Comparative analysis of five related staphylococcal plasmids

The genomic organization of five small multicopy staphylococcal plasmids comprising the pT181 family has been analyzed. In addition to pT181, the family presently includes the streptomycin resistance plasmid pS194 and the chloramphenicol resistance plasmids pC221, pC223, and pUB112. Although they belong to five different incompatibility groups, the five plasmids have similar basic replicons, use the same basic copy control mechanism, and have a common structural organization. It has been demonstrated previously that pT181 and pC221 encode trans-active replication proteins (RepC and RepD, respectively) which specifically recognize the respective plasmid's origin of replication in both cases is initiated by site-specific nicking and 3' extension. The other three plasmids in this family encode similar replication proteins; 63% of the predicted amino acid residues are identical for all five and the least similar pair shows 75% identity at the amino acid level. However, despite this homology, the replication proteins and origins of replication of different members in this family did not show cross complementation in vivo. Outside of the basic replicon, which comprises about one-third of each plasmid's genome, functional organization is also conserved. The resistance determinants are all located in the same position, immediately downstream of the replication protein coding sequence, and all are transcribed in the same direction. The three chloramphenicol resistance determinants encode highly homologous chloramphenicol transacetylases which are unrelated to the tet and str gene products. Three of the five plasmids form relaxation complexes and the involved genome segments are closely related. The other two are not homologous to these three in the corresponding region, but are homologous to each other and encode a site-specific recombinase, Pre. It is suggested that the replication, resistance, and relaxation complex regions of these plasmids can be regarded as conserved segments ("cassettes") assembled in various combinations, but always with the same spatial arrangement.     

Plasmids of Bacillus thuringiensis var. galleriae strain 612

We studied Bacillus thuringiensis var galleriae, strain 612 plasmids. B. thuringiensis cells contain double-stranded plasmid DNA molecules (ranging of about 12% from total DNA content) with buoyant density 1.59 g/cm3. Plasmid DNA content was constant during the exponential and stationary phases of bacterial growth. The plasmid fractions consist of DNA molecules with molecular weights of 5.9 x 10(6), 10.0 x 10(6), and 110.9 x 10(6) daltons (pVD1, pVD2 pVD3, respectively). Endonuclease EcoRI cuts the plasmids pVD2 and pVD3 into two and four fragments, respectivelyy, but pVDI seemed to be resistent to EcoRI treatment. We found that pVD2 and pVD3 plasmids contain a common DNA fragment with the molecular weight of 6.7 x 10(6) dalton as it was shown by restriction analysis. In contrast, the same plasmids contain the common fragment with molecular weight of 7.5 x 10(6) dalton as shown by heteroduplex analysis. Plasmid pVD3 has a transposon-like structure.     

Genetic and Biophysical Study of R Plasmids Conferring Sulfonamide Resistance in Shigella Strains Isolated in 1952 and 1956

The conjugative plasmids determining sulfonamide resistance in five Shigella strains, each isolated from a different patient, have been characterized. One S. flexneri 2a strain, isolated in 1952, harbored an fi(+) plasmid of molecular weight 53 x 10(6), which specified synthesis of F-like pili and bore determinants for sulfonamide resistance (Su) and bacteriocinogeny (Col). This plasmid was compatible with plasmids of groups F(I), F(II), I(alpha), and P. A second S. flexneri 2a strain isolated in 1952 harbored an fi(-) plasmid of molecular weight 59 x 10(6), bearing the Su determinant and compatible with all plasmids tested. This strain also harbored an fi(+) group-F(II) plasmid of molecular weight 42 x 10(6), which bore the Col determinant and specified synthesis of F-like pili. Three S. dysenteriae 2 strains isolated in 1956 carried apparently identical fi(-) plasmids of molecular weight 58 x 10(6), which bore the Su determinant, could form transconjugants in Pseudomonas but not in Proteus, and were incompatible with the P-group plasmid RP4.     

