Molecular cloning of the N-acetylneuraminate lyase gene in Escherichia coli K-12

Summary The gene for N-acetylneuraminate lyase [N-acetylneuraminate pyruvate-lyase; NPL] of Escherichia coli C600 was cloned onto pBR322 as a 9.8 kilobase HindIII fragment of chromosomal DNA and the hybrid plasmid was designated pMK2. The gene in the hybrid plasmid was subcloned in pBR322 as a 1.2 kilobase HindIII-EcoRI fragment and the resultant hybrid plasmid was designated pMK6. NPL activity level was increased more than 5-fold in the pMK6-bearing strain compared with that of the wild type, when the cells were grown on a medium containing inducer (N-acetylneuraminate: NANA). The transformants harbouring pMK6 also showed higher activity even in the absence of inducer. The NPL produced by pMK6-bearing cells was structurally and immunologically the same as that purified from E. coli C600.     

Production of S-lactoylglutathione by glycerol-adapted Saccharomyces cerevisiae and genetically engineered Escherichia coli cells

Summary The enzymatic production of S-lactoylglutathione was studied by applying glyoxalase I to glycerol-grown cells of Saccharomyces cerevisiae and Escherichia coli cells dosed with Pseudomonas putida glyoxalase I gene. The glyoxalase I in S. cerevisiae cells was markedly induced when the cells were grown on glycerol. The activity of the enzyme in glycerol-grown cells was more than 20-fold higher compared with that of the glucose-grown cells. By using extracts of glycerol-grown yeast cells, about 5 mmol/1 (2 g/l) of S-lactoylglutathione was produced from 10 mM methylglyoxal and 50 mM glutathione within 1 h. The extracts of E. coli cells carrying a hybrid plasmid pGI423, which contains P. putida glyoxalase I gene, showed approximately 170-fold higher glyoxalase I activity than that of E. coli cells without pGI423. The extracts were used for production of S-lactoylglutathione and, under optimal conditions, about 40 mmol/l (15 g/l) of S-lactoylglutathione was produced from 50 mM methylglyoxal and 100mM glutathione within 1 h.     

Cloning, restriction endonuclease mapping and post-transcriptional regulation of rpsA, the structural gene for ribosomal protein S1

Transducing lambda phages have been isolated that carry segments of the Escherichia coli chromosome in the aspC region, 20.5 min on the E. coli map. One of these phages, lambda aspC2, carries rpsA, the structural gene for the ribosomal protein S1. A three kilobase fragment from this phage, cloned into either the plasmid pACYC184 or the plasmid pBR322, was found to express S1. In cells carrying the rpsA gene on the high copy number plasmid pBR322 the rate of rpsA mRNA synthesis was increased 40-fold, whereas the rate of protein S1 synthesis was doubled, in comparison with these rates in an rpsA haploid.     

Cloning of a creatinase gene from Pseudomonas putida in Escherichia coli by using an indicator plate.

A genomic library of Pseudomonas putida DNA was constructed by using plasmid pBR322. Transformants of Escherichia coli in combination with Proteus mirabilis cells grown on creatinase test plates were screened for creatinase activity; transformants were considered positive for creatinase activity if a red-pink zone appeared around the colonies. One creatinase-positive clone was further analyzed, and the gene was reduced to a 2.7-kb DNA fragment. A unique protein band (with a molecular weight of approximately 50,000) was observed in recombinant E. coli by minicell analysis.     

Cloning of a creatinase gene from Pseudomonas putida in Escherichia coli by using an indicator plate.

A genomic library of Pseudomonas putida DNA was constructed by using plasmid pBR322. Transformants of Escherichia coli in combination with Proteus mirabilis cells grown on creatinase test plates were screened for creatinase activity; transformants were considered positive for creatinase activity if a red-pink zone appeared around the colonies. One creatinase-positive clone was further analyzed, and the gene was reduced to a 2.7-kb DNA fragment. A unique protein band (with a molecular weight of approximately 50,000) was observed in recombinant E. coli by minicell analysis.     

