Linearization of donor DNA during plasmid transformation in Neisseria gonorrhoeae.

We examined the fate of plasmid DNA after uptake during transformation in Neisseria gonorrhoeae. An 11.5-kilobase plasmid, pFA10, was processed to linear double-stranded DNA during uptake by competent cells, but cleavage of pFA10 was not site specific. A minority of pFA10 entered as open circles. A 42-kilobase plasmid, pFA14, was degraded into small fragments during uptake; no intracellular circular forms of pFA14 were evident. Since pFA10 DNA linearized by a restriction enzyme was not further cut during uptake, the endonucleolytic activity associated with entry of plasmid DNA appeared to act preferentially on circular DNA. Although linear plasmid DNA was taken up into a DNase-resistant state as efficiently as circular DNA, linear plasmid DNA transformed much less efficiently than circular plasmid DNA. These data suggest that during entry transforming plasmid DNA often is processed to double-stranded linear molecules; transformants may arise when some molecules are repaired to form circles. Occasional molecules which enter as intact circles may also lead to transformants.     

Electroporation of Haemophilus influenzae is effective for transformation of plasmid but not chromosomal DNA.

Electroporation of plasmid and chromosomal DNAs were tested in Haemophilus influenzae because of an interest in introducing DNA into mutants that are deficient in competence for transformation. The initial experiments were designed to investigate and optimize conditions for electroporation of H. influenzae. Plasmid DNA was introduced into the competence proficient strain Rd and its competence-deficient uptake mutants com-52, com-59, and com-88, and the recombination deficient mutant rec1. Plasmid DNA could also be electroporated into the non-transforming strains Ra, Rc, Re and Rf. Plasmid DNA without sequences that are involved in tight binding (uptake) of DNA by competent cells of H. influenzae Rd was electroporated into both competent and non-competent cells. Competent cells were several orders of magnitude less efficient than non-competent cells for electroporation of plasmid DNAs. Electroporation of H. influenzae chromosomal DNA was not successful. Low levels of integration of chromosomal markers were observed following electroporation and these could be ascribed to transformation. The treatment of cells with DNasel following electroporation separated the effects due to electroporation from those due to transformation. The DNasel treatment did not affect the efficiency of plasmid incorporation, but severely restricted effects due to natural DNA transformation.     

Differential behavior of plasmids containing chromosomal DNA insertions of various sizes during transformation and conjugation in Haemophilus influenzae.

Plasmids with chromosomal insertions were constructed by removal of a 1.1-kilobase-pair piece from the 9.8-kilobase-pair vector plasmid pDM2 by EcoRI digestion and inserting in its place various lengths of chromosomal DNA (1.7, 3.4, and 9.0 kilobase pairs) coding for resistance to novobiocin. A fourth plasmid was constructed by insertion of the largest piece of chromosomal DNA into the SmaI site of pDM2. The plasmids without inserts were taken up poorly by competent cells and thus were considered not to contain specific DNA uptake sites. The presence of even the smallest insert of chromosomal DNA caused a large increase in transformation of Rec+ and Rec- strains. The frequency of plasmid establishment in Rec+ cells by transformation increased exponentially with increasing insert size, but in Rec- cells there was less transformation by the larger plasmids. Conjugal transfer of these plasmids was carried out with the 35-kilobase-pair mobilizing plasmid pHD147. The frequency of establishment of plasmids by this method not only was not markedly affected by the presence of the insertions, but also decreased somewhat with increase in insert size and was independent of rec-1 and rec-2 genes. Recombination between plasmid and chromosome was readily detected after transformation, but could not be detected after transconjugation even when the recipient cells were Rec+ and made competent. These data suggested that there is a special processing of plasmid DNA that enters the competent cells in transformation that makes possible recombination of homologous regions of the plasmid with the chromosome and pairing with the chromosome that aids plasmid establishment.     

