Expression of a heat stable phytase from Aspergillus fumigatus in tobacco (Nicotiana tabacum L. cv. NC89)

Aspergillus fumigatus contains a heat-stable phytase of great potential. To determine whether this phytase could be expressed in plants as a functional enzyme, we introduced the phytase gene from A. fumigatus (fphyA) in tobacco (Nicotiana tabacum L. cv. NC89) by Agrobacterium-mediated transformation. Phytase expression was controlled by the cauliflower mosaic virus (CaMV) 35S promoter. Secretion of recombinant phytase (tfphyA) to the extracellular fluid was established by use of the signal sequence from tobacco calreticulin. Forty-one independent transgenic plants were generated. Single-copy line A was selected based on segregation of T1 seeds for kanamycin resistance, phytase expression and Southern blotting analysis for use in further study. After 4-weeks of plant growth, the phytase was accumulated in leaves up to 2.3% of total soluble protein. tfphyA was functional and shared similar profiles of pH, temperature and thermal stability to the same enzyme expressed in Pichia pastoris (pfphyA). The expressed enzyme had an apparent molecular mass of 63 kDa and showed maximum activity at pH 5.5, and temperature, 55 degrees C. It had a high thermostability and retained 28.7% of the initial activity even after incubation at 90 degrees C for 15 min. The above results showed that the thermostable A. fumigatus phytase could be expressed in tobacco as a functional enzyme and thus has the potential of overexpressing it in other crop plants also.     

来源于Escherichia coli的高比活植酸酶基因的高效表达

高效表达高比活植酸酶是进一步提高植酸酶发酵效价、降低植酸酶生产成本的一个有效途径。对源于Escherichiacoli的高比活植酸酶基因appA ,按照毕赤酵母 (Pichiapastoris)密码子的偏爱进行了密码子优化改造。该改造后的基因appA m按正确的阅读框架融合到毕赤酵母表达载体pPIC9上的α 因子信号肽编码序列 3′端 ,通过电击转化得到重组转化子。对重组毕赤酵母的Southernblotting分析证实植酸酶基因已整合到酵母基因组中 ,并确定了整合基因的拷贝数。Northernblotting分析证实植酸酶基因得到了正常转录。SDS PAGE分析和表达产物的研究表明 ,植酸酶得到了高效分泌表达 ,在 5L发酵罐中植酸酶蛋白表达量达到 2 5mg mL发酵液 ,酶活性 (发酵效价 )达到 7 5× 10 6 IU mL发酵液以上 ,大大高于目前报道的各种植酸酶基因工程菌株的发酵效价。     

来源于柠檬酸杆菌的高比活植酸酶基因在毕赤酵母中的高效表达

柠檬酸杆菌(Citrobacterbraakii)来源的植酸酶是目前报道的比活最高的植酸酶。按照毕赤酵母(Pichiapastoris)对密码子的选择偏向性,对来源于柠檬酸杆菌的高比活植酸酶基因AppA进行了密码子优化改造。改造后的基因AppA(m)按正确的阅读框架融合到毕赤酵母表达载体pPIC9的α-因子信号肽编码序列3′端,通过电击转化得到重组转化子。通过PCR验证,AppA(m)已整合在酵母染色体上。SDS-PAGE分析和表达产物的研究表明,植酸酶得到了高效分泌表达,在5L发酵罐中植酸酶蛋白表达量达到3·2mg/mL发酵液,发酵效价达到每毫升发酵液1·4×107IU以上,高于目前报道的各种植酸酶基因工程菌株的发酵效价。     

Role of glycosylation in the functional expression of an Aspergillus niger phytase (phyA) in Pichia pastoris

