Altered tetracycline resistance in pSC101 recombinant plasmids

Summary Investigation of tetracycline resistance genetically determined by the plasmid pSC101 and several recombinants of pSC101 containing of EcoRI generated DNA fragments inserted at the EcoRI site has revealed significant differences in the phenotypic expression of that resistance. The altered phenotypes of the recombinant plasmids may be the result of the location of the EcoRI site of pSC101, which has been determined to be near the genetic elements involved with tetracycline resistance.     

Deletions within E. coli plasmids carrying yeast rDNA.

Deletions occur in recombinant DNA plasmids that contain yeast ribosomal DNA (rDNA) inserted into the E. coli plasmids pSC101 and pMB9. Deletions within a pMB9 plasmid containing an insert longer than one tandem rDNA repeat apparently are due to homologous recombination because (1) all of the independently derived deletion products of this plasmid lost one complete rDNA repeat (8.6 kb) and retained only a single copy of the segment repeated at the ends of the original insert and (2) deletions were detected only when the insert had terminal redundancy. Deletions also occur within a pSC101 plasmid containing a tandem duplication of a segment (4.7 kb) including both pSC101 DNA and rDNA. Once again these deletions appear to be due to the presence of a duplicated region because all deletion products have lost one complete repeat. Deletions within both of these plasmids took place in both rec+ and recA- host cells, but occurred more frequently in rec+ cells. Oligomerization of the deletion products also occurred in both hosts and was more frequent in rec+ cells.     

Heterogeneity of tetracycline resistance determinants

We have found that tetracycline resistance on different naturally occurring bacterial plasmids is encoded by more than one genetic determinant. Using restriction enzyme analyses and DNA-DNA hybridization to specific ³²P-labeled genetic probes, we can define at least four genetically distinct tetracycline resistance determiants: Class A (the determinant on prototype plasmid RP1), Class B (that on R222), and Class C (that on plasmid pSC101). At least one other determinant, encoded by plasmid RA1, belongs to none of these three groups and has been designated Class D. These genetic classes confirm phenotypic differences in expression of resistance to tetracycline and tetracycline analogs encoded by the different plasmids.     

On the nature of tetracycline resistance controlled by the plasmid pSC101.

In vitro enzymatic alteration of plasmid phenotype and in vitro construction of recombinant plasmids containing genetic information derived from the plasmid pSC101 have been used to investigate the mechanism of function of tetracycline resistance determined by the plasmid pSC101. The resistance has been shown to be inducible and involves the increased synthesis of membrane-associated polypeptides of 34,000, 26,000 and 14,000 daltons that are encoded for by the plasmid. The 34,000 dalton polypeptide along with another plasmid-encoded polypeptide of 18,000 daltons function in an ATP-independent manner to prevent the accumulation of tetracycline by the cell. These polypeptides are sufficient for resistance. A second component of plasmid-determined resistance involves the 14,000 dalton polypeptide and reduces the initial adsorption of tetracycline by sensitive cells, but is not alone sufficient for the generation of resistance. The role of the 26,000 dalton polypeptide in tetracycline resistance has not been identified.     

Identification by deletion analysis of an inducible protein required for plasmid pSC101-mediated tetracycline resistance.

Plasmids containing small deletions within a tetracycline (Tc) resistance gene(s) of plasmid pHA121 were isolated. Plasmid pHA121 was formed by ligating the EcoRI-digested Tc resistance plasmid pSC101 and similarly digested mini-ColE1 plasmid pHA105. The DNA deletion plasmids were constructed by digesting plasmid pHA121 DNA with the restriction endonucleases BamH1 and Sal1 and, in addition, λ exonuclease. Two plasmids, designated pJT131 and pJT133, had small deletions of approximately 0.64 to 0.8 kb and a comparison of the radioactive polypeptides synthesized in plasmid-containing minicells revealed that a 34-kdal polypeptide was not specified by either pJT131 or pJT133. We conclude that the 34-kdal polypeptide is required for the expression of Tc resistance and that its structural gene probably maps in the deleted region of pSC101 DNA.     

