含苏氨酸操纵子重组质粒的构建及其对大肠杆菌L-苏氨酸积累的影响

摘要：【目的】通过分子生物学手段构建重组质粒,将其转入野生型大肠杆菌W3110,分析含苏氨酸操纵子基因的质粒及质粒定点突变解除反馈抑制时,对L-苏氨酸积累的影响。【方法】以W3110染色体DNA为模板,PCR扩增苏氨酸操纵子基因,即启动子THrLp、编码前导肽基因thrL以及thrA、thrB、thrC基因,通过重叠延伸PCR的方法对thrA基因定点突变,解除苏氨酸对它的反馈抑制,构建出重组表达质粒WYE112和WYE134,5 L发酵实验测定L-苏氨酸的产量。【结果】经5 L发酵罐发酵产酸实验,W3110的L-苏氨酸产量为0.036 ± 0.004 g/L,携带含苏氨酸操纵子质粒的W3110菌株L-苏氨酸产量为2.590 ± 0.115 g/L,质粒上thrA解除反馈抑制后,L-苏氨酸的产量增加到9.223 ± 1.279 g/L。【结论】过表达苏氨酸操纵子基因可以使L-苏氨酸积累,进一步解除thrA基因的反馈抑制,可以增强L-苏氨酸积累的效果,为L-苏氨酸工程菌改造的进一步研究奠定了基础。     

Cloning and characterization of the mutated threonine operon (thrA(1)5A(2)5BC) of Serratia marcescens

The entire threonine operon (thrA(1)5A(2)5BC) of Serratia marcescens TLr156, which lacks threonine-mediated feedback inhibition of both aspartokinase I (AK I) and homoserine dehydrogenase I (HD I), was cloned on a multicopy plasmid pLG339. Hybrid plasmid pSK301 carried a 6.5-kb chromosomal DNA. Several derivatives of pSK301 with Tn1000 insertions were obtained. By examining the phenotypes and the physical maps of these plasmids, we could define the loci of the thrA(1)5A(2)5, thrB, and thrC genes. The thrA(1)5A(2)5 and thrC gene products were identified by the maxicell method as proteins with Mrs of 85,000 and 43,000, respectively. The thrA(1)5A(2)5 genes encode a single polypeptide similar to the thrA1A2 genes of Escherichia coli. Plasmid pSK301 was introduced into S. marcescens T-1112, in which both AK I and HD I are produced constitutively. The resulting transformant carried five to six copies of pSK301 per chromosome and produced the AK I and HD I enzymes at three to four times higher level than control strain T-1112[pLG339]. Strain T-1112[pSK301] produced four times higher levels of threonine than strain T-1112[pLG339], yielding about 35 mg of threonine per ml of a medium containing sucrose and urea.     

Threonine Locus of Escherichia coli K-12: Genetic Structure and Evidence for an Operon

Three genes, thrA, thrB, and thrC, were previously defined and localized in the threonine locus of Escherichia coli K-12. thrA, thrB, and thrC specify the enzymes aspartokinase I-homoserine dehydrogenase I, homoserine kinase, and threonine synthetase, respectively. A complementation analysis of the threonine cluster using derivatives of a lambda phage carrying the threonine genes (lambdadthr(c)) demonstrates that: (i) thrB and thrC each consist of a single cistron; and (ii) thrA is composed of two cistrons, thrA(1) and thrA(2), although it specifies a single polypeptide chain. thrA(1) and thrA(2) correspond to aspartokinase I and homoserine dehydrogenase I, respectively. Their relative order is established. The demonstration of polar effects of mutations (nonsense or induced by phage Mu) in thrA and thrB is taken as evidence for the existence of a thrA thrB thrC operon, transcribed in this order.     

Isolation and study of hybrid plasmids carrying Escherichia coli threonine operon genes

A fragment of Escherichia coli chromosome containing the intact threonine operon or its distinct genes has been cloned on the pBR322 plasmid. This fragment has been mapped using some restriction endonucleases. Cloning results in an increased level of appropriate enzyme activity in cells containing hybrid plasmids. Those carrying the complete threonine operon are capable of accumulating threonine up to 5 g/l in culture medium during 48 h. When multi-copy plasmids are used for gene cloning, interpretation of experiments aimed at transformation of auxotrophic bacterial strains, might be complicated. For example, transformation of appropriate threonine auxotrophs by a hybrid plasmid carrying mutation in the threonine gene, might result in prototrophic phenotype. It is possible that the great amount of mutant enzyme molecules compensated their low activity. On the contrary, the presence of a gene within the plasmid, as shown by restriction and biochemical analysis, did not always ensure the growth on a minimal medium of auxotrophs transformed by this plasmid.     

