大肠杆菌磷酸甘油酸脱氢酶突变体的构建及抗反馈抑制效应

磷酸甘油酸脱氢酶(D-3-phosphoglycerate dehydrogenase,PGDH,EC 1.1.1.95)为L-丝氨酸合成途径的关键酶,其编码基因为ser A,其活性受到合成产物L-丝氨酸的反馈抑制调控。为解除丝氨酸的反馈抑制,采用定点突变技术把编码PGDH酶344位组氨酸或346位天冬氨酸或364位天冬氨酸的密码子定点突变为丙氨酸密码子。改造后的ser AFbr被连到表达载体pT7-7上,并转入大肠杆菌Escherichia coli BL21(DE3)中进行表达,破壁回收粗酶液,通过DEAE阴离子柱纯化PGDH突变体,并对其酶活性和IC_(50)值进行了测定。结果,野生型PGDH酶IC_(50)值为7μmol/L,而PGDH双突变体N346A/H344A催化活性与野生型相近,在丝氨酸浓度为160 mmol/L时,其酶活仍保持未添加丝氨酸时酶活的96%,基本解除反馈抑制。     

大肠杆菌CM/PDT抗反馈抑制突变体的构建及其性质

为了获得具有高催化活性且抗反馈抑制的大肠杆菌分支酸变位酶 预苯酸脱水酶 (chorismatemutase prephenatedehydrataseCM PDT) [EC5 .4 .99.5 EC4 .2 .1.5 1],通过相关菌种CM PDT氨基酸序列同源比较 ,寻找高度保守位点 .用定点突变及PCR法构建突变酶M1(缺失 30 4T、30 5G、Q30 6K)、M2 (缺失W 338)、M3(缺失 30 1～ 386位氨基酸 )、M32 9(E32 9A)和M374 (C374A) ,野生型及各突变型基因与pET2 8a(+ )载体连接后 ,表达融合蛋白 .在非变性条件下 ,由TALON金属螯合亲和层析柱纯化野生型和突变体的酶蛋白 .酶活性测定表明 ,突变体M3的PDT活性下降为野生型活性的 2 9% ,但保持了CM活性 .突变体M374保持了CM ,PDT两种酶的活性 ,突变体M1、M2、M32 9的CM ,PDT活性有一定程度的提高 .酶抗反馈抑制作用检测表明 ,突变体M3、M374解除了苯丙氨酸的反馈抑制作用 ,M1、M2、M32 9部分解除了苯丙氨酸的反馈抑制作用 .与含野生型pheA基因的E .coliBL2 1菌株相比 ,含突变基因的E .coliBL2 1菌株对 10mmol L的苯丙氨酸代谢类似物具有强的抗反馈抑制作用 ,其中M1,M2 ,M3对 2 0mmol L的类似物具有抗反馈抑制作用     

大肠杆菌trpBA和serA基因的串联表达

大肠杆菌trpBA基因编码的色氨酸合成酶(tryptophan synthetase, TSase)是色氨酸合成的关键酶; serA基因编码的磷酸甘油酸脱氢酶(D-3-phosphoglycerate-dehydrogenase, PGDH)为L-丝氨酸合成(色氨酸合成的底物)的关键酶。为了通过基因工程手段来增加色氨酸的产量, 在利用高效的原核表达载体pET22b(+)分别对trpBA和serA基因克隆表达的基础上, 采用PCR方法扩增了抗反馈抑制的serA和trpBA基因, 将两基因串联于pET22b(+)载体上, 共构建了4种方式的串联质粒, 实现了2种蛋白酶在大肠杆菌中的共表达。聚丙烯酰胺电泳分析显示, ABA-Ⅰ重组菌株在37 kD (PGDH)、29 kD(色氨酸合成酶的α亚基)、44 kD(β亚基)处均有明显的蛋白表达带。4种串联表达质粒重组菌的TSase酶活性, 分别比含空载体菌相应酶的活性提高2~4倍, PGDH酶活性分别提高约2.1~3.6倍。经摇瓶发酵实验表明酶活性较高的ABA-I菌株色氨酸合成量亦最高, 约为对照菌株的20.2倍。     

