Cell surface-engineered yeast displaying a histidine oligopeptide (hexa-His) has enhanced adsorption of and tolerance to heavy metal ions

A histidine oligopeptide (hexa-His) with the ability to chelate divalent heavy metal ions was displayed on the yeast cell surface for the purpose of enhanced adsorption of heavy metal ions. We genetically fused a hexa-His-encoding gene with the gene encoding the C-terminal half of alpha-agglutinin that includes a glycosylphosphatidylinositol anchor attachment signal sequence and attached the hexa-His peptide on the cell wall of Saccharomyces cerevisiae. This surface-engineered yeast adsorbed three to eight times more copper ions than the parent strain and was more resistant to copper (4 mM) than the parent (below 1 mM at pH 7.8). It was possible to recover about a half of the copper ions adsorbed by whole cells with EDTA treatment without disintegrating the cells. Thus, we succeeded in constructing a novel yeast cell with both tolerance to toxic contaminants and enhanced adsorption of metal ions onto the cell surface.     

番茄脂氧合酶基因的表达和酶活性分析

将番茄脂氧合酶基因Tom loxD克隆至酵母表达载体pPIC9K中,转化毕赤酵母GS115菌株,构建组成型表达Tom loxD的酵母工程菌株。SDS-PAGE和W estern blot分析表明,经甲醇诱导,Tom loxD蛋白在酵母中得到表达,表达的融合蛋白分子量约为103.56 kD,与预测的分子量一致。酶活性分析表明,酵母中表达的Tom loxD蛋白具有脂氧合酶活性。半定量RT-PCR分析表明,Tom loxD基因在番茄中表达受机械损伤的诱导,损伤处理的番茄叶片中脂氧合酶的活性明显增高。说明Tom loxD基因在番茄防御信号中发挥作用。     

Development of an arming yeast strain for efficient utilization of starch by co-display of sequential amylolytic enzymes on the cell surface

The construction of a whole-cell biocatalyst with its sequential reaction has been performed by the genetic immobilization of two amylolytic enzymes on the yeast cell surface. A recombinant strain of Saccharomyces cerevisiae that displays glucoamylase and α-amylase on its cell surface was constructed and its starch-utilizing ability was evaluated. The gene encoding Rhizopus oryzae glucoamylase, with its own secretion signal peptide, and a truncated fragment of the α-amylase gene from Bacillus stearothermophilus with the prepro secretion signal sequence of the yeast α factor, respectively, were fused with the gene encoding the C-terminal half of the yeast α-agglutinin. The constructed fusion genes were introduced into the different loci of chromosomes of S. cerevisiae and expressed under the control of the glyceraldehyde-3-phosphate dehydrogenase promoter. The glucoamylase and α-amylase activities were not detected in the culture medium, but in the cell pellet fraction. The transformant strain co-displaying glucoamylase and α-amylase could grow faster on starch as the sole carbon source than the transformant strain displaying only glucoamylase. Received: 16 June 1998 / Received last revision: 21 August 1998 / Accepted: 3 September 1998     

Construction of flocculent industrial yeast by the yeast flocculation gene <Emphasis Type="Italic">FLO1</Emphasis>

The structure gene FLO1 from Saccharomyces cerevisiae W303-1A encoding a flocculation protein and the G418 resistance gene kanMX from plasmid pUG6 were amplified by PCR method. The expression vector pYX212 harboring FLO1 gene and kanMX gene was transformed into Angel yeast. The transformant Angel yeast F6 was obtained and showed strong and stable flocculation ability during 20 batches inoculation. And the flocculation ability of the transformant Angel yeast F6 showed no difference in the medium with the initial pH ranging from 3.5 to 6.0. Noteworthily, the flocculation onset of the transformant strain was in the early stationary growth phase, not coincident with the glucose depletion in the cultural medium. And in the experiment the ethanol yield and other properties of the transformant Angel yeast F6 were similar to those of the wild-type strain, although its fermentation time was a little slower comparing with the wild-type strain. Those would be potential application for yeast cells to separate and recycle in the fuel ethanol industry.     

