Nucleotide sequences of Saccharomycopsis fibuligera genes for extracellular beta-glucosidases as expressed in Saccharomyces cerevisiae

We isolated two genes for extracellular beta-glucosidase, BGL1 and BGL2, from the genomic library of the yeast Saccharomycopsis fibuligera. Gene products (BGLI and BGLII) were purified from the culture fluids of Saccharomyces cerevisiae transformed with BGL1 and BGL2, respectively. Molecular weights of BGLI and BGLII were estimated to be 220,000 and 200,000 by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The two beta-glucosidases showed the same enzymatic characteristics, such as thermo-denaturation kinetics and dependencies on pH and temperature, but quite different substrate specificities: BGLI hydrolyzed cellobiose efficiently, but BGLII did not. This result is consistent with the observation that the S. cerevisiae transformant carrying BGL1 fermented cellobiose to ethanol but the transformant carrying BGL2 did not. Southern blot analysis revealed that the two beta-glucosidase genes were derived from Saccharomycopsis fibuligera and that the nucleotide sequences of the two genes are closely related. The complete nucleotide sequences of the two genes were determined. BGL1 and BGL2 encode 876- and 880-amino-acid proteins which were shown to be highly similar to each other. The putative precursors begin with hydrophobic segments that presumably act as signal sequences for secretion. Amino acid analysis of the purified proteins confirmed that BGL1 and BGL2 encode BGLI and BGLII, respectively.     

Simultaneous saccharification and fermentation of acid-pretreated corncobs with a recombinant Saccharomyces cerevisiae expressing beta-glucosidase

To reduce the cellobiose inhibition of exoglucanase and endogulcanase and enhance cellulose hydrolysis during simultaneous saccharification and fermentation (SSF), a beta-glucosidase encoding gene named BGL1 was cloned from Saccharomycopsis fibuligera and integrated into the chromosomal rDNA region of the Saccharomyces cerevisiae industrial strain NAN-27 producing NAN-227. Compared with the parental strain, which had no detectable activity, the beta-glucosidase specific activity in NAN-227 was 1.02 IU/mg of protein. When cellobiose was used as the sole carbon source in a shake-flask, NAN-227 consumed 6.2g/L of cellobiose and produced 3.3g/L of ethanol in 48 h. The yield was 0.532 g/g. The parent strain only consumed 1.92 g/L of cellobiose and no ethanol was detected. During the SSF of acid-pretreated corncobs NAN-227 produced 20 g/L of ethanol at 72 h, which was similar to the parent strain when 20IU of beta-glucosidase/g of substrate was added.     

Hydrolysis and fermentation of amorphous cellulose by recombinant Saccharomyces cerevisiae

In this study, we expressed two cellulase encoding genes, an endoglucanase of Trichoderma reesei (EGI) and the beta-glucosidase of Saccharomycopsis fibuligera (BGL1), in combination in Saccharomyces cerevisiae. The resulting strain was able to grow on phosphoric acid swollen cellulose (PASC) through simultaneous production of sufficient extracellular endoglucanase and beta-glucosidase activity. Anaerobic growth (0.03h(-1)) up to 0.27gl(-1) DCW was observed on medium containing 10gl(-1) PASC as sole carbohydrate source with concomitant ethanol production of up to 1.0gl(-1). We have thus demonstrated the construction of a yeast strain capable of growth on and one-step conversion of amorphous cellulose to ethanol, representing significant progress towards realization of one-step processing of cellulosic biomass in a consolidated bioprocessing configuration. To our knowledge, this is the first report of a recombinant strain of S. cerevisiae growing on pure cellulose.     

Enzymatic properties and intracellular localization of the novel Trichoderma reesei beta-glucosidase BGLII (cel1A)

This paper describes the characterization of an intracellular beta-glucosidase enzyme BGLII (Cel1a) and its gene (bgl2) from the cellulolytic fungus Trichoderma reesei (Hypocrea jecorina). The expression pattern of bgl2 is similar to that of other cellulase genes known from this fungus, and the gene would appear to be under the control of carbon catabolite repression mediated by the cre1 gene. The BGLII protein was produced in Escherichia coli, and its enzymatic properties were analyzed. It was shown to be a specific beta-glucosidase, having no beta-galactosidase side activity. It hydrolyzed both cellotriose and cellotetraose. BGLII exhibited transglycosylation activity, producing mainly cellotriose from cellobiose and sophorose and cellobiose from glucose. Antibodies raised against BGLII showed the presence of the enzyme in T. reesei cell lysates but not in the culture supernatant. Activity measurements and Western blot analysis of T. reesei strains expressing bgl2 from a constitutive promoter further confirmed the intracellular localization of this beta-glucosidase.     