Economical and thermostable phytase enzymes are needed to release phytate-phosphorus in plant foods for human and animal nutrition and to reduce phosphorus pollution of animal waste. Our objectives were to determine if a methylotrophic yeast, Pichia pastoris, was able to express a phytase gene (phyA) from Aspergillus niger efficiently and if suppression of glycosylation by tunicamycin affected its functional expression. The gene (1.4 kb) was inserted into an expression vector pPICZalphaA with a signal peptide alpha-factor, under the control of AOX1 promoter. The resulting plasmid was transformed into two P. pastoris strains: KM71 (methanol utilization slow) and X33 (wild-type). Both host strains produced high levels of active phytase (25-65 units/ml of medium) that were largely secreted into the medium. The expressed enzyme was cross-reacted with the polyclonal antibody raised against the wild-type enzyme and showed two pH optima, 2.5 and 5.5, and an optimal temperature at 60 degrees C. Compared with the phyA phytase overexpressed by A. niger, this phytase had identical capacity in hydrolyzing phytate-phosphorus from soybean meal and slightly better thermostability. Deglycosylation of the secreted phytase resulted in reduction in the size from 95 to 55 kDa and in thermostability by 34%. Tunicamycin (20 microg/ml of medium) resulted in significant reductions of both intracellular and extracellular phytase activity expression. Because there was no accumulation of intracellular phytase protein, the impairment did not seem to occur at the level of translocation of phytase. In conclusion, glycosylation was vital to the biosynthesis of the phyA phytase in P. pastoris and the thermostability of the expressed enzyme.     

Screening, cloning and overexpression of Aspergillus niger phytase (phyA) in Pichia pastoris with favourable characteristics

AIMS: Using gene cloning and overexpression to obtain a potential industrial phytase as a feed additive to upgrade the nutritional quality of phytate-rich seed-based animal feed. METHODS AND RESULTS: A phyA gene from a high extracellular phytase-producing Aspergillus niger sp. was cloned and overexpressed in Pichia pastoris GS115 using the secretive expression vector pPICZalphaA. After cultivation for 4 days in buffered methanol complex medium (BMMY) containing methanol for induction, catalytically active phytase was secreted as a predominantly extracellular protein. The activity of the expressed phytase in fermented broth was 30 000-fold higher than that of native phytase with a specific activity of 503 U mg(-1). The Lineweaver-Burk plot indicated K(m) values of 0.196 mmol l(-1) for sodium phytate and 18.16 mmol l(-1) for p-nitrophenylphosphate (pNPP). Thermostability studies showed that recombinant phytase retained 70% activity after exposure to 90 degrees C for 5 min and 65% activity after 30 min, much higher than for commercial phytase. CONCLUSIONS: The higher activity and high thermostability of recombinant phytase enable it to withstand the temperatures of the feed pelleting process. SIGNIFICANCE AND IMPACT OF THE STUDY: The characteristics of this recombinant phytase, especially the good thermostability, are likely to render it of potential industrial importance.     

Cell-surface phytase on Pichia pastoris cell wall offers great potential as a feed supplement

Cell-surface expression of phytase allows the enzyme to be expressed and anchored on the cell surface of Pichia pastoris . This avoids tedious downstream processes such as purification and separation involved with extracellular expression. In addition, yeast cells with anchored proteins can be used as a whole-cell biocatalyst with high value added. In this work, the phytase was expressed on the cell surface of P. pastoris with a glycosylphosphatidylinositol anchoring system. The recombinant phytase was shown to be located at the cell surface. The cell-surface phytase exhibited high activity with an optimal temperature at 50–55 °C and two optimal pH peaks of 3 and 5.5. The surface-displayed phytase also exhibited similar pH stability and pepsin resistance to the native and secreted phytase. In vitro digestibility test showed that P. pastoris containing cell-surface phytase released phosphorus from feedstuff at a level similar to secreted phytase. Yeast cells expressing phytase also provide additional nutrients, especially biotin and niacin. Thus, P. pastoris with phytase displayed on its surface has a great potential as a whole-cell supplement to animal feed.     

