Cloning and characterization of Escherichia coli K-12 regulator gene tyrR.

The Escherichia coli K-12 regulator gene tyrR was cloned into the multicopy plasmid pBR322 from a lambda(Tn10)tyrR+ specialized transducing phage. Further subcloning localized the gene within a 2.1-kilobase region. Analysis of plasmid-coded proteins showed that the tyrR gene codes for a 63,000-dalton polypeptide.     

A new filamentous phage cloning vector: fd-tet

We have constructed a hybrid chromosome composed of the genome of wild-type fd (a filamentous, male-specific bacteriophage) and a segment of transposon Tn10 coding for tetracycline resistance but not including the Tn10 insertion sequences. The hybrid phage infects male E. coli, thereby transducing the infected cells to tetracycline resistance. The phage DNA can also be propagated in F- cells after transfection. This new phage, fd-tet, may be used as a cloning vector to produce large quantities of cloned DNA in single-stranded form. Its usefulness has been demonstrated by cloning of a fragment from bacteriophage lambda. Some unexpected sequence alterations have been identified in lambda cloning experiments.     

In vitro transposition of transposon Tn3

Transposition of the ampicillin-resistant transposon Tn3 was reproduced in vitro using the Escherichia coli cell extract. In this cell-free system, we used plasmid DNA carrying mini-Tn3 as donor and phage lambda DNA as target and assayed for ampicillin-resistance transducing phages formed by cointegration of these DNA molecules. Ampicillin-resistance transducing phages, which were obtained by in vitro packaging of lambda DNA after the in vitro transposition reaction, were formed only in the presence of Tn3 transposase. The reaction required mini-Tn3 with the proper sequence and orientation of the terminal inverted repeats of Tn3. The reaction also required DNA synthesis but not RNA synthesis by E. coli RNA polymerase.     

Chi Mutation in a Transposon and the Orientation-Dependence of Chi Phenotype

Chi, an element that stimulates recombination via the E. coli RecBC pathway, can arise by spontaneous mutation in the transposon Tn5. When in phage lambda in one orientation, the mutant transposon confers Chi+ phenotype (large plaque and a high rate of exchange near the transposon). In the other orientation, however, the transposon does not confer Chi+ phenotype. The mobility of the transposon allows us to show that the Chi+ orientation of the mutant Tn5 is the same at different locations in lambda. These include a site near gene J, one in gam at 69, one to the right of gam at 73 and several to the right of R between 95.7 and 99.5. To the right of R, the mutant transposon could be found in only one orientation, that which confers Chi+ phenotype. We speculate that the other orientation of Tn5 in that locale is lethal to lambda. The orientation-dependence of Chi+ phenotype also revealed that Tn5 flip-flops in lambda.     

Insertional mutagenesis of the lon gene in Escherichia coli: lon is dispensable.

The lon gene of Escherichia coli codes for an ATP-dependent protease. Mutations in lon cause a defect in the intracellular degradation of abnormal and mutant proteins and lead to a number of phenotypic changes, such as UV sensitivity and overproduction of capsular polysaccharide. We have isolated lambda transducing phage carrying the lon gene and used the lon phage as a target for insertional mutagenesis by a defective transposon Tn10 to produce lon::delta 16 delta 17Tn10 derivatives. The delta 16 delta 17Tn10 (hereafter called delta Tn10) elements were inserted at sites throughout the lon gene and disrupted the coding region between 15 and 75% of the distance from the amino-terminal end. Radioactive labeling of proteins in vivo in cells infected with different lambda lon::delta Tn10 phage demonstrated that the insertions resulted in the synthesis of truncated Lon proteins. The lon::delta Tn10 mutations, when crossed from the phage into the bacterial chromosome, abolished the synthesis of intact Lon protein, as assayed by antibody on Western blots. An analysis of the protein-degradative ability of lon::delta Tn10 cells suggests that although the insertions in lon caused a reduction in ATP-dependent protein degradation, they did not completely eliminate such degradation either in vivo or in vitro. The lon::delta Tn10 mutations and a lon deletion retaining only the amino-terminal 25% of the gene did not affect the energy-dependent degradation of proteins during starvation and led to only a 40 to 60% reduction in the ATP-dependent degradation of canavanine-containing proteins and puromycyl peptides. Our data provide clear evidence that energy-dependent proteolytic enzymes other than Lon exist in E. coli.     

