大肠杆菌ptsG基因敲除及其缺陷株生长特性研究

在大肠杆菌磷酸转移酶系统中,葡萄糖主要由ptsG基因编码的酶ⅡCB^Glc转运入细胞。利用代谢工程技术构建ptsG基因缺陷株,有望降低葡萄糖的摄取速率,减少乙酸累积,促进菌体生长。运用PCR技术,扩增出两翼与ptsG基因上下游序列同源,中间为氯霉素抗性基因的DNA片段。经电转化,将外源DNA片段分别转入Escherichia coli DH5α、JM109中。在Red重组酶的作用下,外源DNA片段与染色体上同源区域重组,将基因ptsG敲除,构建ptsG基因缺陷株DH5αP、JM109P。在LB培养基中,ptsG基因缺陷株的生长状况与亲株无明显差异。在含有葡萄糖的LB培养基中,DH5αP、JM109P的最高菌密度分别是对照菌株DH5α、JM109的3.47倍和4.25倍,ptsG基因缺陷株对葡萄糖的摄入量也明显高于对照菌株。重组蛋白肿瘤坏死因子（TNF）在DH5αP、JM109P中的表达量分别占全菌蛋白的24.3%、20.8%,A600分别为8.28、7.62,TNF在缺陷株中单位体积的表达量明显高于对照菌株。以上结果说明,大肠杆菌ptsG基因缺陷株具有良好的生长能力和表达外源蛋白的能力,在大肠杆菌高密度发酵研究方面具有良好的应用前景。     

大肠杆菌ptsG和ptsM突变体的构建及特性研究

目的：敲除大肠杆菌DH5α中与葡萄糖磷酸化转运相关的ptsG、ptsM基因,考察缺陷株生长特性及其可能的应用。方法：PCR扩增靶基因,构建两翼带有靶基因序列并嵌合抗药基因标记的线性片段,利用Red同源重组技术敲除靶基因。结果：成功敲除了大肠杆菌DH5α的ptsG和ptsM基因;在含有葡萄糖的LB培养基中,DH5αΔptsG最高菌密度是亲本的2.8倍,添加吡咯喹啉醌或导入其生物合成基因后能够产酸;DH5αΔptsM最高菌密度是亲本的4/10,有明显的产酸现象。结论：DH5αΔptsG可用于大肠杆菌高密度发酵和吡咯喹啉醌生物合成基因缺陷株筛选。     

大肠杆菌ptsHIcrr操纵子的快速敲除及敲除菌生长性能测定

敲除大肠杆菌磷酸烯醇式丙酮酸-糖磷酸转移酶系统(简称PTS系统)ptsHIcrr操纵子,考察敲除菌株生长特性并将其与ptsG敲除菌进行比较。利用I-SceⅠ特异性切割和Red同源重组方法成功构建了大肠杆菌DH5α△ptsHIcrr敲除菌。在LB培养基中,DH5α△ptsHIcrr的生长行为与DH5α和DH5α△ptsG明显不同,其最高菌密度是DH5α和DH5α△ptsG的近2倍,而DH5α△ptsG生长行为与DH5α无明显差异。但在含1%葡萄糖的LB中,DH5α△ptsHIcrr和DH5α△ptsG均表现出生长优势,最高菌密度依次是DH5α的2.8和2倍;培养液中最终乙酸含量分别是DH5α的12.2%、47%。在M9修饰培养基中,DH5α△ptsHIcrr比生长速率(1/h)和比葡萄糖消耗速率[g/(g.h)]明显低于DH5α,并略低于DH5α△ptsG。结果说明,ptsHIcrr操纵子敲除菌改变了葡萄糖的代谢速率,并呈现与ptsG基因敲除菌不同的代谢特点。     