Biochemical characterization of cloned Aspergillus fumigatus phytase (phyA)

The gene for Aspergillus fumigatus phytase (phyA) was cloned and expressed in Pichia pastoris. The enzyme expressed was purified to near homogeneity using sequential ion-exchange chromatography and was characterized biochemically. Although A. fumigatus phytase shows 66.2% sequence homology with A. ficuum phytase, the most widely studied enzyme, the cloned phytase showed identical molecular weight and temperature optima profile to the benchmark phytase. The pH profile of activity and kinetic parameters, however, differed from A. ficuum phytase. The cloned enzyme contains the septapeptide RHGARYP motif, which is also identical to the active site motif of A. ficuum phytase. Chemical probing of the active site Arg residues using both cyclohexanedione and phenylglyoxal resulted in the inactivation of phytase. The cloned A. fumigatus phytase, however, was more resistant to phenylglyoxal-induced inactivation. Both cloned A. fumigatus and A. ficuum phytases were identically affected by cyclohexanedione. Both the thermal characterization data and kinetic parameters of cloned and expressed A. fumigatus phytase indicate that this biocatalyst is not superior to the benchmark enzyme. The sequence difference between A. fumigatus and A. ficuum phytase may explain why the former enzyme catalyzes poorly compared to the benchmark enzyme. In addition, differential sensitivity toward the Arg modifier, phenylglyoxal, indicates a different chemical environment at the active site for each of the phytases.     

烟曲霉脯氨酰内肽酶在巴斯德毕赤酵母中的分泌表达与重组酶性质

【目的】研究烟曲霉脯氨酰内肽酶cDNA基因的异源表达及重组酶性质。【方法】以烟曲霉CICIM F0044总RNA为模板,反转录合成cDNA;再以cDNA为模板,通过PCR扩增去除自身信号肽的脯氨酰内肽酶基因,构建表达载体pPIC9K-PEP;电转化酵母宿主菌Pichia pastoris GS115,获得重组菌PEP-09;纯化并分析重组酶性质。【结果】重组菌摇瓶发酵酶活力最高可达647.3 U/L。表达产物纯化后的分子量为63 kD左右。重组酶最适反应温度为65°C,有较好的温度稳定性,在55°C保温8 h能保留90%以上的酶活力。该酶最适pH为5.5,在pH 3.0 9.0范围内有很好稳定性,在pH 6.0 8.0的缓冲液中37°C保温10 d酶活没有明显变化。【结论】烟曲霉脯氨酰内肽酶cDNA基因在巴斯德毕赤酵母中实现了分泌表达,重组酶活性稳定,有一定的应用潜力。     

High level expression of a recombinant acid phytase gene in Pichia pastoris

AIMS: To achieve high phytase yield with improved enzymatic activity in Pichia pastoris. METHODS AND RESULTS: The 1347-bp phytase gene of Aspergillus niger SK-57 was synthesized using a successive polymerase chain reaction and was altered by deleting intronic sequences, optimizing codon usage and replacing its original signal sequence with a synthetic signal peptide (designated MF4I) that is a codon-modified Saccharomyces cerevisiae mating factor alpha-prepro-leader sequence. The gene constructs containing wild type or modified phytase gene coding sequences under the control of the highly-inducible alcohol oxidase gene promoter with the MF4I- or wild type alpha-signal sequence were used to transform Pichia pastoris. The P. pastoris strain that expressed the modified phytase gene (phyA-sh) with MF4I sequence produced 6.1 g purified phytase per litre of culture fluid, with the phytase activity of 865 U ml(-1). The expressed phytase varied in size (64, 67, 87, 110 and 120 kDa), but could be deglycosylated to produce a homogeneous 64 kDa protein. The recombinant phytase had two pH optima (pH 2.5 and pH 5.5) and an optimum temperature of 60 degrees C. CONCLUSIONS: The P. pastoris strain with the genetically engineered phytase gene produced 6.1 g l(-1) of phytase or 865 U ml(-1) phytase activity, a 14.5-fold increase compared with the P. pastoris strain with the wild type phytase gene. SIGNIFICANCE AND IMPACT OF THE STUDY: The P. pastoris strain expressing the modified phytase gene with the MF4I signal peptide showed great potential as a commercial phytase production system.     

