Temperature sensitivity of cell growth in Escherichia coli associated with the temperature sensitive R(KM) factor

A comprehensive list of genes required for the efficient conjugation of plasmid Rts1 was determined by systematic deletion analysis

While conjugation-related genes have been identified in many plasmids by genome sequencing, functional analyses have not yet been performed in most cases, and a full set of conjugation genes has been identified for only a few plasmids. Rts1, a prototype IncT plasmid, is a conjugative plasmid that was originally isolated from Proteus vulgaris. Here, we conducted a systematic deletion analysis of Rts1 to fully understand its conjugation system. Through this analysis along with complementation assays, we identified 32 genes that are required for the efficient conjugation of Rts1 from Escherichia coli to E. coli. In addition, the functions of the 28 genes were determined or predicted; 21 were involved in mating-pair formation, three were involved in DNA transfer and replication, including a relaxase gene belonging to the MOBH12 family, one was involved in coupling, and three were involved in transcriptional regulation. Among the functionally well-analysed conjugation systems, most of the 28 genes showed the highest similarity to those of the SXT element, which is an integrative conjugative element of Vibrio cholerae. The Rts1 conjugation gene set included all 23 genes required for the SXT system. Two groups of plasmids with conjugation systems nearly identical or very similar to that of Rts1 were also identified.

Complete nucleotide sequence of plasmid Rts1: implications for evolution of large plasmid genomes

Rts1, a large conjugative plasmid originally isolated from Proteus vulgaris, is a prototype for the IncT plasmids and exhibits pleiotropic thermosensitive phenotypes. Here we report the complete nucleotide sequence of Rts1. The genome is 217,182 bp in length and contains 300 potential open reading frames (ORFs). Among these, the products of 141 ORFs, including 9 previously identified genes, displayed significant sequence similarity to known proteins. The set of genes responsible for the conjugation function of Rts1 has been identified. A broad array of genes related to diverse processes of DNA metabolism were also identified. Of particular interest was the presence of tus-like genes that could be involved in replication termination. Inspection of the overall genome organization revealed that the Rts1 genome is composed of four large modules, providing an example of modular evolution of plasmid genomes.

Specific protein-DNA and protein-protein interaction in the hig gene system, a plasmid-borne proteic killer gene system of plasmid Rts1

The hig (host inhibition of growth) gene system of plasmid Rts1 belongs to the plasmid-encoded proteic killer gene family. Among the proteic killer genes described so far, hig is unique in that the toxin gene (higB) exists upstream of the antidote gene (higA). There are two promoters in the hig locus, Phig and PhigA, and only the former, which expresses both higB and higA genes, is negatively controlled by HigA and HigB proteins. In this study, we purified HigA protein by means of GST fusion. The electrophoretic mobility shift assay using the purified protein revealed that HigA specifically bound to the Phig region, but not to PhigA. The HigA-binding sequence was determined by DNase I footprinting assay to be a 56-bp sequence that completely covered the -35 and -10 boxes of Phig. The presence of two inverted repeats in the binding sequence and the identification of a dimer form of HigA by cross-linking experiment suggested that the protein bound to the Phig region as a dimer. HigB was purified as a GST fusion protein as well, though it was achieved only in the presence of HigA. HigA and GST-HigB formed a highly stable complex where the two proteins were present in an equimolar ratio.

Three short fragments of Rts1 DNA are responsible for the temperature-sensitive growth phenotype (Tsg) of host bacteria

