the regions conserved in $beta$ -glucosidase subfamily B, and the open bar indicates an SDW motif. Stars indicate the putative active site (Asp) and proton donor (His). Abbreviations: AK BGKA, A. kawachii bglA; AA BGL1, A. aculeatus bgl1 (DDBJ/EMBL/GenBank accession no. D64088); SF BGL1, S. fibuligera bgl1 (SwissProt/GenBank/PIR accession no. P22506/M22475); TR BGL1, T. reesei bgl1 (DDBJ/EMBL/GenBank accession no. U09580).

Expression of bglA cDNA in S. cerevisiae. The bglA cDNA was expressed in S. cerevisiae YPH499 under the control of the glyceraldehyde-3-diphosphate dehydrogenase promoterand the phosphoglycerate kinase (PGK) terminator in multicopyexpression plasmid pG-1. However, $beta$ -glucosidase production wasnot observed (Fig. 4). One possible reason for this result isthat the signal sequence of A. kawachii $beta$ -glucosidase was notfunctional in the S. cerevisiae transformant. Therefore, we usedthe signal sequence from K. lactis (7) instead of the originalbglA signal sequence. The bglA gene with the exchanged signalsequence was expressed under the control of the PGK promoter andthe PGK terminator. As a result, bright fluorescence due to releasedmethlyumbelliferyl was observed with the cells transformed withpYKBA1 (Fig. 4). On the basis of these results, we concluded thatthe bglA gene encodes the $beta$ -glucosidase of A. kawachii.

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FIG. 4. Expression of bglA in yeast. S. cerevisiae YPH499 was transformed with pG-1, pGBGA1, pYEX-S1, and pYBGA1. Three independent cultures transformed with each plasmid were streaked onto YNBD agar plates and incubated at 30°C for 2 days (A). These plates were overlaid with 0.75% agarose containing 10 mM 4-methylumbelliferyl- $beta$ -D-glucose and were incubated for 5 min at room temperature. $beta$ -Glucosidase activity was detected by UV-stimulated fluorescence of cleaved substrates (B).

Characterization of the yeast transformants. The transformants containing pYEX-S1 or pYKBA1 were grown in YNBD medium for 24 h. The rate of increase in cell density ofthe recombinant strain containing pYKBA1, as measured by determiningthe optical density at 660 nm, was not significantly less thanthe rate of increase in cell density of the control recombinantstrain containing pYEX-S1 (data not shown). In addition, microscopicexamination revealed no morphological changes in the cells. Theseresults indicated that production of recombinant $beta$ -glucosidasedid not adversely affect the growth of theyeast.

To better understand the localization of recombinant $beta$ -glucosidase production, yeast cells were fractionated, and $beta$ -glucosidaseactivity was measured by using PNPG as a substrate. Almost allof the $beta$ -glucosidase activity was found in the periplasmic fractionof the recombinant yeast culture, and only a small amount wassecreted into the medium (Table 1). As determined by Westernblot analysis, the recombinant $beta$ -glucosidase was not present inthe broth fraction (Fig. 5, lane 1), but it was present in thewhole-cell fraction (Fig. 5, lane 2), and it had an apparent molecularweight of 120,000. We assumed that this molecular weight, whichis greater than the calculated molecular weight (91,000), wasdue to N-linked glycosylation.

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TABLE 1. Localization of recombinant $beta$ -glucosidase in yeast

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FIG. 5. Western blot analysis of recombinant $beta$ -glucosidase produced by a yeast transformant. The transformant was incubated in YNBD medium at 30°C for 1 day. The protein in the culture medium (lanes 1 and 3) and cell lysate (lanes 2 and 4) was detected by performing a Western blot analysis with anti- $beta$ -glucosidase antiserum. Lanes M contained high-molecular-mass markers.

$beta$ -Glucosidase assays performed with the recombinant cells revealed that the enzyme was satiable at pH values ranging from2.0 to 9.0 and at temperatures lower than 30°C (data notshown).

Disruption of bglA. A. kawachii produces two extracellular $beta$ -glucosidases, EX-1 (145 kDa) and EX-2 (130 kDa), in addition to one cell wall-bound $beta$ -glucosidase (CB-1). Our previous results suggested that thesethree $beta$ -glucosidases are products of the same gene. To examinethis possibility, we attempted to disrupt the bglA gene of A.kawachii by using sC strain SC60 and the A. nidulans sC gene as a selective marker.A 2.8-kbp SacI-SacI fragment containing the promoter region andpart of the ORF of the bglA gene was replaced by the sC gene fromA. nidulans.