The transposable element Tn3 promotes general recombination at the neighboring regions

Transposon Tn3 was inserted into a tRNA operon of the amber suppressor Su+2 on a transducing phage (lambda hcI857nin5pSu+2) by selecting phages with ampicillin resistance and Su- phenotypes. In a strain thus obtained, Tn3 was inserted between the promoter and the first tRNA gene of the operon, which was determined by DNA sequencing. The Su+2 tRNA operon on the transducing phage consisted of two tRNA genes for tRNA(Met) and Su+2 tRNA(2Gln), which was a deletion derivative of the supB-E tRNA operon of E. coli containing seven tRNA genes in the order of promoter-Met-Leu-Gln1-Gln1-Met-Gln2-Gln2. Proliferating the lambda hcI857nin5pSu+2::Tn3 in E. coli cells, a number of phages which had lost Tn3 were isolated, and their tRNA gene compositions as well as the DNA structures of the tRNA operon were analyzed. In many cases the tRNA genes which had been deleted from the original transducing phage were regained from the chromosomal supB-E operon. Thus the loss of Tn3 from the phages was not due to excision of the transposon but due to the replacement of a portion of the tRNA operon, including Tn3, with the host homologous region that did not contain Tn3. This type of replacement takes place rather efficiently as a consequence of Tn3 insertion, owing to the general recombination occurring between homologous tRNA genes of phage and host chromosomes in the presence of either host recA or phage red. No such enhanced recombination in a similar cross between phage and host chromosomes was observed with the Tn3 present in the trans position on an independent plasmid. We conclude that inserting Tn3 in cis promotes general recombination in the neighboring regions. Possible mechanisms for this new type of genetic effect of Tn3 are discussed. During the course of this study, a natural defective mutation (T11) was also detected in one of the duplicated tRNA(2Gln) genes in an E. coli K12 strain we used.     

Identification of citrate utilization transposon Tn3411 from a naturally occurring citrate utilization plasmid.

We have isolated a new transposon, Tn3411, encoding citrate-utilizing ability, from a naturally occurring citrate utilization (Cit) plasmid, pOH3001. Citrate transposon Tn3411 was transposed from pOH3001 to lambda b519 b515 cI857 S7 (abbreviated lambda bb) phage, and further from the resulting lambda bb:Tn3411 to a vector plasmid, pBR322, in recA-deficient strains. The Cit+ plasmids (pOH2 and pOH3) constructed by the integration of Tn3411 into pBR322 were examined by restriction endonuclease and heteroduplex analysis. The results obtained were as follows: (i) Tn3411 was 7.4 kilobases long and flanked by small inverted repeats, and it contained one more pair of inverted repeats at the opposite orientation in the internal region, thus making alternate repeats; and (ii) the Cit+ structure gene was located on the fragment (5.5 kilobases) between two SalI cleavage sites on Tn3411.     

Increase in Transduction Efficiency of Tn551 Mediated by the Methicillin Resistance Marker

The transduction efficiency of Tn551, a staphylococcal transposon coding for erythromycin resistance (ermB), was increased by a factor of about five in acceptor strains carrying the gene for methicillin resistance (mec), as compared with methicillin-sensitive strains. This enhancement was independent of the generalized transducing phage used and of the chromosomal insertion site of the Tn551 transposon.     

Location of ribosome-binding sites on the tetracycline resistance transposon Tn10.

Eight ribosome-binding sites were located on the single-stranded Tn10 DNA loop which was formed after denaturation of lambda phage DNA containing the Tn10 transposon sequence. Ribosomes were bound only to the Tn10 loop contained on the R strand of lambda DNA but not to that on the L strand, suggesting that one of the two strands of Tn10 DNA is selectively transcribed. Six of the eight ribosome binding sites were located in one-half of the DNA loop. The maximum sizes of potential polypeptides were calculated for these genes to range between 9,500 and 84,000 daltons.     

Regulation of glutamine synthetase formation in Escherichia coli: characterization of mutants lacking the uridylyltransferase.

A lambda phage (lambdaNK55) carrying the translocatable element Tn10, conferring tetracycline resistance (Tetr), has been utilized to isolate glutamine auxotrophs of Escherichia coli K-12. Such strains lack uridylyltransferase as a result of an insertion of the TN10 element in the glnD gene. The glnD::Tn10 insertion has been mapped at min 4 on the E. coli chromosome and 98% contransducible by phage P1 with dapD. A lambda transducing phage carrying the glnD gene has been identified. A glnD::Tn10 strain synthesizes highly adenylylated glutamine synthetase under all conditions of growth and fails to accumulate high levels of glutamine synthetase in response to nitrogen limitation. However, this strain, under nitrogen-limiting conditions, allows synthesis of 10 to 20 milliunits of biosynthetically active glutamine synthetase per mg of protein, which is sufficient to allow slow growth in the absence of glutamine. The GlnD phenotype in E. coli can be suppressed by the presence of mutations which increase the quantity of biosynthetically active glutamine synthetase.     

