Structural relationships among chloramphenicol-resistance plasmids of Staphylococcus aureus

Abstract Twelve different chloramphenicol-resistance (Cm^r) plasmids detected in Staphylococcus aureus strains isolated between 1952 and 1981 were characterized by restriction endonuclease, DNA hybridization and heteroduplex analyses. These studies revealed three families of Cm^r plasmids which were distinguished by their chloramphenicol acetyltransferase sequences; the prototype plasmids of the families were pC221, pC223 and pC194. The cat and replication ( rep ) genes of the plasmid pC221 were highly conserved in other pC221 family members and were related to their homologs in the pC223 family plasmids; however, the cat and rep genes of the pC194 family plasmids were distinct.     

A chloramphenicol-streptomycin-resistance plasmid from a clinical strain of Staphylococcus sciuri and its structural relationships to other staphylococcal resistance plasmids

A 5.1-kb plasmid, designated pSCS12, isolated from a naturally occurring Staphylococcus sciuri conferred resistance to chloramphenicol (CmR) and streptomycin (SmR). Restriction endonuclease analyses of pSCS12 revealed partial structural homologies to the CmR-plasmids pC221 from S. aureus and pSCS1 from S. intermedius, to the SmR-plasmids pSAI-1 from S. hyicus and pS194 from S. aureus, as well as to the CmR/SmR plasmid pSK68 from S. aureus. Southern-blot hybridization with specific CmR- and SmR-gene probes confirmed these similarities and allowed the mapping of the CmR- and SmR-determinants in the S. sciuri plasmid pSCS12. These observations lead to the suggestion that CmR/SmR-plasmids, such as pSCS12, may have evolved from CmR- and SmR-plasmids by interplasmidic recombination.     

Nucleotide sequence and structural relationships of a chloramphenicol acetyltransferase encoded by the plasmid pSCS6 from Staphylococcus aureus

M. CARDOSO AND S. SCHWARZ. 1992. The 4.6 kb chloramphenicol resistance (Cm^R) plasmid, pSCS6, isolated from a naturally occurring Staphylococcus aureus biotype C encoded an inducible chloramphenicol acetyltransferase (CAT). The respective cat gene and its regulatory region were cloned. Sequence analyses revealed two open reading frames: one for a 9-amino acid leader peptide and the other for the 215-amino acid CAT monomer. Comparisons of the predicted CAT amino acid sequences revealed a high degree of similarity between CAT from pSCS6 and the CAT variants encoded by Cm^R plasmids of the pC221 family. These close structural relationships suggested an intraspecific exchange of Cm^R-determinants between Staph. aureus of human and bovine biotype.     

Cloning and sequence analysis of a plasmid-encoded chloramphenicol acetyltransferase gene from Staphylococcus intermedius.

The chloramphenicol acetyltransferase gene (cat) of a 3.9 kb chloramphenicol resistance (CmR) plasmid from Staphylococcus intermedius, designated pSCS1, was cloned into an Escherichia coli plasmid vector. Sequence analysis revealed a high degree of base similarity with the cat gene of the S. aureus CmR plasmid pC221 but there were several differences in the regulatory region. A lesser degree of similarity was observed between the cat gene of the S. intermedius plasmid and the cat gene of the S. aureus plasmid pC194.     

Nucleotide sequence of the chloramphenicol resistance determinant of the streptococcal plasmid pIP501

We have sequenced the chloramphenicol resistance determinant (cat) of plasmid pIP501 from Streptococcus agalactiae to investigate its relationship with other cognate cat determinants. Sequence analysis revealed that it exhibits a high degree of similarity with the cat genes of plasmids pC221 and pUB112 from Staphylococcus aureus and pSCS1 from Staphylococcus intermedius. These genes, however, display several differences in their regulatory and coding regions. These results demonstrate that the cat determinant of plasmid pIP501 belongs to the pC221 subgroup of CAT variants.     

Nucleotide sequence and structural relationships of a chloramphenicol acetyltransferase encoded by the plasmid pSCS6 from Staphylococcus aureus.