The nucleotide sequence of the glucoamylase gene GLA1 from Saccharomycopsis fibuligera KZ

The nucleotide sequence of the 2544-bp PstI fragment carrying the glucoamylase gene of Saccharomycopsis fibuligera KZ, designated as GLA1, has been determined. When compared with the nucleotide sequence of the GLU1 gene one nucleotide substitution was found in the 321- bp of the 5'-flanking region: 24 nucleotides were altered within the 1557 bp of the structural gene causing the deduced protein products of both genes to differ in three amino acids in the signal-peptide region and in eight amino acids of the mature protein. Six nucleotide insertions and 27 substitutions were in the 663 bp of the 3'-flanking region. The gene product expressed and secreted in Saccharomyces cerevisiae into the functional enzyme was not homogeneous. In situ detection of the enzyme in a polyacrylamide gel revealed two dominant and three minor bands.     

Purification and characterization of two beta-glucosidases from a thermo-tolerant yeast Pichia etchellsii

The thermo-tolerant yeast Pichia etchellsii produced two cell-wall-bound inducible beta-glucosidases, BGLI (molecular mass 186 kDa) and BGLII (molecular mass 340 kDa), which were purified by a simple, three-step method, comprising ammonium sulfate precipitation, ion-exchange and hydroxyapatite chromatography. The two enzymes exhibited a similar pH and temperature optima, inhibitory effect by glucose and gluconolactone, and stability in the pH range of 3.0-9.0. Placed in family 3 of glycosylhydrolase families, BGLI was more active on salicin, p-nitrophenyl beta-D-glucopyranoside and alkyl beta-D-glucosides whereas BGLII was most active on cellobiose. k(cat) and K(M) values were determined for a number of substrates and, for BGLI, it was established that the deglycosylation step was equally effective on aryl- and alkyl-glucosides while the glycosylation step varied depending on the substrate used. This information was used to synthesize alkyl-glucosides (up to a chain length of C(10)) using dimethyl sulfoxide stabilized single-phase reaction microenvironment. About 12% molar yield of octyl-glucoside was calculated based on a simple spectrophotometric method developed for its estimation. Further, detailed comparison of properties of the enzymes indicated these to be different from the previously cloned beta-glucosidases from this yeast.     

具有a-淀粉酶分泌活性以及低双乙酰产量的啤酒酵母工程菌的构建

扣囊复膜酵母(Saccharomycopsis fibuligera)因具有较强的a-淀粉酶以及葡聚糖酶活性, 使其在以淀粉为唯一碳源的培养基上能够良好的生长。从其基因组中克隆了a-淀粉酶的编码区, 构建了由酵母磷酸甘油酸激酶基因(PGK1)启动子、酿酒酵母a-因子信号序列以及扣囊复膜酵母a-淀粉酶基因编码序列组成的基因表达盒。将该表达盒插入到质粒pPLZ-2的ILV2基因序列内部, 使其两翼具有ILV2基因的同源区。将该表达盒通过同源重组的方式整合到啤酒酵母工业菌株YSF-5的a-乙酰乳酸合成酶(AHAS)基因ILV2内部。在以淀粉为唯一碳源的培养基上进行转化子的筛选。通过多对引物PCR、a-淀粉酶活性以及AHAS活性分析对转化子进行鉴定, 得到一株具有a-淀粉酶分泌表达活性、较低AHAS活性, 并且发酵液中双乙酰产量也相对较低的啤酒酵母工程菌。该菌株在非选择压力条件下连续培养50代后仍然保持其遗传稳定性。还对pH、温度以及金属离子对该转化菌株的a-淀粉酶活性的影响进行了研究。由于所构建的菌株不含有非酵母来源的DNA, 所以生物安全性相对较高, 对酵母育种以及啤酒生产工业都具有较为重要的意义。     

Molecular cloning and expression of the novel fungal beta-glucosidase genes from Humicola grisea and Trichoderma reesei

A novel fungal beta-glucosidase gene (bgl4) and its homologue (bgl2) were cloned from the cellulolytic fungi Humicola grisea and Trichoderma reesei, respectively. The deduced amino acid sequences of H. grisea BGL4 and T. reesei BGL2 comprise 476 and 466 amino acids, respectively, and share 73.1% identity. These beta-glucosidases show significant homology to plant beta-glucosidases belonging to the beta-glucosidase A (BGA) family. Both genes were expressed in Aspergillus oryzae, and the recombinant beta-glucosidases were purified. Recombinant H. grisea BGL4 is a thermostable enzyme compared with recombinant T. reesei BGL2. In addition to beta-glucosidase activity, recombinant H. grisea BGL4 showed a significant level of beta-galactosidase activity, while recombinant T. reesei BGL2 showed weak beta-galactosidase activity. Cellulose saccharification by Trichoderma cellulases was improved by the addition of recombinant H. grisea BGL4.     

