Isolation and Characterization of Circular Deoxyribonucleic Acid Obtained from Lactose-Fermenting Salmonella Strains

Six lac elements originally contained in Salmonella strains were transferred to Escherichia coli WR3026. All of the six E. coli strains that received one of the lac elements were observed to contain supercoiled, circular deoxyribonucleic acid (DNA) when examined by the dye-buoyant density method. Segregants of each of these E. coli WR3026 strains that had lost the ability to utilize lactose, when examined in the same manner as the lactose-fermenting strains, were not observed to contain these supercoiled, circular DNA molecules. Thus the DNA of the lac elements is maintained in E. coli WR3026 in the supercoiled, circular form. Molecular weights of the supercoiled, circular molecules isolated from strains carrying the lac elements were determined by sucrose density gradient centrifugation to be 30 million to 56 million. The calculated number of copies per chromosome of the lac elements varied from 1.4 to 3.7, depending upon the particular lac element examined. Each of the elements was determined to have a guanine plus cytosine composition of 50%. All six of the E. coli WR3026 strains containing a transmissible lac element were tested with the E. coli male-specific phage, R-17, and the E. coli female-specific phage, II, and did not respond to either of these phages as do F-containing derivatives of E. coli K-12.     

Nature of Lactose-fermenting Salmonella Strains Obtained from Clinical Sources

Six of seven lactose-fermenting (lac(+)) Salmonella strains obtained from clinical sources were found to be capable of transferring the lac(+) property by conjugation to Salmonella typhosa WR4204. All of the six S. typhosa strains which received the lac(+) property transferred it in turn to S. typhimurium WR5000 at the high frequencies typical of extrachromosomal F-merogenotes. These six lac elements were also transmissible from S. typhosa WR4204 to Proteus mirabilis and to some strains of Escherichia coli K-12; moreover, they were capable of promoting low frequency transfer of chromosomal genes from S. typhimurium WR5000 to S. typhosa WR4204. One of these lac elements was shown also to be capable of promoting low frequency chromosome transfer in E. coli K-12. E. coli K-12 strains harboring these lac elements exhibited sensitivity to the male specific phage R-17. Sensitivity to R-17 was not detected in Salmonella strains containing the elements. Examination of the lac elements in P. mirabilis by cesium chloride density gradient centrifugation showed that each element had a guanine plus cytosine content of 50%. The sizes of the elements varied from 0.8 to 3% of the total Proteus deoxyribonucleic acid. The amount of beta-galactosidase produced by induced and uninduced cultures of S. typhimurium WR5000 and S. typhosa WR4204 containing the lac elements was lower than that produced by these strains with the F-lac episome. The heat sensitivity of beta-galactosidase produced by the lac elements in their original Salmonella hosts indicated that the enzyme made by these strains differs from E. coli beta-galactosidase.     

Transmission of F'lac plasmid from Escherichia coli K-12 to bacteria of the genus Erwinia]

The F'lac plasmid was transferred by conjugation from Escherichia coli K-12 W1655 to 21 lac- strains of Erwinia spp. (5.2 . 10(-6) to 6.8 . 10(-2) lac+ exconjugants per donor cell). Erw. herbicola and Erw. chrysanthemi were the better recipients than others. The degree of the stability of lac+ genes in Erwinia exconjugants depends on the strains. Stable exconjugants of Erwinia, which harbored F'lac plasmid, were able to utilize lactose, to transfer lac genes by conjugation to Erwinia spp. and E. coli, and were sensitive to the F-specific phages f1, f2, Qbeta. The F'lac plasmid was eliminated from the exconjugants by the treatment with acridine orange, which indicates that this genetic element is not integrated into the Erwinia chromosome.     

