Exchange of chromosomal and plasmid alleles in Escherichia coli by selection for loss of a dominant antibiotic sensitivity marker.

Transfer of an allele from a donor DNA to a recipient DNA molecule was selected by the loss of a dominant conditional lethal mutation previously incorporated ito the gene of interest in the recipient DNA. Both the Escherichia coli chromosome and plasmids carrying E. coli genes were used successfully as donor molecules. Recipient molecules for these exchanges were constructed in vitro by using the rpsL gene, which confers sensitivity to streptomycin, to replace segments of specific E. coli genes located either on multicopy plasmids or in the E. coli chromosome. Plasmids carrying such replacements were capable of acquiring chromosomal alleles of the gene(s) of interest, and strains carrying rpsL replacements in the chromosome were capable of acquiring plasmid-encoded alleles at the sight of the rpsL replacement. In both situations, these allele transfers resulted in loss of the rpsL gene from the recipient DNA molecule. The desired transfer events constituted a large percentage of these events, which gave rise to viable colonies when appropriate donor-recipient pairs were subjected to streptomycin selection. Thus, this is a useful approach for transferring alleles of interest from plasmids to the E. coli chromosome and vice versa.     

Genetic system for reversible integration of DNA constructs and lacZ gene fusions into the Escherichia coli chromosome

A plasmid system for site-specific integration into and excision and recovery of gene constructs and lacZ gene fusions from the Escherichia coli chromosome was developed. Plasmid suicide vectors utilizing the origin of replication of R6K plasmids and containing the attP sequence of bacteriophage lambda, multiple cloning site, and antibiotic resistance markers facilitate reversible integration into the E. coli chromosome by site-specific recombination. Additional vectors permit construction of lacZ gene fusions in three possible reading frames for recombination with the bacterial chromosome. These suicide vectors can be propagated in newly constructed E. coli strains that harbor different pir alleles. Two helper plasmids that encode the necessary gene products for integration (Int) and excision (Int and Xis) were also constructed. This plasmid system was shown to be a reliable and efficient means to integrate and subsequently recover plasmids from the E. coli attB site.     

利用Red重组工程技术解决外源基因在大肠杆菌染色体lac操纵子中的表达

为了应用Red重组工程技术实现外源基因在大肠杆菌染色体上的表达, 寻找染色体上外源蛋白的稳定高效表达位点, 使用Red重组工程系统和kan/sacB无痕迹修饰技术, 将易于定量分析的荧光素酶报告基因替换DY330染色体lac操纵子中的lacZ基因。检测该位点的表达效率结果显示: 大肠杆菌染色体上lac操纵子能够高效稳定表达外源基因, 初步证明了染色体可以作为外源蛋白或抗原的表达载体, 不会影响细菌的生长繁殖。     

利用Red重组工程技术解决外源基因在大肠杆菌染色体lac操纵子中的表达

为了应用Red重组工程技术实现外源基因在大肠杆菌染色体上的表达, 寻找染色体上外源蛋白的稳定高效表达位点, 使用Red重组工程系统和kan/sacB无痕迹修饰技术, 将易于定量分析的荧光素酶报告基因替换DY330染色体lac操纵子中的lacZ基因。检测该位点的表达效率结果显示: 大肠杆菌染色体上lac操纵子能够高效稳定表达外源基因, 初步证明了染色体可以作为外源蛋白或抗原的表达载体, 不会影响细菌的生长繁殖。     

Location of a gene (ssrA) for a small, stable RNA (10Sa RNA) in the Escherichia coli chromosome.

The gene for 10Sa RNA, which is a major small, stable RNA in Escherichia coli, is a unique gene in the E. coli chromosome. The 10Sa RNA gene (ssrA) has been located between 2,760 and 2,761 kilobases on the E. coli genome.     

Mapping of trxB, a mutation responsible for reduced thioredoxin reductase activity.

The mutation (trxB) responsible for reduced thioredoxin reductase activity has been mapped on the Escherichia coli K-12 chromosome clockwise from aroA between 20 and 21 min. The gene order in this region of the E. coli chromosome was found to probably be serC-aroA-trxB. The location of gshA, the structural gene for gamma-glutamylcystein synthetase, relative to srl and recA also was determined.     

