A BAHD acyltransferase is expressed in the tapetum of Arabidopsis anthers and is involved in the synthesis of hydroxycinnamoyl spermidines

BAHD acyltransferases catalyze the acylation of many plant secondary metabolites. We characterized the function of At2g19070 , a member of the BAHD gene family of Arabidopsis thaliana . The acyltransferase gene was shown to be specifically expressed in anther tapetum cells in the early stages of flower development. The impact of gene repression was studied in RNAi plants and in a knockout (KO) mutant line. Immunoblotting with a specific antiserum raised against the recombinant protein was used to evaluate the accumulation of At2g19070 gene product in flowers of various Arabidopsis genotypes including the KO and RNAi lines, the male sterile mutant ms1 and transformants overexpressing the acyltransferase gene. Metabolic profiling of flower bud tissues from these genetic backgrounds demonstrated a positive correlation between the accumulation of acyltransferase protein and the quantities of metabolites that were putatively identified by tandem mass spectrometry as N ¹, N ⁵, N ¹⁰-trihydroxyferuloyl spermidine and N ¹, N ⁵-dihydroxyferuloyl- N ¹⁰-sinapoyl spermidine. These products, deposited in pollen coat, can be readily extracted by pollen wash and were shown to be responsible for pollen autofluorescence. The activity of the recombinant enzyme produced in bacteria was assayed with various hydroxycinnamoyl-CoA esters and polyamines as donor and acceptor substrates, respectively. Feruloyl-CoA and spermidine proved the best substrates, and the enzyme has therefore been named spermidine hydroxycinnamoyl transferase (SHT). A methyltransferase gene ( At1g67990 ) which co-regulated with SHT during flower development, was shown to be involved in the O -methylation of spermidine conjugates by analyzing the consequences of its repression in RNAi plants and by characterizing the methylation activity of the recombinant enzyme.     

The lipase/acyltransferase from Candida parapsilosis: molecular cloning and characterization of purified recombinant enzymes.

Candida parapsilosis has been previously shown to produce a lipase (i.e. able to catalyze efficiently the hydrolysis of insoluble lipid esters such as triacylglycerols) that preferentially catalyses transfer reactions such as alcoholysis in the presence of suitable nucleophiles other than water, even in aqueous media with high (> 0.9) water thermodynamic activity. The present work describes the cloning and the overexpression of the gene coding for this enzyme. Two ORFs (CpLIP1 and CpLIP2) were isolated. The deduced 465-amino-acid protein sequences contained the consensus motif (G-X-S-X-G) which is conserved among lipolytic enzymes. Only one of the two deduced proteins (CpLIP2) contained peptide sequences obtained from the purified lipase/acyltransferase. Homology investigations showed that CpLIP2 has similarities principally with 11 lipases produced by C. albicans (42-61%) and the lipase A from Candida antarctica (31%) but not with the other lipases sequenced so far. Both CpLIP1 and CpLIP2 were expressed in Saccharomyces cerevisiae, but only CpLIP2 coded for an active protein. The substrate specificity and the catalytic behavior of purified recombinant CpLIP2, with or without a C-terminal histidine tag, were not changed compared to those of the native lipase.     

Cloning, disruption and protein secretory phenotype of the GAS1 homologue of Pichia pastoris

The aim of the study was the identification, cloning and disruption of the GAS1 homologue of Pichia pastoris. Gas1p is a glycoprotein anchored to the outer layer of the plasma membrane through a glycosylphosphatidylinositol (GPI) anchor. Gas1p is a beta-1,3-glucanosyltransglycosylase (EC 2.4.1.-). This cross-linking enzyme highly affects the structure and permeability of the yeast cell wall. The gene coding for the GAS1 homologue of P. pastoris was cloned by PCR, and its functionality was proven in a Saccharomyces cerevisiae GAS1 null mutant. Based on the nucleotide sequence information of the P. pastoris GAS1 homologue, a disruption cassette was constructed for the knockout of the GAS1 in P. pastoris. The morphology of DeltaGAS1 P. pastoris was identical to that of S. cerevisiae GAS1 mutants. Finally, the impact of GAS1 disruption on secretion of three recombinant model proteins in P. pastoris, human trypsinogen, human serum albumin and Rhizopus oryzae lipase, was evaluated. While the disruption had no effect on the secretion of trypsinogen and albumin, the amount of lipase released from the cells was doubled.     