Genetic Transfer of Episomic Elements Among Erwinia Species and Other Enterobacteria: F′lac+

The episomic element F'lac(+) was transferred, probably by conjugation, from Escherichia coli to Lac(-) strains of Erwinia herbicola, Erwinia amylovora, and Erwinia chrysanthemi (but not to several other Erwinia spp. In preliminary trials). The lac genes in the exconjugants of the Erwinia spp. showed varying degrees of stability depending on the strain (stable in E. herbicola strains Y46 and Y74 and E. amylovora strain EA178, but markedly unstable in E. chrysanthemi strain EC16). The lac genes and the sex factor (F) were eliminated from the exconjugants by treatment with acridine orange, thus suggesting that both lac and F are not integrated in the Erwinia exconjugants. All of the tested Lac(+) exconjugants of E. herbicola strains Y46 and Y74 and E. amylovora strain EA178, but not of E. chrysanthemi strain EC 16, were sensitive to the F-specific phage M13. The heterogenotes (which harbored F'lac(+)) of E. herbicola strains Y46 and Y74, E. amylovora strain EA178, and E. chrysanthemi strain EC16 were able to transfer lac genes by conjugation to strains of E. herbicola, E. amylovora, E. chrysanthemi, Escherichia coli, and Shigella dysenteriae. The frequency of such transfer from Lac(+) exconjugants of Erwinia spp. was comparable to that achieved by using E. coli F'lac(+) as donors, thus indicating the stability, expression, and restriction-and-modification properties of the sex factor (F) in Erwinia spp.     

Phage t: a group T plasmid-dependent bacteriophage

Phage t was isolated from sewage from Pretoria. It formed plaques only on Escherichia coli and Salmonella typhimurium strains that carried plasmids belonging to incompatibility group T. Five of six group T plasmids permitted visible lysis of R+ host strains. There was no visible lysis of E. coli J53-2 or S. typhimurium LT2trpA8 carrying the T plasmid Rts1 although the strains supported phage growth as indicated by at least a 10-fold increase in phage titre. The latter strains transferred the plasmid at high frequency to E. coli strain CSH2 and the resulting transconjugants plated the phage. Proteus mirabilis strain PM5006(R402) failed to support phage growth although it transferred the plasmid and concomitant phage sensitivity to E. coli J53-2. The phage was hexagonal in outline, RNA-containing, resistant to chloroform and adsorbed to the shafts of pili determined by T plasmids.     

CTnscr94, a conjugative transposon found in enterobacteria.

Conjugational transposons are important for horizontal gene transfer in gram-positive and gram-negative bacteria, but have not been reported yet for enteric bacteria. Salmonella senftenberg 5494-57 has previously been shown to transfer by conjugation genes for a sucrose fermentation pathway which were located on a DNA element called scr-94. We report here that the corresponding scr genes for a phosphoenolpyruvate-dependent sucrose:phosphotransferase system and a sucrose metabolic pathway are located on a large (ca. 100 kb) conjugative transposon renamed CTnscr94. The self-transmissible element integrates at two specific attachment sites in a RecA-independent way into the chromosome of Escherichia coli K-12 strains. One site was identified within pheV, the structural gene for a tRNA(Phe). Sequencing of both ends of CTnscr94 revealed the presence of the 3' part of pheV on one end such that after integration of the element, a complete pheV gene is retained. CTnscr94 represents, to our knowledge, the first conjugational transposon found in enteric bacteria.     

Transfer among Erwinia spp. and other enterobacteria of antibiotic resistance carried on R factors

