乙醛脱氢酶2基因在毕赤酵母中的表达和分离纯化

将乙醛脱氢酶2（ALDH2）基因整合到质粒pPIC9K上,构建重组表达载体pPIC9K-coALDH2,用电转导将表达质粒pPIC9K-coALDH2转化至毕赤酵母GS115中,在毕赤酵母中表达经密码子改造的ALDH2。结果表明：重组基因工程菌GS115（pPIC9K-coALDH2）发酵液中蛋白质量浓度为8.40 mg/L,1 mL发酵液中酶活为11.35 mU。     

表达条件对金属激活酶NAOase离子依赖的活性分析

N-乙酰鸟氨酸脱酰基酶为一种新型手性拆分酶制剂,酶活性依赖于Mg2＋、Mn2＋、Zn2＋及Co2＋ 中的某种金属离子。以高表达NAOase的重组菌DH10B/argE-pHsh为研究对象,考察不同培养条件下Mg2＋、Mn2＋、Zn2＋及Co2＋ 4种离子对重组菌的生长、酶的表达活性及表达量的影响。结果发现：同种离子在不同条件下对重组菌的生长影响不大,但对酶活性影响显著。4种离子在合适浓度时皆能提高酶活性,促进强度从高到低依次为Mn2＋、Mg2＋、Co2＋和Zn2＋。在TB培养基中,Mn2＋为15 mmol/L时：NAOase比酶活达到1 272.7 U/mL,是未添加时的4.67倍,激活作用显著高于其他离子。SDS-PAGE电泳实验表明4种离子的蛋白表达量基本相同。     

Utilizing a regulated targeted integration cell line development approach to systematically investigate what makes an antibody difficult to express

Chinese hamster ovary (CHO) cells are conventionally used to generate therapeutic cell lines via random integration (RI), where desired transgenes are stably integrated into the genome. Targeted integration (TI) approaches, which involve integration of a transgene into a specific locus in the genome, are increasingly utilized for CHO cell line development (CLD) in recent years. None of these CLD approaches, however, are suitable for expression of toxic or difficult-to-express molecules, or for determining the underlying causes for poor expression of some molecules. Here we introduce a regulated target integration (RTI) system, where the desired transgene is integrated into a specific locus and transcribed under a regulated promoter. This system was used to determine the underlying causes of low protein expression for a difficult-to-express antibody (mAb-A). Interestingly, we observed that both antibody heavy chain (HC) and light chain (LC) subunits of mAb-A independently contributed to its low expression. Analysis of RTI cell lines also revealed that while mAb-A LC triggered accumulation of intracellular BiP, its HC displayed impaired degradation and clearance. RTI pools, generated by swapping the WT or point-mutant versions of difficult-to-express antibody HC and LC with that of an average antibody, were instrumental in understanding the contribution of HC and LC subunits to the overall antibody expression. The ability to selectively turn off the expression of a target transgene in an RTI system could help to directly link expression of a transgene to an observed adverse effect. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2772, 2019.     

Integration of cell line and process development to overcome the challenge of a difficult to express protein

This case study addresses the difficulty in achieving high level expression and production of a small, very positively charged recombinant protein. The novel challenges with this protein include the protein's adherence to the cell surface and its inhibitory effects on Chinese hamster ovary (CHO) cell growth. To overcome these challenges, we utilized a multi‐prong approach. We identified dextran sulfate as a way to simultaneously extract the protein from the cell surface and boost cellular productivity. In addition, host cells were adapted to grow in the presence of this protein to improve growth and production characteristics. To achieve an increase in productivity, new cell lines from three different CHO host lines were created and evaluated in parallel with new process development workflows. Instead of a traditional screen of only four to six cell lines in bioreactors, over 130 cell lines were screened by utilization of 15 mL automated bioreactors (AMBR) in an optimal production process specifically developed for this protein. Using the automation, far less manual intervention is required than in traditional bench‐top bioreactors, and much more control is achieved than typical plate or shake flask based screens. By utilizing an integrated cell line and process development incorporating medium optimized for this protein, we were able to increase titer more than 10‐fold while obtaining desirable product quality. Finally, Monte Carlo simulations were performed to predict the optimal number of cell lines to screen in future cell line development work with the goal of systematically increasing titer through enhanced cell line screening. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1201–1211, 2015     

禽流感病毒H9N2血凝素基因和神经氨酸酶因在大肠杆菌中的表达

克隆、表达和鉴定禽流感病毒H9N2 HA,NA基因序列,为制备抗体和基因工程疫苗打下基础。在成功克隆禽流感病毒H9N2全长HA、NA基因并测序的基础上,将部分基因序列克隆到表达载体pET32a(+)上,全基因序列克隆到表达载体pGEX4T-1上,构建了重组表达质粒pET32a(+)/HA(截短)、pET32a(+)/NA(截短)、pGEX4T-1/HA、pGEX4T-1/NA,转化大肠杆菌BL21/rosetta,IPTG诱导表达,利用Ni2+亲和层析柱和GSTrap4B亲和层析柱对重组蛋白进行纯化,并用Western Blotting和ELISA方法检测其抗原性。结果重组蛋白在大肠杆菌中可以高效表达,SDS-PAGE显示其相对分子质量与预计大小一致。ELISA和Western Blotting实验证实,重组蛋白具有良好的抗原性。本研究成功克隆和表达了禽流感病毒H9N2 HA、NA基因序列。为禽流感病毒H9N2诊断试剂和疫苗的开发等进一步的研究奠定了基础。     