Molecular characterization of two beta-lactamase-specifying plasmids isolated from Neisseria gonorrhoeae.

The molecular nature of two distinct gonococcal R plasmids, 4.4 X 10(6) and 3.2 X 10(6) daltons, encoding beta-lactamase activity were examined. Both plasmids contained about 40% of the transposable ampicillin resistance sequence Tn2. Deoxyribonucleic acid-deoxyribonucleic acid polynucleotide sequence studies have shown that the two gonococcal plasmids share about 70% of their sequences and are closely related to RSF0885, a 4.1 X 10(6)-dalton plasmid found in a beta-lactamase-producing strain of Haemophilus influenzae. All three of these R plasmids possess a guanine-plus-cytosine content of 0.40 to 0.41 mol fraction and are present as multicopy gene pools in their bacterial hosts.     

Plasmid deoxyribonucleic acid in clinical isolates of Neisseria gonorrhoeae.

Two different sizes of circular covalently closed deoxyribonucleic acid plasmids have been identified in four independent clinical isolates of eisseria gonorrhoeae. All four strains contained a small plasmid with a molecular weight of 2.8 X 10-6 and two of the four stains also contained a large plasmid with a molecular weight of 24.5 X 10-6. The avirulent derivative of each of these four strains had the same plasmid complement as its virulent parent. There was no correlation between the presence of these plasmids and antibiotic resistance, piliation, and colony type associated with virulence, or ability to grow without seven specific amino acid supplements.     

Comparison of the Deoxyribonucleic Acid Molecular Weights and Homologies of Plasmids Conferring Linked Resistance to Streptomycin and Sulfonamides

Bacterial strains showing linked resistance to streptomycin (Sm) and sulfonamides (Su) were chosen representing a wide taxonomic and geographical range. Their SmSu resistances were transferred to Escherichia coli K-12 and then plasmid deoxyribonucleic acid (DNA) was isolated by ethidium bromide CsCl centrifugation. The plasmid DNA was examined by electron microscopy and analyzed by sedimentation through 5 to 20% neutral sucrose gradients. Plasmid DNA from strains having transmissible SmSu resistance consisted of two or three molecular species, one of which had a molecular mass of about 5.7 Mdal (10(6) daltons), the others varying between 20 to 60 Mdal. By using transformation or F' mobilization, we isolated the SmSu-resistance determinant from any fellow resident plasmids in each strain and again isolated the plasmid DNA. Cosedimentation of each of these with a differently labeled reference plasmid DNA (R300B) showed 9 out of 12 of the plasmids to have a molecular mass not significantly different from the reference (5.7 Mdal); two others were 6.3 and 9.2 Mdal, but PB165 consisted of three plasmids of 7.4, 14.7, and 21.4 Mdal. Three separate isolations of the SmSu determinant from PB165 gave the same three plasmids, which we conclude may be monomer, dimer, and trimer, respectively. DNA-DNA hybridizations at 75 C demonstrated 80 to 93% homology between reference R300B DNA and each isolated SmSu plasmid DNA, except for the 9.2-Mdal plasmid which had 45% homology and PB165 which had 35%. All the SmSu plasmids were present as multiple copies (about 10) per chromosome. The conjugative plasmid of R300 (present as 1.3 copies per chromosome) has been shown to have negligible effect on the number of copies of its accompanying SmSu plasmid R300B. We conclude that the SmSu plasmids are closely related and probably have a common evolutionary origin.     

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.     