扣囊复膜孢酵母b-葡萄糖苷酶基因在工业酿酒酵母中的表达

本文以工业酿酒酵母菌株( Saccharomyces cerevisiae Y )为研究对象,针对其复杂的生理生化遗传特性,建立了相对应的转化体系。以pRS41H质粒为基础载体,构建了含有工业酿酒酵母自身的gpd2启动子、终止子和扣囊复膜孢酵母的b-葡萄糖苷酶基因bgl的重组质粒pRS-gb。电击转化进入工业酿酒酵母细胞,潮霉素抗性筛选,获得重组菌。该重组菌可以在以纤维二糖为唯一碳源的培养基中生长,培养36 h,b-葡萄糖苷酶酶活达到0.967 u/ml。以纤维二糖为唯一碳源的酒精发酵中,酒精度可以达到0.92 g/l。这对工业生产中利用纤维素为原料发酵生产酒精具有重要意义。     

Purification and characterization of two β-glucosidases from a thermo-tolerant yeast Pichia etchellsii

The thermo-tolerant yeast Pichia etchellsii produced two cell-wall-bound inducible β-glucosidases, BGLI (molecular mass 186 kDa) and BGLII (molecular mass 340 kDa), which were purified by a simple, three-step method, comprising ammonium sulfate precipitation, ion-exchange and hydroxyapatite chromatography. The two enzymes exhibited a similar pH and temperature optima, inhibitory effect by glucose and gluconolactone, and stability in the pH range of 3.0–9.0. Placed in family 3 of glycosylhydrolase families, BGLI was more active on salicin, p-nitrophenyl β-d-glucopyranoside and alkyl β-d-glucosides whereas BGLII was most active on cellobiose. k_cat and K_M values were determined for a number of substrates and, for BGLI, it was established that the deglycosylation step was equally effective on aryl- and alkyl-glucosides while the glycosylation step varied depending on the substrate used. This information was used to synthesize alkyl-glucosides (up to a chain length of C₁₀) using dimethyl sulfoxide stabilized single-phase reaction microenvironment. About 12% molar yield of octyl-glucoside was calculated based on a simple spectrophotometric method developed for its estimation. Further, detailed comparison of properties of the enzymes indicated these to be different from the previously cloned β-glucosidases from this yeast.     

Structural stability and unfolding transition of β-glucosidases: a comparative investigation on isozymes from a thermo-tolerant yeast

The folding of proteins in the milieu of the cellular environment involves various interactions among the residues of the polypeptide chain and the microenvironment where it resides. These interactions are responsible for stabilizing the protein molecule, and disruption of the same provides information about the stability of the molecule. β-Glucosidase isozymes, despite having high homology in their primary and tertiary designs, show deviations in their properties such as unfolding, refolding, and stability. In a comparative study on two large cell-wall-bound isozymes, β-glucosidase I (BGLI) and β-glucosidase II (BGLII) from a thermo-tolerant yeast, Pichia etchellsii, we have investigated guanidine hydrochloride (GdnHCl)-induced, alkali-induced, and thermal-unfolding transitions using CD and fluorescence spectroscopy and high sensitivity differential scanning calorimetry. Using spectral parameters (MRE 222 nm) to monitor the conformational transitions of the GdnHCl-induced unfolding phenomenon, it was observed that the midpoints of unfolding, apparent C _m, occurred at 1.2 M ± 0.05 and 0.8 M ± 0.03 GdnHCl, respectively, for BGLI and BGLII. The alkali-induced unfolding process indicated that BGLI showed a mid-transition point at pH 11 ± 0.17, while for BGLII it was at pH 10 ± 0.40, further indicating BGLI to be more stable to alkali denaturation than BGLII. In the case of thermal unfolding, the midpoint of transition was observed at 63 ± 0.12°C for BGLI and at 58 ± 0.55°C for BGLII. Analysis by high sensitivity differential scanning calorimeter supported the unfolding data in which BGLI showed higher melting temperature, T _m, (56.07°C ± 0.34) than BGLII (54.02°C ± 0.36). Our results clearly indicate that BGLI is structurally more rigid and stable than BGLII.     