The 4.6 kb chloramphenicol resistance (Cm) plasmid, pSCS6, isolated from a naturally occurring Staphylococcus aureus biotype C encoded an inducible chloramphenicol acetyltransferase (CAT). The respective cat gene and its regulatory region were cloned. Sequence analyses revealed two open reading frames: one for a 9-amino acid leader peptide and the other for the 215-amino acid CAT monomer. Comparisons of the predicted CAT amino acid sequences revealed a high degree of similarity between CAT from pSCS6 and the CAT variants encoded by Cm plasmids of the pC221 family. These close structural relationships suggested an intraspecific exchange of Cm-determinants between Staph. aureus of human and bovine biotype.     

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).     

Mobilization of the relaxable Staphylococcus aureus plasmid pC221 by the conjugative plasmid pGO1 involves three pC221 loci.

The Staphylococcus aureus plasmid pC221, a 4.6-kilobase multicopy chloramphenicol resistance plasmid that forms plasmid-protein relaxation complexes, was mobilized for transfer by the conjugative plasmid pGO1. Two open reading frames on the pC221 genome, now designated mobA and mobB, as well as a cis-acting locus, the putative oriT, were shown to be in involved in pC221 mobilization. The mobA (but not mobB) and oriT loci were required for pC221 relaxation, and relaxation was necessary but not sufficient for pC221 mobilization by pGO1. oriT was cloned onto a pE194 derivative and complemented in trans for both relaxation and mobilization. Mobilization of relaxable plasmids in S. aureus appears to be analogous to mobilization by donation observed in gram-negative bacteria.     

Specificity of RepC protein in plasmid pT181 DNA replication

The plasmid pT181 of Staphylococcus aureus consists of 4437 base pairs and encodes resistance to tetracycline. Initiation of pT181 DNA replication specifically requires the plasmid-encoded initiator protein, RepC. The initiator protein binds specifically to a 32-base pair sequence within the pT181 origin of replication. RepC protein also has a nicking-closing activity that is specific for the pT181 origin. Replication of pT181 initiates by covalent extension of the nick and proceeds by a rolling circle mechanism. Two other small, multicopy plasmids pC221 and pS194 belong to the pT181 family and have common structural organization and replication properties. The replication proteins and replication origins of these plasmids have extensive sequence homologies, although they belong to different incompatibility groups. In spite of this homology, the replication proteins and replication origins of these three plasmids do not show any cross-reactivity in vivo. We have carried out a series of in vitro experiments to determine the specificity of pT181-encoded initiator protein, RepC. DNA binding experiments showed that although the binding of RepC to the pT181 origin was very efficient, little or no binding was seen with pC221 and pS194 origins. The nicking-closing activity of RepC was found to be equally efficient with the pC221 and pS194 plasmids. The plasmids pC221 and pS194 replicated efficiently in a RepC-dependent in vitro system. However, replication of these plasmids was greatly reduced in the presence of a competing pT181 origin. The results presented here suggest that nicking-closing by RepC at the origin is not sufficient for maximal replication and that tight binding of RepC to the origin plays an important role in the initiation of DNA replication.     

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.     

A vector for recombinant DNA in Staphylococcus aureus

Staphylococcal plasmids pS194 and pSC194 which confer streptomycin and streptomycin-chloramphenicol resistance respectively have been used as vectors for construction of recombinant DNA, since they each carry one single recipient site for endonuclease EcoRI. Hybrid DNA does not express streptomycin resistance, a marker which is present in both vectors, presumably because the marker gene is cleaved by EcoRI. A chloramphenicol marker present in pSC194 was used for positive hybrid selection. Hybrid plasmids generated by joining pSC194 with one or more of the four EcoRI fragments of the large (18.1-10(6) daltons) staphylococcal plasmid pI258 were constructed and permitted us to develop a physical map for pI258.     