Convenient construction of strains useful for transducing recA mutations with bacteriophage P1

Abstract The generalized transducing phage P1 grew well on heterozygous Escherichia coli carrying recA srlC 300::Tn 10 on the chromosome and recA ⁺ on a pBR322-derived plasmid. Because of the close linkage of Tn 10 to recA mutations, including recA 1, recA 13, recA 56, recA deletion and recA allele of E. coli BNG30, the latter can be moved to other strains in transductional crosses for selective resistance to tetracycline.     

Properties of transposon Tn2555 carrying the genes for sucrose utilization

Tn2555, a new transposon coding for genes of sucrose utilization was studied. Tn2555 was shown to integrate into the plasmids RP4 and R6K, phage P1CmClr100 and Escherichia coli K12 chromosome. Tn2555 frequency of transposition to RP4 and R6K DNA is (2-5) X 10(-7) in Rec+-strain, (3-6) X 10(-8) in Rec--strain. Tn2555 integration site in phage P1CmClr100 Sac+-derivative studied has been localised within the C-segment of P1 DNA. In three independent cases of Tn2555 transposition to the chromosome the transposon was found to be integrated in the region between 29 and 32 min of Escherichia coli K12 linkage map. The restriction endonuclease analysis of seven independent isolates of RP4::Tn2555 has shown the grouping of Tn2555 integration sites in the Tn1 region of RP4. Frequent rearrangements occurring within Tn2555 have been revealed by the analysis. However, an invertible DNA segment of about 6-7 kb was preserved in all transposon structures.     

Artificial Tn2551 transposon with replicative properties

A hybrid plasmid, pBE10 was constructed. It consists of DNAs of RSF2124 (ColE1 :: Tn3) plasmid and pUB110 plasmid of Staphylococcus aureus. The latter can be stably maintained in Bacillus subtilis. BamHI cleaved pUB110 was introduced into the BamHI site of transposon Tn3 and the resulting enlarged Tn3 (Tn2551) was transposed from pBE10 onto phage lambda and than to pMB9 (Tc) and RSF1010(Sm Su) plasmids. Restriction and heteroduplex analysis of pMB9 :: Tn2551(pBE21) and RSF1010 :: :: TN2551(pBE32) was carried out. Plasmids pBE10, pBE21 and pBE32 demonstrated some kind of molecular instability when introduced by transformation into Bacillus subtilis.     

Cloning of aroG, the gene coding for phospho-2-keto-3-deoxy-heptonate aldolase(phe), in Escherichia coli K-12, and subcloning of the aroG promoter and operator in a promoter-detecting plasmid

Defective transducing phages carrying aroG, the structural gene for phenylalanine (phe)-inhibitable phospho-2-keto-heptonate aldolase (EC 4.1.2.15; previously known as 3-deoxy-D-arabinoheptulosonate-7-phosphate synthetase[phe]), have been isolated, and DNA from two of these phages has been used to construct a restriction map of the region from att lambda to aroG. A 7.6-kb PstI-HindIII fragment from one of these phages was cloned into pBR322 and shown to contain aroG. The location of aroG within the 7.6 kb was established by subcloning and Tn3 transpositional mutagenesis. A fragment carrying the aroG promoter and operator has been cloned into a high copy number promoter-cloning vector (pMC489), and the resulting aroGpo-LacZ' (alpha) fusion subcloned in a low copy number vector. Strains with this fusion on the low copy number vector exhibit negative regulation of beta-galactosidase expression by both phenylalanine and tryptophan and positive regulation by tyrosine in a tyrR+ background.     

Transposition of a DNA sequence determining kanamycin resistance into the single-stranded genome of bacteriophage fd

Summary Derivatives of bacteriophages fd which transduce kanamycin resistance were selected after growth of the phage in an E. coli strain that carried transposon 5 (Tn5). Different clones of transducing phage and their DNAs were characterized by gel electrophoresis, electron microscopy, and by their ability to multiply in the absence of helper phage. Integration of the intact transposon into the full size phage genome was correlated with an increase in size of the phage particle from 0.95 to 1.7 , and with the appearance in the phage DNA of the stem loop structure characteristic for single-stranded Tn5 DNA. In nondefective phages the site of insertion was mapped by heteroduplex analysis within the intergenic region of the phage genome. Defective transducing phages were characterized as an insertion of Tn5 into a phage gene, and/or as a partial deletion or duplication of phage and transposon DNA. The size of the transducting phage from different defective clones varied from 0.6 to 3.0 and was directly proportional to the DNA content. These results demonstrate that filamentous bacteriophage are highly capable to replicate and package very different amounts of foreign DNA.This work was presented at the EMBO Workshop on single-stranded DNA viruses, October 1976, Harpert, The Netherlands