用于质粒DNA规模化生产的大肠杆菌发酵培养基的筛选

为降低质粒DNA的生产成本,在标准LB培养基的基础上,利用国产试剂配制成十种大肠杆菌液体培养基,以pEGFPC3、pcDNAlacZ和pcDNKLYZ质粒转化的JM109和DH5α大肠杆菌为指示菌进行小规模发酵培养,定时采样测量OD600值及质粒产量,获得一种高性价比培养基。用该培养基培养重组大肠肝菌,绘制生长曲线,并于其对数生长中期进行42℃诱导。结果表明经42℃诱导后,重组大肠肝菌JM109和DH5α的质粒产量均有提高,重组JM109的产量比重组DH5α约提高20％,为低成本、大规模生产重组质粒提供了良好的技术保障。     

Knockout of ptsG Gene in Escherichia coli and Its Influence on Production of L-phenylalanine

L-phe 是重要的食品和医药中间体,用大肠杆菌发酵葡萄糖生成 phe 时,对葡糖糖转运起重要作用的磷酸烯醇丙酮酸糖磷酸转移酶系统(PTS)对 phe 产量合成有很大影响,在大肠杆菌 PTS 系统中,葡糖糖主要由 ptsG 基因编码的葡萄糖特异性转运蛋白酶ⅡCBGlc转运入细胞,通过基因敲除技术获取ptsG缺陷菌株,可以减少菌株对葡糖糖的摄取,减少乙酸的生成,利于菌株的高密度发酵和相关代谢中间物获得.利用 Red 同源重组技术将大肠杆菌染色体上的 ptsG 基因进行敲除,得到 PTS 缺陷菌株 MD-ptsG-.该菌株在以葡萄糖为惟一碳源的培养基中摇瓶培养,菌密度为对照菌株的3.5倍,L-phe 产量提高12％.     

大肠杆菌ptsG基因的敲除及其对L-phe生产的影响

L-phe是重要的食品和医药中间体,用大肠杆菌发酵葡萄糖生成phe时,对葡糖糖转运起重要作用的磷酸烯醇丙酮酸糖磷酸转移酶系统(PTS)对phe产量合成有很大影响,在大肠杆菌PTS系统中,葡糖糖主要由ptsG基因编码的葡萄糖特异性转运蛋白酶ⅡCBGlc转运入细胞,通过基因敲除技术获取ptsG缺陷菌株,可以减少菌株对葡糖糖的摄取,减少乙酸的生成,利于菌株的高密度发酵和相关代谢中间物获得。利用Red同源重组技术将大肠杆菌染色体上的ptsG基因进行敲除,得到PTS缺陷菌株MD-ptsG-。该菌株在以葡萄糖为惟一碳源的培养基中摇瓶培养,菌密度为对照菌株的3.5倍,L-phe产量提高12%。     

基于大肠杆菌受体菌DH5α △asd缺失株的构建及作为基因转化、表达操作系统的评估

基于大肠杆菌(E.coli)染色体上asd基因的已知序列,利用λ噬菌体的Red同源重组系统一步法构建E.coliDH5α的asd基因缺失突变株DH5α△asd::cat,在二次重组中利用携带能够表达FLP位点特异性重组酶的质粒pCP20介导二次同源重组,以去除上述缺失突变株中氯霉素抗性筛选基因。结合PCR扩增和测序结果,证明DH5α△asd缺失突变株的正确构建。该缺失突变株失去了在普通LB培养基上生长的能力,只有添加DAP或导入表达asd基因的质粒(asd基因互补试验)才能在LB培养基上生长,与原型DH5α比较,其生长速度和生长对数期、接受不同拷贝数质粒的转化效率几乎相一致。基于该缺失突变株构建出以asd营养基因为标志的大肠杆菌染色体-质粒平衡致死系统。体外培养连续传代50代次,pnirBMisL-fedF-asd质粒不丢失,并功能性表达F18大肠杆菌黏附素FedF。     