Rts1 is a multiphenotype drug resistance factor, and one of its phenotypes is temperature-sensitive growth (Tsg) of host bacteria. A 3.65-kb fragment from Rts1 DNA was shown to cause the Tsg phenotype in host cells. This tsg fragment was split by a restriction enzyme, HincII, into four fragments. Two of these fragments were called HincII-S (short) and HincII-L (long), respectively. Each of these two fragments conferred the Tsg phenotype, indicating that, in fact, these two independent regions were responsible for the Tsg phenotype. The HincII-S 783-bp and HincII-L 1,479-bp fragments were sequenced. The region in the HincII-S fragment to which the Tsg phenotype was attributed was narrowed to a 146-bp (nucleotides 1 to 146) fragment by various restriction enzyme digestions. Further digestion of the 146-bp fragment with Bal 31 suggested that the 116-bp (nucleotides 9 to 124) fragment is the minimum sequence required for Tsg. On the other hand, in the HincII-L fragment, a fragment of 249 bp (nucleotides 1210 to 1458) and a fragment of 321 bp (nucleotides 1942 to 2262) contained separate temperature-sensitive growth activity. None of three tsg fragments contained open reading frames. The 249-bp fragment had very weak Tsg activity, while the 321-bp fragment had no Tsg activity. On the other hand, when these two fragments were together in the pUC19 vector, they exhibited very strong Tsg activity equivalent to that of the original 1,479-bp fragment. In addition, two of the 249-bp fragments gave similar, strong Tsg activity. The HincII-L 1,479-bp fragment contained an open reading frame for kanamycin resistance which was found between nucleotides 1423 and 2238. This kanamycin resistance gene sequence was different from that of the reported kanamycin resistance gene of Tn903 at 12 positions which were deduced to change seven amino acids.

Site-directed mutations in the repA C-terminal region of plasmid Rts1: pleiotropic effects on the replication and autorepressor functions

We induced site-directed mutations near the 3' terminus of the gene repA, which encodes the protein of 288 amino acid residues essential for plasmid Rts1 replication, and obtained seven repA mutants. Three of them contained small deletions at the 3' terminus. Mutant repAz delta C4, which encodes a RepA protein that lacks the C-terminal four amino acids, expressed a high-copy-number phenotype and had lost both autorepressor and incompatibility functions. Deletion of one additional amino acid residue to form the RepAz delta C5 protein caused restoration of the wild-type copy number and strong incompatibility. Studies of the remaining four repA mutants, each of which contained a single amino acid substitution near the RepA C terminus, suggested that Lys-268 is involved in both ori(Rts1) activation and autorepressor-incompatibility activities and that Arg-279 contributes to ori(Rts1) activation but not to incompatibility. Lys-268 is part of a dual-lysine sequence with Lys-267 and is located 21 amino acids upstream of the RepA C terminus. A dual-lysine sequence is also found at a similar position in both mini-F RepE and mini-P1 RepA proteins.

Effects of mutations in the repA gene of plasmid Rts1 on plasmid replication and autorepressor function

We constructed a system in which wild-type RepA or RepAcop1 protein was supplied in trans in various amounts to coexisting mini-Rts1 plasmids by clones of the repA or repAcop1 gene under the control of the native promoter with or without its operator sequence. RepAcop1 protein which contains a single amino acid substitution (Arg-142 to Lys) within its 288 amino acids could initiate the replication of the mini-Rts1 plasmid efficiently at both 37 and 42 degrees C even if it was supplied in excess. In contrast, excess wild-type RepA inhibited plasmid replication at 37 degrees C but supported replication at 42 degrees C. Therefore, it appears that the initiator activity of RepA is not related to the incompatibility phenotype associated with an excess of RepA protein. An immunoblot analysis revealed that neither RepA nor RepAcop1 synthesis was temperature sensitive and that both were autogenously regulated to a similar extent because of the presence of an operator located immediately upstream of the promoter. Two mutant RepA proteins, each of which contains a 4-amino-acid insertion in the middle of the protein, maintained the autorepressor and incompatibility activities but lost the ori(Rts1)-activating function.

Identification of the Rts 1 DNA fragment responsible for temperature sensitive growth of host cells harboring a drug resistant factor Rts 1

We have placed a kanamycin resistance SalI fragment (3.65 Kb) from the drug resistance factor Rts1 into pUC19 and pBR322. These chimeric plasmids containing the kanamycin resistance fragment from Rts1 cause temperature sensitive growth in E coli. The orientation of the kanamycin resistance fragment in the vector plasmids does not influence this phenotype.

