地鳖虫纤溶活性蛋白cDNA序列克隆与毕赤酵母表达

依据已报道的地鳖虫成熟肽cDNA序列设计引物,通过RT-PCR法从地鳖虫(Eupolyphage sinensis Walker)中克隆得到675 bp地鳖虫纤溶活性蛋白 (fibrinolytic protein,EFP)成熟肽编码序列.将此片段克隆到表达载体pPICZα-A中,转化毕赤酵母GS115,甲醇诱导表达得到重组表达蛋白,经SDS-PAGE电泳和活性鉴定,表明重组EFP在毕赤酵母中均获得表达,重组表达蛋白相对分子质量为28.2 kD,表达产物分子质量与理论分子质量相符.重组蛋白在毕赤酵母中以分泌形式表达,具有纤溶活性.     

人组织型纤溶酶原激活剂-水蛭素融合基因的构建及其在毕赤酵母中的表达

构建并表达兼有溶栓和抗凝活性、减少出血副作用的人组织型纤溶酶原激活剂(t-PA)和水蛭素(HV2)的融合蛋白。通过提取总RNA和RT-PCR获得t-PA基因,与HV2基因通过活化凝血因子X(Fxa)识别序列（IEGR）的对应碱基序列连接构成融合蛋白基因,融合蛋白基因经pGEM-T、pIC9克隆至表达载体pIC9K上,电转导入毕赤酵母（Pichia pastoris）GS115。转化子摇瓶内甲醇诱导表达。纤维蛋白平板溶圈法和纤维蛋白凝块法分别检测溶栓和抗凝活性。琼脂糖凝胶电泳结果显示克隆的t-PA基因片段大小为1700bp,序列测定结果表明其35位氨基酸由文献报道的精氨酸突变为色氨酸。限制性酶切和PCR鉴定结果均表明融合蛋白基因已克隆入表达载体和宿主菌。甲醇利用实验、G418抗性筛选获得多拷贝甲醇利用快型克隆。甲醇诱导表达产物具有纤溶活性并可被抗t-PA抗体抑制。完整融合蛋白无抗凝活性,但以Fxa裂解后可释放抗凝活性。同时,融合蛋白以单链和双链两种形式存在。融合蛋白在血栓部位特有的Fxa作用下靶向释放抗凝活性,具有溶栓抗凝双功能,有望降低临床出血副作用。     

人微小纤溶酶原基因在甲醇营养型酵母中的表达*

用PCR方法扩增人微小纤溶酶原(Microplasminogen,mplg)cDNA,与分泌型酵母表达载体pHIL-D8重组,构成受醇氧化酶基因(AOX1)的启动子与转录终止区控制的酵母表达质粒,然后转化GS115酵母菌,经表型筛选、PCR扩增筛选阳性克隆,然后以甲醇诱导表达,mplg分泌至培液,以酪蛋白-琼脂糖平板溶圈法、发色底物法检测,mplg显示出纤溶活性。     

中介蝮蛇毒纤溶酶基因真核表达载体的构建及其功能的研究

目的:蛇毒纤维蛋白溶解酶能直接溶解纤维蛋白或纤维蛋白原,在心脑血管疾病的治疗方面具有潜在的应用价值。方法:采用双酶切技术从pMD18T-FLE I克隆载体上获得中介蝮蛇毒纤溶酶基因编码区,再将其亚克隆到真核表达载体pFASTBACHTa上,经转化、筛选和鉴定,获得重组真核表达质粒pFASTBACHTa-FLE。重组质粒经小鼠尾静脉快速注入小鼠体内,进行瞬时表达。结果:经SDS-PAGE和Western blot检测,表明在小鼠肝脏组织中有重组FLE蛋白表达。免疫组织化学检测证明该蛋白在小鼠肝脏组织中大量表达。纤维蛋白平板法鉴定该重组蛋白具有较高的纤溶活性,其活性呈现出剂量相关性和时间依赖性。因此为进一步对中介蝮蛇毒纤溶酶的应用奠定了坚实的基础。     