Specificity of the interactions between the Rep proteins and the origins of replication of Staphylococcus aureus plasmids pT181 and pC221

Summary pT181 and pC221 are closely relatedStaphylococcus aureus plasmids with the same genome organization, which is characterized by the overlapping of the origin of replication with the sequence encoding a protein, Rep, essential for plasmid replication. Former results have shown the lack of in vivo cross-complementation between these two plasmids, while in vitro studies have revealed the ability of both Rep proteins to act on either origin. One possible explanation for this difference was based on a previous analysis of the incompatibility expressed by the origin of replication of these plasmids, showing that the origin embedded in therep gene competes for Rep utilization with the origin of a test plasmid and that changes in the sequence of the origin reduce its ability to compete. To avoid this problem, in the present work special hybrids were constructed in which the origin of replication overlapping therep gene was mutationally inactivated, without changing the amino acid sequence of the encoded protein. The level of Rep expression by these hybrids could be varied by taking advantage of what is presently known about the control of Rep synthesis in plasmid pT181. The results of complenentation studies conducted using these hybrids have shown that: (i) at the usual level of expression for a wild-type plasmid each Rep protein can initiate replication strictly from its corresponding origin; (ii) when overproduced, the pT181 RepC protein could also act efficiently on the pC221 origin; a functional pT181 origin present in the same host completely prevented this complementation; (iii) in excess, the RepD protein encoded by pC221 could replicate a plasmid carrying the pT181 origin but could not ensure the hereditary stability of such a plasmid in the absence of another active replication system; (iv) when overproduced both RepC and RepD could act on the origin of replication of three other related plasmids pS194, pC223 and pUB112.     

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.     

Heterogeneity of chromosomal genes encoding chloramphenicol resistance in streptococci

The DNA of 21 chloramphenicol-resistant plasmid-free streptococci was tested for sequence homology with the genes encoding chloramphenicol acetyltransferase (cat) of the staphylococcal plasmids pC194 and pC221. Homology to the cat gene of pC194 was detected in 11 strains, including the 8 strains of Streptococcus pneumoniae examined, and homology to cat of pC221 was found in 3 strains. The DNA of 7 strains did not detectably hybridize with either probe.     

Studies on the synthesis of plasmid-coded proteins and their control in Bacillus subtilis minicells.

The minicell system of Bacillus subtilis has been used to study the expression of plasmid genes using several R plasmids derived from Staphylococcus aureus. pE194, pC194, and pUB110 as well as several mutant and in vitro recombinant derivatives of these plasmids segregate into minicells. A copy control mutant of pE194 was used to show that the extent of segregation is proportional to the copy number. The polypeptides specified by these plasmids were examined by SDS-polyacrylamide gel electrophoresis. Six proteins specified by pE194, an erythromycin resistance plasmid, were identified using cop mutants. These comprise about 90% of the potential coding capacity of the 2.4-Mdal pE194 plasmid. One of these proteins (29,000 daltons) is inducible by erythromycin in the wild type pE194 but is synthesized constitutively in a mutant derivative which also expresses antibiotic resistance constitutively. Several other proteins are detected only in copy control mutants. pUB110, a kanamycin resistance plasmid, expresses three major proteins which comprise 50% of the coding capacity of this 3.0-Mdal plasmid. Two additional minor proteins are occasionally observed. pC194 (2.0 Mdal), which confers chloramphenicol resistance, expresses two polypeptides comprising about 25% of its coding capacity. One of these polypeptides (22,000 daltons) is inducible by chloramphenicol. pBD9, an in vitro composite of pUB110 and pE194, probably expresses all of the major parental plasmid proteins with the exception of one from pUB110 and one from pE194.     

Nucleotide sequence of pS194, a streptomycin-resistance plasmid from Staphylococcus aureus

pS194 is a naturally occurring Staphylococcus aureus plasmid encoding streptomycin resistance. The plasmid has a copy number of about 25 per cell, and belongs to the inc5 incompatibility group. The nucleotide sequence of pS194 has been determined and consists of 4397 base pairs including four open reading frames potentially encoding proteins of greater than 100 amino acids. All four of these reading frames are on the same coding strand. The first reading frame, repE, encodes a 38 kd protein specifically required for pS194 replication. The second open reading frame, str, encodes a 34 kd polypeptide required for streptomycin resistance, probably a streptomycin adenylyltransferase. The third potential polypeptide, rlx, would be 37 kd and is probably required for relaxation complex formation and plasmid mobilization by conjugative plasmids. The fourth, orfD, overlapping the rlx reading frame, is potentially 27 kd, and may also be involved in mobilization.     