Pgk和ilvN基因对谷氨酸棒杆菌产L-丝氨酸的影响

为增加谷氨酸棒杆菌A36的L-丝氨酸合成途径的碳流,首先过表达磷酸甘油酸激酶(pgk),以增加前体物质3-磷酸甘油酸的积累,但经发酵分析发现其对菌株A36的L-丝氨酸产量无显著影响。进一步敲除副产物L-缬氨酸合成途径的乙酰羟酸合酶(AHAS)基因ilvN,敲除该基因后L-缬氨酸只有微量积累,但重组菌并未形成营养缺陷型菌株,L-丝氨酸的产量反而下降,分析发现L-缬氨酸的存在在一定程度上有助于L-丝氨酸的生成。在培养基中分别添加不同质量浓度的L-缬氨酸,在L-缬氨酸添加量为750 mg/L时,重组菌L-丝氨酸产量达到34.19 g/L,糖酸转化率为0.34 g/g,生产强度为0.28 g/(L·h),相比出发菌株A36分别提高了11.8%、13.3%和12.0%。     

PSS定点突变及酶活研究

磷脂酰丝氨酸可在磷脂酰丝氨酸合成酶(PSS)催化下由磷脂酰胆碱和L-丝氨酸生成。通过生物信息学手段对磷脂酰丝氨酸合成酶蛋白质结构进行解析和研究分析,获得2个可突变位点F139和P272,通过Overlap PCR法进行定点突变,测定突变序列,并进行酶活测定。结果显示,PSS位点F139突变为L139、M139,位点P272突变为A272,能提高酶活力,说明蛋白质结构解析结合氨基酸定点突变技术,可以改善重组酶的活力。     

谷氨酸棒杆菌YILW苏氨酸脱水酶基因的克隆表达及酶学性质

将L-异亮氨酸生产菌谷氨酸棒杆菌(Corynebacterium glutamicum YILW)苏氨酸脱水酶(threonine de-hydratase,TD)的编码基因ilvA在大肠杆菌中进行异源表达及进行初步的酶学性质研究。分别以C.glutamicum ATCC13032、YILW的基因组DNA为模板,利用PCR技术扩增出苏氨酸脱水酶的编码基因ilvA,测序获得编码序列。利用质粒PET-His将该基因在大肠杆菌BL21(DE3)中进行重组表达、金属螯合纯化,对其酶学性质进行初步研究。结果显示C.glutamicum YILW编码基因序列与已报道的ilvA序列相差5个碱基,相似度为99.6%,第383位氨基酸由苯丙氨酸突变为缬氨酸。酶学性质研究表明:重组酶YilwTD最适反应温度为32℃,在20~55℃范围内该酶较稳定,最适pH为6.7,该酶底物专一性强,对最适底物苏氨酸的米氏常数Km=8.32 mmol/L,最大反应速度Vmax=3.18×104U/mg,与野生型酶相比,突变(F383V)后可显著降低终产物对酶的反馈抑制作用。为揭示突变对苏氨酸脱水酶活性的影响及进一步利用基因工程技术改造L-异亮氨酸生产菌,提高L-异亮氨酸产量奠定了基础。     