Design, total synthesis, and functional overexpression of the Candida rugosa lip1 gene coding for a major industrial lipase.

The dimorphic yeast Candida rugosa has an unusual codon usage that hampers the functional expression of genes derived from this yeast in a conventional heterologous host. Commercial samples of C. rugosa lipase (CRL) are widely used in industry, but contain several different isoforms encoded by the lip gene family, among which the isoform encoded by the gene lip1 is the most prominent. In a first laborious attempt, the lip1 gene was systematically modified by site-directed mutagenesis to gain functional expression in Saccharomyces cerevisiae. As alternative approach, the gene (1647 bp) was completely synthesized with an optimized nucleotide sequence in terms of heterologous expression in yeast and simplified genetic manipulation. The synthetic gene was functionally expressed in both hosts S. cerevisiae and Pichia pastoris, and the effect of heterologous leader sequences on expression and secretion was investigated. In particular, using P. pastoris cells, the synthetic gene was functionally overexpressed, allowing for the first time to produce recombinant Lipl of high purity at a level of 150 U/mL culture medium. The physicochemical and catalytic properties of the recombinant lipase were compared with those of a commercial, nonrecombinant C. rugosa lipase preparation containing lipase isoforms.     

少根根霉(Rhizopus arrhizus)脂肪酶基因在毕赤酵母中的分泌表达

利用PCR技术从少根根霉中扩增出脂肪酶基因(包括前导序列和成熟肽),并将其连接到酵母分泌表达载体pPIC9K中,转化毕赤酵母GS115。利用抗生素G418从重组阳性克隆中筛选得到高拷贝的转化子。在5 L的发酵罐中,当碳源耗尽后开始流加甲醇诱导脂肪酶的表达,经过96 h培养后发酵液上清液中重组脂肪酶(rRAL)的表达量约为90 mg/L。rRAL经过超滤,SP-Sepharose离子交换层析和Butyl-Sepharose疏水层析纯化。纯化后的蛋白在SDS-PAGE上为单一条带,表观分子量为32 kDa,比酶活为1 543 U/mg。N-端序列分析表明rRAL是经过加工后的产物。同时没有发现全长的Rhizopus arrhizus脂肪酶(RAL)被分泌表达。     

Cloning, expression and characterization of a lipase gene from the Candida antarctica ZJB09193 and its application in biosynthesis of vitamin A esters

Lipase is one of the most important industrial enzymes, which has been widely used in the preparation of food additives, cosmetics and pharmaceuticals industries. In order to obtain a large amount of lipase, the lipase gene from Candida antarctica ZJB09193 was cloned, and expressed in Pichia pastoris with the vector pPICZαA. Under the optimal conditions, the yield of recombinant lipase in the culture broth reached 3.0 g/L. After purification, the properties of recombinant lipase were studied: the optimum pH and temperature were pH 8.0 and 52°C, Ca(2+) activated the activity of lipase, and the apparent K(m) and V(max) values for p-nitrophenyl acetate were 0.34 mM and 7.36 μmol min(-1) mg(-1), respectively. Furthermore, the recombinant lipase was immobilized on pretreated textile for biosynthesis of vitamin A esters. In a system of n-hexane, 0.3 g immobilized recombinant lipase was used in the presence of 0.06 g vitamin A acetate and 0.55 mmol fatty acid (nine different fatty acids were tested). The yield of all vitamin A esters exceeded 78% in 7h at 30°C except using lactic acid and hexanoic acid as substrates. After optimization, the yield of vitamin A palmitate reached 87%. This study has the potential to be developed into industrial application.     

毕赤酵母组成型表达脂肪酶及其高通量筛选方法

【目的】获得组成型表达脂肪酶毕赤酵母,建立利用橄榄油罗丹明B平板高通量筛选组成型表达华根霉脂肪酶基因的有效方法。【方法】运用PCR技术从pGAPZαA表达载体上扩增得到GAP启动子片段,插入到表达载体pPIC9K-proRCL中,构建组成型表达载体pGAPK-proRCL。在保留含有同源双交换重组序列的诱导型启动子AOX1序列的基础上,电转化后华根霉Rhizopus chinensis CCTCC M201021脂肪酶基因proRCL表达盒在毕赤酵母基因组上发生双交换整合事件,从而组成型表达单拷贝的华根霉脂肪酶基因。【结果】重组菌发酵144 h后,脂肪酶最高酶活为130 U/mL。利用橄榄油罗丹明B平板高通量筛选组成型表达华根霉脂肪酶基因。【结论】该方法将初筛时间从12 d缩短为3 d,排除了多拷贝突变株的干扰,为后续脂肪酶的定向进化及筛选奠定了基础。     