Heat sensitivity of Azotobacter vinelandii genetic transformation

Heating competent Azotobacter vinelandii at 37 or 42 degrees C resulted in a total loss of competence with no loss of viability. The transformation process was relatively insensitive to heating at either temperature once DNase-resistant DNA binding was nearly complete. Although competent and 42 degrees C-treated cells bound equivalent amounts of [32P]DNA in a DNase-resistant state, no donor DNA marker (nif) or radioactivity was detected in the envelope-free cell lysate of heated cells, suggesting that DNA transport across the cell envelope was a heat-sensitive event. Competence was reacquired in a 42 degrees C-treated culture after 2 h of incubation at 30 degrees C by a process which required RNA and protein syntheses. The release of a surface glycoprotein, required for competence, from cells treated at 42 degrees C occurred in an insufficient amount to account for the total loss of competence. Recovery of competence in 42 degrees C-treated cells and further transformation of competent cells were prevented by the exposure of cells to saturating amounts of transforming DNA. Further DNase-resistant DNA binding, however, still occurred, suggesting that there were two types of receptors for DNase-resistant DNA binding to competent A. vinelandii. DNase-resistant DNA binding was dependent on magnesium ions, and at least one receptor type did not discriminate against heterologous DNA.     

Marker rescue by a homologous recipient plasmid during transformation of gonococci by a hybrid Pcr plasmid

A 42-kilobase hybrid Pcr plasmid (pFA14) was formed when the naturally occurring 7.2-kilobase Pcr plasmid pFA3 was introduced by transformation into a competent gonococcal recipient containing the 36-kilobase conjugative plasmid pFA2 (Sox et al., J. Bacteriol. 138:510-518). Analysis of the structure of pFA14 showed that it was a stable recombinant between pFA3 and pFA2. The transformation efficiency of pFA14 was increased 300- to 10,000-fold by the presence in isogenic recipients of the homologous plasmid pFA2. The presence of a homologous plasmid in the recipient also markedly increased the likelihood of recovery of intact donor-size Pcr plasmids in the transformants. The presence of pFA2 had no effect on the competence of piliated or nonpiliated gonococci for transformation by either linear chromosomal DNA or a nonhomologous Pcr plasmid. Increased transformation efficiency of the hybrid Pcr plasmid pFA14 may have been due to recombination between the nicked or linearized donor plasmid and the homologous recipient plasmid (marker rescue).     

HP0333, a Member of the dprA Family, Is Involved in Natural Transformation in Helicobacter pylori

Helicobacter pylori is naturally competent for DNA transformation, but the mechanism by which transformation occurs is not known. For Haemophilus influenzae, dprA is required for transformation by chromosomal but not plasmid DNA, and the complete genomic sequence of H. pylori 26695 revealed a dprA homolog (HP0333). Examination of genetic databases indicates that DprA homologs are present in a wide variety of bacterial species. To examine whether HP0333 has a function similar to dprA of H. influenzae, HP0333, present in each of 11 strains studied, was disrupted in two H. pylori isolates. For both mutants, the frequency of transformation by H. pylori chromosomal DNA was markedly reduced, but not eliminated, compared to their wild-type parental strains. Mutation of HP0333 also resulted in a marked decrease in transformation frequency by a shuttle plasmid (pHP1), which differs from the phenotype described in H. influenzae. Complementation of the mutant with HP0333 inserted in trans in the chromosomal ureAB locus completely restored the frequency of transformation to that of the wild-type strain. Thus, while dprA is required for high-frequency transformation, transformation also may occur independently of DprA. The presence of DprA homologs in bacteria known not to be naturally competent suggests a broad function in DNA processing.     

Fate of plasmid DNA in transformation of Bacillus subtilis protoplasts

Summary Polyethylene glycol-treated protoplasts of B. subtilis can be transformed by plasmid DNA at very high frequencies (Chang and Cohen 1979). From analysis of plasmid mediated transformation of transformation-deficient mutants it appeared that mutants, reduced in the transformation by plasmid DNA in the competent state, were plasmid transformation-proficient when transformed as protoplasts. By means of CsCl-gradient centrifugation of re-extracted plasmid DNA it could be demonstrated that plasmid DNA enters the protoplasts in the double-stranded form. In addition, sucrose gradient centrifugation of the re-extracted plasmid DNA showed that the entered DNA is predominantly present as covalently closed circular DNA. The efficiency of plasmid transformation in protoplasts was found to be close to one (each plasmid molecule having entered into the protoplasts gives rise to a transformed cell). This is in good agreement with the observation that little, if any, damage is done to this DNA during or after entry into protoplasts.     

