响应面分析法优化重组原动蛋白2β诱导条件的研究

原动蛋白2β(PK2β)是近年新发现的一个选择性激活PKR1的蛋白质因子。采用响应面分析法(RSM)研究了利用重组BL21(DE3)表达PK2β的最优诱导条件。结果表明,诱导时机与诱导物浓度对PK2β的表达水平具有显著性影响,但诱导时间不具有显著性影响。试验数据拟合与极值分析表明最优诱导条件为工程菌OD600为0.50时,采用终浓度为0.11 mmol/L的IPTG在37℃诱导培养7.73 h,此时PK2β表达水平可达242.78 mg/L。验证试验结果表明,重组PK2β的表达水平比优化前提高了46%,而IPTG的用量减少了89%,有利于大量制备该蛋白质进行后续功能研究及应用研究。     

高产信号分子AI-2乳酸菌的筛选及其Pfs基因的克隆和表达

【目的】从锡盟地区酸马奶酒分离的乳酸菌中筛选出高产信号分子自体诱导物2(Autoinducer-2,AI-2)的乳酸菌,通过优化其重组蛋白Pfs的诱导条件体外合成信号分子AI-2。【方法】利用生物学发光法对不同乳酸菌产信号分子AI-2的产量进行比较,以高产信号分子AI-2乳酸菌基因组DNA为模板,扩增其S-腺苷高半胱氨酸核苷酶(S-adenosylhomocysteine nucleosidase,Pfs)基因,构建原核表达载体。利用异丙基-β-D-硫代吡喃半乳糖苷(IPTG)进行重组蛋白的诱导表达,通过优化培养基、诱导温度、诱导前菌体密度、IPTG浓度以及诱导时间得到高表达的Pfs蛋白,使其与底物作用最终体外合成信号分子AI-2。【结果】10株乳酸菌均可产信号分子AI-2,其中屎肠球菌8-3分泌信号分子AI-2的产量明显高于其他菌株;重组蛋白的最佳诱导条件为:选取SOC(Super optimal broth with catabolite repression)作为诱导表达培养基,菌液OD600为0.5–0.7时加入终浓度为0.1 mmol/L的IPTG,37°C诱导12 h;利用最优诱导条件获得了浓度为4.08 g/L的纯化Pfs蛋白,体外合成了信号分子AI-2。【结论】酸马奶酒中分离出的10株乳酸菌均可产生信号分子AI-2,且屎肠球菌8-3可通过Pfs基因的作用生成信号分子AI-2。     

乳糖诱导重组多价人精子表位肽在大肠杆菌中的表达

旨在研究用乳糖替代IPTG作为诱导剂进行重组多价人精子抗原表位肽的表达及诱导表达的优化条件.在摇瓶发酵条件下,通过改变培养基组成、诱导时机、诱导温度、诱导剂浓度、诱导时间和诱导方式等条件,利用SDS-PAGE电泳和AlphaEase凝胶电泳图像分析系统,研究以上条件改变对GST-重组多价人精子抗原表位肽融合蛋白表达量的影响,并与IPTG诱导结果相比较.结果显示,在摇瓶试验中,最优表达条件为选用TB培养基,在菌体对数生长的中期进行诱导,诱导温度37℃、乳糖诱导终浓度3 mmol/L、诱导时间6 h.GST-重组多价人精子抗原表位肽融合蛋白的表达量占菌体总蛋白的30.5％,且主要以可溶形式表达,与IPTG的诱导结果相同.分批流加乳糖和一次性加入乳糖诱导,效果一样.乳糖可以替代IPTG作为诱导剂诱导GST-重组多价人精子抗原表位肽融合蛋白的表达,优化条件下可获得与IPTG相同的诱导表达效果.     