Antibiotic resistance carried on R factors was transferred by conjugation from Escherichia coli B/r and Shigella flexneri 1a to Erwinia spp. Tetracycline resistance (TetR) carried on R factor R100 drd-56 was transferred from E. coli B/r to strains of Erwinia amylovora, E. aroideae, E. atroseptica, E. chrysanthemi, E. cytolytica, E. dissolvens, E. herbicola, E. nigrifluens, and E. nimipressuralis, but not to strains of Erwinia carotovora, E. carnegieana, E. dieffenbachiae, E. oleraceae, and E. quercina. Multiple antibiotic resistance (chloramphenicol, streptomycin, tetracycline; ChlR-StrR-TetR) carried on R factor SR1 was transferred from a clinical isolate of S. flexneri 1a to strains of E. aroideae, E. chrysanthemi, E. herbicola, and E. nigrifluens, but not to strains of other Erwinia spp. The frequency of this transfer was low with receptive cultures of Erwinia spp. and E. coli (F(-) strain). Antibiotic resistance in the exconjugants showed varying degrees of stability in the presence or absence of acridine orange, depending on the strain tested. The frequencies of segregation to drug susceptibility in the presence of acridine orange, though low, suggest that the elements exist as plasmids in the majority of the Erwinia exconjugants. Multiple antibiotic resistance (ChlR-StrR-TetR) was found to segregate into various resistance classes (ChlR-StrR, StrR-TetR, TetR, StrR, and none) in these exconjugants. The exconjugants of E. amylovora, E. herbicola, and E. nigrifluens, to which R100 drd-56 was transferred from E. coli B/r, were sensitive to the male (F)-specific phage M13. There was a positive correlation between the susceptibility of exconjugants to the F-specific phage M13 and their ability to transfer R100 drd-56 to the recipient cultures of Escherichia coli, Erwinia herbicola, Salmonella typhimurium, and Shigella dysenteriae. Exceptions were, however, noted with Erwinia dissolvens and E. nimipressuralis exconjugants harboring R100 drd-56; these exconjugants, although not susceptible to M13, transferred R100 drd-56 to the recipient cultures. The frequency of transfer of R100 drd-56 and the levels of resistance to tetracycline in Erwinia exconjugants were found to differ markedly depending upon the strain employed. Transfer of multiple antibiotic resistance (ChlR-StrR-TetR) from Erwinia exconjugants was not obtained in preliminary trials with an E. coli F(-) strain as the recipient culture.     

Virulence plasmid pJM1 prevents the conjugal entry of plasmid DNA into the marine fish pathogen Vibrio anguillarum 775.

Studies involving the introduction of cloned homologous genes into Vibrio anguillarum revealed that several plasmids could not be conjugally introduced into V. anguillarum 775(pJM1), but were transmissible to the pJM1-cured derivative H775-3. Recombinant pBR322 plasmids containing V. anguillarum genomic DNA inserts were mobilized from Escherichia coli donors, using pRK2013, into V. anguillarum H775-3 recipients at frequencies of 10(-6) to 10(-5) per recipient. When identical matings were performed with V. anguillarum 775(pJM1) recipients, the infrequent exconjugants recovered carried the pBR322-based plasmid but had lost the large virulence plasmid pJM1. Similar studies were carried out with plasmid RP4 and with recombinant derivatives of the closely related broad-host-range plasmid pRK290. While RP4 was transmissible from E. coli to V. anguillarum H775-3 at frequencies of 6.7 x 10(-2) per recipient, transmission to V. anguillarum 775(pJM1) recipients occurred at frequencies of only 2.5 x 10(-7). When pRK290 contained V. anguillarum DNA inserts, the only exconjugants recovered had lost pJM1, or contained pJM1 and a deletion derivative of the recombinant pRK290 plasmid where all of the DNA insert had been deleted. The use of Dam-, Dcm-, or EcoK- methylation-deficient E. coli donor strains failed to result in appreciable numbers of V. anguillarum 775(pJM1) exconjugants that contained the desired transferred plasmids. Following UV mutagenesis, a derivative of V. anguillarum 775(pJM1) was isolated that would accept conjugally transferred plasmid DNAs at frequencies similar to those observed when using V. anguillarum H775-3 recipients. These data suggest that virulence plasmid pJM1 mediates a restriction system that prevents conjugal transmission of plasmid DNA from E. coli donors into V. anguillarum 775(pJM1). This putative restriction system appears not to be directed towards Dam-, Dcm-, or EcoK-methylated DNA, and appears not to involve a Type II restriction endonuclease.     

Nature of transforming deoxyribonucleic acid in calcium-treated Escherichia coli.

A study of the reactivation of ultraviolet-irradiated plasmid and phage deoxyribonucleic acid molecules after transformation into Escherichia coli strains indicated that, when double-stranded deoxyribonucleic acid was used as the donor species, it was taken up without conversion to the single-standed form.     

