Heterogeneity in the level of ampicillin resistance conferred by pBR322 derivatives with different DNA supercoiling

Summary Cloning of an EcoRI restriction fragment, containing the 900 bp -terminal sequence of transposon Tn1000, into pBR322, resulted in two plasmids, pICV63 and pICV64, which differed in the orientation of the cloned fragment within the replicon and in the level of ampicillin resistance conferred on the host cell. The DNAs of these plasmids differ in superhelicity and we suggest that a change in supercoiling of pICV63 DNA leads to this plasmid conferring resistance to only low levels of ampicillin, probably by reducing the expression of the bla gene. This hypothesis is supported by the fact that topA or supX mutations, which abolish topoisomerase I, reduce still further the level of resistance to ampicillin of pICV63-containing cells, whereas the gyrB226 compensatory mutation renders these cells more ampicillin resistant. Plasmid pICV63, therefore, enables mutant alleles of genes governing DNA topology to be recognized.     

Genetic manipulations in Rhizobium meliloti utilizing two new transposon Tn5 derivatives

Summary Two derivatives of the prokaryotic transposon Tn5 were constructed in vitro. In Tn5-233, the central area of Tn5, which carries resistance to kanamycin/neomycin, bleomycin and streptomycin, is replaced by a fragment carrying resistance to the aminocyclitol antibiotics gentamycin/kanamycin and streptomycin/spectinomycin. In Tn5-235, the Escherichia coli -galactosidase gene is inserted within the streptomycin resistance gene of Tn5, and constitutively expressed from a Tn5 promoter. Both constructs transpose with about the same frequency as Tn5 in Escherichia coli and Rhizobium meliloti. When a Tn5-derivative is introduced into an R. meliloti strain which already contains a different Tn5-derivative, in situ transposon replacement is obtained at high frequency, presumably by a pair of crossovers between the IS50 sequences at the ends of the incoming and resident transposons. In this way we converted a previously isolated recA::Tn5 mutant into the corresponding recA::Tn5-233 strain, which can now be used as a genetic background in the study of complementation of other Tn5-induced mutations. We also replaced the drug markers of several Tn5-induced exo mutants, which we were then able to map relative to each other by transduction with phage M12. In a strain carrying Tn5-235 located near Tn5-233, we were able to isolate deletions of the intervening markers, presumably resulting from general recombination between the two transposons, by screening for loss of the Lac⁺ phenotype. Unlike Tn5 itself, resident Tn5-233 does not appear to suppress transposition of another incoming Tn5-derivative.Abbreviations bp base pairs - Nm neomycin - Km kanamycin - Sm streptomycin - Sp spectinomycin - Gm gentamycin - Tc tetracycline - Tp trimethoprim - Ot oxytetracycline - Rf rifampicin - Xgal 5-bromo-4-chloro-3-indolyl--d-galactoside     

The initiation of chromosome replication in a dnaAts46 and a dnaA+ strain at various temperatures

Summary The regulation of chromosome replication initiation was studied at various temperatures with an E. coli dnaA46 strain and its dnaA ⁺ parent. We find that, in both strains, the initiation mass varies depending upon growth temperature while the replication time remains constant relative to the cell doubling time. In the permissive temperature range, the initiation mass of the dnaA46 mutant strain is larger by a constant factor than that for a dnaA ⁺ strain. We conclude that, even at temperatures permissive for growth of the dnaA46 strain, the activity of the dnaA46 product is lower than that of the wild-type protein. The dnaA gene product, therefore, plays an important role in regulating initiation.     

Function of ribonuclease H in initiation of DNA replication in Escherichia coli K-12

Summary Escherichia coli rnh mutants lacking ribonuclease H (RNase H) activity can tolerate deletion of the origin of DNA Replication (oriC) and transposon-insertional inactivation of an initiator gene (dnaA:Tn10). Introduction of the recA200 allele encoding a thermolabile RecA protein intornh ^– dnaA: Tn10 and rnh ^– oriC mutants strains rendered DNA synthesis and colony formation of these mutants temperature sensitive. The temperature sensitivity and the broth sensitivity (Srm^–) of the rnh ^– dnaA: Tn10 recA200 strain was suppressed by the presenceof plasmids (pBR322 derivatives) carrying dnaA ⁺only when the intact oriC site was present on the chromosome. Lack of RNase H activity neither promoted replication of minichromosomes (pOC24 and pasn20) in the absence of required DnaA⁺ protein nor inhibited dnaA ⁺–dependent minichromosome replication. These results led to the conclusion that RNase H is not directly involved in the events leading to initiation of DNA replication at oriC. Rather, it functions as a specificity factor by eliminating certain forms of RNA-DNA hybrids which could otherwise be used to prime DNA replication at sites other than oriC.     