Incidence of plasmid DNA in Salmonella strains isolated from clinical sources in Ontario, Canada, during 1979 and 1980

Gel electrophoresis of DNA from 70 clinical strains of Salmonella revealed a heterogenous plasmid population. Plasmid DNA, ranging in molecular weight from 1.4 X 10(6) to 145 X 10(6), was demonstrated in 26 of 32 antibiotic-resistant strains. Several resistant strains carried up to six plasmids; however, of these, five strains which were multiply resistant contained a single plasmid of molecular weight 54 X 10(6) to 145 X 10(6). Only one incompatibility group H2 (IncH2) plasmid (pDT28) was detected in a strain of S. heidelberg; thus, this represents a reduction in the prevalence of these plasmids in Ontario Salmonella strains since 1974. The pDT28 plasmid resembled other IncH2 plasmids by its high molecular weight (145 X 10(6) ) and by virtue of its temperature-sensitive mode of transfer, resistance to tellurium, and inhibition of coliphage development. Of the 38 antibiotic-susceptible Salmonella strains, approximately half contained plasmids, ranging in molecular weight from 1.4 X 10(6) to 60 X 10(6). The plasmid-containing antibiotic-susceptible strains carried either a group of two to four small plasmids, with molecular weights less than 4.5 X 10(6), or a single large plasmid of molecular weight 23 X 10(6) or 60 X 10(6).     

Isolation of plasmid deoxyribonucleic acid from two strains of Bacteroides.

Two clinical isolates of Bacteroides contained covalently closed circular deoxyribonucleic acid (DNA) as shown by sedimentation in an alkaline sucrose gradient, CsCl ethidium bromide equilibrium centrifugation, and electron microscopy. Bacteriodes fragilis N1175 contained a homogeneous species of plasmid DNA with a molecular weight of 25 x 10(6). Bacteroides ochraceus 2228 contained two distinct, covalently closed circular DNA elements. The larger cosedimented with the covalently closed circular DNA form of the R plasmid, R100, corresponding to a molecular weight of 70 x 10(6); the smaller sedimented as a 58S molecule with a calculated molecular weight of 25 x 10(6). The roles of these plasmids are unknown. Neither strain transferred antibiotic resistance to plasmid-negative Bacteroides or Escherichia coli, and neither produced bacteriocins active against other Bacteroides or sensitive indicator strains of E. coli.     

Characterization of SmSu plasmids by restriction endonuclease cleavage and compatibility testing.

Twelve plasmids carrying genes for streptomycin and sulfonamide resistance were studied for the number and distribution of sites on the plasmid moleucles susceptible to cleavage by the restriction endonuclease EcoRI. Ten of the twelve were found to have a single cut site, one plasmid (R678) had three such sites, and plasmid PB165, which was isolated as three supercoiled deoxyribonucleic acid species with molecular weights 7.4 x 10(6), 14.7 x 10(6), and 21.4 x 10(6) was reduced to a single (linear) species of molecular weight 7.6 x 10(6) after cutting with EcoRI. We conclude that PB165 forms oligomers in Escherichia coli and that the number of copies of these per chromosome is more consistant and that the number of copies of these per chromosome is more consistent with a negative than a positive control mechanism for plasmid replication. Compatibility testing of a positive control mechanism for plasmid replication. Compatibility testing of these plasmids showed they all belong to the same incompatibility group, which we designate IncQ, suggesting that they may have come from a common ancestor.     

Plasmids in Bacillus stearothermophilus coding for bacteriocinogeny and temperature resistance.

Obligately thermophilic strains of Bacillus stearothermophilus were screened for the presence of plasmids by agarose gel electrophoresis. All strains in our collection contained large plasmids (20 x 10(6)-80 x 10(6)) and were divided into four groups with respect to their plasmid pattern and production of bacteriocins. The major plasmid species were designated pSE407 (38.7 x 10(6)), pSE409 (29.0 x 10(6)), pSE411 (21.5 x 10(6)), and pSE410 (23.5 x 10(6)). Their physical endonuclease maps were constructed, and by Southern blots and hybridizations it was shown that these plasmids were related. From curing experiments and electrotransformations (electroporations) we conclude that pSE407, pSE410, and pSE411 code for temperature resistance. In addition pSE410 codes for bacteriocin production and resistance. Plasmid pSE409 probably also codes for bacteriocin production and resistance.     

Plasmids in Streptococcus lactis: evidence that lactose metabolism and proteinase activity are plasmid linked.