人纤溶酶原kringle 5在大肠杆菌中克隆和分泌表达

构建能够表达分泌性的人纤溶酶原kringle 5（简称hPK-5）的大肠杆菌工程菌。用PCR方法扩增获得hPK-5基因,构建原核表达载体pET-22b（＋）/hPK-5,转化大肠杆菌BL21（DE3）,经IPTG诱导表达并鉴定其免疫学活性。成功表达14kD的重组hPK-5,且约占菌体分泌性蛋白20%以上,经Western Blot分析表明其具有hPK-5的免疫抗原活性。人纤溶酶原kringle 5在大肠杆菌中BL21（DE3）获得可分泌表达。     

异源表达的幽门螺杆菌cag4蛋白有溶菌糖基转移酶活性

摘要【目的】构建融合基因原核表达载体pET-28a- cag4,并表达重组融合蛋白cag4,分析重组融合蛋白的酶活性,为新型抗生素（或是抗菌药物）的研发提供作用靶位。【方法】本研究利用PCR技术从幽门螺杆菌NCTC11637中克隆了cag4基因;经T-A克隆,酶切鉴定,构建了原核表达载体pET-28a- cag4;经测序鉴定正确后,转化进入大肠埃希菌 BL21(DE3)进行异源表达。利用IPTG体外诱导后,经SDS-PAGE和Western Bolt鉴定目的蛋白表达后,采用Ni2＋-NTA柱在变性条件下纯化目的蛋白,并对重组蛋白进行透析复性处理。将SDS煮沸法获得的溶壁微球菌肽聚糖掺入SDS-PAGE作为底物,进行酶谱分析。【结果】在大肠埃希菌 BL21(DE3)中获得高效表达的重组蛋白; 经SDS-PAGE和Western Bolt鉴定表达后,采用Ni2＋-NTA柱在变性条件下纯化,并进行透析复性处理。将SDS煮沸法获得的溶壁微球菌肽聚糖掺入SDS-PAGE作为底物,进行酶谱分析,表明目的蛋白具有明显的肽聚糖水解活性; 通过监测浊度下降速率,比较其在不同pH条件下活性的变化,即?A/（min?mg protein）,结果表明,幽门螺杆菌cag4蛋白具有溶菌糖基转移酶活性。【结论】幽门螺杆菌cag4蛋白具有溶菌糖基转移酶活性。     

新疆家蚕抗菌肽在毕赤酵母中表达及活性研究

目的:在毕赤酵母中表达新疆家蚕抗菌肽基因(Cecropin-XJ)并检测其活性.方法:根据作者实验室已克隆获得的新疆家蚕抗菌肽(Cecropin-XJ)基因设计引物,通过PCR方法扩增Cecropin-XJ,将PCR产物和表达载体pPIC9K用EcoR Ⅰ及Not Ⅰ双酶切,构建重组表达质粒pPIC9K-(Cecropin-XJ),酶切及测序正确后,电转化到毕赤酵母GS115,对分泌表达的重组蛋白进行活性检测.结果:PCR扩增获得192 bp Cecropin-XJ,成功构建pPIC9K-Cecropin-XJ,优化诱导条件证明在pH 6的BMMY培养液中,0.5%甲醇诱导约48h后,获得的表达产物活性较强,对多种革兰氏阴性菌和阳性菌具有抗菌活性,在100℃条件下,其活性可维持100min以上.结论:新疆家蚕抗菌肽在毕赤酵母中分泌表达,为大规模发酵生产奠定了基础.     