Versatile low-copy-number plasmid vectors for cloning in Escherichia coli

Small low-copy-number plasmid vectors were constructed by in vitro and in vivo recombinant DNA techniques. pLG338 and pLG339 are derived from pSC105, have a copy number of six to eight per chromosome, and carry genes conferring resistance to tetracycline and kanamycin. pLG338 (7.3 kb) has unique restriction endonuclease sites for BamHI, SalI, HincII, SmaI, XhoI, EcoRI and KpnI, the first five lying within a drug resistance gene. pLG339 (6.2 kb) lacks the KpnI site, but has unique SphI and PvuII sites. These versatile vectors should be useful for cloning many genes coding for membrane and regulatory proteins which cannot be cloned into high-copy-number plasmids.     

A general method for inserting specific DNA sequences into cloning vehicles

A general method has been developed to introduce any double-stranded DNA molecule into cloning vehicles at different restriction endonuclease sites. In this method a chemically synthesized decadeoxyribonucleotide duplex, containing a specific restriction endonuclease sequence, is joinlex DNA is cut by the same restriction endonuclease to generate the cohesive ends. It is then inserted into the restriction endonuclease cleavage site of the cloning vehicle. To demonstrate the feasibility of this new method, we have inserted separately the synthetic lac operator DNA at the Bam I and HindIII cleavage sites of the plasmid pMB9 DNA.     

Regions associated with the stable maintenance of plasmid pSC101 and its tetracycline resistance

Summary Two regions tentatively called unsA and unsR were identified on pSC101. One, unsA, corresponds to less than 650 bp of the N-terminal in the tetracycline resistance structural gene and seems to inhibit stable maintenance of pSC101. The other, unsR, is defined within the 1 kb XhoI-EcoRI region located upstream of the tetracycline resistance structural gene and is a regulatory gene clearly distinct from tetR (Unger et al. 1984); it serves as a suppressor of the unsA function.     

Plasmid pSC101 replication mutants generated by insertion of the transposon Tn1000

A derivative of pSC101, pLC709, was constructed by ligation of the HincII-A fragment of pSC101 to the mini-colEI plasmid pVH51 and to a DNA fragment encoding resistance to the antibiotics streptomycin and spectinomycin. Insertions of the transposon Tn1000 (gamma-delta) into the pSC101 replication region of pLC709 were isolated following cotransfer of the plasmid with the sex factor F. The sites of insertion of the transposon were determined by restriction enzyme analysis and the replication and incompatibility properties of the insertion plasmids and DNA fragments cloned from them were analysed. The insertion mutations defined a locus, inc, of approximately 200 base-pairs that is responsible for pSC101-specific incompatibility. Two mutations adjacent to this region inactivate pSC101 replication but can be complemented in trans by a wild-type pSC101 plasmid, and thus define a trans-acting replication function, rep. The inc locus is within a larger region of some 450 base-pairs that is essential for pSC101 replication and that includes the origin of replication. This 450 base-pair segment can replicate in the presence of a helper plasmid that supplies the rep function in trans.     

The structures and fidelity of replication of mouse mitochondrial DNA-pSC101 EcoRI recombinant plasmids grown in E. coli K12