Plasmid-mediated changes in virulence of Vibrio cholerae

The effects of several plasmids, including cloning vectors and R factors, on the virulence of Vibrio cholerae CA401R were determined by measuring the dose-related diarrheal response in orally challenged infant mice. The plasmids were also examined for their effects on the colonization ability of strain CA401R by joint infection experiments with a spectinomycin-resistant CA401 strain as an internal standard. One V. cholerae R factor, pVH2, enhanced the diarrheal response, while R factors Rts1 and pVH1 reduced it; plasmids RP4, pRK290, Sa, pSJ8, pSJ5, and pBR328 had no effect. The ability of the plasmids to affect in vitro toxin production by CA401R was variable. Cells containing large plasmids all showed a modest decrease in colonization ability. These results showed that some plasmids affected V. cholerae virulence, but that the cloning vectors pBR328, RP4, and pRK290 did not.

Transfer and stability of drug resistance plasmids inEscherichia coli K12

Mating experiments between pairs of strains ofEscherichia coli containing either the compatible plasmids TP120 (Inc N) and R1 (Inc FII) or the incompatible plasmids TP125 (Inc B) and TP113 (Inc B) were undertaken in mixed continuous-flow cultures and in dialysis sacs suspended in pond water. Plasmid transfer was readily demonstrated between strains carrying compatible plasmids TP120 and R1 in both continuous-flow culture and pond water. In mixed cultures of strains carrying plasmids TP125 and TP113, transfer was only observed in continuous-flow culture systems. Strains ofE. coli containing aggregates of plasmids TP120 and R1 were shown to be stable over 5 months continuous cultivation under carbon limited conditions at a growth rate of 0.1 hours(-1) in the presence of drugs which select for the maintenance of both plasmids. In the strains containing plasmid aggregates, a gene dosage effect was observed with respect to the levels of resistance to drugs whose resistance was encoded by both plasmids. Chemostat experiments showed that no cointegrate plasmids were found from the strains ofE. coli initially containing both plasmid TP120 and plasmid R1.

R-plasmid effects on bacterial multiplication and survival

The multiplication of Escherichia coli C containing either the plasmid R46 or its non-selftransmissible derivative was studied in the presence or absence of the isogenic R- parent strain. Neither plasmid conferred any detectable effect on the host's ability to multiply. Similarly under conditions of prolonged incubation neither plasmid conferred a disadvantage on its host when the bacteria were grown in pure culture. However, when the incubation of mixed R+/R- cultures was prolonged, the possession of either R-plasmid resulted in small but reproducible differences which favoured the R- strain.

Plasmid ColVBtrp maintenance in Erwinia carotovora

Plasmid ColVBtrp maintenance in Erwinia carotovora cells was followed by measuring kinetics of elimination of plasmid genetic markers and loss of plasmid deoxyribonucleic acid. An E. carotovora mutant stably carrying plasmid ColVBtrp was isolated. Besides stable plasmid maintenance, the mutant showed altered sensitivity to male-specific phage MS2, sensitivity to drugs, and colony morphology.

The region controlling the thermosensitive effect of plasmid Rts1 on host growth is separate from the Rts1 replication region

Rts1 is a high-molecular-weight (126 x 10(6)) plasmid encoding resistance to kanamycin. It expresses unusual temperature-sensitive phenotypes, which affect plasmid maintenance and replication, as well as host cell growth. We have cloned the essential replication region of Rts1 from pAK8, a smaller derivative which is phenotypically similar to Rts1. Restriction endonuclease digests of isolated pAK8 deoxyribonucleic acid were allowed to "self-ligate" (ligation without an additional cloning vector) and subsequently were used to transform Escherichia coli strain 20SO to kanamycin resistance. Screening of these strains for the phenotypes of thermosensitive host growth and temperature-dependent plasmid elimination demonstrated that these two properties were expressed independently. Furthermore, it was shown that the Rts1 replication locus per se is not necessarily responsible for altered host growth at the nonpermissive temperature. The kanamycin resistance fragment of pAK8 was also cloned into pBR322. Electrophoretic analysis of BamHI restriction enzyme digests of this plasmid and similar digests of an Rts1 miniplasmid has allowed the identification of an 18.6-megadalton fragment carrying the replication locus and a 14.1-megadalton fragment carrying the kanamycin resistance gene.