Cloning of a gene responsible for the biosynthesis of glutathione in Escherichia coli B

A gene (gshI) responsible for gamma-glutamylcysteine synthetase (GSH-I) activity was cloned to construct an Escherichia coli B strain having high glutathione synthesizing activity. For this purpose, two E. coli B mutants (strains C912 and RC912) were used. C912 was deficient in GSH-I activity. RC912, a revertant of C912, had a GSH-I activity that was desensitized to feedback inhibition of reduced glutathione. To clone gshI, chromosomal DNAs of RC912 and plasmid vector pBR322 were digested with various restriction endonucleases and then ligated with T4 DNA ligase. The whole ligation mixture was used to transform C912, and the transformants were selected as tetramethylthiuramdisulfide-resistant colonies. Of about 20 resistant colonies, 2 or 3 became red when treated with nitroprusside and showed appreciably high GSH-I activities. The chimeric plasmid DNA, designated pBR322-gshI, was isolated from the strain having the highest GSH-I activity and transformed into RC912. The structure and molecular size of pBR322-gshI in RC912 were determined. The molecular size of this plasmid was 6.2 megadaltons, and the plasmid contained a 3.4-megadalton segment derived from RC912 chromosomal DNA, which included gshI gene. The GSH-I activity of RC912 cells containing pBR322-gshI was fourfold higher than that of RC912 cells without pBR322-gshI.     

Cloning of a gene responsible for the biosynthesis of glutathione in Escherichia coli B.

A gene (gshI) responsible for gamma-glutamylcysteine synthetase (GSH-I) activity was cloned to construct an Escherichia coli B strain having high glutathione synthesizing activity. For this purpose, two E. coli B mutants (strains C912 and RC912) were used. C912 was deficient in GSH-I activity. RC912, a revertant of C912, had a GSH-I activity that was desensitized to feedback inhibition of reduced glutathione. To clone gshI, chromosomal DNAs of RC912 and plasmid vector pBR322 were digested with various restriction endonucleases and then ligated with T4 DNA ligase. The whole ligation mixture was used to transform C912, and the transformants were selected as tetramethylthiuramdisulfide-resistant colonies. Of about 20 resistant colonies, 2 or 3 became red when treated with nitroprusside and showed appreciably high GSH-I activities. The chimeric plasmid DNA, designated pBR322-gshI, was isolated from the strain having the highest GSH-I activity and transformed into RC912. The structure and molecular size of pBR322-gshI in RC912 were determined. The molecular size of this plasmid was 6.2 megadaltons, and the plasmid contained a 3.4-megadalton segment derived from RC912 chromosomal DNA, which included gshI gene. The GSH-I activity of RC912 cells containing pBR322-gshI was fourfold higher than that of RC912 cells without pBR322-gshI.     

Expression of a Streptococcus mutans glucosyltransferase gene in Escherichia coli.

Chromosomal DNA from Streptococcus mutans strain UAB90 (serotype c) was cloned into Escherichia coli K-12. The clone bank was screened for any sucrose-hydrolyzing activity by selection for growth on raffinose in the presence of isopropyl-beta-D-thiogalactoside. A clone expressing an S. mutans glucosyltransferase was identified. The S. mutans DNA encoding this enzyme is a 1.73-kilobase fragment cloned into the HindIII site of plasmid pBR322. We designated the gene gtfA. The plasmid-encoded gtfA enzyme, a 55,000-molecular-weight protein, is synthesized at 40% the level of pBR322-encoded beta-lactamase in E. coli minicells. Using sucrose as substrate, the gtfA enzyme catalyzes the formation of fructose and a glucan with an apparent molecular weight of 1,500. We detected the gtfA protein in S. mutans cells with antibody raised against the cloned gtfA enzyme. Immunologically identical gtfA protein appears to be present in S. mutans cells of serotypes c, e, and f, and a cross-reacting protein was made by serotype b cells. Proteins from serotype a, g, and d S. mutans cells did not react with antibody to gtfA enzyme. The gtfA activity was present in the periplasmic space of E. coli clones, since 15% of the total gtfA activity was released by cold osmotic shock and the clones were able to grow on sucrose as sole carbon source.     

Cloning and expression of the yeast galactokinase gene in an Escherichia coli plasmid.

This report describes the construction and isolation of a plasmid, derived from pBR322, which carries a BglII restriction fragment of DNA containing the galactokinase gene from Saccharomyces cerevisiae. This was accomplished by the following procedure: (1) Purified galactokinase mRNA, labelled with 125I, was hybridized to BglII digests of yeast DNA employing Southern's filter transfer technique to identify a restriction fragment containing the galactokinase gene. (2) This fragment was partially purified by agarose gel electrophoresis, ligated into the BamHI site of pBR322 and transformed into Escherichia coli to generate a clone bank containing the galactokinase gene. (3) This bank was screened by in situ colony hybridization with galactokinase mRNA resulting in the identification of a plasmid carrying this gene. This plasmid DNA hybridized with the galactokinase mRNA to the same extent in the presence of absence of a large excess of unlabelled mRNA from cells that were not induced for galactokinase synthesis, while the same amount of unlabelled galactose-induced mRNA reduced the hybridization by 95%. When this plasmid was introduced into an E. coli strain deleted for the galactose operon it caused the synthesis of low levels of yeast galactokinase activity.     