Integration of specialized transducing bacteriophage lambda cI857 St68 h80 dgnd his by an unusual pathway promotes formation of deletions and generates a new translocatable element.

Molecular and genetic studies have revealed that several illegitimate recombinational events are associated with integration of the specialized transducing bacteriophage lambda cI57 St68 h80 dgnd his into either the Escherichia coli chromosome or into a plasmid. Most Gnd+ His+ transductants did not carry the prophage at att phi-80, and 10% were not immune to lambda, i.e., "nonlysogenic." Integration of the phage was independent of the phage Int and Red gene products and of the host's general recombination (Rec) system. In further studies, bacterial strains were selected which carried the phage integrated into an R-factor, pSC50. Restriction endonuclease analysis of plasmid deoxyribonucleic acid (DNA) purified from these strains showed that formation of the hybrid plasmids resulted from recombination between a single region of pSC50 and one of several sites within the lambda-phi 80 portion of the phage. Furthermore the his-gnd region of the phage, present in the chromosome of one nonlysogenic transductant, was shown to be able to translocate to pSC50. Concomitant deletion of phage DNA sequences or pSC50 DNA was frequently observed in conjunction with these integration or translocation events. In supplemental studies, a 22- to 24-megadalton segment of the his-gnd region of the chromosome of a prototrophic recA E. coli strain was shown to translocate to pSC50. One terminus of this translocatable segment was near gnd and was the same as a terminus of the his-gnd segment of the phage which translocated from the chromosome of the nonlysogenic transductant. These data suggest that integration of lambda cI857 St 68 h80 dgnd his may be directed by a recombinationally active sequence on another replicon and that the resulting cointegrate structure is subject to the formation of deletions which extend from the recombinationally active sequence. Translocation of the his-gnd portion of the phage probably requires prior replicon fusion, whereas the his-gnd region of the normal E. coli chromosome may comprise a discrete, transposable element.     

W-reactivation and W-mutagenesis of gamma-irradiated phage lambda.

UV irradiation of Escherichia coli wild-type cells manifested the phenomena of W-reactivation (WR) and W-mutagenesis (WM) of phage lambda irradiated by 60Co gamma-rays in broth. WR of gamma-irradiated phage was half as efficient as that of UV-irradiated phage, although the frequency of c mutations in conditions of WR was about the same in both phages. The xthA and recBrecC sbcB mutants were practically identical with wild-type cells in respect of WR and WM of UV- and gamma-irradiated phage. As in UV-irradiated phage, WR and WM of gamma-irradiated phage were absolutely dependent on the recA+ and lexA+ genes of the host cell. WR and WM required much smaller doses of UV radiation for induction in polA1 and uvrB mutants. The lig-ts mutant, temperature sensitive in polynucleotide ligase, was deficient in WR and WM of UV- and gamma-irradiated phage at the semi-permissive temperature of 37 degrees. The uvrE502 mutant and the allelic recL152 strain were absolutely deficient in WR and WM of gamma-irradiated phage. In UV-irradiated phage WR was reduced, but not eliminated, in the uvrE mutant, and WM was entirely suppressed. This is another example of uncoupling of WR and WM which shows that several repair systems are active in WR but only some of them are mutagenic.     

Repression of lambda-Associated Enzyme Synthesis After lambda(vir) Superinfection of Lysogenic Hosts.

Lisio, Arnold L. (National Institutes of Health, Bethesda, Md.), and Arthur Weissbach. Repression of lambda-associated enzyme synthesis after lambda(vir) superinfection of lysogenic hosts. J. Bacteriol. 90:661-666. 1965.-Phage lambda(vir) is a multiple mutant of lambda which is capable of overcoming the immunity of a host lysogenic for lambda, and initiating normal vegetative replication of the superinfecting phage genome. Superinfection of Escherichia coli K-112 (lambda(22)) with lambda(vir) results in a normal phage yield, lysis time, and H(3)-thymine incorporation compared with infection of the sensitive host, K-112 (S). However, the production of the lambda phage-specific early protein, lambda-exonuclease, after superinfection of E. coli K-112 (lambda(22)) with lambda(vir) is only 25 to 50% of that obtained from corresponding infection of a nonlysogenic host, E. coli K-112 (S). This repression of lambda-exonuclease synthesis is dependent on the C(1) cistron of the prophage and is overcome if the lysogenic host cells are induced prior to superinfection. The data are interpreted as evidence for partial repression of lambda(vir) by the host immunity.     