Recombinant DNAs containing the E. coli plasmid pSC101 and mouse cell (LA9) mitochondrial DNA (mtDNA) were formed in vitro via ligation of DNA fragments from limit EcoRI endonuclease digests and were used to transform E. coli K12. Four structurally different recombinant plasmid DNAs from transformed clones were characterized. Two of these were analyzed extensively and the mtDNA portions compared with mtDNA from LA9 cells. No differences were detected in the physical or chemical properties examined, except that the E. coli mtDNA lacked the alkali lability characteristic of animal mtDNAs.Heteroduplexes between the LA9 portions of the recombinant plasmids and LA9 mtDNA were analyzed by absorbance melting. The melting temperatures were indistinguishable from reannealed LA9 mtDNA homoduplexes, indicating that single-base replication errors occur at a frequency of fewer than 1 nucleotide in 300. Electron microscopic analyses of plasmid-LA9 mtDNA heteroduplexes and a comparison of agarose gel electrophoresis of restriction endonuclease fragments also indicated no differences. These results were independent of the order or the relative orientation of the pSC101 and mtDNA fragments.A third EcoRI fragment in LA9 mtDNA, not found in an earlier study (Brown and Vinograd, 1974), has been positioned in the LA9, EcoRI map. This fragment contains 165±10 nucleotide pairs.     

Control of tryptophan synthetase amplified by varying the numbers of composite plasmids in Escherichia coli cells.

Using pSC101, RSF1010, RSF2124 and RP4 plasmids as vectors and bacteriophage lambdatrpD-A60-3 DNA as a source of the Escherichia coli whole tryptophan operon, composite plasmids of pSC101-trp, RSF1010-trp, RSF2124-trp and RP4-trp were constructed in vitro with EcoRI restriction endonuclease and DNA ligase. Each composite plasmid could be maintained stably in E. coli cells. The copy number of pSC101-trp, RSF1010-trp, RSF2124-trp and RP4-trp were 4.2, 11.2, 11.9 and 1.6 per chromosome respectively. The tryptophan synthetase activities in cells containing pSC101-trp, RSF1010-trp, RSF2124-trp aand RP4-trp plasmid were found to be 2.1, 6.0, 5.0 and 2.5 times compared with the level in chromosomal trp+ cells when they were grown in a minimal medium. By partial derepression with indolylacrylic acid, the enzyme levels were elevated to 10.1, 16.3, 15.3, 12.3 times, respectively, that of the control cells. The tryptophan synthetase activities did not increase in proportion to the copy number of the plasmids, but were strongly affected by the repression system of host cells.     

Hemoglobin switching in sheep. Synthesis, cloning, and characterization of DNA sequences coding for the beta B, beta C, and gamma-globin mRNAs.

Synthetic double-stranded DNAs (sDNAs) were prepared from sheep globin mRNA templates isolated from reticulocytes producing either hemoglobin B (HbB) (alpha 2 beta B2), HbC (alpha 2 beta C2), or HbF (alpha 2 gamma 2). These DNAs were inserted into the Eco RI site of plasmid pMB9 by the homopolymer tailing method and used to transform Escherichia coli X1776 to tetracycline resistance. Recombinant clones were identified by colony hybridization and further characterized by molecular hybridization and restriction endonuclease analysis. All plasmids analyzed thus far contained either beta- or gamma-globin DNA sequences. Moreover, sDNAs used for cloning yielded restriction endonuclease fragments consistent with the presence of predominantly beta- or gamma-sDNA, indicating that formation of double-stranded alpha-sDNA proceeds much less efficiently under our conditions than the formation of non-alpha-sDNAs. Three recombinant plasmids, pS beta B2, pS beta C69, and pS gamma 56, were selected for detailed study. These were shown to contain, respectively, beta B-, beta C-, and gamma-DNA sequences by molecular hybridization and by protection of the appropriate cDNAs from S1 nuclease digestion. Each contained all of the restriction endonuclease sites defined for the synthetic sDNAs and protected at least 90% of the sequence length of homologous cDNA. Restriction endonuclease maps of the beta B- and beta C-globin genes were identical at all 12 sites that were mapped, whereas four differences were identified in the gamma gene compared to the two others; three of these corresponded to differences in amino acid sequence of the globins. A method was developed to isolate the anti-mRNA strand of the insert for use as a specific molecular hybridization probe analogous to complementary DNA.     

The reactions of the EcoRi and other restriction endonucleases.