快速筛选高效表达重组蛋白毕赤酵母菌株新方法的建立及评价

毕赤酵母是当前应用最为广泛的重组蛋白表达系统之一,文中建立了一种快速筛选高效表达重组蛋白的毕赤酵母菌株的新方法。首先,对内质网转膜蛋白Sec63融合表达增强型绿色荧光蛋白EGFP的改造菌株GS115-E表达重组蛋白的能力进行检测;之后将携带不同拷贝数的植酸酶phy基因或木聚糖酶xyn基因的质粒转化进入GS115-E中,得到具有不同植酸酶或木聚糖酶表达水平的重组菌株,分别检测不同菌株的EGFP与重组蛋白的表达水平;最后,利用分选型流式细胞仪,根据绿色荧光值的高低对包含不同植酸酶表达水平的重组菌株的菌群进行分选。结果显示重组菌株中EGFP的荧光值与重组蛋白的活性表达水平之间具有良好的线性相关性(0.8|R|1),且利用流式细胞仪可高效地从混合菌群中筛选得到高产菌株,所分选得到的高荧光菌株在摇瓶发酵120 h时植酸酶表达水平是低荧光菌株的4.09倍。本方法通过检测菌株的EGFP荧光值代替检测重组蛋白的表达水平和活性,从而实现高表达菌株的筛选,大大提高了其应用的便捷性及通用性。与流式细胞仪、液滴微流控等高通量筛选仪器或技术结合将进一步提高筛选的速度与通量,为筛选获得高效表达重组蛋白的毕赤酵母菌株提供了简便、快速的新途径。     

增加植酸酶基因appA-m的拷贝提高其在巴斯德毕赤酵母的表达量

为了进一步提高植酸酶的发酵效价,降低植酸酶生产成本,对毕赤酵母表达载体pGAPZα-A进行了改造。将表达载体pPIC9的AOX1启动子序列引入pGAPZα-A,使之成为甲醇可诱导型表达载体pAOXZα,插入植酸酶基因appA-m后得到重组载体pAOXZα-appA-m。以染色体上带有一个拷贝的appA-m基因、发酵效价可达到7.5×106IU/mL发酵液的重组酵母菌株74#为受体菌进行转化,在该重组菌株的染色体上的另一位点整合含有植酸酶基因的表达盒,经筛选到高表达植酸酶的重组子。通过PCR进行验证,植酸酶基因被整合到重组酵母的染色体上,且受体菌中原有的植酸酶基因结构未改变。重组菌在5L发酵罐经甲醇诱导120h植酸酶蛋白表达量达到4mg/mL发酵液,酶活性(发酵效价)达到1.2×107IU/mL发酵液以上,较含单拷贝植酸酶基因的受体菌株表达量有较大程度提高。PCR检测及表达量分析证明改良的菌株具有很好的遗传稳定性和表达稳定性。     

亮白曲霉乳糖酶基因在毕赤酵母中的高效分泌表达及酶学性质研究

将克隆的亮白曲霉 (Aspergilluscandidus)乳糖酶基因lacb′插入到毕赤酵母 (Pichiapastoris)高效表达载体pPIC9中 ,与分泌信号肽序列α_因子融合 ,通过同源重组将lacb′整合到酵母染色体上。通过SDS_PAGE检测和表达产物的酶活性筛选 ,得到重组转化子 ,证明乳糖酶获得有效分泌和高效表达。表达的乳糖酶为糖蛋白 ,表观分子量为 130kD ,脱糖基后的蛋白分子量下降为 110kD。经过 5L小罐高密度发酵 ,重组酵母中酶蛋白表达量为 6mg mL发酵液 ,每毫升发酵液中乳糖酶的活力为 36 0 0U ,高于目前国内外报道的水平。进一步研究了表达产物的酶学性质 ,该酶最适pH为 5 . 2 ,最适反应温度 6 0℃ ,比活性为 70 6 . 5± 2 . 6U mg ,Km为 1 7mmol L ,Vmax为 3. 3μmol min。与米曲霉ATCC 2 0 4 2 3的乳糖酶相比 ,该乳糖酶具热稳定性强、比活性高、pH范围宽等特点。     