利用degQ基因提高枯草芽孢杆菌纤溶酶表达

从枯草芽孢杆菌(Bacillus subtilis)中通过PCR扩增得到degQ基因,将其克隆到含有枯草杆菌纤溶酶基因的蔗糖诱导表达载体pUBS中,并转化至B．subtillis DB403受体菌,得到基因工程菌DB403(pUBSD)。通过发酵表达证实degQ基因能增强枯草杆菌纤溶酶的表达,酶活提高了2．2倍。同时还对不同种类的糖、不同浓度蔗糖、不同诱导时间等发酵条件进行优化和比较研究。     

利用degQ基因提高枯草芽孢杆菌纤溶酶表达*

从枯草芽孢杆菌(Bacillussubtilis)中通过PCR扩增得到degQ基因,将其克隆到含有枯草杆菌纤溶酶基因的蔗糖诱导表达载体pUBS中,并转化至B.subtillisDB403受体菌,得到基因工程菌DB403(pUBSD)。通过发酵表达证实degQ基因能增强枯草杆菌纤溶酶的表达,酶活提高了2.2倍。同时还对不同种类的糖、不同浓度蔗糖、不同诱导时间等发酵条件进行优化和比较研究。     

重组瑞替普酶在毕赤酵母中的表达

【目的】瑞替普酶(重组组织纤溶酶原激活物,rt PA)被认为是第三代安全有效的溶栓剂,以p PIC9K为载体,以3种不同表型的毕赤酵母(Pichia pastoris)为宿主,探索适合rt PA分泌型表达的最佳体系。【方法】以质粒p ET28a-rt PA为模板,设计特异性引物,PCR扩增目的基因rt PA,插入分泌型表达载体p PIC9K中,获得重组表达质粒p PIC9K-rt PA。重组质粒经限制性内切酶Sal I线性化后,电击转化至3种不同表型的P.pastoris(GS115、SMD1168、KM71)中进行组成型表达;重组表达体系进行甲醇诱导表达,对产物进行Western blot鉴定,并采用纤维蛋白平板溶圈法测定其活性。【结果】重组蛋白分子量约为43 k D;rt PA-GS115和rt PA-KM71均在39 k D处有特异性条带,且前者在32 k D处有轻微降解条带,而后者并无此现象;rt PA-SMD1168无降解现象,且rt PA-SMD1168比活性较rt PA-GS115高27%;rt PA-KM71表达量和活性均为最低。【结论】从重组蛋白生物活性出发,P.pastoris SD1168可作为rt PA的最佳表达体系,在控制宿主蛋白酶活性、减少产物降解的前提下,P.pastoris GS115也是rt PA表达的优选体系。     

Expression, purification, and activity identification of Alfimeprase in Pichia pastoris

Alfimeprase (ALF) is a truncated form of non-hemorrhagic zinc metalloproteinase fibrolase. In order to achieve a high level secretion and full activity expression of ALF, the Pichia pastoris (P. pastoris) expression system was used. ALF coding sequence fused with a 6 *histidine tag and an enterokinase recognition site at the N-terminus was cloned into the expression vector pPIC9K and then expressed in P. pastoris strains of GS115 and KM71 by methanol induction. SDS-PAGE and Western blotting analysis showed that the secreted recombinant ALF (rALF) had a molecular weight of 23.8 kDa and was bound specifically to mouse anti-His. tag monoclonal antibody. Under the optimized culture parameters of pH value, initial A(600) value, methanol daily addition concentration and induction time length, the production of rALF reached up to 510 mg/L and 465 mg/L of the GS115 and KM71 transformants, respectively. It also appeared that KM71 was producing a more pure protein than GS115 while GS115 was producing more rALF per unit volume. Through one-step affinity chromatography, the purity of rALF was as high as 96%. The fibrinolytic activity of rALF revealed by the modified fibrin plate method indicated that the protein was efficiently secreted and functionally expressed, and thrombolysis of rALF was demonstrated to be dose-dependent and time-relative. The improved expression system will facilitate further studies and industrial production of ALF.     