Characterization of the dnaA, gyrB and other genes in the dnaA region of the Escherichia coli chromosome on specialized transducing phages lambda tna.

Summary Specialized transducing phages tna (tryptophanase) harboring chromosomal DNA and genetic markers from the dnaA region of the Escherichia coli chromosome were isolated. Transductional analysis showed that some of these tnaA transducing phages carry two genes important in DNA replication, namely the dnaA gene (initiation of chromosome replication) and the gyrB gene (subunit B of DNA gyrase), formerly designated cou ^R. The following clockwise order of genetic markers was found: uhp, gyrB, dnaA, rimA, tnaA, bglB.The gene-protein relationship was established by the determination of the gene products encoded on the chromosomal DNA of the different tna. A 54 kD and a 91 kD polypeptide appear to be coded for by the dnaA and gyrB genes, respectively; the 91 kD protein is encoded on a region in which coumermycin sensitivity maps and is with respect to electrophoretic behavior identical to subunit B of DNA gyrase. The 54 kD protein is encoded on the region in which different independently isolated dnaA(Ts) mutations (dnaA5, dnaA46, dnaA167, dnaA203, dnaA204, dnaA205, dnaA211, dnaA508) are located. Additional genes which code for polypeptides with hitherto unknown functions were identified and mapped. The acriflavin sensitivity mutation acrB1 was found to be an allele of the gyrB gene (see Note Added in Proof).     

Analysis of the reduction in expression of tetracycline resistance determined by transposon Tn10 in the multicopy state

The tet genes of transposon Tn10 have been mapped in a 2,200 bp DNA sequence by analysing deletion and Tn5 insertion mutations. When the tet genes were present on multi-copy plasmids the level of resistance expressed was about ten-fold lower than that determined by a single copy of Tn10 in the E. coli chromosome. The 36K tet protein known to be encoded by R100 in E. coli minicells was not detected when they harboured a multicopy tet plasmid. However, normal high levels of resistance were expressed when the tet genes were recombined into the host chromosome as part of a lambda lysogen, showing that the multicopy effect was phenotypic. Most of the Tn5 insertions and deletions in tet which caused Tc^s mutations also prevented expression of high level Tc^r from a chromosomal Tn10 element present in the same cell. Only those insertions in the promoter-proximal 90–130 bp of a 1,275 bp HindII fragment known to carry the gene encoding the 36K tet protein did not reduce the single copy Tn10 resistance level.A gene fusion system that results in the constitutive synthesis of -galactosidase from a tet promoter has been used to assay tet repressor activity. The basal (uninduced) -galactosidase level in cells carrying multicopy tet plasmids was 10–20 fold lower than those carrying a single copy. The tet:: Tn5 mutants defective in the trans-dominant multicopy effect still made normal amounts of tet repressor showing that repressor overproduction was not responsible for this effect. In addition a repressor-defective constitutive mutant did not exhibit a higher resistance level when located on a multicopy plasmid vector. We postulate that a regulatory mechanism recognises the amino-terminus of the tet structural gene product when attempts are being made to overproduce the protein and prevents further translation.     

Transposition of a DNA fragment flanked by two inverted Tn1 sequences

The 32 Md fragment (derived from plasmid RP4::Tn1) carrying the Km^r gene and flanked by two inverted Tn1 elements is capable of recA-independent translocation to other plasmids. We designated this new transposon Tn1755. In various crosses, frequencies of Tn1755 transposition to plasmids Co1B-R3, R15 and F′ColVBtrp varied from 2.5 to 90% of the frequencies of Tn1 transposition. Tn1755 can integrate into various sites of the recipient plasmids. We failed to observe transposition of another RP4::Tn1 fragment flanked by two opposingly oriented Tn1 transposons and harboring the Tc^r gene. Presumably, to form a new transposable structure, other features must also be of importance.     