乳糖诱导重组尿酸酶基因在大肠杆菌中的表达

对用乳糖替代异丙基-β-D-硫代半乳糖苷(IPTG)诱导重组产朊假丝酵母尿酸酶基因在E.coli JM109(DE3)中表达进行了研究,拟建立一种高效低成本的生产重组尿酸酶的工艺路线。通过摇瓶试验对诱导所采用的乳糖浓度,诱导时机和诱导持续时间进行了优化,并考察在乳糖诱导下的目的产物表达动力学,随后在5 L发酵罐上进行扩大化培养以验证摇瓶优化的结果,进一步将乳糖作为诱导剂应用于高密度发酵过程。实验结果表明乳糖诱导的最佳浓度为5 g/L,最佳诱导时机是对数生长期中后期,诱导持续时间为9~10h;按照优化的条件在摇瓶和5 L发酵罐上进行分批培养,重组尿酸酶最大表达量可达菌体总蛋白的26%左右,可溶性蛋白的36%左右,略高于IPTG的诱导效果;高密度发酵过程菌体终密度达到OD600值40以上,尿酸酶表达量占菌体总蛋白25%左右。     

肝靶向肽-抗肿瘤肽CSP-MDA-7/IL-24融合基因原核表达条件优化

目的:优化肝靶向肽-抗肿瘤肽(CSP-MDA-7/IL-24)在大肠杆菌中诱导表达的相关条件。方法:通过考察CSP-MDA-7/IL-24重组菌生长曲线,选择合适的诱导时机,通过SDS-PAGE检测CSP-MDA-7/IL-24蛋白的表达量,单因素分析诱导时间、培养基p H值、诱导温度和诱导剂IPTG浓度,在此基础上各选取5个水平进行正交实验,摸索最佳诱导表达条件。结果:培养基p H7.0、IPTG浓度0.12 mmol/L、培养温度42℃、诱导表达4 h为重组蛋白的最佳表达条件。结论:为进一步制备重组蛋白CSP-MDA-7/IL-24及评价其生物活性奠定了基础。     

乳糖诱导木聚糖酶基因在大肠杆菌中的可溶性表达

以构建好的大肠杆菌工程菌BL21(DE3)/xylanase为研究对象,研究了以IPTG和乳糖作为诱导剂时重组蛋白的表达规律。在摇瓶发酵条件下研究了诱导剂浓度、诱导时机、诱导培养时间和诱导培养温度对目标蛋白表达的影响。实验结果表明,乳糖作为诱导剂时,重组菌产酶活力33.9 U/mg略高于IPTG作为诱导剂时重组菌产酶活力28.10 U/mg,这为乳糖作为诱导剂应用于重组大肠杆菌生产木聚糖酶提供了参考依据。     

重组菌BL21-HTa-cgkZ产κ-卡拉胶酶的发酵条件优化

【目的】优化重组菌BL21-HTa-cgkZ产生κ-卡拉胶酶的发酵条件。【方法】通过单因子筛选和响应面分析方法对在IPTG诱导下的κ-卡拉胶酶的产生菌BL21-HTa-cgkZ进行产酶条件优化。【结果】该菌产酶的最佳培养基组成为：乳糖7 g/L,胰蛋白胨10 g/L,酵母粉5 g/L,NaCl 10 g/L,CaCl2 0.666 g/L。最佳诱导条件为：在工程菌接种1.55 h后添加IPTG,IPTG的浓度为0.89 mmol/L,诱导时间为24 h,诱导温度为23.03 °C。并确定了在培养基中添加乳糖、Triton X-100对κ-卡拉胶酶分布的影响。【结论】实验结果为产κ-卡拉胶酶工程菌的规模化生产奠定基础。     

多表位恶性疟疾疫苗M.RCAg-1在大肠杆菌表达的条件优化和大规模培养

通过以培养基配方、IPTG浓度、金属离子复合液浓度、镁离子浓度、表达时间、接种量、诱导时间点等发酵的重要条件对重组蛋白表达量影响的研究,确定多表位恶性疟疾疫苗M.RCAg-1蛋白最佳表达条件为以改良TB培养基培养、最优Mg2+,诱导剂IPTG和金属离子复合液浓度分别为10mmol/L,0.5mmol/L,6μl/ml,接种量为10%,表达时间为4.5h,将优化后的参数用于50L发酵罐进行连续3批中试规模的发酵,最终收获菌体湿重平均为31.8±1.78g/L,目的蛋白表达量可占菌体总蛋白的50%左右,试验确定了恶性疟疾多表位随机组合蛋白M.RCAg-1在大肠杆菌中的最优表达条件,该条件能够适合大规模培养需要。     