Populations of lactose positive (Lac+) and proteinase positive (Prt+) cells from Streptococcus lactis M18, C10, and ML3 grown at 39 degrees C gave rise to increasing proportions of Lac- Prt- clones. The deficiencies did not appear until after a number of generations at the elevated temperature, and the rate depended on the strain.Lac- Prt+ and Lac+ Prt- mutants were isolated after treatment with ethidium bromide. Plasmid deoxyribonucleic acid was isolated by cesium chloride-ethidium bromide equilibrium density gradient centrifugation from the parent cultures as well as from their Lac- Prt-, Lac- Prt+, and Lac+ Prt- mutants. Five distinct plasmid sizes of approximate molecular weights of 2,4, 8, 21, and 27 million were found in S. lactis C10, whereas the Lac- Prt- derivative lacked the 8- and 21-million-dalton plasmids, but the 8-million-dalton plasmid was present in the Lac-Att mutant. In S. lactis m18 five plasmids possessing molecular weights of about 2, 4, 10, 18 and 27 million were observed. The 10- and 18-million-dalton plasmids were not detected in the Lac- Prt- mutants, whereas the Lac- Prt+ derivative lacked only the 18-million-dalton plasmid and the Lac+ Prt- mutant lacked only the 10-million-dalton plasmid. In S. lactis ML3 five distinct plasmids, with approximate molecular weights of 2, 4, 8, 22, and 30 million, were present. The 8- and 22-million-dalton plasmids were not detected in the Lac- Prt- derivative, but the 8-million-dalton plasmid was present in the Lac- Prt+ mutant. The evidence suggests that lactose-fermenting ability and proteinase activity in these organisms are mediated through two distinct plasmids having molecular weights of 8 x 10(6) to 10 x 10(6) for proteinase activity and 18 x 10(6) to 22 x 10(6) for lactose metabolism.     

Plasmids Controlling Synthesis of Hemolysin in Escherichia coli: Molecular Properties

Covalently closed extrachromosomal deoxyribonucleic acid (DNA) was isolated from alpha-hemolytic wild-type strains of Escherichia coli. Most strains examined were able to transfer the hemolytic property with varying frequencies to nonhemolytic recipient strains. Out of eight naturally isolated alphahemolytic E. coli strains, four contained a set of three different supercoiled DNAs with sedimentation coefficients of 76S (plasmid A), 63S (plasmid B), and 55S (plasmid C). The sedimentation coefficients and the contour lengths of the isolated molecules correspond to molecular weights of 65 x 10(6), 41 x 10(6), and 32 x 10(6). Three alpha-hemolytic wild-type strains carried only one plasmid with a molecular weight of 41 x 10(6), and one strain harbored two plasmids with molecular weights of 41 x 10(6) and 32 x 10(6). Alpha-hemolytic transconjugants were obtained by conjugation of E. coli K-12 with the hemolytic wild-type strains. A detailed examination revealed that plasmids with the same sizes as plasmids B and C of the wild-type strains can be transferred separately or together to the recipients. Both plasmids possess the hemolytic determinant and transfer properties. Plasmid A appears to be, at least in one wild-type strain, an additional transfer factor without a hemolytic determinant. In one case a hemolytic factor was isolated, after conjugation, that is larger in size than plasmid A and appears to be a recombinant of both plasmids B and C.     

Characterization and construction of molecular cloning vehicles within Staphylococcus aureus.