Nucleotide sequence of the glucoamylase gene GLU1 in the yeast Saccharomycopsis fibuligera.

The complete nucleotide sequence of the glucoamylase gene GLU1 from the yeast Saccharomycopsis fibuligera has been determined. The GLU1 DNA hybridized to a polyadenylated RNA of 2.1 kilobases. A single open reading frame codes for a 519-amino-acid protein which contains four potential N-glycosylation sites. The putative precursor begins with a hydrophobic segment that presumably acts as a signal sequence for secretion. Glucoamylase was purified from a culture fluid of the yeast Saccharomyces cerevisiae which had been transformed with a plasmid carrying GLU1. The molecular weight of the protein was 57,000 by both gel filtration and acrylamide gel electrophoresis. The protein was glycosylated with asparagine-linked glycosides whose molecular weight was 2,000. The amino-terminal sequence of the protein began from the 28th amino acid residue from the first methionine of the putative precursor. The amino acid composition of the purified protein matched the predicted amino acid composition. These results confirmed that GLU1 encodes glucoamylase. A comparison of the amino acid sequence of glucoamylases from several fungi and yeast shows five highly conserved regions. One homology region is absent from the yeast enzyme and so may not be essential to glucoamylase function.     

Trehalose accumulation in a high-trehalose-accumulating mutant of Saccharomycopsis fibuligera sdu does not respond to stress treatments

The isolation of high-trehalose-accumulating mutant A11 from Saccharomycopsis fibuligera sdu has been previously described. In this paper, accumulation of trehalose under various stress conditions in S. fibuligera A11 was investigated. Neither activation of trehalose-6-phosphate synthase (SfTps1) nor change in trehalose content was observed under stress exposure of S. fibuligera A11 cells. A fragment of the Sftps1 gene in this strain was also cloned by degenerate PCR using the CoDeHOP strategy and multiply-aligned Tps1 sequences. This sequence allowed us to investigate the expression of the Sftps1 gene, which was also kept constant under the various stress conditions. Altogether, these results indicate that trehalose metabolism in S. fibuligera A11 in response to stress conditions clearly differs from that of Saccharomyces cerevisiae and most other fungi. The expression of the Sftps1 gene was not responsive to different stress treatments.     

Starch fermentation by recombinant saccharomyces cerevisiae strains expressing the alpha-amylase and glucoamylase genes from lipomyces kononenkoae and saccharomycopsis fibuligera

Lipomyces kononenkoae and Saccharomycopsis fibuligera possess highly efficient alpha-amylase and/or glucoamylase activities that enable both of these yeasts to utilize raw starch as a carbon source. Eight constructs containing the L. kononenkoae alpha-amylase genes (LKA1 and LKA2), and the S. fibuligera alpha-amylase (SFA1) and glucoamylase (SFG1) genes were prepared. The first set of constructs comprised four single gene cassettes each containing one of the individual amylase coding sequences (LKA1, LKA2, SFA1 or SFG1) under the control of the phosphoglycerate kinase gene (PGK1) promoter and terminator, while the second set comprised two single cassettes containing SFA1 and SFG1 linked to their respective native promoters and terminators. The third set of constructs consisted of two double-gene cassettes, one containing LKA1 plus LKA2 under the control of the PGK1 promoter and terminator, and the other SFA1 plus SFG1 controlled by their respective native promoters and terminators. These constructs were transformed into a laboratory strain Saccharomyces cerevisiae (Sigma1278b). Southern-blot analysis confirmed the stable integration of the different gene constructs into the S. cerevisiae genome and plate assays revealed amylolytic activity. The strain expressing LKA1 and LKA2 resulted in the highest levels of alpha-amylase activity in liquid media. This strain was also the most efficient at starch utilization in batch fermentations, utilizing 80% of the available starch and producing 0.61g/100 mL of ethanol after 6 days of fermentation. The strain expressing SFG1 under the control of the PGK1 expression cassette gave the highest levels of glucoamylase activity. It was shown that the co-expression of these heterologous alpha-amylase and glucoamylase genes enhance starch degradation additively in S. cerevisiae. This study has resulted in progress towards laying the foundation for the possible development of efficient starch-degrading S. cerevisiae strains that could eventually be used in consolidated bioprocessing, and in the brewing, whisky, and biofuel industries.     