日本血吸虫信号转导蛋白Sjwnt_4基因的克隆、表达及功能分析

由Wnt基因家族产物与其它相关基因产物构成的Wnt信号通路,是细胞发育和生长调节的一个关键途径,对动物的发育特别是生殖系统的发育起重要的调节作用。在人类和小鼠中,Wnt4蛋白是性腺分化过程中主要调节因子,在胚胎发育中起着关键作用。利用RACE技术从日本血吸虫19d童虫中首次扩增到一个Wnt家族基因,序列分析表明该基因的完整编码框含1311bp,编码436个氨基酸,理论分子量49.6kD。同源性分析结果表明,该基因的氨基酸序列具有典型Wnt家族蛋白特征,与日本三角涡虫、人Wnt4的氨基酸序列相似性分别达43％、37％,推测为血吸虫的Wnt4基因,命名为Sjwnt4（GenBank登陆号DQ643829）。实时定量PCR分析显示该基因在14d童虫、19d童虫、31d虫体、44d雌虫及44d雄虫中均有表达,其中19d童虫中的表达量明显高于其它发育阶段,44d雌虫中的表达量明显高于雄虫。构建了该基因的原核表达载体pGEX_4T_2_Sjwnt4,应用大肠杆菌系统进行了表达,表达蛋白以包涵体形式存在,Western印迹显示表达产物能被日本血吸虫成虫粗抗原免疫血清所识别。Sjwnt4基因及其表达产物的获得,为探索Wnt信号通路对血吸虫发育、生殖的调节提供了重要基础。     

S-腺苷甲硫氨酸代谢途径相关基因在小麦水分胁迫中的表达

以小麦品种‘晋麦47’为材料,利用半定量RT-PCR方法,对S-腺苷甲硫氨酸代谢途径中的S-腺苷甲硫氨酸合成酶(SAMS)基因、S-腺苷甲硫氨酸脱羧酶(SAMDC)基因和γ-谷氨酰半胱氨酸合成酶(-γECS)基因在正常供水、PEG-6000模拟水分胁迫和复水过程中小麦叶片的表达模式进行了分析。结果表明,3个基因在正常生长情况下有一定量的表达,SAMS和SAMDC基因在水分胁迫早期(PEG-6000胁迫6、12、244、8 h)上调表达,水分胁迫后期(PEG-6000胁迫75 h)表达量下降;复水后3~6 h上调表达,复水9 h后表达量下调至对照水平。-γECS基因在水分胁迫阶段呈上调表达,复水后表达量下调至对照水平。可见,小麦SAMS、SAMDC和-γECS基因的表达都受水分胁迫诱导,同时,SAMS与SAMDC基因还参与水分胁迫后的复水调节,说明S-腺苷甲硫氨酸代谢途径在小麦抗旱节水中具有重要作用。     

家蚕Bms3a基因真核表达载体的构建及其在家蚕细胞和蚕体中的表达

Bms3a基因可能在家蚕Bombyx mori抗病或细胞凋亡中有一定的作用。将融合有绿色荧光蛋白的Bins3a基因克隆到杆状病毒转移载体pFastBac1中获得了pFastBac-IE1-Bms3a-EGFP真核表达载体,利用杆状病毒(Bac-to-Bac)表达系统筛选重组杆状病毒,以重组病毒感染家蚕BmN细胞和五龄幼虫,分别在感染24h和48h检测到有绿色荧光蛋白的表达,Western blot证明表达的融合蛋白在相对分子量约57kD处出现特异条带,与预计的蛋白理论值相符。结果表明BmS3A-EGFP融合蛋白在家蚕细胞BmN及幼虫体中得到高效表达。研究结果为进一步研究BmS3A蛋白的功能奠定了基础。     

咽侧体提取物成分诱导散居型雄性蝗虫表皮变黄(英文)

黄色蛋白(yellow protein,YP)对雄性成年蝗虫的黄色表皮形成起着重要作用,而此过程需要有高量的保幼激素(juvenile hormone,JH)存在的条件下才会发生.而对于蝗虫大脑中是什么因素激活JH的合成,目前仍属未知.给散居型蝗虫注射L.migratoria蝗虫咽侧体(corpora allata,CA)提取物后,肉眼观察表明:散居型蝗虫表皮变黄.此后的定量PCR实验证实了散居型蝗虫表皮变黄是因为YP的(表达或存在).这暗示着黄色蛋白沉淀于散居型蝗虫的表皮.因此我们可以得出结论:给散居型蝗虫注射CA提取物,可以引发YP-mRNA的表达,CA提取物中有激活JH合成的因子.     

应加强对单细胞生物分批培养生长曲线中减速期的认识和教学

根据单细胞生物分批培养过程中比生长速率(μ)的变化,其生长曲线分为延滞期、加速期、对数期、减速期、稳定期和衰亡期6个时期.与其他生长时期相比,在减速期生物的生长、基质的利用、产物的合成和基因表达谱等方面有显著的不同,并对发酵生产有着重要作用.然而,长期以来,对减速期的认识和教学相当薄弱,亟需加强对减速期的认识和教学.