We investigated nine transformants by performing a Southern blot analysis to screen for the bglA-deleted strain. With thewild-type bglA strain (SC60), the signal should have been observedat a position corresponding to 2.3 kbp (Fig. 6, lane A). Whenthe bglA gene was disrupted by homologous recombination with theintroduced DNA fragment, the signal should have been shifted to3.8 kbp (Fig. 6, lane B). When the introduced DNA fragment wasintegrated into a different locus of bglA, two signals shouldhave appeared (Fig. 6, lane C). One of the nine transformantsanalyzed was found to have the hybridization pattern associatedwith a disrupted bglA gene (Fig. 6, lane B). We designated thistransformant strain BAD574.

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FIG. 6. Gene structure and Southern blot analysis of A. kawachii IFO4308 (wild-type) bglA (A), a bglA disruptant (B), and a nonhomologous recombinant (C). Isolated genomic DNA was digested by PstI, and then a Southern blot analysis was performed by using a 368-bp PstI-SacI bglA fragment as the probe. Lane M contained a DNA molecular marker ( $lambda$ HindIII digest and $phi$ 174 HaeIII digest). The open box indicates the bglA ORF. The stippled boxes indicate 5'- and 3'-end-flanking regions. The hatched boxes indicate the sC gene of A. nidulans. The solid boxes indicate the regions where the probe bound.

Characterization of the bglA disruptant. Both the extracellular and cell wall-bound $beta$ -glucosidase activities of the bglA disruptant were measured to determine whetherboth types of $beta$ -glucosidases are encoded by bglA. The cell wall-bound $beta$ -glucosidase activity of the bglA disruptant was at least 80%lower than the cell wall-bound $beta$ -glucosidase activity of the wild-typestrain in both liquid and solid cultures (Fig. 7). However, whatwas the source of the remaining $beta$ -glucosidase activity in thebglA disruptant? DEAE ion-exchange chromatography of the solubilizedcell-bound enzymes from the wild-type strain, the sC mutant strain, and the pUSC-transformed sC mutant strain resulted in a peak with a retention time of 25min in each case (Fig. 8A). However, this peak was absent in thebglA-disrupted strain, and a minor peak was observed at 20 min.Moreover, a Western blot analysis of the bglA disruptant in whichanti- $beta$ -glucosidase CB-1 antiserum was used revealed no $beta$ -glucosidasesignal (Fig. 8B). These results show that $beta$ -glucosidase CB-1 wasnot produced by the bglA disruptant. Thus, the remaining $beta$ -glucosidaseactivity was produced by another gene that is not homologous tobglA.

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FIG. 7. Production of extracellular and cell wall-bound $beta$ -glucosidases by different strains of A. kawachii in liquid and solid media. IFO4308 was a wild-type strain; SC60 was an sC strain; NASC was an SC60 strain transformed with the A. nidulans sC gene; and BAD574 was a bglA disruptant. Each strain was incubated in basic medium containing 1% glucose and 2% xylan (liquid culture) at 30°C for 3 days or on steamed rice grains for 2 days. $beta$ -Glucosidase activity was measured by using PNPG as the substrate.

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FIG. 8. Analysis of cell wall-bound $beta$ -glucosidase in the bglA disruptant. Each strain was incubated in basic medium containing 1% glucose and 2% xylan (liquid culture) at 30°C for 3 days. The mycelia were washed and lysed by using Yatalase (Takara) in isoosmotic buffer for 3 h and then centrifuged. The supernatant was isolated and used as a sample. (A) Elution profile of cell wall-bound $beta$ -glucosidase activity obtained with a DEAE-5PW column. The open triangle indicates the main peak at an elution time of 25 min, and the solid triangle indicates a minor peak at an elution time of 20 min. (B) Western blot analysis of cell wall-bound $beta$ -glucosidase. Cell wall lysates were detected with anti- $beta$ -glucosidase antiserum. Lane 1, A. kawachii IFO4308; lane 2, BAD574; lane M, molecular mass markers. The solid triangle indicates the band corresponding to $beta$ -glucosidase.

Production of extracellular $beta$ -glucosidase was not observed in liquid cultures, and the amount produced was less than 1% ofthe amount produced by the wild-type bglA strains in solid cultures(Fig. 7). Moreover, a Western blot analysis of the extracellularfraction of the solid culture in which anti- $beta$ -glucosidase antiserumwas used revealed no signal with the bglA disruptant (data notshown). These results clearly indicate that the extracellular $beta$ -glucosidases are also encoded by the bglAgene.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The results obtained in this study indicate that the bglA gene of A. kawachii encodes both extracellular $beta$ -glucosidases andcell wall-bound $beta$ -glucosidase CB-1.