Evidence for Different Pathways during Horizontal Gene Transfer in Competent Bacillus subtilis Cells

Cytological and genetic evidence suggests that the Bacillus subtilis DNA uptake machinery localizes at a single cell pole and takes up single-stranded (ss) DNA. The integration of homologous donor DNA into the recipient chromosome requires RecA, while plasmid establishment, which is independent of RecA, requires at least RecO and RecU. RecA and RecN colocalize at the polar DNA uptake machinery, from which RecA forms filamentous structures, termed threads, in the presence of chromosomal DNA. We show that the transformation of chromosomal and of plasmid DNA follows distinct pathways. In the absence of DNA, RecU accumulated at a single cell pole in competent cells, dependent on RecA. Upon addition of any kind of DNA, RecA formed highly dynamic thread structures, which rapidly grew and shrank, and RecU dissipated from the pole. RecO visibly accumulated at the cell pole only upon addition of plasmid DNA, and, to a lesser degree, of phage DNA, but not of chromosomal DNA. RecO accumulation was weakly influenced by RecN, but not by RecA. RecO annealed ssDNA complexed with SsbA in vitro, independent of any nucleotide cofactor. The DNA end-joining Ku protein was also found to play a role in viral and plasmid transformation. On the other hand, transfection with SPP1 phage DNA required functions from both chromosomal and plasmid transformation pathways. The findings show that competent bacterial cells possess a dynamic DNA recombination machinery that responds in a differential manner depending if entering DNA shows homology with recipient DNA or has self-annealing potential. Transformation with chromosomal DNA only requires RecA, which forms dynamic filamentous structures that may mediate homology search and DNA strand invasion. Establishment of circular plasmid DNA requires accumulation of RecO at the competence pole, most likely mediating single-strand annealing, and RecU, which possibly down-regulates RecA. Transfection with SPP1 viral DNA follows an intermediate route that contains functions from both chromosomal and plasmid transformation pathways.     

Plasmid transformation of naturally competent Acinetobacter calcoaceticus in non-sterile soil extract and groundwater

The natural transformation of Acinetobacter calcoaceticus BD413 (trp E27) was characterized with respect to features that might be important for a possible gene transfer by extracellular DNA in natural environments. Transformation of competent cells with chromosomal DNA (marker trp ⁺) occurred in aqueous solutions of single divalent cations. Uptake of DNA into the DNase I-resistant state but not the binding of DNA to cells was strongly stimulated by divalent cations. An increase of transformation of nearly 3 orders of magnitude was obtained as a response to the presence of 0.25 mM Ca²⁺. With CaCl₂ solutions the transformation frequencies approached the highest values obtained under standard broth conditions, followed by MnCl₂ and MgCl₂. It is concluded that transformation requires divalent cations. DNA competition experiments showed that A. calcoaceticus does not discriminate between homologous and heterologous DNA. Furthermore, circular plasmid DNA competed with chromosomal DNA fragments and vice versa. The equally efficient transformation with plasmid pKT210 isolated from A. calcoaceticus or Escherichia coli indicated absence of DNA restriction in transformation. High efficiency plasmid transformation was obtained in samples of non-sterile natural groundwater and in non-sterile extracts of fresh and air-dried soil. Heat-treatment (10 min, 80°C) of the non-sterile liquid samples increased transformation only in the dried soil extract, probably by inactivation of DNases. The results presented suggest that competent cells of A. calcoaceticus can take up free high molecular weight DNA including plasmids of any source in natural environments such as soil, sediment or groundwater.     

Transformation of competent Bacillus subtilis cells by chromosomal and plasmid DNA incorporated in liposomes

Transformation with chromosomal and plasmid DNAs comprised in liposomes of different compositions was studied on competent cells of Bacillus subtilis. Transformation with chromosomal DNA comprised in liposomes appeared to constitute 1.1 to 1.5% of the control, and transformation with plasmid DNA in liposomes reaches 8 to 11%, as compared to the control. It has been revealed that absorbtion of chromosomal or plasmid DNA comprised in liposomes by competent cells is 1-2 orders higher than that of chromosomal or plasmid DNAs which are not contained in liposomes. Besides, chromosomal DNA in liposomes was found to be transferred to competent cells in the double-stranded form, while during common transformation without liposomes, the DNA transferred is single-stranded.     