Survival of and plasmid stability in Pseudomonas and Klebsiella spp. introduced into agricultural drainage water

Cell survival and plasmid stability in Pseudomonas fluorescens R2f and Pseudomonas putida CYM 318 containing respectively, plasmid RP4 and pRK2501, and Klebsiella aerogenes NCTC 418 harboring plasmid pBR322 were studied in sterile and nonsterile agricultural drainage water under both aerobic and anaerobic conditions and in the absence and presence of added nutrients. Both Pseudomonas strains survived well in sterile drainage water incubated aerobically, with or without added nutrients. However, Klebsiella aerogenes NCTC 418 (pBR322) only survived in the presence of added nutrients. Pseudomonas fluorescens R2f (RP4) and K. aerogenes NCTC 418 (pBR322) did not survive under anerobic conditions without added nutrients, but showed good survival in the presence of nutrients. Survival of all three strains was negatively affected in nonsterile agricultural drainage water when compared with survival in sterile water. Maintenance of the three plasmids was host, plasmid, and environment dependent. Plasmid pBR322 was not stably maintained in K. aerogenes NCTC 418 under all conditions used in the study, and pRK2501 was readily lost from P. putida CYM 318. Maintenance of RP4 by P. fluorescens R2f was markedly influenced by added nutrients, which caused a loss of the plasmid from cells. The results of the present study demonstrate the influence of nutrients, O2, and native microorganisms on the survival of introduced bacterial strains and plasmid stability in agricultural drainage water.     

Acquisition of a sucrose utilization system in Escherichia coli K-12 derivatives and its application to industry.

An Escherichia coli strain, B-62, that was isolated from a clinical source and was epidemiologically unrelated to E. coli K-12 was the source of chromosomal DNA for a sucrose utilization system (Scr+) in the construction of a plasmid, pST621. The cloned insert of a gene encoding Scr+ in pST621 conferred a sucrose-positive phenotype onto transformed cells of E. coli K-12 derivatives. Sucrase activity of the transformants was as high as that which would correspond to a "gene dosage effect" of a vector plasmid pBR322, whereas the transformants' sucrose uptake activity was always lower than that of E. coli B-62. A region within an XhoI-SacI fragment (3.2 kb) of pBR322-glyA was replaced in the construction of another plasmid, pST5R7, by a fragment (about 2.6 kb) of pST622 containing the gene encoding Scr+. A genetically stable Scr+ derivative of E. coli K-12 was obtained by introducing the gene encoding Scr+ onto E. coli chromosome via homologous recombination between pST5R7 and the chromosome and subsequent plasmid segregation. The use of low-copy-number plasmid RP4 as a cloning vector was also effective for enhancing the stability of Scr+. Tryptophan producers E. coli SGIII1032S, in which the gene encoding Scr+ was cloned onto the chromosome, and E. coli SGIII1032, which carried Scr+ plasmid RP4.5R7, produced from 6% sucrose in shake flasks (33 degrees C, 96 h) 2.3 and 5.7 g of tryptophan per liter, respectively.     

Acquisition of a sucrose utilization system in Escherichia coli K-12 derivatives and its application to industry.

An Escherichia coli strain, B-62, that was isolated from a clinical source and was epidemiologically unrelated to E. coli K-12 was the source of chromosomal DNA for a sucrose utilization system (Scr+) in the construction of a plasmid, pST621. The cloned insert of a gene encoding Scr+ in pST621 conferred a sucrose-positive phenotype onto transformed cells of E. coli K-12 derivatives. Sucrase activity of the transformants was as high as that which would correspond to a "gene dosage effect" of a vector plasmid pBR322, whereas the transformants' sucrose uptake activity was always lower than that of E. coli B-62. A region within an XhoI-SacI fragment (3.2 kb) of pBR322-glyA was replaced in the construction of another plasmid, pST5R7, by a fragment (about 2.6 kb) of pST622 containing the gene encoding Scr+. A genetically stable Scr+ derivative of E. coli K-12 was obtained by introducing the gene encoding Scr+ onto E. coli chromosome via homologous recombination between pST5R7 and the chromosome and subsequent plasmid segregation. The use of low-copy-number plasmid RP4 as a cloning vector was also effective for enhancing the stability of Scr+. Tryptophan producers E. coli SGIII1032S, in which the gene encoding Scr+ was cloned onto the chromosome, and E. coli SGIII1032, which carried Scr+ plasmid RP4.5R7, produced from 6% sucrose in shake flasks (33 degrees C, 96 h) 2.3 and 5.7 g of tryptophan per liter, respectively.     