Initiation of chromosomal DNA replication which is stimulated without oversupply of DnaA protein in Escherichia coli

Summary The temperature-sensitive dnaA46 mutation in Escherichia coli can be phenotypically suppressed at 42° C by oversupply of GroELS proteins, and the suppressed cells grow extremely slowly at 30° C. We found that the phenotype of dnaA46 showing this cold sensitivity was dominant over the phenotype of dnaA ⁺, and could not be rescued by introduction of oriC-independent replication systems. These results suggest that the cold sensitivity was not caused by a simple defect in replication. When a growing culture of a dnaA46 strain with a GroELS-overproducing plasmid was shifted from 42° to 30° C in the presence of chloramphenicol, the chromosomal DNA replicated excessively. Initiation of replication occurred at the site of oriC repeatedly four or five times during a 4 h incubation period without concomitant protein synthesis, indicating an excessive capacity for initiation. Such overreplication did not take place at 42° C in the suppressed dnaA46 strain, or at either temperature in GroELS-oversupplied dnaA ⁺ cells. No significant difference was detected between the cellular content of DnaA protein in suppressed cells where the initiation capacity was abnormally high, and that in wild-type cells in which the initiation capacity was normal. Thus, DnaA protein might function in vivo through some phase control mechanism for initiation, apart from a simple regulation by its total amount. A possible mechanism is proposed based on the participation of GroELS proteins in protein folding.A preliminary account of this work was presented at the Annual Meeting of the Molecular Biology Society of Japan in 1989.     

Construction of a Tn5 derivative encoding bioluminescence and its introduction in Pseudomonas, Agrobacterium and Rhizobium

Summary A simple method based upon the use of a Tn5 derivative, Tn5-Lux, has been devised for the introduction and stable expression of the character of bioluminescence in a variety of gram-negative bacteria. In Tn5-Lux, the luxAB genes of Vibrio harveyi encoding luciferase are inserted on a SalI-BglII fragment between the kanamycin resistance (Km^r) gene and the right insertion sequence. The transposon derivative was placed on a transposition suicide vehicle by in situ recombination with the Tn5 suicide vector pGS9, to yield pDB30. Mating between Escherichia coli WA803 (pDB30) and a strain from our laboratory, Pseudomonas sp. RB100C, gave a Km^r transfer frequency of 10^-6 per recipient, a value 10 times lower than that obtained with the original suicide vehicle pGS9. Tn5-Lux was also introduced by insertion mutagenesis in other strains of gram-negative soil bacteria. The bioluminescence marker was expressed in the presence of n-decanal, and was monitored as chemiluminescence in a liquid scintillation counter. The recorded light intensities were fairly comparable among the strains, and ranged between 0.2 to 1.8x10⁶ cpm for a cell density of 10³ colony forming units/ml. Nodules initiated by bioluminescent strains of Rhizobium leguminosarum on two different hosts were compared for intensity of the bioluminescence they produced.     

Effect of an Insertional Mutation in the cspA Gene Encoding the Major Cold-Shock Protein on Radiation Resistance of Escherichia coli

Plasmid pCspA::Km carrying a cloned mutant allele of the cspA gene for the major Escherichia coli cold-shock protein CspA with an insertion of the kanamycin resistance gene cassette from transposon Tn903 into the core region of the coding sequence causes a 2.3-fold increase in radioresistance of wild-type E. coli cells (cspA ⁺). The radiation protective effect of this plasmid is abolished or drastically reduced in mutants recA13and rpoH15defective in RecA protein and in induction of the heat-shock protein regulon, respectively. Plasmid pCspA::Km causes a 1.3-fold elevation in the resistance to -irradiation of E. coli mutants with an intermediate level of radiation resistance (Gam^r445 and KS0160) but slightly diminishes resistance of a highly radiation-resistant Gam^r444 mutant. In the chromosome of E. coli strain with normal DNA repair systems, the cspA::Km mutation in the homozygous state enhances resistance to the lethal effect of -rays and UV light 2.9 and 1.4 times, respectively. These data suggest that the system of cold-shock proteins can modulate resistance of E. colicells to the lethal effect of -rays and UV light.     

Escherichia coli DNA Topoisomerase I and Suppression of Killing by Tn5 Transposase Overproduction: Topoisomerase I Modulates Tn5 Transposition

Tn5 transposase (Tnp) overproduction is lethal to Escherichia coli. The overproduction causes cell filamentation and abnormal chromosome segregation. Here we present three lines of evidence strongly suggesting that Tnp overproduction killing is due to titration of topoisomerase I. First, a suppressor mutation of transposase overproduction killing, stkD10, is localized in topA (the gene for topoisomerase I). The stkD10 mutant has the following characteristics: first, it has an increased abundance of topoisomerase I protein, the topoisomerase I is defective for the DNA relaxation activity, and DNA gyrase activity is reduced; second, the suppressor phenotype of a second mutation localized in rpoH, stkA14 (H. Yigit and W. S. Reznikoff, J. Bacteriol. 179:1704–1713, 1997), can be explained by an increase in topA expression; and third, overexpression of wild-type topA partially suppresses the killing. Finally, topoisomerase I was found to enhance Tn5 transposition up to 30-fold in vivo.     