Mating due to loss of surface exclusion as a cause for thermosensitive growth of bacteria containing the Rtsl plasmid

At 25 degrees C, Rtsl+ bacteria grow to about 5 X 10(9) bacterial/ml before leveling off, whereas at 42 degrees C they grow from 2.6 X 10(8) bacteria/ml for only 2-3 generations after temperature shift before the growth is inhibited with a zig-zag pattern at the plateau. When diluted, Rtsl+ bacteria grow rapidly at 42 degrees C, until the concentration reaches as high as the undiluted 42 degrees C culture when growth measured by colony counts stops and the zig-zag pattern again appears. This density-dependent growth inhibition is not due to the presence of stable growth inhibitor(s). Mating experiments show that at 42 degrees C, Rtsl+ bacteria retain good donor ability; at the same time, they become good recipients in mating with Hfr (Rtsl) bacteria. SDS-PAGE reveals that membranes are altered at 42 degrees C. Examination of DNA synthesis indicates that chromosomal DNA is synthesized at both 25 degrees C and 42 degrees C at high bacterial concentration, but that of the Rtsl plasmid is slowed down at 42 degrees C. The labeling experiments suggest that in 2 h there are 2 rounds of plasmid replication at 25 degrees C, 3.5 rounds at 42 degrees C when bacteria are diluted, and 0.6 rounds at 42 degrees C when bacteria are not diluted. These results suggest that the growth inhibition of Rtsl+ bacteria at 42 degrees C is probably the consequence of mating initiated due to loss of surface exclusion.

Escherichia coli mutants incapable of supporting replication of F-like plasmids at high temperature: isolation and characterization of mafA and mafB mutants

Mutants of Escherichia coli K-12 defective in replication of F-like plasmids at a high temperature (42 degrees C) were found among threonine-independent (Thr+) revertants of a threonine-requiring F' stain after localized mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. Transduction experiments with phage P1 permitted us to divide these mutations into two classes with respect to man location; some mutations were located between thr and ara at about 0.8 min, very close to maf-1 reported previously (Wada et al., J. Mol. Biol. 108:25-41, 1976 and the others probably were located between leu and azi at about 1.8 min. The former class of mutants designated mafA exhibited the same plasmid specificity as maf-1; replication of plasmids F and ColVB trp, but not R386 or R222, were affected at a high temperature. By contrast, the latter mutants designated mafB were defective in replication of nay of these plasmids at a high temperature. When a culture of mafA mutants carrying an F' plasmid was transferred from 30 to 42 degrees C, the plasmid replication as determined by incorporation of [3H]thymidine into covalently closed circular F DNA was markedly inhibited. Under certain conditions, the temperature shift-up caused severe growth inhibition of the mutant cells. Examination of merodiploids (mafA/FmafA+) for plasmid maintenance suggested that the two mafA mutations tested (mafA23 and mafA36) were both dominant, at least partially, over the wild-type mafA+ allele. These properties of the mafA mutants, manifested at the restrictive temperature, are similar to those previously reported for the maf-1 mutant. Taken together with other evidence it is likely that these mutations affect either the same gene (mafA) or a set of closely linked genes, playing a specific role in autonomous plasmid replication in E. coli.

Defective F pili and other characteristics of Flac and Hfr Escherichia coli mutants resistant to bacteriophage R17

Mutants resistant to the donor-specific bacteriophage R17 were isolated from Hfr and Flac-containing strains of Escherichia coli K-12. Thirty-five mutants were examined for the presence of F pili by electron microscopy. The pilus morphology was studied, as were the abilities of the cells to retract their pili and to synthesize new pili. Measurements were made of the efficiency of the conjugal deoxyribonucleic acid transfer and of M13 and R17 phage infection. All mutants had noticeable defects in pilus production, structure, or function. Mutants were found which produced unusually long pili, displayed wide variations in the number of pili per cell, and were deficient in pilus retraction and synthesis. Evidence is presented that there may be two pathways of pilus retraction.

Interaction between the plasmid R6K and Escherichia coli with defective DNA polymerase I

Initial experiments demonstrated that the plasmid R6K cannot be transferred to or maintained readily in theE. coliDNA polymerase I deficient strain JG138polA1. Results withE. coliMM386polA12(R6K), which has a temperature sensitive polymerase I enzyme, showed cell division becomes abnormal when the polymerase I enzyme of the host bacteria is inactivated at the restrictive temperature. Under conditions of polymerase I deficiency, R6K replication, as measured by monitoring R-factor-mediated β-lactamase activity, also becomes abnormal with the loss of multiple R6K copies per cell and the apparent maintenance of a single R-factor copy per cell.