High-level expression of extracellular lipase Lip2 from Yarrowia lipolytica in Pichia pastoris and its purification and characterization

The extracellular lipase gene from Yarrowia lipolytica (YlLip2) was cloned into the pPICZalphaA and integrated into the genome of the methylotrophic yeast Pichia pastoris X-33. The lipase was successfully expressed and secreted with an apparent molecular weight of 39kDa using Saccharomyces cerevisiae secretion signal peptide (alpha-factor) under the control of the methanol inducible promoter of the alcohol oxidase 1 gene (AOX1). The lipase activity of 12,500,000U/l (2.10g total protein and 0.63g lipase per liter) was obtained in a fed-batch cultivation, where methanol feeding was linked to the dissolved oxygen content after initial glycerol culture. After fermentation, the supernatant was concentrated by ultrafiltration with a 10kDa cut off membrane and purified with ion exchange chromatography using Q Sepharose FF. Deglycosylation showed that the recombinant lipase is a glycoprotein which contains the same content of sugar (about 12%) as the native lipase from Y. lipolytica. The optimum temperature and pH of the recombinant lipase was 40 degrees C and 8.0, respectively. The lipase showed high activity toward long-chain fatty acid methyl esters (C12-C16).     

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。     

白地霉脂肪酶在毕赤酵母表面展示

将白地霉脂肪酶基因N端与酿酒酵母FLO絮凝结构域序列融合,构建成脂肪酶毕赤酵母表面展示载体并转化毕赤酵母GS115。免疫荧光检测证实脂肪酶已展示于毕赤酵母细胞表面。甲醇诱导96 h后展示酶活性达到81 U/g干细胞,酶的热稳定性较游离酶有较大提高,50℃孵育4 h后酶活仍保持初始酶活70%以上。     

Expression and characterization of recombinant Rhizopus oryzae lipase for enzymatic biodiesel production

The Rhizopus oryzae lipase containing prosequence was expressed in Pichia pastoris. Recombinant lipase subunit showed a molecular mass of 32 kDa. The maximum activity of recombinant lipase obtained from Mut(s) recombinant was 90 IU/ml. The enzyme was stable in broad ranges of temperatures and pH, with the optimal temperature at 35 °C and pH 7.0. The crude recombinant R. oryzae lipase can be directly used for the transesterification of plant oils at high-water content of 60-100% (w/w) based on oil weight. The addition of 80% water to the transesterification systems resulted in the yield of methyl ester of 95%, 94% and 92% after 72 h using soybean oil, Jatropha curcas seed raw oil and Pistacia chinensis seed raw oil as raw material, respectively. These results indicate that the recombinant lipase is an effective biocatalyst for enzymatic biodiesel production.     

Production of glycosylated thermostable Providencia rettgeri penicillin G amidase in Pichia pastoris

Penicillin G amidase from Providencia rettgeri is a heterodimer of 92 kDa. We have previously expressed the Pr. rettgeri pac gene coding for this enzyme in Saccharomyces cerevisiae, and now we report the expression and characterization in the methylotrophic yeast Pichia pastoris. The recombinant catalytically active enzyme (rPAC(Pr)) was secreted from shake flask-grown P. pastoris cells into the medium at a level of approximately 0.18 U ml(-1). This yield of rPAC(Pr) was higher, by two orders of magnitude, than that obtained using a single-copy expression plasmid in S. cerevisiae. In addition, the secreted recombinant enzyme was entirely N-glycosylated. The recombinant PAC(Pr) was further characterized in terms of specific activity, kinetic parameters and thermostability. Except the significantly higher thermostability of the glycosylated rPAC(Pr) produced in P. pastoris, the other parameters were very similar to those of the corresponding non-glycosylated enzymes produced in bacteria or in S. cerevisiae. The higher thermostability of this recombinant enzyme has a clear industrial advantage.     