Suppression of the Escherichia coli dnaA46 mutation by amplification of the groES and groEL genes

Summary A hybrid phage (Sda1), containing an 8.1 kb EcoRI DNA fragment from the Escherichia coli chromosome, was selected on the basis of its ability to suppress bacterial thermosensitivity caused by the dnaA46 mutation. We have shown that this suppression is due to a recA ⁺-dependent amplification of the 8.1 kb fragment; consistent with this observation, cloning of the 8.1 kb fragment into a high copy number plasmid (pBR325) leads also to suppression of dnaA46. In the suppressed strains growing at high temperature, bidirectional replication starts in or near the oriC region and requires the presence of the DnaA polypeptide. These findings suggest that the overproduction of a gene product(s), encoded by the cloned 8.1 kb fragment, can restore dnaA-dependent initiation of replication at high temperature in the oriC region. Genetic mapping shows that the groES (mopB) and groEL (mopA) genes are located on the 8.1 kb suppressor fragment. Further analysis, including in vitro mutagenesis and subcloning, demonstrates that the amplification of the groES and groEL genes is both necessary and sufficient to suppress the temperature sensitive phenotype of the dnaA46 mutation.     

IS8- and Tn2353-mediated cointegration of the plasmids R15 and RP4::Tn1

Summary The plasmids R15 and RP4:: Tn1 form fused structures (85 Md and 92 Md cointegrates). The cointegrates do not resolve practically in recA ^– Escherichia coli cells and have a mean life-time of more than 50 generations in a recA ⁺ background.The 85 Md cointegrates were generated at a frequency of 4×10^–4 per R15 transconjugant during a mating between E. coli [R15; RP4:: Tn1] and E. coli [FColVBtrp:: Tn1755]. These plasmids carry two directly repeated copies of the mobile element IS8 at the junctions between R15 and RP4:: Tn1. The transposition of IS8 from RP4:: Tn1 to the R15 plasmid and the formation of hybrid molecules promoted by this process appear to be induced by the IS8 element of the Tn1755 structure during or after conjugal transfer of FColVBtrp:: Tn1755 into E. coli [R15; RP4:: Tn1] cells.The formation of the 92 Md cointegrates occurs at a frequency of 2×10^–5. The fused molecules of R15 and RP4:: Tn1 carry two direct copies of an 8.65 Md R15 fragment at the junctions between these replicons. The fragment has specific features of a new transposon. This element designated Tn2353 determines resistance to Hg, Sm and Su and contains two sites for each BamHI, BglII and SalI and three sites for both EcoRI and PstI. The physical map and some other characteristics of Tn2353 are presented.Abbreviations Ap ampicillin - EtBr ethidium bromide - Km kanamycin - Md megadaltons - Sm streptomycin - Su sulfanilamide - Tc tetracycline - [] brackets indicate plasmid-carrier state     

Does Tn10 transpose via the cointegrate molecule?

Summary It has been well established that Tn3 and its relatives transpose from one replicon to another by two successive reactions: formation of the cointegrate molecule and resolution from it. Whether or not the 9300 base pair tetracycline resistance transposon Tn10 transposes in the same manner as Tn3 was investigated by two methods.In the first method, 55, a lambda phage carrying Tn10 was lysogenized in an Escherichia coli strain carrying a Tn10 insertion; the phage has a deletion in attP, hence it was lysogenized in a Tn10 sequence in the E. coli chromosome by reciprocal recombination. The chromosomal structure in these lysogens is equivalent to the Tn10-mediated cointegrate molecule of lambda and the E. coli chromosomal DNA. The stability of the cointegrate molecule was examined by measuring the rate of excision of lambda from the host chromosome, and was found to be stable, especially in a Rec^- strain. Because of this stability, the cointegrate molecule should be accumulated if Tn10 transposes via the cointegrate molecule. Then, we examined the configuration of products made by transposition of Tn10 from 55 to the E. coli chromosome. The cointegrate molecule was found in products of Tn10 transposition in a Rec⁺ strain at a frequency of 5% per Tn10 transposition, but this molecule could not be found in a Rec^- strain. Since transposition of Tn10 was recA-independent, absence of the cointegrate molecule formed in a RecA^- strain strongly suggested that the cointegrate molecule is not an obligatory intermediate of transposition of Tn10.In the second method, mobilization of pACYC177 by R388 and by R388:: Tn10 was examined. The pACYC177 plasmid was mobilized by R388::Tn10 at a frequency of 10^-4 per donor but not by R388. It occurred, in most cases, by inverse transposition of R388::Tn10 to pACYC177 forming plasmids such as pACYC177::IS10-R388-IS10. Mobilization of pACYC177 by a Tn10-mediated cointegrate in the form of pACYC177::Tn10-R388-Tn10 was not observed in crosses using a Rec^- donor. These observations also suggested that transposition of Tn10 in Rec^- cells does not occur via the cointegrate molecule.     

