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ABSTRACT: Glycoside hydrolase family 3 (GH3) beta-glucosidases (BGLs) from filamentous fungi have been widely and commercially used for supplementation of cellulases. BGL from the fungus Aspergillus aculeatus (AaBGL1) belongs to GH3 and shows high activity toward cellooligosaccharides up to high degree of polymerization. Here we determined the crystal structure of AaBGL1. In addition to the substrate-free structure, complex structures with glucose and various inhibitors were determined. The AaBGL1 structure is highly glycosylated with 88 monosaccharides (18 N-glycan chains) in the dimer. The largest N-glycan chain comprises 10 monosaccharides and is one of the largest glycans ever observed in protein crystal structures. A prominent insertion region exists in a fibronectin type III domain, and this region extends to cover a wide surface area of the enzyme. The subsite +1 of AaBGL1 is highly hydrophobic. Three aromatic residues are involved in the subsite +1 and located in short loop regions that are uniquely present in this enzyme. There is a long cleft extending from the subsite +1, which appears to be suitable for binding long cellooligosaccharides. The crystal structures of AaBGL1 will provide an important structural basis for the technical improvement of enzymatic cellulosic biomass conversion.
Biochemical Journal 03/2013; · 4.90 Impact Factor
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ABSTRACT: Auxotrophic mutants of Aspergillus can be isolated in the presence of counter-selective compounds, but the process is laborious. We developed a method to enable reversible impairment of the ku80 gene (Aaku80) in the imperfect fungus Aspergillus aculeatus. Aaku80 was replaced with a selection marker, orotidine 5'-phosphate decarboxylase (pyrG), followed by excision of pyrG between direct repeats (DR) to yield the Aaku80 deletion mutant (MR12). The gene-targeting efficiency at the ornithine carbamoyltransferase (argB) locus was drastically elevated from 3% to 96% in MR12. The frequency of marker recycling depended on DR length. One uridine auxotroph was obtained from 3.3 x 105, 1.4 x 105, and 9.2 x 103 conidia from strains harboring 20-, 98-, and 495-bp DRs, respectively. Because these strains maintained the short DRs after 5 d of cultivation, we investigated whether Aaku80 function was disrupted by pyrG insertion with the 20-bp DR and restored after excision of pyrG. The Aaku80 disruption mutant (coku80) was bred by inserting pyrG sandwiched between 20-bp DRs into the second intron of Aaku80, followed by excision of pyrG between the DRs to yield the coku80rec strain. Analyses of homologous recombination frequency and methyl methanesulfonate sensitivity demonstrated that Aaku80 function was disrupted in coku80 but restored in coku80rec. Furthermore, pyrG was maintained in coku80 at least for ten generations. These data indicated that reversible impairment of ku80 in A. aculeatus is useful for functional genomics in cases where genetic segregation is not feasible.
AMB Express. 01/2013; 3(1):4.
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ABSTRACT: Although the capabilities of Trichoderma reesei cellulases have been greatly improved, these enzymes are still too costly for commercial use. The aim of this research was to assess the biomass saccharification capability of JN11, a recombinant cellulase, compared with that of the commercially available cellulases Accellerase 1500 and Cellic CTec. The activities of JN11, Accellerase 1500, and Cellic CTec were compared by using various types of cellulosic biomass, including rice straw, Erianthus, eucalyptus, and Japanese cedar. JN11 had higher saccharification capability for rice straw, Erianthus, eucalyptus, and Japanese cedar compared with the commercial cellulases. The JN11 saccharification of cellulosic biomasses, including hemicellulose (NaOH-pretreated biomasses), resulted in high glucose and xylose yields because of the high xylanase/xylosidase activity of JN11. Moreover, even JN11 saccharification of hemicellulose-free biomasses (sulfuric acid-, hydrothermally, and steam exploded-pretreated biomasses) resulted in high glucose yields. The cellulase activity of JN11, however, was comparable to that of its commercial counterparts. These findings indicate that the saccharification ability of cellulase is unrelated to its cellulase activity when measured against Avicel, CMC, pNP-lactoside, and other substrates. JN11 showed high activity for all types of pretreated cellulosic biomasses, indicating its usefulness for saccharification of various cellulosic biomasses.