过表达pps基因和aroG~(fbr)基因对北京棒杆菌L-色氨酸合成的影响

【目的】通过增加北京棒杆菌(Corynebacterium pekinense)PD-67芳香族氨基酸合成的前体物质磷酸烯醇式丙酮酸(PEP)的供应,解除终产物对芳香族氨基酸合成途径中第一个酶同时也是关键酶3-脱氧-D-阿拉伯庚酮糖-7-磷酸合酶(DS)的反馈抑制并提高抗反馈抑制的DS的活力,使碳流更多地流向芳香族氨基酸合成途径,从而积累更多L-色氨酸。【方法】运用PCR技术扩增北京棒杆菌PD-67磷酸烯醇式丙酮酸合酶基因pps,与表达载体连接构建重组质粒pXPS;运用重叠PCR技术定点突变大肠杆菌(Escherichia coli)受苯丙氨酸调控的DS基因aroG,使相应的编码氨基酸序列发生突变:Leu175Asp,新的基因命名为aroGfbr,与表达载体连接构建重组质粒pXA;构建pps和aroGfbr的共表达重组质粒pXAPS。将3个重组质粒分别转入菌株PD-67,构建工程菌株PD-67/pXPS、PD-67/pXA和PD-67/pXAPS。通过摇瓶发酵研究工程菌株的发酵特性。【结果】酶活分析结果表明,pps基因和aroGfbr基因在北京棒杆菌PD-67中均实现了表达。工程菌株PD-67/pXA粗酶液DS抗反馈抑制分析表明,AroGfbr已解除酪氨酸和苯丙氨酸的反馈抑制。过表达pps基因和aroGfbr基因分别使工程菌L-色氨酸产量提高12.1%和26.8%,双基因共表达可使工程菌的产酸量提高35.9%。【结论】北京棒杆菌PD-67pps基因的过表达以及大肠杆菌来源的解除反馈抑制的aroGfbr的过表达均有助于增加PD-67 L-色氨酸的合成,而双基因的共表达可以进一步提高L-色氨酸的积累量。     

应用定点突变与分子模建方法研究蛋白酶抑制剂eglin C突变体对蛋白酶furin和kexin的抑制活力

蛋白质前体加工酶参与许多重要蛋白质闪体的加工成熟过程,哺乳动物来源的furin和酵母中的kexin是该家族的重要成员。首先人工合成了编码枯草杆菌蛋白酶抑制剂eglin C的基因片段,组装后在大肠杆菌中得到表达。以定点突变方法在野生型eglin C抑制活性中心的P1、P2和P4位引入碱性氨基酸残基可以将其改造为很强的furin抑制剂（Ki约10^-9mol/L）,和kexin抑制剂（Ki约10^-11mol/L）。同时根据枯草杆菌蛋白酶和eglin C复合物的晶体结构,计算机同源模建了前体加工酶与eglin C突变体结构之间的相互作用,并结合实验数据得到以下结果：（1）P1位引入的碱性残基是该抑制剂活力的前提;（2）P4位碱性残基的引入可以极大地提高抑制剂活力约两个数量级;（3）P2 的碱性残基将有效提高抑制剂的活力。然而同时可以破坏抑制剂本身的稳定性。（4）野生型P3位的疏水性残基参与抑制剂活性环附近疏水核心的构成。     

杰氏棒杆菌L-天冬氨酸α脱羧酶半理性改造及全细胞催化合成β-丙氨酸

β-丙氨酸是多个药物合成的重要砌块，可以通过天冬氨酸α脱羧酶（Pan D）催化L-天冬氨酸脱羧来合成，但普遍在用的Pan D酶活性不高是制约全细胞催化合成β-丙氨酸的瓶颈。因此，本研究通过酶的挖掘，选择将杰氏棒杆菌来源（Corynebacterium jeikeium）Pan D在Escherichia coli中异源表达。对杰氏棒杆菌来源Pan D进行Alaph Fold2建模和分子对接，采用Rosetta虚拟突变确定突变热点，结合薄层层析初筛和纯化后复筛，最终筛选到突变体L39A，其比酶活为13.45 U/mg，相比野生型酶的比酶活（9.6 U/mg）提升了1.4倍。酶学性质表征数据表明，野生型酶和L39A突变体最适p H均为6.5，且在p H 6.0-7.0之间酶活性稳定；两者最适温度为55℃，但L39A热稳定性较野生型提高；突变体酶的催化效率比野生型提升了1.4倍。对突变体进行结构解析发现，39位取代为侧链基团更小的丙氨酸，亲水性增强，增加了关键催化氨基酸58位酪氨酸与其他氨基酸的相互作用，使活性中心周围的区域稳定性提高，从而提高了催化活性。全细胞催化数据表明，在OD600=4...     