Yeast cells harboring human alpha-1,3-fucosyltransferase at the cell surface engineered using Pir, a cell wall-anchored protein

Human alpha-1,3-fucosyltansferase (FucT) encoded by the FUT6 gene was displayed at the cell surface of yeast cells engineered using the yeast cell wall protein Pir1 or Pir2, and the FucT activity was detected at the surface of cells producing the Pir1-HA-FUT6 or Pir2-FLAG-FUT6 fusion proteins. To obtain higher activity, we engineered the host yeast cells in which endogenous PIR genes of the PIR1-4 gene family were disrupted. Among the disruptants, the pir1Delta pir2Delta pir3Delta strain with the PIR1-HA-FUT6 fusion gene showed the highest FucT activity, which was about three-fold higher than that of the wild-type strain. Furthermore, the co-expression of both the Pir1-HA-FUT6 and the Pir2-FLAG-FUT6 fusions showed an approximately 1.5-fold higher activity than that in the cell wall displaying Pir1-HA-FUT6 alone. The present method was thus effective for producing yeast cells that can easily synthesize various oligosaccharides, such as Le(x) and sLe(x), using Pir-glycosyltransferase fusions in combination with the deletion of endogenous PIR genes.     

Chemical synthesis and expression of a cassette adapted ubiquitin gene

A gene encoding the yeast ubiquitin was chemically synthesized and expressed in yeast under regulatory control of the copper metallothionein (CUP1) promoter. The gene was assembled in a one-step ligation reaction from eight oligonucleotide fragments ranging in length from 50 to 64 nucleotides. To facilitate mutagenesis and gene fusion studies, eight unique 6-base-cutting restriction enzyme sites were placed in the reading frame which did not alter the encoded protein sequence or force the utilization of rare codons. In a copper-resistant yeast strain (CUP1r), expression of the gene was induced by copper to approximately 5% of the total yeast proteins, as determined by Coomassie-stained polyacrylamide gels. The protein, purified from yeast, reacted with ubiquitin-specific antibodies and was found to be biologically active in supporting ubiquitin-dependent protein degradation in vitro.     

Expression of fungal phytase on the cell surface ofSaccharomyces cerevisiae

Phytase improves the bioavailability of phytate phosphorus in plant foods to humans and animals, and reduces the phosphorus pollution of animal waste. We have engineered the cell surface of the yeast,Saccharomyces cerevisiae by anchoring active fungal phytase on its cell wall, in order to apply it as a dietary supplement containing bioconversional functions in animal foods and a whole cell bio-catalyst for the treatment of waste. The phytase gene (phyA) ofAspergillus niger with a signal peptide of rice amylase 1A (Ramy1A) was fused with the gene encoding the C-terminal half (320 amino acid residues from the C-terminus) of yeast α-agglutinin, a protein which is involved in mating and is covalently anchored to the cell wall. The resulting fusion construct was introduced intoS. cerevisiae and expressed under the control of the constitutive glyceraldehydes-3-phosphate dehydrogenase (GPD) promoter. Phytase plate assay revealed that the surface-engineered cell exhibited a catalytically active opaque zone which was restricted to the margin of the colony. Additionally, the phytase activity was detected in the cell fraction, but was not detected in the culture medium when it was grown in liquid. These results indicate that the phytase was successfully anchored to the cell surface of yeast and was displayed as its active form. The amount of recombinant phytase on the surface of yeast cells was estimated to be 16,000 molecules per cell.     

vMIP-II-TfN融合蛋白在毕赤酵母中的表达和纯化

目的:构建pPIC-vMIP-II-TfN酵母表达载体,表达纯化vMIP-II-TfN融合蛋白。方法:利用PCR方法扩增编码人转铁蛋白N端半分子的基因片段,通过酶切、连接、转化等分子克隆方法构建pPIC-vMIP-II-TfN酵母表达载体;电击法转化X33酵母菌;用甲醇诱导重组酵母菌表达融合蛋白,利用硫酸铵沉淀、透析、Ni-NTA层析等技术进行蛋白纯化,SDS-PAGE和Western blot检测蛋白表达和纯化情况,利用趋化实验进行纯化蛋白活性检测。结果:经过两次PCR扩增了一个长约1.1kb的包含Xba I酶切位点的IgG3-TfN基因片段,插入pPIC-vMIP-II的Xba I酶切位点,经菌液PCR鉴定获得重组子,测序结果表明构建载体pPIC-vMIP-II-TfN的表达框正确无误,转化X33酵母菌,用甲醇诱导表达出48kDa的vMIP-II-TfN融合蛋白,经硫酸铵沉淀、透析、Ni-NTA纯化后得到纯度约为95%的vMIP-II-TfN融合蛋白。Western印迹结果表明融合蛋白能与转铁蛋白抗体特异性结合。活性检测表明经过诱导表达的vMIP-II-TfN融合蛋白具有趋化抑制活性。结论:成功构建pPIC-vMIP-II-TfN酵母表达载体,重组酵母工程菌经甲醇诱导成功表达出vMIP-II-TfN融合蛋白,纯化后的vMIP-II-TfN融合蛋白具有趋化抑制活性。     