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。     

B→O血型转变工具酶α-半乳糖苷酶cDNA克隆及表达

 α-半乳糖苷酶是实现 B→O血型转变、制备通用型血的关键工具酶 .利用反转录 PCR方法从中国海南 Catimor咖啡豆中克隆α-半乳糖苷酶 c DNA,插入嗜甲基酵母 P.pastoris分泌表达载体 p PIC9K中 ,转化 P.pastoris GS1 1 5,筛选高表达重组菌株 .经甲醇诱导表达 7d后 ,发酵液总蛋白分泌量约 1 .2 mg/ml,SDS- PAGE呈现约 41 k D特异表达带 ,与专一性底物对 -硝基 -苯基 -α- D-吡喃半乳糖苷反应证明 ,表达产物具有 α-半乳糖苷酶活性 ,最高达到 1 8U/ml.初步实验表明 ,表达的 α-半乳糖苷酶可酶解 B型红细胞 ,成功实现 B→O血型转变 .     

高温α-淀粉酶基因突变体在大肠杆菌、毕赤酵母中的表达

对地衣芽孢杆菌(Bacillus licheniformis)高温α-淀粉酶(amyE)基因进行改造获得的基因突变体(amyEM),通过PCR扩增,将此基因分别克隆至大肠杆菌表达载体pBV220和毕赤酵母表达载体pPIC9K上,并分别转化大肠杆菌DH5α和毕赤酵母GS115感受态细胞,获得重组大肠杆菌和重组毕赤酵母。通过表达产物的酶活性检测和SDS-PAGE分析,证明突变α-淀粉酶(AmyEM)在大肠杆菌、毕赤酵母中获得有效表达。对重组大肠杆菌产生的α-淀粉酶的粗酶性质分析表明,此酶分子量约为55kDa。其最适反应温度为80℃~90℃,与野生型基因相比,其最适pH均为6.0,但不同的是突变体在pH 5.0~5.5时表现出较高的酶活力;在毕赤酵母细胞的表达产物可分泌至胞外。由于酵母可对蛋白进行糖基化,酶分子量增加到60kDa,最适pH也改变为5.5。此高温α-淀粉酶突变体所具有的在微酸性环境具有较高酶活力的性质,具有重要的潜在工业应用价值。     

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。     

重组毕赤酵母表达棘孢木霉几丁质酶Tachi1的酶学性质研究及表达条件优化

【目的】对转棘孢木霉几丁质酶基因tachi1的毕赤酵母工程菌GS-tachi1-K进行诱导表达,研究重组几丁质酶Tachi1的酶学性质,优化表达条件。【方法】对GS-tachi1-K进行甲醇诱导培养,纯化目的蛋白Tachi1进行几丁质酶酶学性质的研究;通过单因素和正交试验对GS-tachi1-K菌株产几丁质酶Tachi1表达条件进行优化。【结果】GS-tachi1-K表达的几丁质酶Tachi1表观分子量约为44 kDa,酶反应最适的温度和pH分别为50℃和5.5,具有较宽的温度、pH适用范围;50℃以下保持较高的酶活力,在碱性条件下稳定性较差;受Ag+、Hg2+、Cu2+、Fe2+和高浓度的SDS及β-巯基乙醇强烈抑制。该菌株的最佳表达条件为:pH为6.5,甲醇诱导浓度为0.5%,起始细胞浓度为OD600=2,甲醇诱导时间为180 h;几丁质酶Tachi1活力可达17.93 U/mL,蛋白表达量为6.19 g/L。【结论】成功实现了棘孢木霉新几丁质酶基因tachi1的毕赤酵母高效分泌表达,工程菌GS-tachi1-K具有高表达量和表达产物酶活性高两个特点,明确了几丁质酶Tachi1的酶学性质和最佳诱导表达条件,为该几丁质酶及其基因的深入研究和开发利用奠定了基础。     

高密度发酵P.pastoris诱导表达egⅡ基因

用套叠PCR法扩增里氏木霉(Trichoderma reesei)的葡聚糖内切酶II(egⅡ)基因.扩增基因经EcoR I和Not I双酶切后克隆进P.pastoris表达载体pPIC9k,获得重组表达质粒pPIC9K-egⅡ.通过电转法将egⅡ基因重组于P.pastoris基因组,筛选高G418抗性的转化子作为工程菌...     

