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.     

Construction and BamHL analysis of chimeric plasmids containing EcoRL DNA fragments of the F sex factor.

The construction of seven chimeric plasmids (pRS series) carrying EcoRI endonuclease-generated segments of the F sex factor cloned onto the vector pSC101 is described. BamHI endonuclease analysis of these seven plasmids, the six previously described pRS plasmids (Skurray, R. A., Nagaishi, H., and Clark, A. J. (1976) Proc. Nat. Acad. Sci. USA73, 64–68) and F plasmid DNA has enabled a partial BamHI map of F to be constructed; the orientation of insertion of F DNA segments into the pSC101 vector was also established for nine of the pRS plasmids. Results indicate that in the absence of their normal promoter, F cistrons cloned into the EcoRI site of pSC101 are expressed regardless of orientation of insertion although there is a preferred orientation for high levels of expression.     

Mitochondrial DNA from Podospora anserina

Summary EcoRI fragments of the 94 kilobase mitochondrial DNA (mtDNA) from young, wild type Podospora anserina were cloned into the EcoRI site of the E. coli plasmid vector pBR325. A complete EcoRI clone bank was developed, containing all 16 of the EcoRI fragments from the native mtDNA. Restriction endonuclease maps for the enzymes SalI, XhoI, BamHI, EcoRI, BglII, and HaeIII were constructed from the analysis of single, double, and triple restriction digests of cloned and native mtDNA. In constructing the maps data were refined by extensive Southern analysis of the native genome hybridized to cloned DNA probes. Restriction maps were analyzed and permitted us to locate the origin of mtDNA derived from senescent cultures.Both the large and small rRNA genes were then localized on these restriction maps using Southern and Northern blot analysis. We have shown the large rRNA locus to lie within a 10.8 kb region of EcoRI fragments E5 and E7, and the small rRNA locus to lie on a 5 kb subfragment of EcoRI fragment E1. The limit of separation between these two loci was determined to be between 6 and 9 kb.Surprisingly, when electrophoresed in agarose-CH₃HgOH gels, the large rRNA was found to be 3.8 kb long, 500 bases longer than that from the very closely related Neurospora crassa, making it the largest rRNA yet described.     

Molecular cloning and mapping of a deletion derivative of the plasmid Rts 1

The plasmid pTW20 is a deletion derivative of the kanamycin resistance plasmid Rts1. By digesting pTW20 DNA with EcoRI endonuclease six fragments were generated, and each was cloned in the vector plasmid pACYC184. These cloned EcoRI fragments were further digested with various endonucleases, and the cleavage map of pTW20 was constructed. A SalI fragment (1.5 Md) in E1 (the largest EcoRI fragment; 11.5 Md) contained the genes kan (kanamycin resistance) and puv (uv sensitization of host). An electron microscopy study of a BamHI fragment containing kan revealed the presence of a transposon-like structure in the fragment. The smallest EcoRI fragment E6 (2.0 Md) was capable of autonomous replication in a polA host, indicating that E6 contained replication genes of pTW20. These genes were found to be located on a 1.1-Md HindIII fragment in E6. Two incompatibility genes were identified on the pTW20 genome, one located on each of the fragments E6 and E5 (3.5 Md), and expressed T incompatibility independently. The nature of the temperature sensitivity of pTW20 was discussed.     

Molecular cloning of restriction fragments and construction of a physical and genetic map of the Escherichia coli plasmid R538-1.

A genetic and physical map of Escherichia coli plasmid R538-1 was constructed using restriction endonucleases and molecular cloning techniques. R538-1 DNA was cleaved into 12 fragments by endonuclease · R · EcoRI, 6 fragments by endonuclease R · HindIII, and 3 fragments by endonuclease R · BamHI. The order of these fragments was determined by standard restriction fragment mapping techniques. Endo · R · EcoRI, endo · R · HindIII, endo · R · BamHI, and endo · R · PstI fragments obtained from R538-1 and ColE1-derived plasmids (pMB9, ColE1Ap^r, and pBR322) were ligated in vitro and used to transform E. coli C600. Transformants were selected for antibiotic resistance markers carried by R538-1. Analysis of the R538-1 fragments contained in these hybrid plasmids permitted the construction of a genetic map of the R538-1 plasmid. The genetic map of this plasmid is very similar to that of plasmid R100.     

Replication Region Fragments Cloned from Flac+ Are Identical to EcoRI Fragment f5 of F

The replication region fragments from Flac⁺ cloned in plasmids pSC138 and pML31 are identical with each other and with EcoRI fragment 5 of plasmid F.     

Characterization of small plasmids from Staphylococcus aureus.