基于易错PCR定向进化扩展青霉 Penicillium expansum FS1884碱性脂肪酶

为改善扩展青霉FS1884碱性脂肪酶的活性及酶学性质,利用连续两轮易错PCR对扩展青霉FS1884脂肪酶基因PEL进行随机突变,在大肠杆菌JM109中构建突变文库。含突变脂肪酶基因的重组质粒电击转化巴斯德毕赤酵母GS115,经过YPOM板初筛和橄榄油检验板复筛,获得一株酶活性提高的脂肪酶突变体:PEL-ep25-GS。与野生型脂肪酶PEL-GS相比,在最适温度40℃、pH9.4时突变体的酶活力是野生型酶的1.3倍。测序结果表明:该突变体第253位氨基酸发生了突变,由赖氨酸变成蛋氨酸。     

A combined approach for improving alkaline acetyl xylan esterase production in Pichia pastoris, and effects of glycosylation on enzyme secretion, activity and stability

High level expression of axe1, a gene previously cloned from Volvariella volvacea that encodes an acetyl xylan esterase with two potential N-linked glycosylation sites, has been achieved in Pichia pastoris using a codon-optimized axe1 synthesized by the primer extension PCR procedure. The GC content of the codon-optimized axe1 was 48.62% compared with 55.49% in the native gene. Using the codon-optimized construct, AXE1 expression in P. pastoris was increased from an undetectable level to 136.45U/ml six days after induction of yeast cultures grown in BMMY medium. A further increase (to 463U/ml) was achieved when conditions for yeast culture were optimized as follows: 2.8% methanol, 0.63% casamino acids, and pH 8.0. This latter value represented a 3.4-fold and 246-fold increase in the enzyme levels recorded in non-optimized P. pastoris cultures and in rice straw-grown cultures of V. volvacea, respectively. N-linked glycosylation played an essential role in AXE1 secretion but had only a slight effect on the catalytic activity and stability of the recombinant enzyme.     

Enhanced thermostability of a Rhizopus chinensis lipase by in vivo recombination in Pichia pastoris

ABSTRACT: BACKGROUND: Lipase from Rhizopus chinensis is a versatile biocatalyst for various bioconversions and has been expressed at high-level in Pichia pastoris. However, the use of R. chinensis lipase in industrial applications is restricted by its low thermostability. Directed evolution has been proven to be a powerful and efficient protein engineering tool for improvement of biocatalysts. The present work describes improvement of the thermostability of R. chinensis lipase by directed evolution using P. pastoris as the host. RESULTS: An efficient, fast and highly simplified method was developed to create a mutant gene library in P. pastoris based on in vivo recombination, whose recombination efficiency could reach 2.3 x 105 /mug DNA. The thermostability of r27RCL was improved significantly by two rounds of error-prone PCR and two rounds of DNA shuffling in P. pastoris. The S4-3 variant was found to be the most thermostable lipase, under the conditions tested. Compared with the parent, the optimum temperature of S4-3 was two degrees higher, Tm was 22 degrees higher and half-lives at 60degreesC and 65degreesC were 46- and 23- times longer. Moreover, the catalytic efficiency kcat/Km of S4-3 was comparable to the parent. Stabilizing mutations probably increased thermostability by increasing the hydrophilicity and polarity of the protein surface and creating hydrophobic contacts inside the protein. CONCLUSIONS: P. pastoris was shown to be a valuable cell factory to improve thermostability of enzymes by directed evolution and it also could be used for improving other properties of enzymes. In this study, by using P. pastoris as a host to build mutant pool, we succeeded in obtaining a thermostable variant S4-3 without compromising enzyme activity and making it a highly promising candidate for future applications at high temperatures.     