灰葡萄孢菌及其抗短梗霉素突变体AUR1基因序列及其酶活性的分析

【目的】探讨灰葡萄孢菌及其抗Ab A突变体AUR1基因序列与IPC合成酶活性的关系。【方法】通过分子生物学方法测定野生型及突变体的AUR1的基因序列,高效液相荧光色谱法测定IPC合成酶活力,苯甲酰化法测定神经酰胺含量。【结果】AUR1基因序列和IPC合成酶活性测定表明4株不同的突变体均产生了对IPC合成酶抑制剂Ab A的抗性,它们的突变类型为:(1)AUR1序列中缺失内含子;(2)AUR1序列中缺失内含子和P155S氨基酸突变;(3)AUR1序列中缺失内含子和V33A的氨基酸突变;(4)AUR1序列中缺失内含子和P155S、S177P、F237L的氨基酸突变。AUR1缺失内含子和既缺失内含子又伴随P155S氨基酸突变的突变体的Ab A抗性较强。神经酰胺含量测定表明野生型IPC合成酶被抑制,导致神经酰胺积累,而突变体则能抵抗Ab A对IPC合成酶的抑制作用。【结论】AUR1基因中的内含子对IPC合成酶的调控起重要的作用。Ab A通过抑制IPC合成酶引起神经酰胺积累,IPC合成酶是鞘脂代谢的关键酶。     

3-Phosphoglycerate dehydrogenase from Corynebacterium glutamicum: the C-terminal domain is not essential for activity but is required for inhibition by L-serine

The serA gene of Corynebacterium glutamicum coding for 3-phosphoglycerate dehydrogenase (PGDH) was isolated and functionally characterized. It encodes a polypeptide of 530 aminoacyl residues (aa), which is substantially longer than the corresponding Escherichia coli polypeptide of 410 aa. The difference is largely due to an additional stretch of aa in the carboxy- (C)-terminal part of the polypeptide. Overexpression of serA in C. glutamicum results in a 16-fold increase in specific PGDH activity to 2.1 U/mg protein, with activity being inhibited by high concentrations of L-serine. A set of muteins that were progressively truncated at the C-terminal end was constructed. When overexpressed, mutein SerADelta197 showed a specific PGDH dehydrogenase activity of 1.3 U/mg protein, with the activity no longer being sensitive to L-serine. Gel filtration experiments showed that wild type PGDH is a homotetramer, whereas mutein SerADelta197 constitutes a dimer. Thus, the specific regulatory features of C. glutamicum PGDH are due to the C-terminal part of the polypeptide, which can be deleted with almost no effect on the catalytic activity of the enzyme.     

烟曲霉sho1、pbs2基因额外拷贝对几种应激能力的影响

目的构建烟曲霉额外拷贝菌株,了解额外拷贝烟曲霉sho 1、pbs 2基因能否增强菌株对高渗透压、过氧化氢(H2O2)、碱性pH、刚果红应激的抵抗能力,探讨HOG通路(high osmolarity glycerol pathway)参与的应激反应。方法用原生质体法构建分别含有烟曲霉sho 1、pbs 2基因的额外拷贝菌株,采用Real-time PCR方法检测额外拷贝株中sho 1、pbs 2的表达情况。观察并比较缺陷株、额外拷贝株对NaCl(1 mol/L)、H2O2(5 mmol/L)、刚果红(400 mg/L)及碱性pH(10.0)应激的反应。结果获得了含有烟曲霉sho 1、pbs 2基因的额外拷贝菌株MCsho1、MCpbs2,和含空白质粒的对照株Empty。额外拷贝株sho 1、pbs 2的表达水平增高,对NaCl(1 mol/L)、H2O2(5 mmol/L)、刚果红(400 mg/L)、碱性pH(10.0)应激的抵抗强于Empty。MCpbs2对这些应激的抵抗较MCsho1更显著。烟曲霉缺陷株△sho 1、△pbs 2对NaCl(1 mol/L)、H2O2(5mmol/L)、碱性pH(10.0)的敏感性高于野生株AF293。△sho 1对刚果红(400 mg/L)的敏感性高于野生株,△pbs 2对刚果红的敏感性与野生株比,无显著差别。结论额外拷贝烟曲霉sho 1或pbs 2基因能增强菌株对高渗透压、氧化压力、刚果红、碱性pH应激的抵抗能力。     

Characterization,modification, and overexpression of 3-phosphoglycerate dehydrogenase in Corynebacterium glutamicum for enhancing l-serine production