Specific pattern of instability of Escherichia coli HisG gene cloned in Bacillus subtilis via the Staphylococcus aureus plasmid pCS194

The plasmid pCS194, generated in vivo by recombination of two Staphylococcus aureus plasmids, pC194 and pS194, coding, respectively, for chloramphenicol (Cm) and streptomycin (Sm) resistance, can be replicated also in Bacillus subtilis in the presence of either of the two antibiotics. In their absence, no segregation of the individual components is observed, but the whole plasmid is lost at a rate of about 10% per generation. The unique EcoRI site of pCS194 is located in the Sm^R determinant. EcoRI-cleaved pCS194 has been joined to an EcoRI-linearized Escherichia coli replicon, the in vitro recombinant pHisG plasmid, composed of the vector pBR313 plus a BglII-segment of E. coli chromosomal DNA, containing a functional hisG gene. The ligation mixture has been used to transform either E. coli or B. subtilis. Following E. coli transformation and selection for Ap^R and Cm^R (the latter is expressed in E. coli by the pC194 determinant), two his⁺ clones were picked at random and the plasmids extracted. These appear identical and contain the original segments. Conversely, after transformation of B. subtilis and selection for Cm^R, only his^? clones have been obtained. From them, deleted plasmids have been extracted. They have lost part or, more frequently, all of the E. coli DNA insert. In the latter case also most of the bracketing pS194 sequence has been lost, and the resulting plasmids are almost identical to pC194, the Cm^R parent of pCS194. When the intact recombinant plasmids, isolated from his⁺ Ap^R Cm^RE. coli clones, have been used to transform B. subtilis cells for Cm^R, again deleted plasmids almost identical to pC194 have been obtained. The events causing these rearrangements occur after in vitro ligation, during either transformation or early propagation of the plasmids, and are probably caused by a translocatable element present in pCS194. A detailed physical map of pC194, carrying the restriction sites for HindIII, HaeIII, HpaII, MboII, AluI, HhaI, and BglI, is presented.     

Introduction of plasmid pC194 into Bacillus thuringiensis by protoplast transformation and plasmid transfer

The Staphylococcus aureus plasmid pC194 which codes for resistance to chloramphenicol was introduced into six Bacillus thuringiensis strains representing five varieties by protoplast transformation. Six other varieties could not be transformed. pC194 could be identified in transformed strains as autonomous plasmid. The transformed clones contained in addition a new extrachromosomal element of somewhat lower electrophoretic mobility hybridizing with pC194, and pC194 in multimeric forms. pC194 was also transferred from one B. thuringiensis variety to another and from Bacillus thuringiensis to Bacillus subtilis and vice versa by a conjugation-like process, requiring close cell-to-cell contact.Non-standard abbreviations BSA bovine serum albumin - CAT chloramphenicol acetyltransferase - Cm^R chloramphenicol resistant - PAB Penassay broth - SDS sodiumdodecylsulfate - Tc^R tetracycline resistant     

Role of lysogenizing phages in the spread of drug-resistance plasmids in a staphylococcal population

The frequency of the transduction of plasmids rms5, rms7, pT127, pC194, pS194 and pUB101 by phages belonging to serological group B (80, 52, 52A, 53, 85, phi 11, S2) in two systems was compared. In system 1 phages for transduction were obtained from plasmid-containing lysogenic donors in the process of induction with mitomycin C; in system 2 phages for transduction were obtained by their multiplication in plasmid-containing nonlysogenic donors. In system 1 the transduction of plasmids rms5, rms7, pT127, pS194 by phage 52A was found to occur with a greater (by 3-5 orders) frequency than in system 2 (the frequency of transduction was 10(-2) to 10(-4), and 10(-6) to 10(-8) respectively). A similar situation was observed with plasmids rms5 and rms7 and phage 52; plasmid pT127 and phage 53; but not observed with plasmids rms5 and rms7 and phages 80, phi 11 and S2; plasmids pC194 and pS194 and phage 53; plasmid pUB101 and phages 52A, 80 and phi 11; plasmids pC194, pS194 and pT127 and phage 85.