Although one $beta$ -glucosidase cDNA has been isolated from an Aspergillus species (A. aculeatus) and described, its genomic sequencehas not been described. In the present study, we determined thepositions of the introns and the sequence of the bglA promoterregion. The first intron interrupts the signal peptide and N-terminalamino acid sequence of the mature protein, and the other intronsare in the mature protein. In contrast, the $beta$ -glucosidase of thefilamentous fungus T. reesei (bgl1) has only two introns, andtheir positions are different from the positions of the A. kawachiibglAintrons.

The mature BglA protein consists of 842 amino acids and has an apparent molecular weight of 91,000. However, the molecularweight of $beta$ -glucosidase CB-1 was determined to be 120,000 by SDS-polyacrylamidegel electrophoresis. $beta$ -Glucosidase CB-1 is known to be a glycoprotein,so the difference in molecular weight is most likely due to thecarbohydrate portion. Fourteen potential N-glycosylation siteswere found in the predicted amino acid sequence of BglA. We previouslydetermined the molecular weight of $beta$ -glucosidase CB-1 after weeliminated N-linked sugar chains by using N-endo- $beta$ -acetylglucosaminidaseH. The molecular weight (98,000) agreed well with the predictedmolecular mass of the BglAprotein.

In a previous paper (19), we described purification and some of the characteristics of the two extracellular $beta$ -glucosidasesof A. kawachii (EX-1 and EX-2). The molecular masses of theseproteins were different from the molecular mass of $beta$ -glucosidaseCB-1, but the three proteins have the same N-terminal amino acidsequence. When both the extracellular and cell wall-bound $beta$ -glucosidaseswere treated with N-endo- $beta$ -acetylglucosaminidase, the molecularmasses were the same, 98 kDa. Moreover, all of the enzymatic propertiesof these three enzymes were identical. These results suggest thatthe two extracellular $beta$ -glucosidases are also encoded by bglAand are modified by different degrees of glycosylation. The resultsobtained with the bglA disruptant clearly showed that the bglAgene encodes both extracellular $beta$ -glucosidases (EX-1 and EX-2)and a cell wall-bound $beta$ -glucosidase (CB-1) and is the major $beta$ -glucosidasegene in A. kawachii.

The extracellular $beta$ -glucosidases and cell wall-bound $beta$ -glucosidase are encoded by the same gene, despite the different destinationsof the enzymes. Culture conditions were found to affect the destinationof BglA. In liquid cultures, about 80% of the $beta$ -glucosidase activitywas attributed to cell wall-bound $beta$ -glucosidase (Fig. 7). In aprevious study, we found that cell wall-bound $beta$ -glucosidase CB-1adsorbed tightly, but not covalently, to the cell wall fractionof A. kawachii and consequently localized in the cell wall fraction.Furthermore, when we expressed the cDNA of bglA in yeast, mostof the recombinant BglA proteins were localized in the yeast periplasmicfraction, and only small amounts of the $beta$ -glucosidases were secretedinto the medium. Based on these results, we suspect that the recombinantBglA protein adsorbs to the cell wall and consequently is localizedin the cell wall fraction of yeast cells. On the other hand, insolid cultures, about 80% of the $beta$ -glucosidase activity was attributedto extracellular $beta$ -glucosidase. Purified extracellular $beta$ -glucosidasesalso adsorbed tightly to the purified cell wall fraction of A.kawachii. Some soluble cell wall material seemed to be involvedin the location of these enzymes. However, it is still not clearwhether the three $beta$ -glucosidases are translated from the samemRNA transcribed from the bglA gene. Some types of posttranscriptionalmodification, such as processing, different ways of splicing,partial duplication of transcription, etc., may be involved. Additionalexperiments are needed to more fully understand the factors thatregulate the activity and control the destination of $beta$ -glucosidases.Additional studies of bglA mRNA transcription in solid culturesare needed to understand thesefactors.