应用正交实验法优化大肠杆菌表达CTB-PSMA624-632蛋白的条件

通过基因工程方法,将含霍乱毒素B亚单位(CTB)和前列腺特异性膜抗原(PSMA)表位肽的重组质粒pET28a-CTB-PSMA624-632,转化表达宿主菌BL21 (DE3)。CTB蛋白的表达有利于开发粘膜佐剂和霍乱弧菌基因工程疫苗,同时抗原肽疫苗也是肿瘤免疫治疗的理想候选。本研究采用正交实验法,优化条件以增加大肠杆菌中CTB-PSMA624-632蛋白的表达量。选取了5个单因素作为考察因子,分别为:预诱导时间、诱导时间、诱导温度、IPTG浓度、诱导转速。先做了4水平的实验L16(45)。根据极差分析的数据对影响较大的3个因素又做了细调型的3水平实验L9(33)。结果表明,在早期指数生长期的诱导能得到相对高水平的包涵体形式的CTB-PSMA624-632蛋白,并且此蛋白的表达随着诱导温度升高到37℃而逐渐增加;相比于使用正常浓度的IPTG诱导得到的蛋白表达量,用100%μmol/L诱导足以诱导蛋白的表达,这比通常使用的IPTG浓度小10倍;此外,诱导时间5 h与7 h对蛋白的表达量差距甚微,因此选定较短时间的5 h,240 r/min的诱导转速也被认为是能诱导目的蛋白CTB-PSMA624-632具有高表达量的最优条件。     

乳糖替代IPTG诱导脱色酶TpmD基因在大肠杆菌中的高效表达

本文考察了乳糖代替IPTG诱导三苯基甲烷类染料脱色酶TpmD在大肠杆菌BL21(DE3)中表达的可行性, 分别对用乳糖作为诱导剂时的诱导时机、乳糖浓度、诱导持续时间和添加方式进行优化并与IPTG诱导的差异等方面进行了比较分析, 确定了乳糖诱导的最佳条件。结果表明, 在工程菌对数生长中期(OD600约为0.8)添加终浓度为0.4 mmol/L的乳糖诱导6 h的条件下能获得最大量的目的蛋白和菌体量。由于乳糖可以作为碳源被菌体利用, 分批添加乳糖效果优于一次性添加。乳糖诱导条件下目的蛋白表达量占总蛋白的35.62%, 与IPTG诱导条件下的35.03%无明显差异。乳糖诱导后外源蛋白的表达时间有所滞后, 但收获的菌体量高于IPTG诱导, 显示出了乳糖同样是一种T7启动子的廉价高效诱导剂, 可以代替昂贵的IPTG用于脱色酶TpmD的规模化发酵, 同时也为其他重组蛋白的生产提供了有益的参考和借鉴。     

High level expression of recombinant BoNT/A-Hc by high cell density cultivation of <Emphasis Type="Italic">Escherichia coli</Emphasis>

The carboxylic domain of the Clostridium botulinum neurotoxin heavy chain (BoNT/A-HC), which has been reported as a vaccine candidate, contains the principle protective antigenic determinants. In this study, the high level expression of the BoNT/A-Hc was achieved by high cell density cultivation of recombinant Escherichia coli in a 2-l batch stirred-tank bioreactor. In order to maximize protein expression, post-induction time and IPTG inducer concentration were optimized by the Taguchi statistical design method. Results showed that the middle of the logarithmic phase and an IPTG concentration of 1 mM presented the optimum conditions for the maximum expression of BoNT/A-HC. High cell density cultivation was subsequently carried out as an effective strategy for the high level expression of recombinant BoNT/A-Hc. Consequently, soluble BoNT/A-Hc was produced at the maximum level of 486 mg l⁻¹, at 3 h post-induction, which was approximately 9.3 and 7.8 times higher than the levels produced by the shake flask and batch culturing methods, respectively.     