Yeast metallothionein function in metal ion detoxification

A genetic approach was taken to test the function of yeast metallothionein in metal ion detoxification. A yeast strain was constructed in which the metallothionein locus was deleted (cup1 delta). The cup1 delta strain was complemented with normal or mutant metallothionein genes under normal or constitutive regulatory control on high copy episomal plasmids. Metal resistance of the cup1 delta strain with and without the metallothionein-expressing vectors was analyzed. The normally regulated metallothionein gene conferred resistance only to copper (1000-fold); constitutively expressed metallothionein conferred resistance to both copper (500-fold) and cadmium (1000-fold), but not to mercury, zinc, silver, cobalt, nickel, gold, platinum, lanthanum, uranium, or tin. Two mutant versions of the metallothionein gene were constructed and tested for their ability to confer metal resistance in the cup1 delta background. The first had a deletion of a highly conserved amino acid sequence (Lys-Lys-Ser-Cys-Cys-Ser). The second was a hybrid gene consisting of the sequences coding for the first 20 amino acids of the yeast protein fused to the monkey metallothionein gene. Expression of these genes under the CUP1 promoter provided significant protection from copper, but none of the other metals tested. These results demonstrate that there is significant flexibility in the structural requirements for metallothionein to function in copper detoxification and that yeast metallothionein is also capable of detoxifying cadmium under conditions of constitutive expression.     

Delta 9-fatty acid desaturase from arachidonic acid-producing fungus. Unique gene sequence and its heterologous expression in a fungus, Aspergillus.

Based on the sequence information for delta 9-desaturase genes (from rat, mouse and yeast), which are involved in the desaturation of palmitic acid and stearic acid to palmitoleic acid and oleic acid, respectively, the corresponding cDNA and genomic gene were cloned from the fungal strain, Mortierella alpina 1S-4, which industrially produces arachidonic acid. There was a cytochrome b5-like domain linked to the carboxyl terminus of this Mortierella desaturase, as also seen in the yeast delta 9-desaturase. The Mortierella delta 9-desaturase genomic gene had only one intron, in which a novel phenomenon was observed: there was a GC-end at the 5'-terminus instead of a GT-end that is, in general, found in introns of eukaryotic genes. The full-length cDNA clone was expressed under the control of an amyB promoter in a filamentous fungus, Aspergillus oryzae, resulting in drastic changes in the fatty acid composition in the transformant cells; the contents of palmitoleic acid (16:1) and oleic acid (18:1) increased significantly, with accompanying decreases in palmitic acid (16:0) and stearic acid (18:0). These changes were controlled by the addition of maltose as a carbon source to the medium. Also, the expression of the gene caused a significant change in the lipid composition in the Aspergillus transformant. Genomic Southern blot analysis of the transformant with the Mortierella delta 9-desaturase gene as a probe confirmed the integration of this gene into the genome of A. oryzae.     

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。     

Genetically Controlled Self-Aggregation of Cell-Surface-Engineered Yeast Responding to Glucose Concentration

We constructed an arming (cell-surface-engineered) yeast displaying two types of agglutinin (modified a-agglutinin and α-agglutinin) on the cell surface, with agglutination being independent of both mating type and pheromones. The modified a-agglutinin was artificially prepared by the fusion of the genes encoding Aga1p and Aga2p. The modified a-agglutinin could induce agglutination of cells displaying Agα1p (α-agglutinin). The upstream region of the isocitrate lyase gene of Candida tropicalis (UPR-ICL), active at a low glucose concentration, was used as the promoter to express the modified a-agglutinin- and α-agglutinin-encoding genes. The arming yeast displaying both agglutinins agglutinated and sedimented in response to decreased glucose concentration. When the glucose concentration was high, the arming yeast grew normally. In the late log phase, when the glucose concentration became very low, agglutination occurred suddenly and drastically and yeast cells sedimented completely. Sedimentation was confirmed by weighing the aggregated cells after filtration of the broth. Strains in which aggregation can be genetically controlled can be used in industrial processes in which the separation of yeast cells from the supernatant is necessary.     

Genetically controlled self-aggregation of cell-surface-engineered yeast responding to glucose concentration

We constructed an arming (cell-surface-engineered) yeast displaying two types of agglutinin (modified a-agglutinin and alpha-agglutinin) on the cell surface, with agglutination being independent of both mating type and pheromones. The modified a-agglutinin was artificially prepared by the fusion of the genes encoding Aga1p and Aga2p. The modified a-agglutinin could induce agglutination of cells displaying Agalpha1p (alpha-agglutinin). The upstream region of the isocitrate lyase gene of Candida tropicalis (UPR-ICL), active at a low glucose concentration, was used as the promoter to express the modified a-agglutinin- and alpha-agglutinin-encoding genes. The arming yeast displaying both agglutinins agglutinated and sedimented in response to decreased glucose concentration. When the glucose concentration was high, the arming yeast grew normally. In the late log phase, when the glucose concentration became very low, agglutination occurred suddenly and drastically and yeast cells sedimented completely. Sedimentation was confirmed by weighing the aggregated cells after filtration of the broth. Strains in which aggregation can be genetically controlled can be used in industrial processes in which the separation of yeast cells from the supernatant is necessary.     