Ohta et al. reported that the $beta$ -glucosidase of A. kawachii has a role in flavor formation during production of sweet potatoshochu (29, 30). The compounds that most strongly affect theflavor of sweet potato shochu are linalool, $alpha$ -terpineol, citronellol,nerol, and geranol. However, these compounds are also presentin the form of two nonvolatile precursors in sweet potato, neryl- $beta$ -glucosideand geranyl- $beta$ -glucoside. These terpenyl- $beta$ -glucosides are hydrolyzedby shochu koji $beta$ -glucosidases in the shochu mash. The liberatedaglycons, which are nerol and geraniol, are transformed into citronellolby the shochu yeast in the shochu mash and into linalool and $alpha$ -terpineolby acid and heat during distillation. As a result, there are severalfree monoterpene alcohols that contribute to the sweet potatoshochu flavor. Thus, the $beta$ -glucosidase of A. kawachii is the keyenzyme that affects flavor formation during production of sweetpotato shochu. Almost all of the $beta$ -glucosidase activity (about95% in a solid culture) is due to the enzyme encoded by bglA.Thus, it should be possible to regulate flavor formation in sweetpotato shochu by controlling bglA geneexpression.

When A. kawachii was grown in solid cultures in which rice or barley was used as the medium, the production of $beta$ -glucosidasewas 5- to 10-fold higher than the production in liquid cultureswhen xylan and xylose were used. In addition, Ohta et al. reportedthat production of $beta$ -glucosidase rapidly increased in the latephase of cultures and was greater at low temperatures than athigh temperatures (31). In view of these results, numerous factorsmust be involved in the regulation of bglA expression. We arecurrently attempting to determine how such factors control theproduction of $beta$ -glucosidase.

	ACKNOWLEDGMENT

We are very grateful to Tadaaki Hashimoto for helpfuldiscussions.

	FOOTNOTES

^* Corresponding author. Mailing address: National Research Institute of Brewing, 7-3-1, Kagamiyama, Higashihiroshima, Hiroshima739-0046, Japan. Phone: 81-824-20-0800. Fax: 81-824-20-0809. E-mail:iwasita{at}nrib.go.jp.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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2. Becker, D. M., and L. Guarente. 1991. High-efficiency transformation of yeast by electroporation. Methods Enzymol. 194:182-187[Medline].

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6. Buxton, F. P., D. I. Gwynne, and R. W. Davies. 1989. Cloning of a new bidirectionally selectable marker for Aspergillus strains. Gene 84:329-334[Medline].

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8. Castle, L. A., K. D. Smith, and R. O. Morris. 1992. Cloning and sequencing of an Agrobacterium tumefaciens $beta$ -glucosidase gene involved in modifying a vir-inducing plant signal molecule. J. Bacteriol. 174:1478-1486[Abstract/Free Full Text].