山梨糖脱氢酶基因在大肠杆菌染色体上整合及表达

以质粒pKF3为模板,扩增出两翼与ptsG基因上下游序列同源,中间为氯霉素抗性基因的DNA片段,连至pMD18T载体,构建得到pMD18PC。以质粒pQE60SDH为模板,扩增山梨糖脱氢酶基因sdh,与pMD18PC连接,得到pMD18PCSDH。将其用PvuⅡ酶切,回收含ptsG1catsdhptsG2的目的片段,电转化至JM109/pKD46,在Red重组酶的作用下,外源DNA片段与染色体上对应区域发生同源重组,将基因ptsG敲除,替换为catsdh基因,获得整合sdh基因的JM109s。经检测JM109s具有山梨糖脱氢酶活性。以 ptsG基因上下游序列为引物,JM109s基因组DNA为模板进行PCR,扩增产物测序结果表明sdh基因染色体整合成功。     

一种快速、精确构建大肠杆菌组氨酸营养缺陷型的方法

将表达Red体内重组蛋白的质粒pKD46转化大肠杆菌：DH5α,用5′端与组氨酸基因同源,3′端与卡那霉素抗性基因同源的引物获得具有卡那霉素抗性基因的PCR产物,然后电击转化DH5α,在λRed重组系统的帮助下,通过卡那霉素抗性基因两侧的组氨酸基因序列在体内与大肠杆菌染色体上的组氨酸基因发生同源重组,置换了DH5α组氨酸操纵元中的hisDCB基因,最后利用卡那霉素抗性基因两端的FRT位点,通过FTP位点专一性重组将卡那霉素抗性基因去除,最终获得了不具抗性的大肠杆菌组氨酸营养缺陷型菌株。为在大肠杆菌及其他菌株中快速、精确的构建营养缺陷型菌株提供了有益的参考。     

一种快速、精确构建大肠杆菌组氨酸营养缺陷型的方法*

将表达Red体内重组蛋白的质粒pKD46转化大肠杆菌DH5α,用 5′端与组氨酸基因同源 ,3′端与卡那霉素抗性基因同源的引物获得具有卡那霉素抗性基因的PCR产物 ,然后电击转化DH5α,在λRed重组系统的帮助下 ,通过卡那霉素抗性基因两侧的组氨酸基因序列在体内与大肠杆菌染色体上的组氨酸基因发生同源重组 ,置换了DH5α组氨酸操纵元中的hisDCB基因 ,最后利用卡那霉素抗性基因两端的FRT位点 ,通过FTP位点专一性重组将卡那霉素抗性基因去除 ,最终获得了不具抗性的大肠杆菌组氨酸营养缺陷型菌株。为在大     

Modified Escherichia coli B (BL21), a superior producer of plasmid DNA compared with Escherichia coli K (DH5alpha)

Plasmid DNA (pDNA) is an emerging experimental vaccine, produced in E. coli, initially targeted for viral diseases. Unlike traditional protein vaccines whose average dose is micrograms, the average dose of pDNA is on the scale of milligrams. Production yields are, therefore, important for the future development of this vaccine. The E. coli strains currently used for pDNA production, JM109 and DH5alpha, are both suitable for production of stable pDNA due to the deletion of recA and endA, however, these two E. coli K strains are sensitive to growth conditions such as high glucose concentration. On the other hand E. coli BL21 is less sensitive to growth conditions than E. coli JM109 or DH5alpha, this strain grows to higher densities and due to its active glyoxylate shunt and anaplerotic pathways is not sensitive to high glucose concentration. This strain is used for recombinant protein production but not for pDNA production because of its inability to produce stable pDNA. To adapt E. coli BL21 for stable pDNA production, the strain was mutated by deleting both recA and endA, and a proper growth and production strategy was developed. Production values, reaching 2 g/L were obtained using glucose as a carbon source. The produced plasmid, which was constructed for HIV clinical study, was found to have identical properties to the plasmid currently produced by E. coli DH5alpha.     