The reaction of the EcoRI restriction endonuclease was studied with both the plasmid pMB9 and DNA from bacteriophage lambda as the substrates. With both circular and linear DNA molecules, the only reaction catalysed by the EcoRI restriction endonuclease was the hydrolysis of the phosphodiester bond within one strand of the recognition site on the DNA duplex. The cleavage of both strands of the duplex was achieved only after two independent reactions, each involving a single-strand scission. The reactivity of the enzyme for single-strand scissions was the same for both the first and the second cleavage within its recognition site. No differences were observed between the mechanism of action on supercoiled and linear DNA substrates. Other restriction endonucleases were tested against plasmid pMB9. The HindIII restriction endonuclease cleaved DNA in the same manner as the EcoRI enzyme. However, in contrast with EcoRI, the Sa/I and the BamHI restriction endonucleases appeared to cleave both strands of the DNA duplex almost simultaneously. The function of symmetrical DNA sequences and the conformation of the DNA involved in these DNA--protein interactions are discussed in the light of these observations. The fact that the same reactions were observed on both supercoiled and linear DNA substrates implies that these interactions do not involve the unwinding of the duplex before catalysis.     

Plasmid-conferred tetracycline resistance confers collateral cadmium sensitivity to E. coli cells

E. coli HB101 cells transformed to tetracycline resistance with the plasmids pMB9 or pBR322 display a 10⁵–10⁶-fold lower plating efficiency on agar containing 440 μm CdCl₂ than nontransformed cells. When DNA is inserted into the BamH1 site of the plasmid tet gene, or when DNA spanning the BamH1 site is deleted, tetracycline resistance and cadmium hypersensitivity are both lost. In contrast, insertion of DNA into the ampicillin resistance gene does not affect cadmium hypersensitivity.     

Effect of dna mutations on the replication of plasmid pSC101 in Escherichia coli K-12.

Escherichia coli strains with mutations in genes dnaB, dnaC, and dnaG were tested for their capacity to replicate pSC101 deoxyribonucleic acid (DNA) at a nonpermissive temperature. Only a small amount of radioactive thymine was incorporated into pSC101 DNA in the dna mutants at 42 degrees C, whereas active incorporation into plasmid DNA took place in wild-type strains under the same conditions. The effects of the dnaB and dnaC mutations were greater on plasmid DNA synthesis than on host chromosomal DNA synthesis, suggesting that these gene products are directly involved in the process of pSC101 DNA replication. In dnaG mutants, both plasmid and chromosomal DNA synthesis were blocked soon after the shift to high temperature; although the extent of inhibition of the plasmid DNA synthesis was greater during the early period of temperature shift to 42 degrees C as compared with that of the host DNA synthesis, during the later period it was less. It was found that the number of copies of pSC101 per chromosome in dnaA and dnaC strains, grown at 30 degrees C, was considerably lower than that in wildtype strains, suggesting that the replication of pSC101 in these mutant strains was partially suppressed even under the permissive conditions. No correlation was found between the number of plasmid copies and the tetracycline resistance level of the host bacterium.     

Use of the T4 polynucleotide ligase in the joining of flush-ended DNA segments generated by restriction endonucleases.

Double-stranded DNA segments with completely base-paired ends were obtained by the action of various restriction endonucleases on phage and plasmid DNAs. These segments were joined covalently by the T4 polynucleotide ligase. The joining was monitored by the electron microscopy count of intramolecularly circularized segments. The highest extent of joining, close to 75%, was observed at 15-25 degrees C with the segments resulting from the action of the Bacillus subtilis (strain R) restriction endonuclease Bsu on the DNA of bacteriophage SPPI or of the plasmid pSC 101. The joining of double-stranded termini required about 10 times more enzyme than the short single-stranded termini produced by the Escherichia coli restriction endonuclease EcoRI. A shortened purification of the T4 ligase was found to give an enzyme devoid of interfacing nucleases.