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1.	Barnett, C. C., R. M. Berka, and T. Fowler. 1991. Cloning and amplification of the gene encoding an extracellular $beta$ -glucosidase from Trichoderma reesei: evidence for improved rates of saccharification of cellulosic substrates. Bio/Technology 9:562-567[Medline].
2.	Becker, D. M., and L. Guarente. 1991. High-efficiency transformation of yeast by electroporation. Methods Enzymol. 194:182-187[Medline].
3.	Béguin, P. 1990. Molecular biology of cellulose degradation. Annu. Rev. Microbiol. 44:219-248[Medline].
4.	Béguin, P., and J. P. Aubert. 1994. The biological degradation of cellulose. FEMS Microbiol. Rev. 13:25-58[Medline].
5.	Bhat, K. M., J. S. Gaikwad, and R. Maheshwari. 1993. Purification and characterization of an extracellular $beta$ -glucosidase from the thermophilic fungus S. thermophile and its influence on cellulase activity. J. Gen. Microbiol. 139:2825-2832.
6.	Buxton, F. P., D. I. Gwynne, and R. W. Davies. 1989. Cloning of a new bidirectionally selectable marker for Aspergillus strains. Gene 84:329-334[Medline].
7.	Castelli, L. A., C. J. Mardon, P. M. Strike, A. A. Azad, and I. G. Macreadie. 1994. High-level secretion of correctly processed $beta$ -lactamase from Saccharomyces cerevisiae using a high-copy-number secretion vector. Gene 142:113-117[Medline].
8.	Castle, L. A., K. D. Smith, and R. O. Morris. 1992. Cloning and sequencing of an Agrobacterium tumefaciens $beta$ -glucosidase gene involved in modifying a vir-inducing plant signal molecule. J. Bacteriol. 174:1478-1486[Abstract/Free Full Text].
8a.	DNA Data Bank of Japan. 21 September 1999, revision date. Database searches. [Online.] http://www.ddbj.nig.ac.jp/. [2 April 1999, last date accessed.]
9.	Dowzer, C. E., and J. M. Kelly. 1989. Cloning of the creA gene from Aspergillus nidulans: a gene involved in carbon catabolite repression. Curr. Genet. 15:457-459[Medline].
10.	Drysdale, M. R., S. E. Kolze, and J. M. Kelly. 1993. The Aspergillus niger carbon catabolite repressor encoding gene, creA. Gene 130:241-245[Medline].
11.	Enari, T. M., and M. L. Niku-Paavola. 1987. Enzymatic hydrolysis of cellulose. Is the current theory of the mechanisms of hydrolysis valid? Crit. Rev. Biothechnol. 5:67-87.
11a.	Genome Net Website. 25 September 1997, revision date. FASTA program. [Online.] http://www.genome.ad.jp/. [2 April 1999, last date accessed.]
12.	Grabnitz, F., K. P. Rucknagel, M. Seiss, and W. L. Staudenbauer. 1989. Nucleotide sequence of the Clostridium thermocellum bgIB gene encoding thermostable $beta$ -glucosidase B: homology to fungal $beta$ -glucosidases. Mol. Gen. Genet. 217:70-76[Medline].
13.	Gunata, Y. Z., C. L. Bayonove, R. L. Baumes, and R. E. Cordonnier. 1985. The aroma of grapes. I. Extraction and determination of free and glycosidically bound fractions of some grape aroma components. J. Chromatogr. 331:83-90.
14.	Hata, Y., K. Kitamoto, K. Gomi, C. Kumagai, G. Tamura, and S. Hara. 1991. The glucoamylase cDNA from Aspergillus oryzae: its cloning, nucleotide sequence, and expression in Saccharomyces cerevisiae. Agric. Biol. Chem. 55:941-949[Medline].
15.	Iimura, Y., K. Gomi, H. Uzu, and S. Hara. 1987. Transformation of Aspergillus oryzae through plasmid-mediated complementation of the methionine-auxotrophic mutation. Agric. Biol. Chem. 51:323-328.
16.	Ito, K., T. Ikemasu, and T. Ishikawa. 1992. Cloning and sequencing of the xynA gene encoding xylanase A of Aspergillus kawachii. Biosci. Biotechnol. Biochem. 56:906-912[Medline].
17.	Ito, K., K. Iwashita, and K. Iwano. 1992. Cloning and sequencing of the xynC gene encoding acid xylanase of Aspergillus kawachii. Biosci. Biotechnol. Biochem. 56:1338-1340[Medline].
18.	Ito, K., H. Ogasawara, T. Sugimoto, and T. Ishikawa. 1992. Purification and properties of acid stable xylanases from Aspergillus kawachii. Biosci. Biotechnol. Biochem. 56:547-550.
19.	Iwashita, K., K. Todoroki, H. Kimura, H. Shimoi, and K. Ito. 1998. Purification and characterization of extracellular and cell wall bound $beta$ -glucosidases from Aspergillus kawachii. Biosci. Biotechnol. Biochem. 62:1938-1946[Medline].
20.	Kamei, K., Y. Yamamura, S. Hara, and T. Ikenaka. 1989. Amino-acid sequence of chitinase from Streptomyces erythraeus. J. Biochem. 105:979-985[Abstract/Free Full Text].
21.	Kawaguchi, T., T. Enoki, S. Tsurumaki, J. Sumitani, M. Ueda, T. Ooi, and M. Arai. 1996. Cloning and sequencing of the cDNA encoding $beta$ -glucosidase 1 from Aspergillus aculeatus. Gene 173:287-288[Medline].
22.	Kohchi, C., and A. Toh-e. 1985. Nucleotide sequence of Candida pelliculosa $beta$ -glucosidase gene. Nucleic Acids Res. 13:6273-6282[Abstract/Free Full Text].
23.	Lecas, M., Z. Y. Gunata, J. Sapis, and C. L. Bayonove. 1991. Purification and partial characterization of $beta$ -glucosidase from grape. Phytochemistry 30:451-454.
24.	Legler, G., K. R. Roeser, and H. K. Illig. 1979. Reaction of $beta$ -D-glucosidase A3 from Aspergillus wentii with D-glucal. Eur. J. Biochem. 101:85-92[Medline].
25.	Machida, M., I. Ohtsuki, S. Fukui, and I. Yamashita. 1988. Nucleotide sequences of Saccharomycopsis fibuligera genes for extracellular $beta$ -glucosidases as expressed in Saccharomyces cerevisiae. Appl. Environ. Microbiol. 54:3147-3155[Abstract/Free Full Text].
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The bglA Gene of Aspergillus kawachii Encodes Both Extracellular and Cell Wall-Bound -Glucosidases

The bglA Gene of Aspergillus kawachii Encodes Both Extracellular and Cell Wall-Bound $beta$ -Glucosidases