Location of trpR Mutations in the serB-thr Region of Salmonella typhimurium

Tryptophan biosynthesis in Salmonella is controlled by at least one regulatory gene, trpR, which is cotransducible with thr genes and not with the trp operon. Mutations in trpR cause derepression of tryptophan enzyme synthesis and confer resistance to growth inhibition by 5-methyltryptophan. Nineteen trpR mutations were mapped with respect to thrA and serB markers by two-point (ratio) and three-point transduction tests. The results are all consistent with the site order serB80-trpR-thrA59 on the Salmonella chromosome. Very low or undetectable levels of recombination between different trpR mutations have so far prevented the determination of fine structure in the trpR gene. Thirteen other 5-methyltryptophan-resistant mutants previously found not to be cotransducible with either the trp operon or thrA, and designated trpT, were also used in these experiments. Lack of cotransducibility with thrA was confirmed, and no linkage with serB was detected. The nature and location of trpT mutations remain obscure.     

Instability study of Escherichia coli strains containing hybrid plasmids with threonine operon fragments

The stability of Escherichia coli strains carrying hybrid plasmids which contain ColE1-like replicon and threonine operon genes was studied. It was shown that the main reason for instability is the loss of a plasmid. The second reason for instability is the rec-dependent recombination that leads to formation of new plasmids. All experiments where instability of strains was observed, can be quantitatively described by the model that presumes a random loss of plasmids in cell population with a frequency of about 7.10(-4), which results in diappearance of plasmid-borne cells due to their low growth rate. Instability increases during the stationary phase but it is not easy to quantitatively estimate this process.     

Cloning and structural-functional analysis in Escherichia coli of genes of glutamate-producing corynebacteria controlling biosynthesis of amino acids of aspartic acid series

A library of EcoRI DNA fragments from Brevibacterium flavum was constructed using plasmid vector. The genes complementing ThrA2 and ThrB mutations in Escherichia coli were identified in the library. The gene thrA2 of B. flavum codes for mutant enzyme homoserine dehydrogenase insensitive to inhibition by threonine. The genes thrA2 and thrB are localized wihtin the EcoRI fragment 4.1 kb long and are expressed under the control of their own promoters in E. coli cells. Structural and functional analysis of cloned C. glutamicum gene ilvA was performed. The gene of C. glutamicum complemented ilvA mutation in E. coli and appeared to be localized within the EcoRI--SacI DNA fragment 1.6 kb in size. Using E. coli minicells we have demonstrated that the gene ilvA of C. glutamicum controls the synthesis of polypeptide of relative molecular mass 50 kD.     

Development of the vector-host system in Corynebacterium. Cloning and expression of homoserine dehydrogenase and homoserine kinase genes in Corynebacterium cells

Novel cloning vectors for glutamic acid producing bacteria have been constructed. The cryptic plasmid pBO1 (4.4 kb) from Brevibacterium sp. recombined with the plasmid pACYC184 (4.0 kb) from Escherichia coli was used to produce composite plasmid named pKA1. The plasmid could propagate and express the Cm-r phenotype in E. coli and coryneform glutamic acid producing bacteria Br. flavum, C. glutamicum, Br. lactofermentum. The pKA1 plasmid and its variants deleted within non-essential plasmid regions with unique restriction sites HindIII, SalGI, SphI were used in cloning experiments. The genes coding for threonine biosynthesis of C. glutamicum and Br. flavum were subcloned into shuttle vectors in C. glutamicum cells. Recombinant plasmids were introduced into protoplasts by polyethylenglycol-mediated transformation of plasmid DNAs. It was shown that the presence of plasmids containing the Br. flavum thrA2 gene in C. glutamicum (thrB) caused 10-fold increase in homoserine dehydrogenase activity, as compared to that of wild type strain, and in homoserine production.     

Nucleotide sequence of the Serratia marcescens threonine operon and analysis of the threonine operon mutations which alter feedback inhibition of both aspartokinase I and homoserine dehydrogenase I.

The nucleotide sequence of the Serratia marcescens threonine operon (thrA1A2BC) was determined. Three long open reading frames were identified; these open reading frames code for aspartokinase I (AKI)-homoserine dehydrogenase I (HDI), homoserine kinase, and threonine synthase, in that order. The predicted amino acid sequences of these enzymes were similar to the amino acid sequences of the corresponding enzymes in Escherichia coli. The AKI-HDI protein is apparently a tetramer composed of monomer polypeptides that are 819 amino acids long. A deletion analysis revealed that the central and C-terminal region was responsible for threonine-resistant HDI activity, a monomeric fragment extending from the N terminus to residue 306 was responsible for threonine-resistant AKI activity, and an N-terminal portion containing 468 residues was responsible for threonine-sensitive AKI activity. The thrA(1)1A(2)1 and thrA(1)5A(2)5 mutations of threonine-excreting strains HNr21 and TLr156, which result in the loss of threonine-mediated feedback inhibition of both AKI activity and HDI activity, cause single amino acid substitutions (Gly to Asp at position 330 and Ser to Phe at position 352, respectively) in the central region of the AKI-HDI protein. The thrA1+A(2)2 mutation of strain HNr59, which results in a threonine-sensitive AKI and a threonine-resistant HDI, also causes a single amino acid substitution (Ala to Thr at position 479).     