TOL plasmid in Pseudomonas aeruginosa PAO: thermosensitivity of self-maintenance and inhibition of host cell growth

The TOL plasmid originally isolated in Pseudomonas putida (arvilla) mt-2 was transmissible to strains of the fluorescens group of Pseudomonas, i.e., P. putida, P. fluorescens, and P. aeruginosa, except for a strain of P. aeruginosa, strain PAO. The same strain, however, could accept the plasmid when its restriction and modification abilities were lost by mutations or by growing at high temperature. In addition, the transmissibility of the TOL plasmid from strain PAO to P. putida was low when the plasmid was modified by the donor. By using P. aeruginosa PAO carrying the TOL plasmid, the stability and genetic expression of the plasmid as well as its effect on the host cell growth were examined. Thus the self-maintenance of the plasmid was found to be thermosensitive. Furthermore, the TOL plasmid inhibited the growth of strain PAO at high temperature, accompanied by the formation of some filamentous cells. These thermosensitive properties of the TOL plasmid were host dependent and not exhibited in another strain of P. aeruginosa.

Host-dependent, thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae

The thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae, was studied. pJY5 consisted of 61 million daltons of covalently closed circular (CCC) deoxyribonucleic acid (DNA) with a buoyant density of 1.714 g/cm3 (55 mol % guanine plus cytosine). In Escherichia coli, this plasmid replicated stringently at 32 degrees C, but ceased its CCC DNA replication after a short incubation at 42 degrees C, resulting in production of R- segregants. The thermosensitive replication of pJY5 was not overcome by the coexistence of non-thermosensitive R plasmids. The plasmid manifested an inhibitory effect on host bacterial cell growth at 42 degrees C, although the effect was less prominent than that of R plasmids belonging to the T-incompatibility group, Rts1, R401, and R402. When the pJY5 plasmid was transferred into E. cloacae, however, no R- segregants were detected at any culture temperature, even 42 degrees C. Alkaline sucrose gradient analysis revealed that a significant amount of pJY5 CCC DNA was synthesized in E. cloacae at the high temperature but not in E. coli. Furthermore, the growth-inhibitory effect of pJY5 on hosts at 42 degrees C was not observed in E. cloacae. On the other hand, Rts1 and R401 were found to be thermosensitive in E. cloacae as well as in E. coli.

Temperature sensitive R plasmids isolated from Proteus strains

Out of 32 R plasmids isolated from Proteus strains, 17 were found to be temperature sensitive with respect to inheritance in E. coli cells. They were fi- and classified into incompatibility group T or V. Cells carrying T group Rms273 plasmid were temperature sensitive with respect to growth and conjugal transfer in both E. coli and Proteus. The V group YOR-10 plasmid was stable in Proteus even at 42 C. However, the loss frequency of YOR-10 plasmid in E. coli reached 100% after 4 hr of incubation at 42 C, in spite of stable inheritance at 25 C. Conjugal transfer of the YOR-10 plasmid in E. coli was also strongly inhibited at 42 C. It has been concluded that instability of V group R plasmids in E. coli is due to their thermosensitive inheritance in the progeny cells at high temperatures.

Requirement of cyclic adenosine 3',5'-monophosphate for the thermosensitive effects of Rts1 in a cyclic adenosine 3',5'-monophosphate-less mutant of Escherichia coli