大肠杆菌工程菌ptsG基因敲除及其缺陷株混合糖同型乙醇发酵

为实现可同时利用木糖和葡萄糖进行生产发酵,以产乙醇的大肠杆菌工程菌SZ470为出发菌株(△pflB,△frdABCD,△ackA,△ldhA),采用同源重组技术,敲除葡萄糖转运基因ptsG,以构建不受葡萄糖抑制效应影响的菌株SZ470P.SZ470P在5％混合糖(2.5％木糖和2.5％葡萄糖)培养基中能同时利用葡萄糖和木糖进行发酵,葡萄糖消耗量是13 g/L,为对照菌株SZ470的一半;木糖消耗量是20 g/L,是SZ470的3.8倍;乙醇的最高产量为15.01 g/L,转化率为89.13％,比SZ470提高了14.32％.结果表明,工程菌SZ470P可同时利用葡萄糖和木糖发酵生产高产量的乙醇.     

利用大肠杆菌工程菌廉价高效生产聚羟基丁酸酯

利用大肠杆菌生产聚羟基脂肪酸酯是近来国际上生物可降解塑料的研究热点,本研究通过对适宜于聚羟基脂肪酸酯生产的大肠杆菌菌株的选择和碳源利用试验,初步确立了大肠杆菌代谢工程改造生产聚羟基脂肪酸酯的基础。并在此基础上,通过对大肠杆菌磷酸烯醇式丙酮酸葡萄糖转移酶系统的改造和工程菌环境诱导系统的应用,解决了大肠杆菌工程菌无法同时利用多种碳源合成聚羟基脂肪酸酯的难题。发酵试验证明,工程化改造的大肠杆菌利用廉价底物在5L发酵罐中分批培养32h后,菌体终浓度能够达到8.24g/L,聚羟基脂肪酸酯占细胞干重的84.6%。     

Mutation of the ptsG gene results in increased production of succinate in fermentation of glucose by Escherichia coli

Escherichia coli NZN111 is blocked in the ability to grow fermentatively on glucose but gave rise spontaneously to a mutant that had this ability. The mutant carries out a balanced fermentation of glucose to give approximately 1 mol of succinate, 0. 5 mol of acetate, and 0.5 mol of ethanol per mol of glucose. The causative mutation was mapped to the ptsG gene, which encodes the membrane-bound, glucose-specific permease of the phosphotransferase system, protein EIICB(glc). Replacement of the chromosomal ptsG gene with an insertionally inactivated form also restored growth on glucose and resulted in the same distribution of fermentation products. The physiological characteristics of the spontaneous and null mutants were consistent with loss of function of the ptsG gene product; the mutants possessed greatly reduced glucose phosphotransferase activity and lacked normal glucose repression. Introduction of the null mutant into strains not blocked in the ability to ferment glucose also increased succinate production in those strains. This phenomenon was widespread, occurring in different lineages of E. coli, including E. coli B.     

Comparison of recombinant Escherichia coli strains for synthesis and accumulation of poly-(3-hydroxybutyric acid) and morphological changes