pMB9 plasmids bearing the Salmonella typhimurium his operon and gnd gene

A plasmid containing the entire Salmonella typhimurium his operon was constructed from plasmid pM89 and an EcoRI fragment of phi 80 his imm lambda DNA. The recombinant pST41 also includes the glucose 6-phosphate dehydrogenase (gnd) gene and has one EcoRI endonuclease cleavage site in the integrated fragment. This plasmid served as a source for the construction of two additional plasmids, one carrying the OGDC-region of the his operon and the other a CBHAFIE segment of the his gene along with the gnd gene. The presence of the his operon in the constructed plasmids was confirmed by hybridization to S. typhimurium his RNA. The location of the gnd gene in the CBHAFIE fragment of the his gene was confirmed genetically: after transfection with the plasmid bearing the gnd gene, a gnd recipient gained the capacity to utilize gluconate as a sole carbon source. The DNAs of the three hybrid plasmids were analyzed by gel electrophoresis. By comparing the EcoRI endonuclease cleavage pattern of these three hybrid plasmids with the DNA cleavage pattern of phi 80 his imm lambda, phi 80 imm lambda and lambda phages, the EcoRI cleavage map of phi 80 his imm lambda was obtained.     

Fine structure analysis of the threonine operon in Escherichia coli K-12.

Summary A fine structure analysis of the threonine operon in Escherichia coli K-12 was performed by deletion mapping. Lambda transducing bacteriophages carrying various parts of the threonine operon were isolated from strains in which the lacZ gene was fused to a thr gene. We tested for recombination between deletions of the threonine promotor extending into the threonine operon, carried by the phage, and bacterial thr auxotrophs. The relative order of thrO (operator) mutations was established. We propose that an operator region is located between a promoter region and the structural genes. Mutations leading to the desensitization of the aspartokinase I-homoserine dehydrogenase I towards threonine were localized in two different regions of the thrA gene.     

Cloning and study of Corynebacterium glutamicum genes complementing ilvA and thrA2 mutations in Escherichia coli

Molecular cloning and expression of Corynebacterium glutamicum genes complementing Escherichia coli mutations thrA2 and ilvA was performed. It was demonstrated that the thrA2 gene of C. glutamicum is located close to thrB on EcoRI DNA fragment 4.1 kb long. The fragment was cloned in pUC18 vector. The thrA2 gene is expressed in the recombinant plasmid pOBT3 under control of the vector pUC18 Plac promoter. In E. coli minicells, the genes thrA2 and thrB determined synthesis of proteins of Mr 43kD and 25 kD, respectively. A gene complementing ilvA mutation of E. coli was identified in a library of EcoRI C. glutamicum DNA fragments. This library was constructed using plasmid vector. It was shown that the ilvA gene of C. glutamicum is located inside the 3.6 kb EcoRI fragment and is expressed using its own promoter.     

Effectiveness of expression of the chloramphenicol acetyltransferase gene controlled by foreign regulator regions in Escherichia coli cells. II. Molecular cloning of promoters

The trpOP, lacUV5, tacOP, PR and PL-promotors were cloned in the previously obtained pML4 vector plasmid. The expression of structural gene cat was studied by the chloramphenicolacetyltransferase determination in cell extracts. The level of protein synthesis by appropriate recombinant plasmids was analysed in vivo and in vitro. It was shown that the efficiency of the gene expression is determined by both the "strength" of the promotors and mRNA translation specificity. The obtained collection of the plasmids might be used for the determination of the promotor strength by the hybridization of pulse-labeled mRNA with DNA and an effective expression of the genes by means of "hybrid protein gene" and "hybrid operon" constructions.     

Transposon mutagenesis analysis of meta-cleavage pathway operon genes of the TOL plasmid of Pseudomonas putida mt-2.

Hybrid plasmids containing the regulated meta-cleavage pathway operon of TOL plasmid pWWO were mutagenized with transposon Tn1000 or Tn5. The resulting insertion mutant plasmids were examined for their ability to express eight of the catabolic enzymes in Escherichia coli. The physical locations of the insertions in each of 28 Tn1000 and 5 Tn5 derivative plasmids were determined by restriction endonuclease cleavage analysis. This information permitted the construction of a precise physical and genetic map of the meta-cleavage pathway operon. The gene order xylD (toluate dioxygenase), L (dihydroxycyclohexidiene carboxylate dehydrogenase), E (catechol 2,3-dioxygenase), G (hydroxymuconic semialdehyde dehydrogenase), F (hydroxymuconic semialdehyde hydrolase), J (2-oxopent-4-enoate hydratase), I (4-oxalocrotonate decarboxylase), and H (4-oxalocrotonate tautomerase) was established, and gene sizes were estimated. Tn1000 insertions within catabolic genes exerted polar effects on distal structural genes of the operon, but not on an adjacent regulatory gene xylS.