Improved production of recombinant ovine interferon-tau by mut(+) strain of Pichia pastoris using an optimized methanol feed profile

Recombinant ovine interferon-tau (r-oIFN-tau) production by Pichia pastoris was studied using methanol as the sole carbon source during induction. The cells were grown on glycerol up to a certain cell density before induction of the AOX1 promoter by methanol for expression of the recombinant protein. Cell growth on methanol has been modeled using a substrate-feed equation, which served as the basis for an effective computer control of the process. The r-oIFN-tau concentration in the culture began to decline despite continued cell growth after 50 (+/- 6) h of induction, which was associated with an increase in proteolytic activity of the fermentation broth. A specific growth rate of 0.025 h(-1) was found to be optimal for r-oIFN-tau production. No significant improvement in r-oIFN-tau production was observed when the specific growth rate was stepped up before the critical point when r-oIFN-tau concentration started decreasing during fermentation. However, best results were obtained when the specific growth rate was stepped down from 0.025 to 0.02 h(-1) at 38 h of induction, whereby the active production period was prolonged until 70 h of induction and the broth protease activity was correspondingly reduced. The corresponding maximum protein yield was 391.7 mg x L(-1) after 70 h of fermentation. The proteolytic activity could be reduced by performing fermentations at specific growth rates of 0.025 h(-1) or below. The recombinant protein production can be performed at an optimal yield by directly controlling the methanol feed rate by a computer-controlled model. The production profile of r-oIFN-tau was found to be significantly different from other secreted and intracellular recombinant protein processes, which is an indication that recombinant protein production in Pichia pastoris needs to be optimized as individual processes following established principles.     

High-level secretion and purification of recombinant acetylcholinesterase from human cerebral tissue in P. pastoris and identification by chromogenic reaction

The gene encoding human cerebral tissue acetylcholinesterase (AChE) was cloned from an 18-week fetal cerebral tissue and expressed in Pichia pastoris. Twenty-two positive transformants were obtained by Mut⁺/Mut^s phenotypes screening in MD/MM medium and polymerase chain reaction amplification, and four recombinant P. pastoris strains that could secrete active AChE at high level were identified by simple and specific development reaction with indoxyl acetate as the chromogenic substrate. In shake-flask culture induced with methanol, the recombinant human AChE (rhAChE) content was about 76% of the total secreted proteins, and rhAChE activity in supernatant was 40 U/ml. The enzyme was purified through anion-exchange and affinity chromatography. Purity of the rhAChE was up to 96% after the simple purification procedure. The enzymatic activity reached 200 U/mg.     

Enhanced heterologous protein production in Pichia pastoris under increased air pressure

Pichia pastoris is a widely used host for the production of heterologous proteins. In this case, high cell densities are needed and oxygen is a major limiting factor. The increased air pressure could be used to improve the oxygen solubility in the medium and to reach the high oxygen demand of methanol metabolism. In this study, two P. pastoris strains producing two different recombinant proteins, one intracellular (β‐galactosidase) and other extracellular (frutalin), were used to investigate the effect of increased air pressure on yeast growth in glycerol and heterologous protein production, using the methanol AOX1‐inducible system. Experiments were carried out in a stainless steel bioreactor under total air pressure of 1 bar and 5 bar. The use of an air pressure raise of up to 5 bar proved to be applicable for P. pastoris cultivation. Moreover, no effects on the kinetic growth parameters and methanol utilization (Mut) phenotype of strains were found, while an increase in recombinant β‐galactosidase‐specific activity (ninefold) and recombinant frutalin production was observed. Furthermore, the air pressure raise led to a reduction in the secreted protease specific activity. This work shows for the first time that the application of an air pressure of 5 bar may be used as a strategy to decrease protease secretion and improve recombinant protein production in P. pastoris. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:1040–1047, 2014