Effect of glycerol on plasmid transfer in genetically competent Haemophilus influenzae

Summary The small plasmid pAT4 transformed at characteristically low frequencies those competent Haemophilus influenzae Rd strains that had no DNA homology with this plasmid. Transformation was increased up to 100 times, however, when the recipient cells were exposed to 30% glycerol before plating for transformants. Expression of plasmid resistance markers was then immediate. Ultraviolet irradiation experiments indicated that this large increase was due to release by the glycerol of double-stranded plasmid molecules, presumably from transformasomes. Several other plasmids exhibited the same phenomenon. Dimethylsulfoxide also stimulated plasmid transformation but lysolecithin and high concentrations of NaCl or glucose were ineffective. Glycerol did not increase the efficiency of transformation by either chromosomal DNA or linearized plasmid DNA.     

Natural Transformation of Acinetobacter calcoaceticus by Plasmid DNA Adsorbed on Sand and Groundwater Aquifer Material

It is known that plasmid DNA and linear duplex DNA molecules adsorb to chemically purified mineral grains of sand and to particles of several clay fractions. It seemed desirable to examine whether plasmid DNA would also adsorb to nonpurified mineral materials taken from the environment and, particularly, whether adsorbed plasmid DNA would be available for natural transformation of bacteria. Therefore, microcosms consisting of chemically pure sea sand plus buffered CaCl₂ solution were compared with microcosms consisting of material sampled directly from a groundwater aquifer (GWA) plus groundwater (GW) with respect to the natural transformation of Acinetobacter calcoaceticus by mineral-associated DNA. The GWA minerals were mostly sand with inorganic precipitates and organic material plus minor quantities of silt and clay (illite and kaolinite). The amount of plasmid DNA which adsorbed to GWA (in GW) was about 80% of the amount which adsorbed to purified sand (in buffered CaCl₂ solution). Plasmid DNA adsorbed on sand transformed A. calcoaceticus significantly less efficiently than did plasmid DNA in solution. In contrast, the transformation by sand-adsorbed chromosomal DNA was as high as that by DNA in solution. In GWA/GW microcosms, the efficiency of transformation by chromosomal DNA was similar to that in sand microcosms, whereas plasmid transformation was not detectable. However, plasmid transformants were found at a low frequency when GWA was loaded with both chromosomal and plasmid DNA. Reasons for the low transformation efficiency of plasmid DNA adsorbed to mineral surfaces are discussed. Control experiments showed that the amounts of plasmid and chromosomal DNA desorbing from sand during incubation with a cell-free filtrate of a competent cell suspension did not greatly contribute to transformation in sand microcosms, suggesting that transformation occurred by direct uptake of DNA from the mineral surfaces. Taken together, the observations suggest that plasmid DNA and chromosomal DNA fragments which are adsorbed on mineral surfaces in a sedimentary or soil habitat may be available (although with different efficiencies for the two DNA species) for transformation of a naturally competent gram-negative soil bacterium.     

Repair of plasmid DNA treated with 8-methoxypsoralen and long-wave UV light (lambda=365 nm) in wild type and mutant rad2 cells of Saccharomyces cerevisiae

The method of repeated irradiation has been used to study excision of 8-MOP monoadducts from plasmid and chromosomal DNA in cells of wild type and rad2 mutant of Saccharomyces cerevisiae. The measurement of kinetics of monoadduct removal from chromosomal DNA in intact and competent yeast cells showed that monoadducts were excised in both types of cells with normal repair, but this process was blocked in intact and competent cells of the rad2 mutant. The survival of pYF91 plasmid treated in vitro with 8-MOP plus near UV-light has been studied in the cells of the wild type and in incision-defective rad2 mutant by the measurement of cell transformation frequency. Episomic pYF91 plasmid used in these experiments contained the yeast nuclear LEU2 gene, a portion of 2 mkm DNA and DNA of bacterial plasmid pBR322 with resistance to ampicillin. The pYF91 plasmid was treated with 8-MOP plus near UV-light in vitro, then unbound 8-MOP was removed by dialysis. This DNA was used for transformation. The transformed yeast cells were irradiated repeatedly. The quantitative alteration of the yield of transformants, depending on the time of keeping these yeast cells in complete liquid medium at 30 degrees C, prior to repeated irradiation, allowed to measure the kinetics of monoadduct excision from plasmid DNA. It was shown that monoadducts were removed equally effectively from plasmid DNA introduced into cells of the wild type and rad2 mutant. Possibly, the repair system of both these strains provides excision of monoadducts from plasmid DNA, but this process is blocked in the rad2 mutant, relatively to monoadduct excision from chromosomal DNA.     