The TGV transgenic vectors for single-copy gene expression from the Escherichia coli chromosome

Plasmid-based cloning and expression of genes in Escherichia coli can have several problems: plasmid destabilization; toxicity of gene products; inability to achieve complete repression of gene expression; non-physiological overexpression of the cloned gene; titration of regulatory proteins; and the requirement for antibiotic selection. We describe a simple system for cloning and expression of genes in single copy in the E. coli chromosome, using a non-antibiotic selection for transgene insertion. The transgene is inserted into a vector containing homology to the chromosomal region flanking the attachment site for phage lambda. This vector is then linearized and introduced into a recombination-proficient E. coli strain carrying a temperature-sensitive lambda prophage. Selection for replacement of the prophage with the transgene is performed at high temperature. Once in the chromosome, transgenes can be moved into other lysogenic E. coli strains using standard phage-mediated transduction techniques, selecting against a resident prophage. Additional vector constructs provide an arabinose-inducible promoter (P(BAD)), P(BAD) plus a translation-initiation sequence, and optional chloramphenicol-, tetracycline-, or kanamycin-resistance cassettes. These Transgenic E. coli Vectors (TGV) allow drug-free, single-copy expression of genes from the E. coli chromosome, and are useful for genetic studies of gene function.     

Amplification of a novel gene, sanA, abolishes a vancomycin-sensitive defect in Escherichia coli.

We have isolated an Escherichia coli gene which, when overexpressed, is able to complement the permeability defects of a vancomycin-susceptible mutant. This gene, designated sanA, is located at min 47 of the E. coli chromosome and codes for a 20-kDa protein with a highly hydrophobic amino-terminal segment. A strain carrying a null mutation of the sanA gene, transferred to the E. coli chromosome by homologous recombination, is perfectly viable, but after two generations at high temperature (43 degrees C), the barrier function of its envelope towards vancomycin is defective.     

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.     

Genetic analysis of sacB, the structural gene of a secreted enzyme, levansucrase of Bacillus subtilis Marburg

The structural gene sacB encoding B. subtilis levansucrase, a secreted enzyme, expresses in E. coli. E. coli hosts of the sacB gene are poisoned by sucrose. This property allowed a powerful selection of mutants affected in the cloned gene. The plasmidic mutations were readily introduced in the B. subtilis chromosome. Using a collection of plasmids bearing various deletions extending in sacB we developed a technique of deletion mapping based on plasmid integration in the chromosome of B. subtilis. A generalization of this technique is discussed.     

Site-directed mutagenesis of the Escherichia coli chromosome near oriC: identification and characterization of asnC, a regulatory element in E. coli asparagine metabolism

We developed a new method for the specific mutagenization of the E. coli chromosome. This method takes advantage of the fact that a pBR322 plasmid containing chromosomal sequences is mobilizable during an Hfr-mediated conjugational transfer, due to an homologous recombination between the E. coli Hfr chromosome and the pBR322 derivative. Transconjugants are screened with a simple selection procedure for integration of mutant sequences in the chromosome and loss of pBR322 sequences. Using this method we specifically inactivated several genes near the E. coli replication origin oriC. We found that a gene coding for asparagine synthetase A. This regulatory mechanism was investigated in detail by determining in vivo regulation of asnA promoter activity by the 17kD protein under different growth conditions. Results obtained also suggest a general regulatory role of the 17kD protein in E. coli asparagine metabolism. Therefore the 17kD gene is proposed to be renamed asnC.     

Biochemical and genetic analysis of Salmonella typhimurium and Escherichia coli mutants defective in specific incorporation of selenium into formate dehydrogenase and tRNAs

Mutation of a single gene, referred to as selA1 in Salmonella typhimurium and as selD in Escherichia coli, results in the inability of these organisms to insert selenium specifically into the selenopolypeptides of formate dehydrogenase and into the 2-selenouridine residues of tRNAs. The mutation does not involve transport of selenite into the cell or reduction of selenite to selenide since both mutant strains synthesize selenocysteine and selenomethionine from added selenite and incorporate these selenoamino acids non-specifically into numerous proteins of the bacterial cells. Complementation of the mutation in S. typhimurium with the selD gene from E. coli indicates functional identity of the selA1 and selD genes. Although the selA1 gene maps at approximately 21 min on the S. typhimurium chromosome and the selD gene at approximately 38 min on the E. coli chromosome, only a single gene in wild-type S. typhimurium hybridized to the E. coli selD gene probe. Transformation of the mutant Salmonella strain with a plasmid bearing the E. coli selD gene restored formate dehydrogenase activity, 75Se incorporation into formate dehydrogenase seleno-polypeptides and [75Se]seleno-tRNA synthesis. Transformation with an additional plasmid carrying an E. coli formate dehydrogenase selenopolypeptide-lacZ gene fusion showed that the selD gene allowed readthrough of the UGA codon and synthesis of beta-galactosidase in the Salmonella mutant.     