Novel host-vector system for selection and maintenance of plasmid-bearing, streptomycin-dependent Escherichia coli cells in antibiotic-free media

A novel system for selection and maintenance of cells carrying a recombinant plasmid has been developed, using the streptomycin-dependent (Smd) Escherichia coli 4D host and a plasmid vector carrying an rpsL gene from an Sm-resistant (Smr) mutant of E. coli which masks the Smd phenotype. Strain 4D carrying the Smr pBR322 plasmid can grow without Sm. Using this host-vector system, we can select for cells carrying an Smr recombinant plasmid and maintain them in antibiotic-free media.     

噬菌体T7基因6.5和6.7的克隆及其缺失变种的构建

 用适当的限制性内切酶,将噬菌体T7基因6.5和6.7从整个噬菌体T7基因组中分离出来,插入到质粒pBR322中去,转化E.Coli HMS174,筛选出这两个基因的成功克隆。运用同样手段,从整个噬菌体T7基因组中分离出含有部分基因6编码序列,而不含基因6.5和6.7编码序列的T7DNA片段,插入到pBR322的衍生质粒中去,转化Ecoli C1757,再用含有基因6和基因7的双突变噬菌体T7去感染这一转化菌,通过同源交叉而得到缺失基因6.5和6.7的噬菌体T7缺失变种。这种噬菌体只能在载有噬菌体T7基因6.5和6.7,或者只载有基因6.7质粒的寄主中增殖。通过噬菌体结构蛋白电泳分析证明,这种噬菌体丢失了野生型菌体T7所具有的两条结构蛋白带。     

Accumulation of methylglyoxal in anaerobically grown Escherichia coli and its detoxification by expression of the Pseudomonas putida glyoxalase I gene.

Anaerobic glycerol fermentation by Escherichia coli strains expressing genes from the Klebsiella pneumoniae dha regulon showed that cell growth and 1,3-propanediol (1,3-PD) production are significantly inhibited when 5 g/L or higher of glycerol is initially present. One reason for this inhibition may be methylglyoxal (MG) accumulation. Assays of both intracellular and extracellular MG levels indicated an accumulation of MG in anaerobic glycerol fermentation of transgenic E. coli. Pseudomonas putida glyoxalase I was expressed in the transgenic E. coli to enhance MG detoxification. The activity of glyoxalase I in the transgenic E. coli with the P. putida glyoxalase I under anaerobic conditions was 12-fold higher than that in the control cells. Compared to the control cells, the transgenic cells with the P. putida glyoxalase I displayed a reduction of 35-43% in intracellular MG and a decrease of 30% in extracellular MG. These decreases were statistically significant (P>94). Furthermore, the expression of the P. putida glyoxalase I in the transgenic E. coli markedly improved cell growth and resulted in a 50% increase in 1,3-PD production.     

Nucleotide sequence of the thermostable direct hemolysin gene of Vibrio parahaemolyticus.

The gene encoding the thermostable direct hemolysin of Vibrio parahaemolyticus was characterized. This gene (designated tdh) was subcloned into pBR322 in Escherichia coli, and the functional tdh gene was localized to a 1.3-kilobase HindIII fragment. This fragment was sequenced, and the structural gene was found to encode a mature protein of 165 amino acid residues. The mature protein sequence was preceded by a putative signal peptide sequence of 24 amino acids. A putative tdh promoter, determined by its similarity to concensus sequences, was not functional in E. coli. However, a promoter that was functional in E. coli was shown to exist further upstream by use of a promoter probe plasmid. A 5.7-kilobase SalI fragment containing the structural gene and both potential promoters was cloned into a broad-host-range plasmid and mobilized into a Kanagawa phenomenon-negative V. parahaemolyticus strain. In contrast to E. coli, where the hemolysin was detected only in cell lysates, introduction of the cloned gene into V. parahaemolyticus resulted in the production of extracellular hemolysin.