Plasmid marker rescue transformation in Bacillus subtilis

We constructed an 18-megadalton plasmid (pBD221) carrying resistance determinants for kanamycin, chloramphenicol, and erythromycin, as well as the hisH determinant from the Bacillus licheniformis chromosome. This plasmid has a copy number of about one and can be stably maintained in Bacillus subtilis. Linear fragments of pBD221 DNA were used to transform competent cultures carrying mutant variants of the same plasmid. Rescue transformation did not proceed by recircularization and replication of the donor DNA. Rescue transformation exhibited first-order dependence on DNA concentration, and the concentration dependence curve was virtually identical to the curve obtained with chromosomal DNA. The donor DNA molecular weight dependence of plasmid marker rescue transformation obtained by using restriction fragments was not distinguishable from previously published data obtained by using fractionated sheared chromosomal DNA. Plasmid rescue transformation, like chromosomal transformation, was dependent on the recE, recA, recB, and recD gene products. Plasmid rescue transformation, like chromosomal transformation, proceeded with few exchanges. Linkage data obtained with the plasmid rescue system fit a quantitative model based on studies with chromosomal transformation. We conclude that plasmid marker rescue transformation probably proceeds by a mechanism similar to the mechanism used during the formation of chromosomal transformants and hence may be considered an appropriate general model for the study of transformational recombination.     

Genetic transformation in bacteria

Certain species of bacteria can become competent to take up high molecular weight DNA from the surrounding medium. DNA homologous to resident chromosomal DNA is transported, processed and recombined with the resident DNA. There are some variations in steps leading to transformation between Gram-positive bacteria likebiplococcus pneumoniae and Gram-negative bacteria represented byHaemophilus influenzae but the integration is by single-strand displacement in both cases. Plasmid (RSF0885) transformation is low inHaemophilus influenzae but this is increased significantly if (homologous) chromosomal DNA is spliced to plasmid DNA. InHaemophilus influenzae, rec1 function is required for peak transformation with chimeric plasmids. Chimeric plasmid fixed presumably extrachromosomally undergoes frequent recombination between homologous segments contained in resident chromosome and the plasmid.     

Species-specific uptake of DNA by gonococci is mediated by a 10-base-pair sequence.

Piliated Neisseria gonorrhoeae are known to be transformed less readily if transforming DNA competes with DNA containing the 10-bp sequence GCCGTCTGAA. It has been postulated that the 10-bp sequence is a recognition sequence which is required for efficient DNA uptake. We show that the presence of various forms of this 10-bp sequence results in increased uptake of double-stranded DNA into a DNase-resistant state and allows genetic transformation by an otherwise nontransformable plasmid.     

Natural plasmid transformation in a high-frequency-of-transformation marine Vibrio strain.

The estuarine bacterium Vibrio strain DI-9 has been shown to be naturally transformable with both broad host range plasmid multimers and homologous chromosomal DNA at average frequencies of 3.5 X 10(-9) and 3.4 X 10(-7) transformants per recipient, respectively. Growth of plasmid transformants in nonselective medium resulted in cured strains that transformed 6 to 42, 857 times more frequently than the parental strain, depending on the type of transforming DNA. These high-frequency-of-transformation (HfT) strains were transformed at frequencies ranging from 1.1 X 10(-8) to 1.3 X 10(-4) transformants per recipient with plasmid DNA and at an average frequency of 8.3 X 10(-5) transformants per recipient with homologous chromosomal DNA. The highest transformation frequencies were observed by using multimers of an R1162 derivative carrying the transposon Tn5 (pQSR50). Probing of total DNA preparations from one of the cured strains demonstrated that no plasmid DNA remained in the cured strains which may have provided homology to the transforming DNA. All transformants and cured strains could be differentiated from the parental strains by colony morphology. DNA binding studies indicated that late-log-phase HfT strains bound [3H]bacteriophage lambda DNA 2.1 times more rapidly than the parental strain. These results suggest that the original plasmid transformation event of strain DI-9 was the result of uptake and expression of plasmid DNA by a competent mutant (HfT strain). Additionally, it was found that a strain of Vibrio parahaemolyticus, USFS 3420, could be naturally transformed with plasmid DNA. Natural plasmid transformation by high-transforming mutants may be a means of plasmid acquisition by natural aquatic bacterial populations.     