Expression of recombinant GFP-actin fusion protein in the methylotrophic yeast Pichia pastoris

The integrative vector pPIC3 for the yeast Pichia pastoris and a cDNA fragment encoding a fusion protein consisting of green fluorescent protein (GFP) and actin 5C of the fruit fly Drosophila melanogaster were used to construct a pPIC3-GFP-actin 5C expression plasmid. The P. pastoris host strain GS115 was transformed with the pPIC3-GFP-actin 5C carrying HIS4 as a selective marker. The transformants were selected on a histidine-deficient medium, and were shown to contain the gene of GFP-actin 5C fusion protein. Expression was induced by cultivation of the transformant cells in a methanol-containing medium. Production of the fusion protein in the yeast was detected by the bright green fluorescence of the GFP tag. The pattern of yeast cytoskeleton labeling by the fusion indicated proper folding and functioning of GFP-actin 5C in a heterologous system in vivo. After cell destruction, purification of GFP-actin 5C was performed by DNase I-Sepharose. Efficient binding of the chimera to the DNase I indicated nativity of the actin 5C fusion in vitro. SDS electrophoresis and further Western blot confirmed the purified protein to exhibit the expected molecular mass of about 70 kDa. The recombinant GFP-actin 5C was used to produce polyclonal antibodies, which had not been reported so far but are extremely needed for immuno-labeling and isolation of wild-type and mutant forms of actin 5C.     

Genetic immobilization of proteins on the yeast cell surface

A genetic system has been exploited to immobilize proteins in their active and functional forms on the cell surface of yeast, Saccharomyces cerevisiae. DNAs encoding proteins with a secretion signal peptide were fused with the genes encoding yeast agglutinins, a- and alpha-type proteins involved in mating. The fusion gene was introduced into S. cerevisiae and expressed under the control of several promoters. Appearance of the fused proteins expressed on the cell surface was demonstrated biochemically and by immunofluorescence and immunoelectron microscopy techniques. Alpha-galactosidase from Cyamopsis tetragonoloba seeds, peptide libraries including scFv and variable regions of the T cell receptor from mammalian cells have been successfully immobilized on the yeast cell wall in the active form. Recently, surface-engineered yeasts have been constructed by immobilizing the enzymes and a functional protein, for example, green fluorescent protein (GFP) from Aequorea victoria. The yeasts were termed 'arming yeasts' with biocatalysts or functional proteins. Such arming cells displaying glucoamylase from Rhizopus oryzae and alpha-amylase from Bacillus stearothermophilus, or carboxymethylcellulase and beta-glucosidase from Aspergillus acleatus, could assimilate starch or cellooligosaccharides as the sole carbon source, although S. cerevisiae cannot intrinsically assimilate these substrates. GFP-arming cells can emit green fluorescence from the cell surface in response to the environmental conditions. The approach described in this review will enable us to endow living cells, including yeast cells, with novel additional abilities and to open new dimensions in the field of biotechnology.     

Expression and functional characterization of a recombinant targeted toxin with an uPA cleavable linker in Pichia pastoris

A recombinant targeted toxin (Disintegrin-Conj-Mel) was developed that contained a disintegrin connected to cytotoxic melittin by a urokinase plasminogen activator (uPA)-cleavable linker. This recombinant targeted toxin was designed to target tumor cells expressing integrin αvβ3. The fusion gene was expressed under the control of the promoter AOX1 in Pichia pastoris. Electrophoresis by SDS-PAGE and Western blotting assays of culture broth from a methanol-induced expression strain, demonstrated that an approximately 13 kDa fusion protein was secreted into the culture medium. The molecular weight was that calculated from the predicted amino acid sequence. After optimizing the growth and expression conditions of the transformant strain, about 160 mg/L of the recombinant protein was achieved. The recombinant protein was purified to more than 95% purity by SP Sepharose ion exchange chromatography and Sephadex G-75 gel filtration chromatography. The hemolysis bioactivity test revealed that the fusion had no hemolytic activity or cytotoxicity against uPA non-expressing 293 cells, but exerted dose-dependent inhibition on uPA-expressing A549 cell proliferation.