Expression of glycosylated haloalkane dehalogenase LinB in Pichia pastoris

Heterologous expression of the bacterial enzyme haloalkane dehalogenase LinB from Sphingomonas paucimobilis UT26 in methylotrophic yeast Pichia pastoris is reported. The haloalkane dehalogenase gene linB was subcloned into the pPICZalphaA vector and integrated into the genome of P. pastoris. The recombinant LinB secreted from the yeast was purified to homogeneity and biochemically characterized. The deglycosylation experiment and mass spectrometry measurements showed that the recombinant LinB expressed in P. pastoris is glycosylated with a 2.8 kDa size of high mannose core. The specific activity of the glycosylated LinB was 15.6 +/- 3.7 micromol/min/mg of protein with 1,2-dibromoethane and 1.86 +/- 0.36 micromol/min/mg of protein with 1-chlorobutane. Activity and solution structure of the protein produced in P. pastoris is comparable with that of recombinant LinB expressed in Escherichia coli. The melting temperature determined by the circular dichroism (41.7+/-0.3 degrees C for LinB expressed in P. pastoris and 41.8 +/- 0.3 degrees C expressed in E. coli) and thermal stability measured by specific activity to 1-chlorobutane were also similar for two enzymes. Our results show that LinB can be extracellularly expressed in eukaryotic cell and glycosylation had no effect on activity, protein fold and thermal stability of LinB.     

Overexpression, purification and characterization of the Trichoderma atroviride endochitinase, Ech42, in Pichia pastoris

The endochitinase gene ech42 from Trichoderma atroviride was cloned and expressed in Pichia pastoris using a constitutive expression system. Over 98% of the recombinant protein was secreted into the culture medium as glycoprotein. A high endochitinase concentration, 186 mg/L with a specific enzyme activity of 14,128 Umg(-1) was produced. The optimal enzyme kinetic parameters for the recombinant protein were identical to those reported for the enzyme isolated from T. atroviride. The recombinant endochitinase possesses suitable features for biotechnological applications, such as activity at acidic pH and thermostability.     

Biochemical properties of a thermostable phytase from Neurospora crassa

A gene (Ncphy) encoding a putative phytase in Neurospora crassa was cloned and expressed in Pichia pastoris, and the biochemical properties of the recombinant protein were examined in relation to the phytic acid hydrolysis in animal feed. The recombinant phytase (rNcPhy) hydrolyzed phytic acid with a specific activity of 125 U mg-1, Km of 228 micromol L-1, Vmax of 0.31 nmol (phosphate) s-1 mg-1, a temperature optimum of 60 degrees C and a pH optimum of 5.5 and a second pH optimum of 3.5. The enzyme displayed pH stability around pH 3.5-9.5 and showed satisfactory thermostability at 80 degrees C. The phytase from N. crassa has potential for improving animal feed processing at higher temperatures.     

Design and expression of a synthetic phyC gene encoding the neutral phytase in Pichia pastoris

The 1074-bp phyCs gene (optimized phyC gene) encoding neutral phytase was designed andsynthesized according to the methylotrophic yeast Pichia pastoris codon usage bias without altering theprotein sequence.The expression vector,pP9K-phyCs,was linearized and transformed in P.pastoris.Theyield of total extracellular phytase activity was 17.6 U/ml induced in Buffered Methanol-complex Medium(BMMY) and 18.5 U/ml in Wheat Bran Extract Induction (WBEI) medium at the flask scale,respectively,improving over 90 folds compared with the wild-type isolate.Purified enzyme showed temperature optimumof 70℃ and pH optimum of 7.5.The enzyme activity retained 97% of the relative activity afterincubation at 80℃ for 5 min.Because of the heavy glycosylation the expressed phytase had a molecularsize of approximately 51 kDa.After deglycosylation by endoglycosylase H (EndoH_f),the enzyme had anapparent molecular size of 42 kDa.Its property and thermostability was affected by the glycosylation.     

A novel phytase with preferable characteristics from Yersinia intermedia

A Yersinia intermedia strain producing phytase was isolated from glacier soil. The phytase gene, appA, was isolated by degenerate PCR and TAIL-PCR. The full-length fragment contained 2354bp with a 1326-bp open reading frame encoding 441 amino acids. APPA contained the active site RHGXRXP and HD sequence motifs that are typical of histidine acid phosphatases. To our knowledge, this is the first report of the detection of phytase activity and cloning of the relevant gene from Y. intermedia. The gene was overexpressed in Pichia pastoris, and the purified recombinant APPA had a specific activity for sodium phytate of 3960U/mg, which is higher than that of the Citrobacter braakii phytase (previously the highest specific activity known). Recombinant APPA had high activity from pH 2 to 6 (optimum 4.5) and optimal temperature of 55 degrees C; the enzyme was resistant to pepsin and trypsin. These characteristics suggest that APPA may be highly suitable for use in the feed industry.     