Small molecular weight plasmids from Staphylococcus aureus were characterized with respect to size, restriction enzyme cleavage pattern and transforming capacity. The plasmids pS194 and pC194 which encode streptomycin and chloramphenicol resistance respectively contained 3.0 and 2.0 megadaltons of DNA as determined by zonal rate centrifugation and electron-microscopy. Both plasmids transformed S. aureus with high efficiency. Plasmid pC194 contained only one cleavage site for endonuclease HindIII and pS194 contained single cleavage sites for HindIII and EcoRI. A natural recombinant between these two plasmids, pSC194, shared the high transforming capacity of the parental plasmids and contained one EcoRI site And two HindIII sites. pSC194 DNA also transformed B. subtilis with high efficiency. The recombinant plasmid pSC194 may be used as an EcoRI vector for construction and propagation of hybrid DNA in S. aureus as shown in the following paper (Löfdahl et al., 1978).     

A comparison of the structural organization of amplified ribosomal DNA from Xenopus mulleri and Xenopus laevis.

Secondary structure maps of long single strands of amplified ribosomal DNA from two closely related species of frogs, Xenopus laevis and X. mulleri, have been compared. The secondary structure pattern of the gene region is identical in both ribosomal DNAs while the patterns in the non-transcribed spacers² differ. In X. mulleri, the spacer shows an extended region without any secondary structure adjacent to the 28 S ribosomal RNA sequence. In contrast, the same region in the X. laevis spacer has extensive secondary structure. A comparison of secondary structure maps and denaturation maps of these two ribosomal DNAs (Brown et al., 1972) reveals that the portion without secondary structure in the X. mulleri spacer corresponds to an early melting A + T-rich region. As in X. laevis ribosomal DNA, Escherichia coli restriction endonuclease (EcoRI) makes two cuts in each repeating unit of amplified ribosomal DNA from X. mulleri. The position of the cleavage sites is identical in the two species as judged from secondary structure mapping of the two classes of EcoRI fragments generated. The small fragments of X. mulleri ribosomal DNA are homogeneous in size with a duplex molecular weight of 3.0 × 10⁶, and contain about 85% of the 28 S ribosomal RNA gene and about 17% of the 18 S ribosomal RNA gene. The large fragments are heterogeneous in size with molecular weights ranging from 4.2 to 4.9 × 10⁶, and contain the remaining portions of the gene regions and the nontranscribed spacer. Heteroduplexes made between large fragments of different lengths show only deletion loops. The position of these loops indicates that the length heterogeneity resides in the non-transcribed spacer region. Electrophoretic analysis of EcoRI digests of chromosomal ribosomal DNA from X. mulleri demonstrates that this DNA is heterogeneous in length as well.     

Restriction endonuclease mapping of the root-inducing plasmid of Agrobacterium rhizogenes 1855

The root-inducing plasmid of the agropine type Agrobacterium rhizogenes 1855 was mapped by means of the restriction endonuclease EcoRI. The circular arrangement of the more than 60 fragments generated by this enzyme was established by electrophoretic analysis of pBR322 clones harboring overlapping segments of pRi1855 derived by partial digestion with EcoRI. A large region of the plasmid comprising the T-DNA was mapped with two additional enzymes, BamHI and HindIII, by means of Southern blot hybridizations between the fragments generated by the three enzymes.     

Cloning of human mitochondrial DNA in Escherichia coli

In order to determine its nucleotide sequence, human mitochondrial DNA (mtDNA) purified from term placentae was cloned in Escherichia coli using the plasmid vector pBR322. The products of an mtDNA MboI digestion (23 fragments ranging in size from 2800 to 25 base-pairs (bp)) were ligated with BamHI-cut pBR322. The ampicillin-resistant tetracycline-sensitive colonies obtained upon transformation of E. coli χ1776 were screened by agarose gel electrophoresis of colony lysates, colony hybridization and restriction analysis. All but MboI fragment 2 were obtained in this way. MboI fragments 5 and 8 were each found only once among the 705 clones screened. All other MboI fragments were approximately equally represented in the population of clones except for a slight bias towards smaller fragments. MboI fragment 2 overlaps with the mtDNA BamHI/EcoRI (1.7 kb³) and the 0.9 kb HinIII fragments. These were cloned in similarly restricted pBR322 to provide a set of clones covering most of the mtDNA molecule. Clones representative of each MboI fragment were shown to be complementary to mtDNA by hybridization to Southern blots of mtDNA digests and were thereby partially mapped. Further mapping was obtained by restriction analysis of mtDNA sequentially degraded by exonuclease III. A collection of recombinant clones has thus been obtained using the mtDNA isolated from a single placenta and is now being used to obtain a complete nucleotide sequence of human mtDNA.     