Molecular cloning and functional expression of a novel extracellular lipase from the thermotolerant yeast Candida thermophila

The thermotolerant yeast Candida thermophila SRY-09 isolated from Thailand produces an extracellular lipase that hydrolyses various triglycerides. To clone the gene encoding the lipase, Saccharomyces cerevisiae was transformed with a C. thermophila genomic library and screened for lipase activity on medium containing olive oil emulsion and rhodamine B. One C. thermophila lipase gene (CtLIP) was found that contained an ORF of 1317 bp encoding a deduced polypeptide of 438 amino acids. Candida thermophila lipase contained a Gly-Asp-Ser-Gln-Gly motif which matched the consensus Gly-X-Ser-X-Gly conserved among lipolytic enzymes. Heterologous expression of the cloned CtLIP under the control of the alcohol oxidase gene (AOX1) promoter in the methylotrophic yeast Pichia pastoris, and enzymatic measurements confirmed the function of the respective protein as a lipase. The recombinant CtLIP could hydrolyse various substrates at high temperature (55 degrees C) with higher efficiency than at 37 or 45 degrees C and preferentially hydrolysed two-positional ester bonds. As with C. thermophila, the heterologously expressed lipase was secreted into the medium by Pichia pastoris.     

枯草芽孢杆菌(Bacillus subtilis)碱性脂肪酶基因在毕赤酵母中的表达

将来自枯草芽孢杆菌的碱性脂肪酶基因经密码子优化,全基因合成后克隆到pPICZαA载体,构建了pPICZαA-bsl分泌型重组质粒,该重组质粒经限制性内切酶PmeI线性化后使用LiCl法转化到毕赤酵母X-33,经过筛选获得分泌表达碱性脂肪酶的重组毕赤酵母X-33/pPICZαA-bsl。摇瓶发酵液上清酶活最高可达4.78 U/mL,初步研究了该脂肪酶的酶学性质,其最适作用温度为40-60℃,最适pH9.0,且具有高度耐碱的特性。该重组脂肪酶对旧新闻纸具备较明显的脱墨能力。     

内生多粘芽孢杆菌EJS-3纤溶酶基因在毕赤氏酵母中的表达

以自构建的重组质粒pET-DsbA/PPFE-I为模板,扩增内生多粘芽孢杆菌纤溶酶基因PPFE-I,构建Pichia pastoris表达载体pPICZαA/PPFE-I,通过电击转化,pPICZαA/PPFE-I 被整合到Pichia pastoris SMD1168基因组中,抗性筛选得到的阳性转化子,用终浓度为1%甲醇诱导72 h,酶活达到286 IU/ml,是野生菌的2.6倍,表达产物用SDS-PAGE进行分析,在相对分子质量63 kDa处出现明显的蛋白条带,降解人血纤维蛋白试验中rPPFE-I最先降解人血纤维蛋白原的α链,其次是β链,而对γ链降解最缓慢。实现了多粘类芽孢杆菌纤溶酶基因在毕赤酵母中的表达,为植物内生菌来源溶栓药物的开发提供了新的途径。     

基于基因的重新设计与高通量筛选策略选育解脂耶氏酵母脂肪酶高产菌株

脂肪酶（EC 3.1.1.3）是应用广泛的工业用酶。高效的脂肪酶产生菌是脂肪酶工业生产和应用的前提。通过基因的重新设计与合成技术优化了解脂耶氏酵母（Yarrowia lipolytica）脂肪酶YLL的密码子,并实现了其在毕赤酵母（Pichia pastoris）中的高效表达;通过高通量筛选策略获得了更高效的脂肪酶基因工程菌菌株SILVER。在14 L发酵罐条件下,菌株SILVER酶活达40 500 U/ml、蛋白质含量达2.52 g/L发酵液,为该类脂肪酶的产业化奠定了基础。     

疏棉状嗜热丝孢菌脂肪酶基因在毕赤酵母工程菌中的遗传稳定性

【背景】重组工程菌的传代稳定性是保证外源蛋白高效稳定表达的前提,是决定工业化生产能力的关键因素之一。【目的】对异源的疏棉状嗜热丝孢菌脂肪酶基因在毕赤酵母重组工程菌中的遗传稳定性进行研究。【方法】将工程菌连续传代15次,取第1、5、10、15代作为受检代次,结合重组菌的菌落及菌体形态、水解酶活、目的基因片段、外源基因拷贝数等指标综合评价其遗传稳定性。【结果】传代过程中重组菌的菌落和菌体形态、目的蛋白分子量、目的基因序列均保持一致。目的基因的整合拷贝数经5次传代后发生一定损失,但随后稳定为7左右,而脂肪酶的相对酶活则提高至90%以上。【结论】适量的整合拷贝数更有利于该脂肪酶基因在毕赤酵母重组菌中的表达,经综合评价此工程菌的遗传稳定性良好,应用于工业化大规模生产是可行的。