Aspergillus fumigatus来源植酸酶的Q23L和Q23LG272E突变研究

Aspergillus fumigatus来源的植酸酶具有热稳定性好、pH作用范围广的优点,但其比活性很低。设计的植酸酶Q23L突变能在pH4.5～7.0范围内大幅提高比活性,但pH稳定性却显著下降,为了进一步改良Q23L的pH稳定性,在Q23L分子上加入了G272E突变。将原酶、突变酶Q23L和突变酶Q23LG272E分别在毕赤酵母GS115中表达,表达酶经纯化后进行酶学性质比较分析,结果表明:突变酶Q23L的比活性比原酶显著提高,在pH5.5比活性由51u/mg提高到109u/mg,但其pH稳定性,尤其是在pH3.0～4.0酸性条件下的稳定性却显著降低,低于80%。突变酶Q23LG272E在pH3.0～4.5和pH6.5～7.0时的稳定性比Q23L有所提高,恢复到原酶的水平,而比活性基本维持在Q23L的水平。通过一级序列和三维结构比较,分析了可能影响Q23LG272E酶学性质的因素,为进一步研究植酸酶的结构与功能提供了材料。     

Production, characterization and crystallization of the Plasmodium falciparum aquaporin

The causative agent of malaria, Plasmodium falciparum posses a single aquaglyceroporin (PfAQP) which represents a potential drug target for treatment of the disease. PfAQP is localized to the parasite membrane to transport water, glycerol, ammonia and possibly glycolytic intermediates. In order to enable design of inhibitors we set out to determine the 3D structure of PfAQP, where the first bottleneck to overcome is achieving high enough yield of recombinant protein. The wild type PfAQP gene was expressed to low or undetectable levels in the expression hosts, Escherichia coli and Pichia pastoris, which was assumed to be due to different genomic A+T content and different codon usage. Thus, two codon-optimized PfAQP genes were generated. The Opt-PfAQP for E. coli still did not result in high production yields, possibly due to folding problems. However, PfAQP optimized for P. pastoris was successfully expressed in P. pastoris for production and in Saccharomyces cerevisiae for functional studies. In S. cerevisiae, PfAQP mediated glycerol transport but unexpectedly water transport could not be confirmed. Following high-level membrane-localized expression in P. pastoris (estimated to 64mg PfAQP per liter cell culture) PfAQP was purified to homogeneity (18mg/L) and initial attempts at crystallization of the protein yielded several different forms.     

Isolation, characterization, and molecular cloning of the cDNA encoding a novel phytase from Aspergillus niger 113 and high expression in Pichia pastoris

Phytases catalyze the release of phosphate from phytic acid. Phytase-producing microorganisms were selected by culturing the soil extracts on agar plates containing phytic acid. Two hundred colonies that exhibited potential phytase activity were selected for further study. The colony showing the highest phytase activity was identified as Aspergillus niger and designated strain 113. The phytase gene from A. niger 113 (phyI1) was isolated, cloned, and characterized. The nucleotide and deduced amino acid sequence identity between phyI1 and phyA from NRRL3135 were 90% and 98%, respectively. The identity between phyI1 and phyA from SK-57 was 89% and 96%. A synthetic phytase gene, phyI1s, was synthesized by successive PCR and transformed into the yeast expression vector carrying a signal peptide that was designed and synthesized using P. pastoris biased codon. For the phytase expression and secretion, the construct was integrated into the genome of P. pastoris by homologous recombination. Over-expressing strains were selected and fermented. It was discovered that ~4.2 g phytase could be purified from one liter of culture fluid. The activity of the resulting phytase was 9.5 U/mg. Due to the heavy glycosylation, the expressed phytase varied in size (120, 95, 85, and 64 kDa), but could be deglycosylated to a homogeneous 64 kDa species. An enzymatic kinetics analysis showed that the phytase had two pH optima (pH 2.0 and pH 5.0) and an optimum temperature of 60 degrees C.