A stable high-copy-number plasmid pSYL105 containing the Alcaligenes eutrophus polyhydroxyalkanoic acid (PHA) biosynthesis genes was constructed. This plasmid was transferred to seven Escherichia coli strains (K12, B, W, XL1-Blue, JM109, DH5alpha, and HB101), which were subsequently compared for their ability to synthesize and accumulate ploy- (3-hydroxybutyric acid) (PHB). Growth of recombinant cells and PHB synthesis were investigated in detail in Luria-Bertani (LB) medium containing 20 g/L glucose. Cell growth, the rate of PHB synthesis, the extent of PHB accumulation, the amount of glucose utilized, and the amount of acetate formed varied from one strain to another. XL1-Blue (pSYL105) and B (pSYL105) synthesized PHB at the fastest rate, which was ca. 0.2 g PHB/g true cell mass-h, and produced PHB up to 6-7 g/L. The yields of cell mass, true cell mass, and PHB varied considerably among the strains. The PHB yield of XL1-Blue (pSYL105) in LB plus 20 g/L glucose was as high as 0.369 g PHB/g glucose. Strains W (pSYL105) and K12 (pSYL105) accumulated the least amount of PHB with the lowest PHB yield at the lowest synthesis rate. JM109 (pSYL105) accumulated PHB to the highest extent (85.6%) with relatively low true cell mass (0.77 g/L). Considerable filamentation of cells accumulating PHB was observed for all strains except for K12 and W, which seemed to be due either to the overexpression of the foreign PHA biosynthesis enzymes or to the accumulation of PHB. (c) 1994 John Wiley & Sons, Inc.     

Effect of modified glucose uptake using genetic engineering techniques on high-level recombinant protein production in escherichia coli dense cultures

Reduction of acetate excretion using a modified cellular glucose uptake rate was examined. An Escherichia coli strain bearing a mutationin ptsG, a gene encoding enzyme II in glucose phosphotransferase system (PTS), was constructed and characterized. The growth rate of the mutant strain was slower than its parent in glucose defined medium, butwas not affected in complex medium. Experimental results using this mutant strain showed a significant improvement in culture performance in simple batch cultivations due to reduced acetate excretion through the modified glucose uptake. Both biomass and recombinant protein productivity were increased by more than 50% with the ptsG mutant when compared to the parent strain. Recombinant protein productivity by the newly constructed strain at a level of more than 1.6 g/L was attained consistently in a simple batch bioreactor. (c) 1994 John Wiley & Sons, Inc.     

Improving the growth rate of Escherichia coli DH5alpha at low temperature through engineering of GroEL/S chaperone system

GroEL/S is a molecular chaperone system in Escherichia coli which not only assists the folding of intracellular proteins but also affects the cellular activity against the change of environmental condition. Here we show that the growth rate of E. coli DH5alpha can be improved at low temperature by expressing a GroEL/S variant achieved through irrational protein engineering approach. The GroELS variant (GroELS(var)) accelerating the growth of E. coli DH5alpha was screened through enrichment culture of the mutant libraries obtained by random mutagenesis. E. coli DH5alpha harboring the groELS(var) gene exhibited approximately 1.5-2 times higher growth rate compared to the strain with wild-type GroELS at 15-30 degrees C. At 10 degrees C, a temperature that the growth of E. coli DH5alpha almost stops, the GroELS(var) triggered the growth of E. coli DH5alpha. We identified that seven nucleotides of groELS gene and six amino acids of the GroELS were changed through the mutagenesis and screening. Site directed mutagenic analysis revealed that H360 in GroEL(var) is the most crucial residue determining the activity of GroELS(var) and more than one of the other residues in GroEL(var) may be additionally involved in the activity of GroELS(var). The improvement of growth rate induced by the GroELS(var) was observed only in the strain DH5alpha and not detected in other E. coli strains, such as BL21, BW25113, codon+, JM110, Top10, and XL1-blue.     

Construction of a pTOC-T vector using GST-ParE toxin for direct cloning and selection of PCR products

Using linker insertion mutations, we determined the most stable region of the parE gene which encodes a toxic protein (ParE) that inhibits growth of Escherichia coli. The toxicity of ParE was sustained until a 144 bp linker was inserted into this region. We have developed a 3' T-overhang vector based on these characteristics of the GST-ParE toxin, and named pTOC-T. Because pTOC-T uses a post-segregational killing system, all transformants grown up on the plates can be considered as recombinants containing foreign DNA. pTOC-T not require X-Gal, IPTG or other substrates for selection. This T-vector using a positive selection system can be applied to various E. coli strains such as XL1-Blue, BL21, DH5alpha, JM109, and JM110.