Adsorptive capacity of bacteriophage Mu on Escherichia coli K-12 strains with deletions in the attlambda region]

Escherichia coli strains with deletions in att lambda region were obtained. The comparison of the extent of deletions with the sensitivity of the corresponding mutant clones to phage Mu showed that the gene controlling the sensitivity of E. coli K-12 to the phage Mu is located in nad A-gal region of the bacterial chromosome. It is shown that the resistance of E. coli strains which had lost the region of bacterial chromosome between nad A gene and genes of gal-operon have adsorption character. Deletion of the nad A-gal region does not affect the adsorption of other phages (lambda, P1 and T4). Thus, the gene, located in this region, is responsible for the specific adsorption of the phage Mu.     

Recombination-promoting activity of the bacteriophage lambda Rap protein in Escherichia coli K-12

The rap gene of bacteriophage lambda was placed in the chromosome of an Escherichia coli K-12 strain in which the recBCD gene cluster had previously been replaced by the lambda red genes and in which the recG gene had been deleted. Recombination between linear double-stranded DNA molecules and the chromosome was tested in variants of the recGDelta red(+) rap(+) strain bearing mutations in genes known to affect recombination in other cellular pathways. The linear DNA was a 4-kb fragment containing the cat gene, with flanking lac sequences, released from an infecting phage chromosome by restriction enzyme cleavage in the cell. Replacement of wild-type lacZ with lacZ::cat was monitored by measuring the production of Lac-deficient chloramphenicol-resistant bacterial progeny. The results of these experiments indicated that the lambda rap gene could functionally substitute for the E. coli ruvC gene in Red-mediated recombination.     

Engineering large fragment insertions into the chromosome of Escherichia coli

An effective DNA replacement system has been established for engineering large fragment insertions into the chromosome of Escherichia coli. The DNA replacement plasmid, pHybrid I, was first constructed based on the bacterial artificial chromosome (BAC) vector. Two fragments of the E. coli genome, 5.5 and 6.5 kb in length, were introduced into the vector for homologous recombination. In addition to the chloramphenicol gene, a second gene neo was introduced for double marker screening for recombinant clones. By shot-gun cloning and homologous recombination techniques, using our new recombinant vector (pHybrid I), a 20-kb fragment from Lactococcus lactis genomic DNA has been successfully integrated into the chromosome of the E. coli strain J93-140. Plating tests and PCR amplification indicated that the integration remained stable after many generations in cell culture. This system will be especially useful for the chromosome engineering of large heterologous fragment insertions, which is necessary for pathway engineering.     

The great GATC: DNA methylation in E. coli

In Escherichia coli the methylation of the adenine in the sequence 5'-GATC-3' is catalysed by the dam gene product, a DNA adenine methylase. We review the proposed roles for this methylation, and the sequence it modifies, in mismatch repair, DNA-protein interaction, gene expression, the initiation of chromosome replication, chromosome segregation, chromosome structure and the occurrence of mutational hotspots.     

Mapping of the gene for cytidine deaminase (cdd) in Escherichia coli K-12

The structural gene encoding cytidine deaminase (cdd) has been mapped in Escherichia coli K-12. It is located counterclockwise to ptsF between 46 and 47 min. The gene order in this region of the E. coli chromosome was found to be his-udk-gat-dld-cdd-ptsF.     

Genetic control of glutamine synthetase in Klebiella aerogenes.

Mutations at two sites, glnA and glnB, of the Klebsiella aerogenes chromosome result in the loss of glutamine synthetase. The locations of these sites on the chromosome were established by complementation by episomes of Escherichia coli and by determination of their linkage to other genetic sites by transduction with phage P1. The glnB gene is located at a position corresponding to 48 min on the Taylor map of the E. coli chromosome; it is linked to tryA, nadB, and GUA. The glnA gene is at a position corresponding to 77 min on the Taylor map and is linked to rha and metB; it is also closely linked to rbs, located in E. coli at 74 min, indicating a difference in this chromosomal region between E. coli and K. aerogenes. Mutations in the glnA site can also lead to nonrepressible synthesis of active glutamine synthetase. The examination of the fine genetic structure of glnA revealed that one such mutation is located between two mutations leading to the loss of enzymatic activity. This result, together with evidence that the structural gene for glutamine synthetase is at glnA, suggests that glutamine synthetase controls expression of its own structural gene by repression.