Previous publications showed that a covalently closed circular (CCC) Rts1 plasmid deoxyribonucleic acid (DNA) that confers kanamycin resistance upon the host bacteria inhibits host growth at 42 degrees C but not at 32 degrees C. At 42 degrees C, the CCC Rts1 DNA is not formed, and cells without plasmids emerge. To investigate the possible role of cyclic adenosine 3',5'-monophosphate (cAMP) in the action of Rts1 on host bacteria, Rts1 was placed in an Escherichia coli mutant (CA7902) that lacks adenylate cyclase or in E. coli PP47 (a mutant lacking cAMP receptor protein). Rts1 did not exert the thermosensitive effect on these cells, and CCC Rts1 DNA was formed even at 42 degrees C. Upon addition of cAMP to E. coli CA7902(Rts1), cell growth and formation of CCC Rts1 DNA were inhibited at 42 degrees C. The addition of cAMP to E. coli PP47(Rts1) did not cause inhibitory effects on either cell growth or CCC Rts1 DNA formation at 42 degrees C. The inhibitory effect of cAMP on E. coli CA7902(Rts1) is specific to this cyclic nucleotide, and other cyclic nucleotides such as cyclic guanosine 3',5'-monophosphate did not have the effect. For this inhibitory effect, cells have to be preincubated with cAMP; the presence of cAMP at the time of CCC Rts1 DNA formation is not enough for the inhibitory effect. If the cells are preincubated with cAMP, one can remove cAMP during the [(3)H]thymidine pulse and still observe its inhibitory effect on the formation of CCC Rts1 DNA. The presence of chloramphenicol during this preincubation period abolished the inhibitory effect of cAMP. These observations suggest that cAMP is necessary to induce synthesis of a protein that inhibits CCC Rts1 DNA formation and cell growth at 42 degrees C.

Chromosome-plasmid interaction in Escherichia coli K-12 carrying a thermosensitive plasmid, Rts1, in autonomous and in integrated states

An Hfr strain of Escherichia coli K-12 was obtained by integrative suppression with a thermosensitive plasmid, Rts1. The R plasmid was integrated into the chromosome between rif and thr, and transfer of the chromosome occurred counterclockwise. The thermosensitivity of host cell growth due to the dnaA mutation was markedly but not completely reduced in this integratively suppressed Hfr strain. When the dnaA mutation was removed by transducing the dnaA+ genome to this Hfr, the thermosensitivity of cell growth due to existence of Rts1 was suppressed in contrast to strains carrying it autonomously. Thermosensitivity of cell growth appeared again when the plasmid was detached from the chromosome to exist autonomously. Contrary to the effect on cell growth, the transfer of the chromosome and the plasmid itself and the ability to "restrict" T-even phages were still thermosensitive in all of these strains carrying Rts1, irrespective of its state of existence. The detached plasmid as well as the original Rts1 were segregated upon growth at 42 C. These data are discussed in relation to chromosome-plasmid interaction. One of the most important conculusions is that some plasmid genes, related to their replication, are phenotypically suppressed by the chromosome when it is integrated.

Change in the cell envelope of Escherichia coli carrying the thermosensitive drug resistance factor, Rts 1, at the nonpermissive temperature

Escherichia coli, harboring the temperature-sensitive drug-resistant factor Rts 1, formed filaments on solid medium at the nonpermissive temperature (42 C). In addition, the rate of adsorption of T4D phage progressively decreased during growth at 42 C. Susceptibility to a variety of antibiotics increased suggesting that the permeability barrier to these antibiotics may be disrupted at the nonpermissive temperature. These observations were interpreted to suggest that the target of the temperature-sensitive Rts 1 gene product responsible for altering host growth may be the cell envelope.

Plasmid mutations affecting self-maintenance and host growth in Escherichia coli

As reported in the accompanying paper, a number of mutants of the ColVBtrp plasmid that can not be maintained stably in the host cell of Escherichia coli have been isolated. Each of the mutated plasmids has been transferred to an isogenic Col minus strain, and the resulting Col+ strains were studied to examine the effects of plasmid mutations on some properties of the host bacteria. Many of the strains harboring a mutated plasmid were thus found to be temperature sensitive; they failed to grow and divide normally at high temperatures. Some of them formed "filaments" under these conditions. These abnormal growth characteristics were accompanied by an increased susceptibility to sodium deoxycholate and methylene blue, suggesting that the cytoplasmic membrane has been altered. Moreover, studies of temperature-independent revertants obtained from two of these temperature-sensitive Col+ strains suggested that a single mutation on the plasmid is responsible for the pleiotropic effects exerted on the host cell. The bearing of these findings on the mode of replication and segregated of stringent-type plasmids such as ColVBtrp in the host bacteria is discussed.