Cloning and analysis of pif, replication and leading regions of the F plasmid

Summary We describe the molecular cloning of BglII fragments of the hybrid plasmid pRS5 (pSC101 and EcoRI fragments of F; f7, f5, f3 and f6). The clones isolated were examined for the expression of F-specified replication, incompatibility, mobilization and inhibition of T7 bacteriophage multiplication. Proteins directed by the BglII clones were labelled in Escherichia coli K12 maxicells and analyzed by SDS-polyacrylamide gel electrophoresis. The sizes of previously reported proteins, encoded by the replication, incompatibility and leading regions encompassed by these plasmids have been confirmed in this study. In addition, the results demonstrate that a pif gene, which encodes an 80,000 dalton polypeptide essential for the inhibition T7 phage multiplication, is located on the BglII fragment that spans the junction of EcoRI fragments f7 and f5.     

Structural organization of the genome of Dictyostelium discoideum: Analysis by EcoR1 restriction endonuclease

The genome of the cellular slime mold Dictyostelium discoideum has been analyzed by limit digestion with EcoR1 restriction endonuclease. Approximately 15% of the nuclear genome is cleaved into nine discrete fragments as analyzed by agarose gel electrophoresis. These fragments appear to be derived from two nuclear buoyant density satellites, one of which contains sequences coding for ribosomal RNA. The bulk of the nuclear DNA is digested into approximately 7000 fragments with a mean molecular weight of 4 × 10⁶ to 5 × 10⁶. The mitochondrial DNA is digested into four fragments. One of the nuclear bands has been cloned in Escherichia coli using plasmid pSC101 carrying tetracyline resistance. Analysis by renaturation kinetics indicates that it is repeated approximately 200 times per haploid genome and that it is not internally repeated.     

An electron microscopic method for studying and mapping the region of weak sequence homology between simian virus 40 and polyoma DNAs.

A procedure for investigating the possibility of small amounts of partial DNA sequence homology between two defined DNA molecules has been developed and used to test for sequence homology between simian virus 40 and polyoma DNAs. This procedure, which does not necessitate the use of separated viral DNA strands, involves the construction of hybrid DNA molecules containing a simian virus 40 DNA molecule covalently joined to a polyoma DNA molecule, using the sequential action of EcoRI restriction endonuclease and Escherichia coli DNA ligase. Denaturation of such hybrid DNA molecules then makes it possible to examine intramolecularly rather than intermolecularly renatured molecules. Visualization of these intramolecularly renatured “snapback” molecules with duplex regions of homology by electron microscopy reveals a 15% region of weak sequence homology. This region is denatured at about 35 °C below the melting temperature of simian virus 40 DNA and therefore corresponds to about 75% homology. This region was mapped on both the simian virus 40 and polyoma genomes by the use of Hemophilus parainfluenzae II restriction endonuclease cleavage of the simian virus 40 DNA prior to EcoRI cleavage and construction of the hybrid molecule. The 15% region of weak homology maps immediately to the left of the EcoRI restriction endonuclease cleavage site in the simian virus 40 genome and halfway around from the EcoRI restriction endonuclease cleavage site in the polyoma genome.     

Protein expression in E. coli minicells by recombinant plasmids.

The polypeptides synthesized in E. coli minicells from recombinant plasmids containing DNA fragments from cauliflower mosaic virus, Drosophila melanogaster, and mouse mitochondria were examined. Molecularly cloned fragments of cauliflower mosaic virus DNA directed the synthesis of high levels of three polypeptides, which were synthesized entirely from within the cloned virus DNA fragments independent of their insertion into the plasmid vehicles. Several fragments of D. melanogaster DNA were capable of initiating polypeptide synthesis; however, termination of these polypeptides was dependent upon the insertion into the plasmid vehicle. The majority of D. melanogaster DNA fragments examined did not direct the detectable synthesis of any polypeptides. Insertion of DNA into the Eco RI site of ColE1 and pSC101 plasmids resulted in the altered expression of plasmid-encoded polypeptides. In the case of ColE1, this site of insertion lies within the colicin E1 structural gene, and insertion of foreign DNA into the site results in the synthesis of an inactive truncated colicin E1 molecule. It is probable that the Eco RI site in pSC101 lies within the structural gene for a polypeptide involved in tetracycline resistance, and insertion of DNA into this site may also result in the synthesis of a truncated or elongated polypeptide.     

Mapping of the resistance genes of the R plasmid NR1.