Four chloramphenicol resistance (Cm) and four tetracycline resistance (Tc) plasmids from Staphylococcus aureus were characterized by restriction endonuclease mapping. All four Tc plasmids had molecular masses of 2.9 megadaltons (Mdaltons) and indistinguishable responses to seven different restriction endonucleases. The four Cm plasmids (pCW6, pCW7, pCW8, and pC221) had molecular masses of 2.6, 2.8, 1.9, and 2.9 Mdaltons, respectively. The four Cm plasmids also differed both in the level of resistance to Cm and in susceptibility to retriction endonucleases. Single restriction endonuclease sites contained within each plasmid included the following: in pCW6 for HindIII, XbaI, HpaII, and BstEII; in pCW7 for HindIII, BstEII, BglII, HaeIII, and HpaII; in pCW8 for HindIII, HaeIII, and HpaII; in pC221 for HindIII, BstEII, and EcoRI. The molecular cloning capabilities of pCW8 and pC221 were determined. Cm and erythromycin resistance (Em) recombinant plasmids pCW12, PCW13, and pCW14 were constructed and used to transform S. aureus 8325-4. A 2.8-Mdalton HindIII fragment from plasmid pI258 was found to encode Em resistance and contain single sites for the retriction endonucleases BglII, PstI, HaeIII, and HpaII. The largest EcoRI fragment (8 Mdaltons) from pI258 contained the HindIII fragment encoding Em resistance intact. Cloning of DNA into the BglII site of pCW14 did not alter Em resistance. Cloning of DNA into the HindIII site of pCW8 and the HindIII and EcoRI sites of pC221 did not disrupt either plasmid replication of Cm resistance.     

Stability in Escherichia coli of an antibiotic resistance plasmid from Bacteroides fragilis.

A Bacteroides fragilis strain resistant to penicillin G, tetracycline, and clindamycin was screened for the presence of plasmid deoxyribonucleic acid (DNA). Agarose gel electrophoresis of ethanol-precipitated DNA from cleared lysates of this strain revealed two plasmid DNA bands. The molecular weights of the plasmids were estimated by their relative mobility in agarose gel and compared with standard plasmids with known molecular weights. The molecular weights were 3.40 +/- 0.20 x 10(6) and 1.95 +/- 0.05 x 10(6) for plasmids pBY1 and pBY2, respectively. Plasmid DNA purified by cesium chloride-ethidium bromide gradient centrifugation was used to transform a restriction- and modification-negative strain of Escherichia coli. Penicillin G- and tetracycline-resistant transformants were screened for the presence of plasmid DNA. A plasmid band corresponding to a molecular weight of 1.95 x 10(6) was present in all transformants tested. Curing experiments demonstrated that the plasmid, referred to as pBY22 when present in transformants, was responsible for penicillin G and tetracycline resistance. Plasmid pBY22 was mobilized and transferred to other E. coli strains by plasmid R1drd-19. Stability of pBY22 was examined in different E. coli strains and was shown to be stably maintained in both restriction-negative and restriction-positive strains. Unexpectedly, pBY2 and pBY22 were resistant to digestion by 12 different restriction endonucleases.     

Colicin V virulence plasmids.

ColV plasmids are a heterogeneous group of IncFI plasmids which encode virulence-related properties such as the aerobactin iron uptake system, increased serum survival, and resistance to phagocytosis. These plasmids have been found in invasive strains of Escherichia coli which infect vertebrate hosts including humans and livestock. Colicin V was the first colicin to be identified, in 1925, but not until the field experienced a renewed interest has the mechanism of colicin V activity been explored. As encoded by ColV plasmid pColV-K30, the aerobactin iron uptake system has been extensively investigated, but other ColV-encoded phenotypes remain largely uncharacterized. Restriction enzyme mapping of the 144-kb pColV-K30 and of the 80-kb pColV-B188 has facilitated systematic study, so that questions can be addressed by a molecular and comparative approach regarding the contributions of individual factors and plasmids to the virulence of host E. coli in model systems. The family of large ColV plasmids could be analogous to other families of large virulence plasmids, and insights gained from studying these plasmids should contribute to our understanding of cross-genetic interactions and the role of large plasmids in bacterial pathogenesis.     

Colicin V virulence plasmids.