Integration of R plasmid Rts1 to the gal region of the Escherichia coli chromosome

An R plasmid Rts1 was integrated into the gal region of the chromosome of Escherichia coli XA-7012 (galE) strain by the directed transposition technique. The integration of the Rts1 genome was confirmed mainly by conjugation studies and also by transduction experiments using phage P1. As a result, it was found that the integrated genome contained genes responsible for kanamycin resistance, conjugal transferability, and for autonomous replication. As reported previously, Rts1 is temperature sensitive in replication and inhibits the growth of the host at nonpermissive temperature. However, although a plasmid derived from the integrated Rts1 genome still demonstrates temperature sensitivity upon transfer and high level of kanamycin resistance, this plasmid no longer displays temperature sensitivity in replication and the inhibitory effect on the host. These results indicate that the temperature sensitivity of replication of Rts1 and its inhibitory effect on the host cell are due to the presence of a gene or gene cluster on the Rts1 genome and that the gene(s) is clearly discriminated from the one responsible for the temperature sensitivity of transfer.

Molecular nature of the deoxyribonucleic acid of a thermosensitive R factor, Rts1

The deoxyribonucleic acid of the thermosensitive R factor, Rts1, has been examined by the technique of sedimentation in alkaline sucrose, electron microscopy, and radiation target size. All these methods yielded a molecular weight of approximately 120 million for Rts1 deoxyribonucleic acid in Escherichia coli. Sedimentation analysis revealed that Rts1 deoxyribonucleic acid in Proteus mirabilis was also 120 million daltons. Rts1 did not segregate into E. coli minicells under the conditions where another smaller non-thermosensitive R factor could.

The thermosensitive lesion in the replication of the drug resistance factor, Rts1

The DNA of the thermosensitive R factor, Rts1, has been examined by the technique of sedimentation in alkaline sucrose density gradients. Rts1 DNA was found as closed covalent circles in only a few copies per cell in an Escherichia coli host at the permissive temperature. Rts1 DNA appears to be synthesized at the nonpermissive temperature, but was not found as closed covalent circles. However, circular DNA could be recovered upon shift down to the permissive temperature. The large number of plasmid-negative cells which accumulate after prolonged culture at non-permissive temperature may be due to a strong selective pressure favoring the growth of rare R(-) segregants.

Molecular and genetic studies of an R factor system consisting of independent transfer and drug resistance plasmids

Certain genetic, structural, and biochemical properties of a class 2 R-factor system consisting of the conjugally proficient transfer plasmid I and the naturally occurring non-conjugative tetracycline (Tc) resistance plasmid 219 are reported. I and 219 exist as separate plasmid deoxyribonucleic acid (DNA) species in both Escherichia coli and Salmonella panama, having molecular weights of 42 x 10(6) and 5.8 x 10(6), respectively. The buoyant densities of I and 219 are 1.702 and 1.710 g/cm(3), respectively, in neutral cesium chloride. Although the Tc resistance plasmid is not transmissible in a normal conjugal mating, it is mobilized in a three-component mating by plasmid I and by certain other conjugative plasmids of the fi(+) or fi(-) phenotype. Mobilization does not appear to involve intermolecular recombination between plasmids, and no covalent linkage of resistance markers and fertility functions is observed. Transformation of CaCl(2)-treated E. coli by plasmid DNA is shown to be a useful procedure for studying the biological properties of different plasmid molecular species that have been fractionated in vitro, and for selectively inserting non-self-transmissible plasmids into specific bacterial strains. The effects of tetracycline on the rate of protein synthesis carried out by plasmid 219 were studied by using isolated E. coli minicells into which this plasmid had segregated. Consistent with the results of earlier investigations showing the inducibility of plasmid-mediated Tc resistance in E. coli, the antibiotic was observed to stimulate protein synthesis in minicells carrying the plasmid 219 and totally inhibit (3)H-leucine incorporation by minicells lacking the Tc resistance marker. Five discrete polypeptide species were synthesized by minicells carrying plasmid 219; exposure of minicells or parent bacteria to Tc resulted in specific and reproducible changes in polypeptide synthesis patterns.