Summary The drug resistance genes on the r-determinants component of the composite R plasmid NR1 were mapped on the EcoRI restriction endonuclease fragments of the R plasmid by cloning the fragments using the plasmid RSF2124 as a vector. The sulfonamide (Su) and streptomycin/spectinomycin (Sm/Sp) resistance genes are located on EcoRI fragment G of NR1. The expression of resistance to mercuric ions (Mer) requires both EcoRI fragment H and I of NR1. The expression of chloramphenicol (Cm) and fusidic acid (Fus) resistance requires EcoRI fragments A and J of NR1. The kan fragment of the related R plasmid R6-5 can substitute for EcoRI fragment J of NR1 in the expression of Cm and Fus resistance. The structural genes for Cm and Fus resistance appear to be a part of an operon whose expression is controlled by the same promoter.     

Physical mapping of plasmid pDB101: A potential vector plasmid for molecular cloning in streptococci

A physical map of the streptococcal macrolides, lincomycin, and streptogramin B (MLS) resistance plasmid pDB101 was constructed using six different restriction endonucleases. Ten recognition sites were found for HindIII, seven for HindII, eight for HaeII, and one each for EcoRI, HpaII, and KpnI. The localization of the restriction cleavage sites was determined by double and triple digestions of the plasmid DNA or sequential digestions of partial cleavage products and isolated restriction fragments, and all sites were aligned with a single EcoRI reference site. Plasmid pDB101 meets all requirements essential for a potential molecular cloning vehicle in streptococci; i.e., single restriction sites, a MLS selection marker, and a multiple plasmid copy number. The vector plasmid described here makes it possible to clone selectively any fragment of DNA cleaved with EcoRI, HpaII, or KpnI, or since the sites are close to each other in map position, any combination of two of these restriction enzymes.     

Restriction endonuclease mapping and mutagenesis of the F sex factor replication region

Summary The plasmids pSC138 and pML31 each contain the EcoRI-generated f5 replicator fragment of the conjugative plasmid F in addition to an EcoRI fragment encoding antibiotic resistance: ampicillin resistance derived from Staphylococcus aureus in pSC138 and kanamycin resistance from Escherichia coli in pML31. We have mapped one HindIII and two BamHI restriction sites in the f5 region of these plasmids and one HindIII site in the antibiotic resistance region of each plasmid. The HindIII site in the Km region of pML31 occurs in the kan gene whereas the HindIII site in the Ap region of pSC138 appears to occur in an area important for the regulation of -lactamase production.By means of in vitro recombinant DNA manipulation of plasmids pML31 and pSC138, we have shown that 1.9x10⁶ daltons of the 6.0x10⁶ dalton f5 fragment can be deleted without disrupting plasmid stability. In addition, we have used these same techniques to isolate a novel F-controlled Ap plasmid cloning vehicle which contains a single restriction site for each of the enzymes EcoRI, HindIII, and BamHI. This cloning vehicle has been linked via either its EcoRI or HindIII site to a ColE1 plasmid replicon to yield stable recombinants.     

Restriction Fragment Length Polymorphism Analyses of the Plasmid DNAs in Strains of Xanthomonas campestris pv. vesicatoria from Different Geographic Areas

Restriction fragment length polymorphisms (RFLPs) of plasmid DNAs in Xanthomonas campestris pv. vesicatoria were analysed using 77 strains from the United states, Argentina, Australia, Taiwan, and Korea. One or more plasmids were detected in all tested strains, irrespective of geographic origin, host plant from which isolated, or chemical resistance. All Korean strains contained a few plasmids of similar high molecular weight, whereas some small plasmids occured only in strains from the United States, Argentina, and Taiwan. After digesting total plasmid DNAs with each of four restriction endonucleases, 18 fragments with sizes from about 1 to 23 kb were visualized. Seventy-seven strains of diverse geographic origins, with different levels of resistance to streptomycin and copper, were classified into the 14 RFLP groups based on the restriction endonuclease digestion patterns of their plasmid DNAs. Strains belonging to each group shared DNA fragments of identical size, suggesting the possible presence of similar plasmids in these strains. A 5.8-kb EcoRI plasmid DNA probe prepared from the United States strain 81-23 hybridized to EcoRI plasmid digests from all tested strains. Other plasmid DNA fragments of the strain81-2,3 used as probes had no homology to plasmid DNA fragments from several strains around the world. The variation in hybridization profiles of plasmid DNA was very similar to the results obtained by RFLP analysis of plasmid DNA digested by four restriction enzymes. Most of the Korean strains tested were highly sensitive to streptomycin and copper, whereas most strains from other geographic areas showed a high level of resistance to one or two of the chemicals. Cluster analysis of genetic distance between the strains based on the data obtained generated the dendrograms that separated all Korean strains from the other strains, suggesting that plasmid DNA of the Korean strains may be genetically very different from those of the others.