Lactic fermentation of cellobiose by a yeast strain displaying β-glucosidase on the cell surface

The Aspergillus aculeatus beta-glucosidase 1 (bgl1) gene was expressed in a lactic-acid-producing Saccharomyces cerevisiae strain to enable lactic fermentation with cellobiose. The recombinant beta-glucosidase enzyme was expressed on the yeast cell surface by fusing the mature protein to the C-terminal half region of the alpha-agglutinin. The beta-glucosidase expression plasmids were integrated into the genome. Three strong promoters of S. cerevisiae, the TDH3, PGK1, and PDC1 promoters, were used for beta-glucosidase expression. The specific beta-glucosidase activity varied with the promoter used and the copy number of the bgl1 gene. The highest activity was obtained with strain PB2 that possessed two copies of the bgl1 gene driven by the PDC1 promoter. PB2 could grow on cellobiose and glucose minimal medium at the same rate. Fermentation experiments were conducted in non-selective-rich media containing 95 g l(-1) cellobiose or 100 g l(-1) glucose as a carbon source under microaerobic conditions. The maximum rate of L-lactate production by PB2 on cellobiose (2.8 g l(-1) h(-1)) was similar to that on glucose (3.0 g l(-1) h(-1)). This indicates that efficient fermentation of cellobiose to L-lactate can be accomplished using a yeast strain expressing beta-glucosidase from a mitotically stable genomic integration plasmid.     

Nucleotide sequence of Candida pelliculosa beta-glucosidase gene.

The nucleotide sequence of the DNA fragment containing the beta-glucosidase gene of Candida pelliculosa was determined. Analysis of the sequence revealed three open reading frames which could encode 65,825, and 412 amino acid residues. The presence of the second frame was found to be sufficient for the expression of the beta-glucosidase gene in a heterologous host Saccharomyces cerevisiae. Putative protein encoded by this gene had hydrophobic amino acids, resembling a signal peptide, at its N-terminal region and 19 potential glycosylation sites. Codon usage of Candida genes had the similar pattern shown in S.cerevisiae. Codon bias of the beta-glucosidase gene of Candida was relatively low, compared with that of the highly expressed genes of S. cerevisiae.     

The bglA gene of Aspergillus kawachii encodes both extracellular and cell wall-bound beta-glucosidases

We cloned the genomic DNA and cDNA of bglA, which encodes beta-glucosidase in Aspergillus kawachii, based on a partial amino acid sequence of purified cell wall-bound beta-glucosidase CB-1. The nucleotide sequence of the cloned bglA gene revealed a 2,933-bp open reading frame with six introns that encodes an 860-amino-acid protein. Based on the deduced amino acid sequence, we concluded that the bglA gene encodes cell wall-bound beta-glucosidase CB-1. The amino acid sequence exhibited high levels of homology with the amino acid sequences of fungal beta-glucosidases classified in subfamily B. We expressed the bglA cDNA in Saccharomyces cerevisiae and detected the recombinant beta-glucosidase in the periplasm fraction of 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 disrupted produced none of the three beta-glucosidases, as determined by enzyme assays and a Western blot analysis. Thus, we concluded that the bglA gene encodes both extracellular and cell wall-bound beta-glucosidases in A. kawachii.     

Expression of a library of fungal β-glucosidases in Saccharomyces cerevisiae for the development of a biomass fermenting strain

Converting cellulosic biomass to ethanol involves the enzymatic hydrolysis of cellulose and the fermentation of the resulting glucose. The yeast Saccharomyces cerevisiae is naturally ethanologenic, but lacks the enzymes necessary to degrade cellulose to glucose. Towards the goal of engineering S. cerevisiae for hydrolysis of and ethanol production from cellulose, 35 fungal β-glucosidases (BGL) from the BGL1 and BGL5 families were screened for their ability to be functionally expressed and displayed on the cell surface. Activity assays revealed that the BGL families had different substrate specificities, with only the BGL1s displaying activity on their natural substrate, cellobiose. However, growth on cellobiose showed no correlation between the specific growth rates, the final cell titer, and the level of BGL1 activity that was expressed. One of the BGLs that expressed the highest levels of cellobiase activity, Aspergillus niger BGL1 (Anig-Bgl101), was then used for further studies directed at developing an efficient cellobiose-fermenting strain. Expressing Anig-Bgl101 from a plasmid yielded higher ethanol levels when secreted into the medium rather than anchored to the cell surface. In contrast, ethanol yields from anchored and secreted Anig-Bgl101 were comparable when integrated on the chromosome. Flow cytometry analysis revealed that chromosomal integration of Anig-Bgl101 resulted in a higher percentage of the cell population that displayed the enzyme but with overall lower expression levels.