Production of heterologous thermostable glycoside hydrolases and the presence of host-cell proteases in substrate limited fed-batch cultures of Escherichia coli BL21(DE3)

Metabolic stress is a phenomenon often discussed in conjunction with recombinant protein production in Escherichia coli. This investigation shows how heterologous protein production and the presence of host cell proteases is related to: (1) Isopropyl-beta- D-thiogalactopyranoside (IPTG) induction, (2) cell-mass concentration at the time of induction, and (3) the presence of metabolites (glutamic acid or those from tryptone soy broth) during the post-induction phase of high cell density fed-batch cultivations. Two thermostable xylanase variants and one thermostable cellulase, all originating from Rhodothermus marinus, were expressed in E. coli strain BL21 (DE3). A three-fold difference in the specific activity of both xylanase variants [between 7,000 and 21,000 U/(g cell dry weight)], was observed under the different conditions tested. Upon induction at high cell-mass concentrations employing a nutrient feed devoid of the metabolites above, the specific activity of the xylanase variants, was initially higher but decreased 2-3 h into the post-induction phase and simultaneously protease activity was detected. Furthermore, protease activity was detected in all induced cultivations employing this nutrient feed, but was undetected in uninduced control cultivations (final cell-mass concentration of 40 g/l(-1)), as well as in induced cultivations employing metabolite-supplemented nutrient feeds. By contrast, maximum specific cellulase activity [between 700 and 900 U/(g cell dry weight)] remained relatively unaffected in all cases. The results demonstrate that detectable host cell proteases was not the primary reason for the decrease in post-induction activity observed under certain conditions, and possible causes for the differing production levels of heterologous proteins are discussed.     

Optimization of an extracellular zinc-metalloprotease (SVP2) expression in Escherichia coli BL21 (DE3) using response surface methodology

In this work, SVP2 from Salinivibrio proteolyticus strain AF-2004, a zinc metalloprotease with suitable biotechnological applications, was cloned for expression at high levels in Escherichia coli with the intention of changing culture conditions to generate a stable extracellular enzyme extract. The complete ORF of SVP2 gene was heterologously expressed in E. coli BL21 (DE3) by using pQE-80L expression vector system. In initial step, the effect of seven factors include: incubation temperature, peptone and yeast extract concentration, cell density (OD600) before induction, inducer (IPTG) concentration, induction time, and Ca(2+) ion concentrations on extracellular recombinant SVP2 expression and stability were investigated. The primary results revealed that the IPTG concentration, Ca(2+) ion concentration and induction time are the most important effectors on protease secretion by recombinant E. coli BL21. Central composite design experiment in the following showed that the maximum protease activity (522 U/ml) was achieved in 0.0089 mM IPTG for 24h at 30 °C, an OD600 of 2, 0.5% of peptone and yeast extract, and a Ca(2+) ion concentration of 1.3 mM. The results exhibited that the minimum level of IPTG concentration along with high cell density and medium level of Ca(2+) with prolonged induction time provided the best culture condition for maximum extracellular production of heterologous protease SVP2 in E. coli expression system.     

Excretory overexpression of <Emphasis Type="Italic">Paenibacillus pabuli</Emphasis> US132 cyclodextrin glucanotransferase (CGTase) in <Emphasis Type="Italic">Escherichia coli</Emphasis>: gene cloning and optimization of the culture conditions using experimental design

The gene encoding the cyclodextrin glucanotransferase of Paenibacillus pabuli US132 was connected to the amylase signal peptide of Bacillus stearothermophilus. This leads to an efficient secretion of the recombinant enzyme into the culture medium of Escherichia coli as an active form contrasting with the native construction leading to a periplasmic production. The optimum cultivation conditions for the maximum expression were optimized, using a Box-Behnken design under the response surface methodology, and found to be a post-induction temperature of 24°C, an induction-starting A₆₀₀ nm of 0.85, an isopropyl-β-D-thiogalactopyranoside level of 0.045 mM and a post-induction time of 3.9 h. The screening of media components and their concentration were achieved using a Plackett-Burman and a Box-Behnken designs sequentially. Under the optimized conditions selected and in agreement with the predicted model, an activity of 6.03 U/mL was attained. This CGTase production was three-times higher than that using the non-optimized culture conditions (2 U/mL).     