Natural plasmid transformation in a high-frequency-of-transformation marine Vibrio strain

The estuarine bacterium Vibrio strain DI-9 has been shown to be naturally transformable with both broad host range plasmid multimers and homologous chromosomal DNA at average frequencies of 3.5 X 10(-9) and 3.4 X 10(-7) transformants per recipient, respectively. Growth of plasmid transformants in nonselective medium resulted in cured strains that transformed 6 to 42, 857 times more frequently than the parental strain, depending on the type of transforming DNA. These high-frequency-of-transformation (HfT) strains were transformed at frequencies ranging from 1.1 X 10(-8) to 1.3 X 10(-4) transformants per recipient with plasmid DNA and at an average frequency of 8.3 X 10(-5) transformants per recipient with homologous chromosomal DNA. The highest transformation frequencies were observed by using multimers of an R1162 derivative carrying the transposon Tn5 (pQSR50). Probing of total DNA preparations from one of the cured strains demonstrated that no plasmid DNA remained in the cured strains which may have provided homology to the transforming DNA. All transformants and cured strains could be differentiated from the parental strains by colony morphology. DNA binding studies indicated that late-log-phase HfT strains bound [3H]bacteriophage lambda DNA 2.1 times more rapidly than the parental strain. These results suggest that the original plasmid transformation event of strain DI-9 was the result of uptake and expression of plasmid DNA by a competent mutant (HfT strain). Additionally, it was found that a strain of Vibrio parahaemolyticus, USFS 3420, could be naturally transformed with plasmid DNA. Natural plasmid transformation by high-transforming mutants may be a means of plasmid acquisition by natural aquatic bacterial populations.     

Transformation ofHaemophilus influenzae following electroporation with plasmid and chromosomal DNA

Naturally transformable species, such asHaemophilus influenzae, have evolved systems for the efficient uptake and integration of DNA from the surrounding environment. We compared this competence-dependent DNA uptake system to electroporation, which has been widely used in the past few years to introduce DNA into cells, for transformingHaemophilus influenzae. Electroporation improved transformation efficiency when noncompetent cells were used and when DNA lackingHaemophilus-specific uptake sequences was used for transformation of competent cells. An increase in plasmid-to-chromosome recombination was seen when plasmid DNA containing chromosomal inserts was introduced into competent cells by electroporation, as observed previously for natural transformation.     

Mutations in Prophage φ11 That Impair the Transducibility of Their Staphylococcus aureus Lysogens for Methicillin Resistance

Methicillin resistance (mec) is not transduced into Staphylococcus aureus 8325-4, but is transduced into this host after it has been lysogenized with phage phi11 and has acquired the penicillinase plasmid pI524 by a separate transduction (Cohen and Sweeney, 1970, 1973). Strain 8325-4 is competent for transformation of typical plasmid or chromosomal markers and for mec only if it is lysogenic for phi11 or a related prophage (Sj?str?m et al., 1974, 1975). A mutant strain of phi11 that was temperature sensitive (Ts) for vegetative multiplication did not mediate competence for transformation of its 8325-4 lysogen if the lysogen had been grown at a nonpermissive temperature (Sj?str?m and Philipson, 1974). We isolated four Ts mutants of phi11 that did not mediate transducibility of their 8325-4(pI524) lysogens for mec after growth at nonpermissive temperatures (40 to 42 degrees C). Transduction of typical plasmid or chromosomal markers was not affected. These phi11-Ts mutants mediated normal competence of their lysogens for transformation of a tetracycline resistance plasmid. Similarly, phi11-Ts mutants that rendered their lysogens temperature sensitive for transformation did not depress the frequency of transduction of mec. These two types of phi11-Ts mutants fell into two different genetic complementation groups that differed in the physiology of deoxyribonucleic acid synthesis and in the time of expression of the mutations during a single-burst growth cycle at a nonpermissive temperature. A virulent mutant of phi11, which plaqued with 100% efficiency on 8325(phi11), also failed to condition strain 8325-4 for transducibility of mec but retained the ability to confer competence for transformation of a tetracycline resistance plasmid. Different genetic loci and physiological functions are involved in phi11 mutations that affect transducibility of mec and those that affect competence for transformation of markers generally in S. aureus 8325-4.