ColV plasmids are a heterogeneous group of IncFI plasmids which encode virulence-related properties such as the aerobactin iron uptake system, increased serum survival, and resistance to phagocytosis. These plasmids have been found in invasive strains of Escherichia coli which infect vertebrate hosts including humans and livestock. Colicin V was the first colicin to be identified, in 1925, but not until the field experienced a renewed interest has the mechanism of colicin V activity been explored. As encoded by ColV plasmid pColV-K30, the aerobactin iron uptake system has been extensively investigated, but other ColV-encoded phenotypes remain largely uncharacterized. Restriction enzyme mapping of the 144-kb pColV-K30 and of the 80-kb pColV-B188 has facilitated systematic study, so that questions can be addressed by a molecular and comparative approach regarding the contributions of individual factors and plasmids to the virulence of host E. coli in model systems. The family of large ColV plasmids could be analogous to other families of large virulence plasmids, and insights gained from studying these plasmids should contribute to our understanding of cross-genetic interactions and the role of large plasmids in bacterial pathogenesis.     

Molecular cloning of DNA sequences coding for mouse embryonic globins

Yolk sac derived erythroid cells in mouse embryos synthesize four embryonic globins of which two are alpha-like and two are beta-like. Pure globin messenger RNAs from these cells were used as templates for two successive polymerizing reactions and a mixture of double stranded cDNAs coding for the four globins was obtained. These molecules were blunt-end ligated to an ECoR1 digested pBR322 plasmid and the recombinant plasmids were used to transform E. coli Hb101. Bacterial clones which proved positive upon hybridization with 32P-labelled embryonic globin cDNA were amplified and their plasmid DNA was isolated. Three different plasmids were studied, namely no. 2, 16 and 54. The restriction map of these plasmids showed that: 1) plasmid no. 2 and 54 had lost extensive DNA sequences comprising the genes responsible for tetracycline resistance; 2) the size of inserted sequences ranges from 427 base pairs of plasmid no. 16 to about 280 base pairs of plasmid no. 54; 3) plasmid no. 2 does not share any of the studied restriction sites with the other plasmids, while no. 2 and 54 have at least one site in common. The coding properties of inserted DNA were determined by positive hybrid translation showing that no. 2 codes for the alpha-like embryonic chain x, while no. 16 and 54 code for a beta-like embryonic chain, either y or z.     

Comparison of plasmids in strains of Zymomonas mobilis

Four strains of Zymomonas mobilis were examined for their resistance to antimicrobial agents and found to have similar resistance profiles. Plasmid DNA was extracted and purified by CsCl dye-buoyant density centrifugation; molecular weights were determined by agarose gel electrophoresis and electron microscopy. All four strains harbored a large plasmid (46 X 10(6) Da) and a smaller plasmid (16-21 X 10(6) Da) whose molecular weight was strain dependent. Two strains, Ag11 and ATCC 10988, had smaller plasmids of unique molecular weight. Homology existed between the plasmids in the four strains as shown by cross-reaction in DNA-DNA blot hybridizations. Only one plasmid appeared unique to the host from which it was isolated.     

Plasmid pC present in Salmonella enterica serovar Enteritidis PT14b strains encodes a restriction modification system

Salmonella enterica serovar Enteritidis (S. Enteritidis) possesses plasmids of different sizes and roles. Besides the serovar-specific virulence plasmid present in most field strains, S. Enteritidis can harbour plasmids of low molecular mass whose biological role is poorly understood. We therefore sequenced plasmid pC present in S. Enteritidis strains belonging to phage type PT14b. The size of plasmid was determined to be 5,269 bp and it was predicted to encode four open reading frames (ORFs). The first two ORFs were found (initial 3,230 bp) to be highly homologous to rom and mbeA genes of ColE1 plasmid of Escherichia coli. Proteins encoded by the other two ORFs were 99% homologous to a restriction methylase and restriction endonuclease encoded by plasmid pECO29 of a field strain of E. coli. Using insertional mutagenesis we confirmed experimentally that the plasmid pC-encoded restriction modification system was functional and could explain the high resistance of S. Enteritidis PT14b strains to phage infection.