argE基因在大肠杆菌中的表达优化

N-乙酰鸟氨酸脱酰基酶可在重组菌BL21（DE3）-pET22b-argE中表达。首先确定了该酶的细胞表达定位,再研究了诱导温度、诱导剂种类及浓度、诱导起始菌体密度、诱导时间等因素对重组菌生长及目的蛋白表达活性的影响。结果表明,IPTG和乳糖皆可诱导目的蛋白表达,乳糖的诱导效果优于IPTG。在诱导起始0D600为0．46时加入15g／L乳糖,20℃诱导18h最适于目的蛋白的活性表达。表达条件优化后,酶活从1．68U／mL提高至282．99U／mL,约为原来的168倍。     

重组尿酸氧化酶发酵工艺优化

目的:优化并获得重组尿酸氧化酶(rUOX)基因工程大肠杆菌BL21(DE3)/pET-32a-uox高密度发酵的工艺参数。方法:在三角摇瓶中进行培养条件的优化实验,分别考察了pH值、接种量、无机盐、碳源、诱导强度等对工程菌生长和重组蛋白表达的影响,得到了优化的发酵条件;在此基础上放大至NBS BIOFLO 110 14 L发酵罐,通过对诱导时机的优化,利用分批补料发酵的方式,使rUOX在高密度培养的条件下得到高表达。结果:在优化的发酵条件下,菌体密度(D600nm)最终达到50以上,相当于20 g/L干重;可溶性rUOX占菌体总蛋白量的45%,其含量达到3.45 g/L。结论:为规模化制备重组黄曲霉尿酸氧化酶奠定了基础。     

基于响应面分析方法的钩端螺旋体三联属特异性蛋白抗原原核表达条件的优化

脂蛋白LipL32和LipL21及穿膜蛋白OMPL1是问号钩端螺旋体(简称钩体)属特异性表面抗原,可作为通用型钩体基因工程疫苗抗原.[目的]在我们的研究中,为了获得使得重组人工融合基因lipL32/1-lipL21-ompL1/2获得较高的表达水平,我们优化了重组宿主大肠杆菌的表达条件.[方法]我们采用了基于中心复合设计(CCD)的响应面分析方法(RSM).影响重组大肠杆菌生长的主要因素包pH、诱导剂IPTG浓度、诱导前培养实践、诱导时间以及诱导温度.响应面分析方法可以从这些因素中找到适合目的蛋白表达的最优表达条件.[结果]我们的结果显示在pH7.9、0.20mmol/LIPTG、诱导前培养时间2.5 h、诱导时间5.83 h、诱导后温度31℃条件下,可获得目的重组蛋白37.78 mg/L的最大表达量.[结论]实验结果表明采用基于中心复合设计的响应面分析方法能够较吹靥岣吣康牟锏牟?利用统计方法不但可以减少试验的次数,而且还能够从影响蛋白的因素中找出最重要的影响因素,因此该方法不仅对重组蛋白表达条件的优化有用,而且是一种很好的筛选方法.     

乳糖诱导的重组人血管内皮抑素(rhEndostatin)蛋白的表达

研究用乳糖替代IPTG作为诱导剂进行重组蛋白的表达,观察乳糖对乳糖操纵子调控的基因工程菌发酵及重组血管内皮抑素表达的影响,从而选取最佳诱导表达条件。以重组人血管内皮抑素表达工程菌pETrhEN/BL21(DE3)作为研究对象,分别用IPTG和乳糖作为诱导剂,在摇瓶中进行表达实验。并对重组蛋白质表达量进行分析。然后在5 L发酵罐中进行验证。在摇瓶培养条件下,乳糖浓度大于0.5 g/L即可以诱导目的蛋白的表达。乳糖浓度1 g/L时诱导目的蛋白表达量与1 mmol/L的IPTG相当,当乳糖浓度为10 g/L,目的蛋白表达量达到最大。在发酵罐培养条件下,补料4 h后葡萄糖浓度基本耗尽,此时开始加入乳糖。诱导后1 h,即有重组蛋白表达,在诱导后4 h达到高峰(占菌体可溶性蛋白的56%),与此同时,诱导后5 h菌体浓度也达到最高值。在以乳糖操纵子为调控手段的工程菌表达系统中,可以使用乳糖作为诱导剂,诱导应在葡萄糖消耗完后进行。