Host cell growth in the presence of the thermosensitive drug resistance factor, Rts1

We have confirmed and extended the observation of Terawaki et al. that the R factor, Rts1, alters the growth of its host at 42 C. In all media tested there was a period during which total cell numbers increased linearly, while viable counts remained constant. During this period the rate of precursor incorporation per cell particle into deoxyribonucleic acid, ribonucleic acid, and protein declined steadily. These patterns were a consequence of the accumulation of increasing numbers of cells which had lost colony-forming ability. A temperature shiftdown experiment showed that the colony formers could, after a lag, go on to divide normally, whereas most of the noncolony formers could not undergo even a limited number of divisions after shiftdown. The number of normal divisions which occurred after shiftup of Rts1 cells to 42 C was medium dependent. In rich medium there were, on the average, two or three doublings; in glucose medium, one; and in glycerol medium, only a fraction of a doubling. Even in glucose medium, however, no increase in viable counts was observed during growth at 42 C if the cells were first starved for glucose for 1 h at 42 C. A temperature shiftdown from 42 C to 27 C during glucose starvation reversed the effect of starvation at 42 C alone. These results are consistent with the hypothesis that the thermosensitive Rts1 component(s) responsible for the host effects is present at permissive temperature, but can undergo a reversible temperature-induced alteration which then interferes with some essential host function. The detrimental effects of this R factor on its host were also reflected in a heightened sensitivity to kanamycin and actinomycin D at 42 C. Electron microscope observations revealed changes in the appearance of the cell membrane. Membranous invaginations were noted at discrete sites in the cell.

Replication of the R factor Rts1 in Proteus mirabilis

The replication of the R factor Rts1 in Proteus mirabilis was examined by using the technique of CsCl density-gradient centrifugation. The proportion of Rts1 deoxyribonucleic acid (DNA) relative to the host chromosomal DNA (% R-DNA) was 7% in both exponential and stationary growth phases in Penassay Broth and supplemented M9 minimal medium at 30 C. The chromosomal DNA content per cell varied over a threefold range in the different growth media. In agreement with previous genetic observations, the replication of Rts1 was found to be temperature-sensitive and Rts1 DNA was diluted from the cells during exponential growth at 42 C. (14)N-(15)N medium transfer experiments have shown that individual copies of Rts1 are selected at random for replication during the duplication of the multicopy episome pool.

Presence of bacteriophage-like inhibitory particles in Escherichia coli

Bacteriophage-like particles were found in the supernatant fluids of Escherichia coli O111a and O111:B(4). Caution is urged in the study of deoxyribonucleic acid synthesis and replication in these strains.

Facilitation of the transfer of R factor by the resident R factor

Transfer of some R factors were shown to be facilitated by resident R factors. The sex factor itself may be responsible for this phenomenon.

Base composition of deoxyribonucleic acid of the temperature-sensitive kanamycin-resistant R factor, Rts1

The buoyant density of deoxyribonucleic acid (DNA) from the temperature-sensitive R factor, Rts1, was determined by CsCl density-gradient centrifugation. Rts1 was found to consist of a single species of DNA of density 1.705 g/cm(3), which corresponds to a base composition of 45% guanine plus cytosine. This value is distinct from the densities previously reported for other R factors, suggesting that Rts1 represents a new molecular class of R factors.

Recombination between a thermosensitive kanamycin resistance factor and a nonthermosensitive multiple-drug resistant factor

The thermosensitive kanamycin (KM) resistance factor, R(KM)(t), and a nonthermosensitive multiple-drug resistance factor, R(100), were simultaneously introduced into Escherichia coli and Salmonella typhimurium. The temperature sensitivity of both R factors remained unchanged as long as they replicated independently. Under certain conditions, however, a new thermosensitive R factor harboring resistance markers for kanamycin, streptomycin (SM), and sulfanilamide (SA) was obtained by recombination between the R(KM)(t) and R(100) factors. R factors carrying resistance markers for KM and SA, or for SM and SA, were obtained from the recombinant R(KM SA SM)(t) by spontaneous segregation. Though the R(100) factor has been known as an fi(+) (positive for F-mediated fertility inhibition of its host) type and it does not restrict any coexisting phages, the thermosensitive recombinants of R(100) with R(KM)(t) and their segregants were found to be fi(-) and to restrict the replication of all T-even phages, as does the R(KM)(t) factor. Double infection immunity was not observed between the R(KM)(t) and R(100) factors.