Isolation of the Bacteriophage Lambda Receptor from Escherichia coli

A factor which inactivates the phage lambda can be extracted from Escherichia coli. This factor is a protein and is located in the outer membrane of the bacterial envelope. It is found in extracts of strains which are sensitive to phage lambda, but not in extracts of strains specifically resistant to this phage. We conclude that this factor is the lambda receptor, responsible for the specific adsorption of the phage lambda to E. coli cells. A partial purification of the lambda receptor is described. Inactivation of the phage by purified receptor is shown to be accompanied by the release of deoxyribonucleic acid from the phage.     

Purification and Chemistry of Bacteriophage ?

From a stock of varkappa phage grown on Salmonella, a host-range mutant which attacks Escherichia coli was isolated. As in the case of Salmonella, only motile strains of E. coli are sensitive to varkappa. The phage shows an eclipse period of 35 min and a minimal latent period of 52 min. The adsorption rate constant is 3 x 10(-9) ml/min. Adsorption shows a marked dependence on temperature. Bacteriophage varkappa was purified by differential centrifugation and CsCl density gradient centrifugation. It contains deoxyribonucleic acid (DNA) which is double-stranded. The DNA has a molecular weight of 42 million and a guanine plus cytosine content of 57%. Of 68 molecules of DNA inspected, 7 were circular. The phage particle weight is about 90 million.     

Acceptance and transfer of plasmid Rts1 by bacteria of the genus Erwinia]

The ability of 13 Erwinia strains to accept, to inherit and to transmit the Rts1 factor by conjugation was studied. 11 strains accepted the Rts1 factor from Escherichia coli K-12 CSH-2 with the frequency of about 10(-7)--10(-3). The Rts1 factor was genetically stable in the Erwinia cells and was not eliminated by acriflavine and under the temperature of 37 and 42 degrees C. All the R+ exconjugants were characterized with more high degree of the resistance of kanamycin than E. coli cells harbouring the same R factor. Erwinia strains harbouring the Rts1 plasmid transferred it by conjugation into homologic (Erwinia) and heterologic (E. coli) bacteria. The study of kinetics of the transfer of the Rts1 factor in different mating systems showed that the transfer of this plasmid from R+ Erwinia into R- Erwinia and R- E. coli--in the liquid medium. It is concluded that Erwinia can be the host and the donor of the Rts1 factor.     

Insertional specificity of transposon Tn5 in Acinetobacter sp.

Suicide plasmid pJB4JI, containing transposon Tn5 and phage Mu, was introduced from Escherichia coli 1830 into Acinetobacter sp. strain HO1-N and Acinetobacter calcoaceticus BD413. Kanamycin-resistant (Kmr) exconjugants of HO1-N and BD413, isolated on complex medium, were screened for auxotrophic requirements. Over 10,000 Kmr clones were examined, but no auxotrophs were detected. Several Kmr exconjugants of BD413 and HO1-N, obtained from independent matings, were chosen for further study. All Tn5-containing strains exhibited kanamycin phosphotransferase activity. Kmr strains lacked plasmid DNA as determined by three plasmid screening procedures, and the Kmr phenotype was not transferable by conjugal matings to kanamycin-sensitive BD413, HO1-N, or E. coli HB101. The chromosomal location of Tn5 insertions in independently isolated Kmr exconjugants of BD413 and HO1-N was characterized by restriction endonuclease mapping and hybridization studies. Results obtained from Southern hybridization studies were consistent with a single Tn5-specific insertion site in HO1-N and two such sites in BD413. Phage Mu sequences were not detected in Tn5-containing Acinetobacter sp.     