Journal of Industrial Microbiology 09/2012; · 1.80 Impact Factor
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ABSTRACT: The cellobiose- and cellulose-responsive induction of the FIII-avicelase (cbhI), FII-carboxymethyl cellulase (cmc2), and FIa-xylanase (xynIa) genes is not regulated by XlnR in Aspergillus aculeatus, which suggests that this fungus possesses an unknown cellulase gene-activating pathway. To identify the regulatory factors involved in this pathway, we constructed a random insertional mutagenesis library using Agrobacterium tumefaciens-mediated transformation of A. aculeatus NCP2, which harbors a transcriptional fusion between the cbhI promoter (P ( CBHI )) and the orotidine 5'-phosphate decarboxylase gene (pyrG). Of the ~6,000 transformants screened, one 5-FOA-resistant transformant, S4-22, grew poorly on cellulose-containing media and exhibited reduced cellobiose-induced expression of cbhI. Southern blot analysis and nucleotide sequencing of the flanking regions of the T-DNA inserted in S4-22 indicated that the T-DNA was inserted within the coding region of a previously unreported Zn(II)(2)Cys(6)-transcription factor, which we designated the cellobiose response regulator (ClbR). The disruption of the clbR gene resulted in a significant reduction in the expression of cbhI and cmc2 in response to cellobiose and cellulose. Interestingly, the cellulose-responsive induction of FI-carboxymethyl cellulase (cmc1) and FIb-xylanase (xynIb) genes that are under the control of XlnR, was also reduced in the clbR-deficient mutant, but there was no effect on the induction of these genes in response to D: -xylose or L: -arabinose. These data demonstrate that ClbR participates in both XlnR-dependent and XlnR-independent cellobiose- and cellulose-responsive induction signaling pathways in A. aculeatus.
Applied Microbiology and Biotechnology 08/2012; · 3.42 Impact Factor
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ABSTRACT: The expression levels of the cellulase and xylanase genes between the host strain and an xlnR disruptant were compared by quantitative RT-PCR (qPCR) to identify the genes controlled by XlnR-independent signaling pathway. The cellulose induction of the FI-carboxymethyl cellulase (cmc1) and FIb-xylanase (xynIb) genes was controlled by XlnR; in contrast, the cellulose induction of the FIII-avicelase (cbhI), FII-carboxymethyl cellulase (cmc2), and FIa-xylanase (xynIa) genes was controlled by an XlnR-independent signaling pathway. To gain deeper insight into the XlnR-independent signaling pathway, the expression profile of cbhI was analyzed as a representative target gene. Cellobiose together with 1-deoxynojirimycin (DNJ), a glucosidase inhibitor, induced cbhI the most efficiently among disaccharides composed of β-glucosidic bonds. Furthermore, cellobiose with DNJ induced the transcription of cmc2 and xynIa, whereas cmc1 and xynIb were not induced. GUS reporter fusion analyses of truncated and mutated cbhI promoters revealed that three regions were necessary for effective cellulose-induced transcription, all of which contained the conserved sequence 5'-CCGN(2)CCN(7)G(C/A)-3' within the CeRE, which has been identified as the upstream activating element essential for expression of eglA in A. nidulans (Endo et al. 2008). The data therefore delineate a pathway in which A. aculeatus perceives the presence of cellobiose, thereby activating a signaling pathway that drives cellulase and hemicellulase gene expression under the control of the XlnR-independent regulation through CeRE.
Current Genetics 02/2012; 58(2):93-104. · 2.56 Impact Factor
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ABSTRACT: Agrobacterium tumefaciens-mediated transformation (AMT) was applied to Aspergillus aculeatus. Transformants carrying the T-DNA from a binary vector pBIG2RHPH2 were sufficiently mitotically stable to allow functional genomic analyses. The AMT technique was optimized by altering the concentration of acetosyringone, the ratio and concentration of A. tumefaciens and A. aculeatus cells, the duration of co-cultivation, and the status of A. aculeatus cells when using conidia, protoplasts, or germlings. On average, 30 transformants per 104 conidia or 217 transformants per 107 conidia were obtained under the optimized conditions when A. tumefaciens co-cultured with fungi using solid or liquid induction media (IM). Although the transformation frequency in liquid IM was 100-fold lower than that on solid IM, the AMT method using liquid IM is better suited for high-throughput insertional mutagenesis because the transformants can be isolated on fewer selection media plates by concentrating the transformed germlings. The production of two albino A. aculeatus mutants by AMT confirmed that the inserted T-DNA disrupted the polyketide synthase gene AapksP, which is involved in pigment production. Considering the efficiency of AMT and the correlation between the phenotypes and genotypes of the transformants, the established AMT technique offers a highly efficient means for characterizing the gene function in A. aculeatus.
AMB Express. 12/2011; 1(1):46.