Reversion of a truncated gene for ampicillin resistance by genetic rearrangements in Escherichia coli K12

Summary The composite transposon Tn2672 is a derivative of the Tn3-related transposon Tn902 whose bla gene providing ampicillin resistance had been inactivated by the insertion of the IS1-flanked multiple drug resistance transposon Tn2671. Most ampicillin resistant revertants of Tn2672 are due to precise excision of Tn2671. However, a rare Bla⁺ revertant which still retains all the previously acquired drug resistance markers was isolated. On this revertant, the 5 part of the split bla gene on Tn2672 has converted to an intact, active bla gene, and the entire Tn902 is structurally restored. In contrast, the adjacent IS1b element belonging to Tn2671 has its terminal 142 base pairs deleted. Despite of this rearragement, the split 3 part of bla and its adjacent sequences have remained unchanged. Models are presented to explain the observed DNA rearrangements, and their similarity with gene conversion events is discussed.     

Characterization and properties of very large inversions of the E. coli chromosome along the origin-to-terminus axis

Summary Suppression of a dnaA46 mutation by integration of plasmid R100.1 derivatives in the termination region of chromosome replication in E. coli results in medium dependence, the suppressed bacteria being sensitive to rich medium at 42° C. Derivatives of such bacteria have been selected for growth at 42° C in rich medium and we have analyzed representatives of the most frequently observed type: bacteria displaying, once cured of the suppressor plasmid, both rich-medium sensitivity and temperature sensitivity. We found, in all cases, that the chromosome had undergone a major inversion event between two inverted IS5's. One is located at 29.2 min on the chromosome map and the other at either one of two positions between 69 and 80 min. The consequences of such inversions for cell growth are discussed. Some of them result from the fact that the replication terminator T2 is located, in inverted chromosomes, close to oriC in the orientation which allows its functioning as a terminus (de Massy et al. in press). Our observations allow an estimation of the frequency of inversions arising from recombination between pairs of inverted chromosomal IS, which could be as high as 10^-2 per cell per generation. We also found that inversion reversal occurs frequently after Hfr conjugational transfer of one of the IS5's, in its wild-type location. This led us to propose a new mechanisms of recombination, in which the incoming DNA strands serve as guides to favor recombination between the resident sequences.Abbreviations Sin suppresive integration - Rms/Rmr rich medium sensitivity/resistance - Ts/Tr temperature sensitivity/resistance - Ap^r ampicillin resistance - Nal^r nalidixic acid resistance - Sp^r spectinomycin resistance - St^r streptomycin resistance - Tc^r tetracycline resistance     

Cloning and expression of a tylosin resistance gene from a tylosin-producing strain of Streptomyces fradiae

Summary A gene conferring high-level resistance to tylosin in Streptomyces lividans and Streptomyces griseofuscus was cloned from a tylosin-producing strain of Streptomyces fradiae. The tylosin-resistance (Tyl^r) gene (tlrA) was isolated on five overlapping DNA fragments which contained a common 2.6 Kb KpnI fragment. The KpnI fragment contained all of the information required for the expression of the Tyl^r phenotype in S. lividans and S. griseofuscus. Southern hybridization indicated that the sequence conferring tylosin resistance was present on the same 5 kb SalI fragment in genomic DNA from S. fradiae and several tylosin-sensitive (Tyl^s) mutants. The cloned tlrA gene failed to restore tylosin resistance in two Tyl^s mutants derived by protoplast formation and regeneration, and it restored partial resistance in a Tyl^s mutant obtained by N-methyl-N-nitro-N-nitrosoguanidine (MNNG) mutagenesis. The tlrA gene conferred resistance to tylosin, carbomycin, niddamycin, vernamycin-B and, to some degree, lincomycin in S. griseofuscus, but it had no effect on sensitivity to streptomycin or spectinomycin, suggesting that the cloned gene is an MLS (macrolide, lincosamide, streptogramin-B)-resistance gene. Twenty-eight kb of S. fradiae DNA surrounding the tlrA gene was isolated from a genomic library in bacteriophage Charon 4. Introduction of these DNA sequence into S. fradiae mutants blocked at different steps in tylosin biosynthesis failed to restore tylosin production, suggesting that the cloned Tyl^r gene is not closely linked to tylosin biosynthetic genes.