The direct fermentative production of l-serine from renewable biomass using Corynebacterium glutamicum is attracting increasing attention. In this study, wild-type C. glutamicum SYPS-062 produced up to 6.65 ± 0.23 g/L l-serine; to further improve l-serine production, the serA gene was cloned, and the C-terminal domain of 3-phosphoglycerate dehydrogenase (PGDH) from this strain was truncated. When expressed in Escherichia coli, the resultant mutein SerAΔ197 showed a specific PGDH activity of 1.092 ± 0.05 U/mg protein, representing a decrease of 25.87 % from that encoded by serA, and was no longer sensitive to high concentrations of l-serine. When serA Δ591 was overexpressed in C. glutamicum SYPS-062, the activity of PGDH in C. glutamicum pJC1-tac-serA Δ591 increased by 47.72 %, and the resultant strain C. glutamicum pJC1-tac-serA Δ591 could accumulate 7.69 ± 0.22 g/L l-serine. Furthermore, when serA Δ591 was overexpressed in C. glutamicum SYPS-062ΔsdaA, the resultant strain could accumulate 8.84 ± 0.23 g/L l-serine at 102 h, and the yield of l-serine on cells (Y p/x) improved by 60 % when compared with that noted in the control. These results demonstrate that l-serine production in C. glutamicum SYPS-062 could be improved by overexpressing a C-terminal truncation of PGDH in combination with other genetic modifications.     

Role of the C-terminal tail on the quaternary structure of aldehyde dehydrogenases

To assess the importance of the C-terminal tail in the structure of aldehyde dehydrogenases (ALDH), mutants of tetrameric ALDH1 were generated by adding a tail of 5 amino acids (ALDH1-5aa) or the tail from the class 3 enzyme. A mutant of dimeric ALDH3 was made, where 17 amino acids from the C-terminus were deleted to generate ALDH3ΔTail. The expression and solubility of the ALDH1 mutants was slightly lower than the wild type. Expression of ALDH3ΔTail mutant was similar to wild type, but the solubility was only about 30%. The activity of ALDH1-5aa mutant was 30%, while ALDH1-H3Tail mutant was 60% active, compared to the wild type. The activity of the class 3 mutant was similar to the activity of the parent ALDH3 enzyme. Analysis of stability against temperature demonstrated that ALDH1-5aa was more stable than ALDH1 wild type, while the ALDH1-H3Tail mutant was considerably less stable than ALDH1, showing a stability similar to ALDH3. However, native gel and size exclusion analysis, showed no changes in the oligomerization state of these mutants. ALDH3ΔTail mutant was more stable than wild type; the stability against temperature was similar to ALDH1. The ALDH3ΔTail mutant showed an elution similar to that of ALDH1 from the size exclusion column, indicating that it was possibly a tetramer. These results show that the tail in ALDH3, is involved in the determination of the quaternary structure of ALDH3, but has no effect on the ALDH1 enzyme; the absence of the C-terminal tail is not the only factor participating in holding the dimers together. Thus, the interaction between single residues, or interactions with the N-terminal region might be more important for maintaining stable tetramers.     

Role of the C-terminal tail on the quaternary structure of aldehyde dehydrogenases

To assess the importance of the C-terminal tail in the structure of aldehyde dehydrogenases (ALDH), mutants of tetrameric ALDH1 were generated by adding a tail of 5 amino acids (ALDH1-5aa) or the tail from the class 3 enzyme. A mutant of dimeric ALDH3 was made, where 17 amino acids from the C-terminus were deleted to generate ALDH3DeltaTail. The expression and solubility of the ALDH1 mutants was slightly lower than the wild type. Expression of ALDH3DeltaTail mutant was similar to wild type, but the solubility was only about 30%. The activity of ALDH1-5aa mutant was 30%, while ALDH1-H3Tail mutant was 60% active, compared to the wild type. The activity of the class 3 mutant was similar to the activity of the parent ALDH3 enzyme. Analysis of stability against temperature demonstrated that ALDH1-5aa was more stable than ALDH1 wild type, while the ALDH1-H3Tail mutant was considerably less stable than ALDH1, showing a stability similar to ALDH3. However, native gel and size exclusion analysis, showed no changes in the oligomerization state of these mutants. ALDH3DeltaTail mutant was more stable than wild type; the stability against temperature was similar to ALDH1. The ALDH3DeltaTail mutant showed an elution similar to that of ALDH1 from the size exclusion column, indicating that it was possibly a tetramer. These results show that the tail in ALDH3, is involved in the determination of the quaternary structure of ALDH3, but has no effect on the ALDH1 enzyme; the absence of the C-terminal tail is not the only factor participating in holding the dimers together. Thus, the interaction between single residues, or interactions with the N-terminal region might be more important for maintaining stable tetramers.     