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Hikaru Nakazawa,
Tetsushi Kawai,
Noriko Ida,
Yosuke Shida,
Yoshinori Kobayashi,
Hirofumi Okada, Shuji Tani,
Jun-Ichi Sumitani,
Takashi Kawaguchi,
Yasushi Morikawa,
Wataru Ogasawara
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ABSTRACT: To develop a Trichoderma reesei strain appropriate for the saccharification of pretreated cellulosic biomass, a recombinant T. reesei strain, X3AB1, was constructed that expressed an Aspergillus aculeatus β-glucosidase 1 with high specific activity under the control of the xyn3 promoter. The culture supernatant from T. reesei X3AB1 grown on 1% Avicel as a carbon source had 63- and 25-fold higher β-glucosidase activity against cellobiose compared to that of the parent strain PC-3-7 and that of the T. reesei recombinant strain expressing an endogenous β-glucosidase I, respectively. Further, the xylanase activity was 30% lower than that of PC-3-7 due to the absence of xyn3. X3AB1 grown on 1% Avicel-0.5% xylan medium produced 2.3- and 3.3-fold more xylanase and β-xylosidase, respectively, than X3AB1 grown on 1% Avicel. The supernatant from X3AB1 grown on Avicel and xylan saccharified NaOH-pretreated rice straw efficiently at a low enzyme dose, indicating that the strain has good potential for use in cellulosic biomass conversion processes.
Biotechnology and Bioengineering 08/2011; 109(1):92-9. · 3.95 Impact Factor
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ABSTRACT: A homologous transformation system was developed using the endogenous ATP-sulfurylase gene, AasC, as a selectable marker in Aspergillus aculeatus. Spontaneous mutation was proved to be beneficial in isolating AasC-deficient mutants. Molecular analysis of sC(+) transformants revealed that the frequency of single copy integration at ATP-sulfurylase locus was more than 40%.
Bioscience Biotechnology and Biochemistry 06/2009; 73(5):1197-9. · 1.28 Impact Factor
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ABSTRACT: AmyR is a Zn(II)(2)Cys(6) transcriptional activator that regulates expression of the amylolytic genes in Aspergillus species. Subcellular localization studies of GFP-fused AmyR in A. nidulans revealed that the fusion protein preferentially localized to the nucleus in response to isomaltose, the physiological inducer of the amylolytic genes. The C-terminal domains of AmyR, designated MH3 (residues 419-496) and MH4 (residues 516-542), were essential for sensing the inducing stimulus and regulating the subcellular localization. The MH2 domain (residues 234-375) located in the middle of AmyR was required for transcriptional activation of the target genes, and the nuclear localization signals were identified within the N-terminal Zn(II)(2)Cys(6) DNA binding motif.
Bioscience Biotechnology and Biochemistry 03/2009; 73(2):391-9. · 1.28 Impact Factor
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ABSTRACT: AmyR is a transcriptional activator in Aspergillus spp. necessary for induction of the amylolytic enzyme genes. It recognizes 5'-CGGN8CGG-3' conserved in a number of the amylolytic gene promoters, and in addition 5'-CGGAAATTTAA-3' in the A. oryzae alpha-amylase promoter. In this report, interaction of AmyR with the 5'-CGGAAATTTAA-3' type binding site in the Taka-amylase gene (taaG2) promoter was precisely characterized by DNase I footprinting analysis and electrophoretic mobility shift assay in vitro, and also by examination of the in vivo activity of the mutated promoters. The in vitro and in vivo analyses indicated that two AmyR molecules bind cooperatively to the 5'-CGGAAATTTAA-3' sequence by recognizing the CGG triplet at the 5'-end and the AGG triplet just downstream of the sequence.
Bioscience Biotechnology and Biochemistry 10/2004; 68(9):1906-11. · 1.28 Impact Factor
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ABSTRACT: The Aspergillus nidulans amyR gene and its cDNA were cloned and sequenced. The genomic gene comprised 2,092 bp, interrupted by two short introns, and encoded
a cys-6 zinc transcriptional activator (AMYR) of 662 amino acid residues with a calculated molecular mass of 72,862 Da. Disruption
of the amyR gene caused defects in the utilization of maltose and starch and abolished expression of the taaG2 gene encoding A. oryzae Taka-amylase A, which is inducibly and abundantly expressed in the wild-type A. nidulans. Expression of the amyR gene was under the control of the carbon catabolite repressor, CREA. The growth defect of the malA1 mutant on maltose was complemented by the amyR gene; and the amyR gene derived from the mutant possessed a single mutation, from A to T, at position 1,483, resulting in a substitution of
His478 to Leu. These results indicate that the amyR gene is identical to the genetically defined malA gene. AMYR possessed five domains (Zn and MH1–MH4) homologous to Mal63p, a transcriptional activator for the genes involved
in maltose utilization in Saccharomyces cerevisiae. The His478 to Leu substitution lay within the MH3 domain, corresponding to the negative regulatory domain of Mal63p which
relieves the inhibitory effect on the activation function in response to maltose.
Current Genetics 01/2001; 39(1):10-15. · 2.56 Impact Factor