Escherichia coli females defective in conjugation and in adsorption of a single-stranded deoxyribonucleic acid phage

We predicted that, among mutants resistant to infection by single-stranded deoxyribonucleic acid viruses, there would be some also resistant to "infection" by single-stranded conjugal deoxyribonucleic acid. Approximately 5% of the Escherichia coli K-12 females selected for resistance to phage ST-1 were defective as recipients in conjugation. These spontaneous mutants fell into two classes. Type A accepted both plasmid and chromosomal markers at greatly reduced frequencies (<10(-6) of normal for at least one strain), formed "rough" colonies, and (unlike their parent) were nonflagellated. Type B strains accepted both chromosomal and plasmid markers at reduced frequencies (10(-2) to 10(-1) of normal), were temperature sensitive for growth, and showed increased susceptibility towards antibiotics and deoxycholate. Both classes of mutants also were resistant to certain female-specific viruses.     

Host-controlled Restriction of T-even Bacteriophages: Relation of Four Bacterial Deoxyribonucleases to Restriction

Escherichia coli strains B and K-12, which restrict growth of nonglucosylated T- even phage (T(*) phage), and nonrestricting strains (Shigella sonnei and mutants of E. coli B) were tested for levels of endonuclease I and exonucleases I, II, and III, by means of in vitro assyas. Cell-free extracts freed from deoxyribonucleic acid (DNA) were examined with three substrates: E. coli DNA, T(*)2 DNA, and T2 DNA. Both restricting and nonrestricting strains had comparable levels of the four nuclease activities and had similar patterns of preference for the three substrates. In addition, mutants of E. coli B and K-12 that lack endonuclease I were as effective as their respective wild types in restricting T(*) phage.     

Synthesis of Indicator Strains and Density of Ribonucleic Acid-Containing Coliphages in Sewage

Escherichia coli strains freshly isolated from natural sources are inefficient indicators of coliphages present in sewage. Four E. coli strains recently isolated from clinical specimens were mutagenized to obtain lac(-) mutants. Such mutants were infected with an F'lac(+) sex factor of E. coli K-12. Pairs of isogenic lac(-) and lac(-)/F'lac(+) strains were used as indicators of coliphages present in sewage, and it was found that such strains can be effectively used for a direct and almost selective enumeration of F-specific coliphage contents of sewage samples. Serological tests were applied to a number of F-specific phages isolated. All the isolates that were tested fell into two distinguishable antigenic classes: members of one class being related to ribonucleic acid (RNA) phage MS2 and those of the other being related to another RNA phage, namely, Qbeta. MS2-related phages have been found to be more widely distributed than the Qbeta related phages. Most habitats sampled were found to yield only one or the other kind of phage. Single-stranded deoxyribonucleic acid-containing F-specific phages were not detectable by the methods employed by us.     

Salmonella typhimurium SA host specificity system is based on deoxyribonucleic acid-adenine methylation.

We have determined the nature of the deoxyribonucleic acid (DNA) modification governed by the SA host specificity system of Salmonella typhimurium. Two lines of evidence indicate that SA modification is based on methylation of DNA-adenine residues. (i) The SA+ locus of Salmonella was transferred into Escherichia coli B, a strain that does not contain 5-methylcytosine in its DNA; although the hybrid strain was able to confer SA modification, its DNA still did not contain 5-methylcytosine. (ii) the N6-methyladenine content of phage L DNA was measured after growth in various host strains; phage lacking SA modification contained fewer N6-methyladenine residues per DNA. We also investigated the possibility, suggested by others (32), that SA modification protects phage DNA against restriction by the RII host specificity system. Phages lambda, P3, and L were grown in various SA+ and SA- hosts and tested for their relative plating ability on strains containing or lacking RII restriction; the presence or absence of SA modification had no effect on RII restriation. In vitro studies revealed, however, that Salmonella DNA is protected against cleavage by purified RII restriction endonuclease (R-EcoRII). This protection is not dependent on SA modification; rather, it appears to be due to methylation by a DNA-cytosine methylase which has overlapping specificity with the RII modification enzyme, but which is not involved in any other known host specificity system.