Analysis of interferon signaling by infectious hepatitis C virus clones with substitutions of core amino acids 70 and 91

Substitution of amino acids 70 and 91 in the hepatitis C virus (HCV) core region is a significant predictor of poor responses to peginterferon-plus-ribavirin therapy, while their molecular mechanisms remain unclear. Here we investigated these differences in the response to alpha interferon (IFN) by using HCV cell culture with R70Q, R70H, and L91M substitutions. IFN treatment of cells transfected or infected with the wild type or the mutant HCV clones showed that the R70Q, R70H, and L91M core mutants were significantly more resistant than the wild type. Among HCV-transfected cells, intracellular HCV RNA levels were significantly higher for the core mutants than for the wild type, while HCV RNA in culture supernatant was significantly lower for these mutants than for the wild type. IFN-induced phosphorylation of STAT1 and STAT2 and expression of the interferon-inducible genes were significantly lower for the core mutants than for the wild type, suggesting cellular unresponsiveness to IFN. The expression level of an interferon signal attenuator, SOCS3, was significantly higher for the R70Q, R70H, and L91M mutants than for the wild type. Interleukin 6 (IL-6), which upregulates SOCS3, was significantly higher for the R70Q, R70H, and L91M mutants than for the wild type, suggesting interferon resistance, possibly through IL-6-induced, SOCS3-mediated suppression of interferon signaling. Expression levels of endoplasmic reticulum (ER) stress proteins were significantly higher in cells transfected with a core mutant than in those transfected with the wild type. In conclusion, HCV R70 and L91 core mutants were resistant to interferon in vitro, and the resistance may be induced by IL-6-induced upregulation of SOCS3. Those mechanisms may explain clinical interferon resistance of HCV core mutants.     

C-terminal region of the active domain enhances enzymatic activity in dinoflagellate luciferase.

The dinoflagellate luciferase of Lingulodinium polyedrum has three catalytic domains in its single polypeptide chain (M(r) = 137 kDa), and each 42 kDa domain is enzymatically active. Deletion mutants for N- or C-terminal regions of domain 3 of the luciferase, ranging from 29 to 38 kDa, were constructed and expressed in E. coli cells. The activities of N-terminal deleted mutants were above 20% of wild type, but showed different pH-activity profiles. By contrast, the activities of C-terminal deleted mutants decreased drastically to below 1% of wild type, although their pH-activity profiles and spectra were identical to those of wild type L. polyedrum luciferase. These results indicate that the C-terminal region of this enzyme could be important for the bioluminescence reaction, although based on crystal structure of the luciferase domain, this region does not contain active or regulatory sites.     

人重组t-PA突变体与β2糖蛋白Ⅰ的相互作用

利用重组DNA技术和原核表达,得到了人体组织型纤溶酶原激活剂t-PA 的缺失型突变体r-PA和Kringle2功能区,并在变性条件下通过金属螯合层析纯化得到纯度较高的r-PA和Kringle2重组蛋白.用纤维蛋白活性平板检测到复性的r-PA和Kringle2都具有体外纤溶活性,并且β 2糖蛋白Ⅰ (β2-glycoprotein Ⅰ, β2GPⅠ)对r-PA的体外纤溶活性有显著的促进作用:在β2GPⅠ浓度为1 μmol/L和4 μmol/L时,r-PA的纤溶活性分别提高1.8和2.1倍.ELISA方法检测发现, β2GPⅠ与r-PA,Kringle2均有特异性结合,并且随着β2GPⅠ浓度的增加,它与包被在酶标板上的重组蛋白r-PA和Kringle2的结合都有趋于饱和的趋势,但其饱和浓度却均远高于β2GPⅠ与t-PA结合的饱和浓度.