pAMbeta1-Associated Mobilization of Proteinase Plasmids from Lactococcus lactis subsp. lactis UC317 and L. lactis subsp. cremoris UC205

A combination of plasmid curing and DNA-DNA hybridization data facilitated the identification of proteinase plasmids of 75 (pCI301) and 35 kilobases (pCI203) in the multi-plasmid-containing strains Lactococcus lactis subsp. lactis UC317 and L. lactis subsp. cremoris UC205, respectively. Both plasmids were transferred by conjugation to a plasmid-free background only after introduction of the conjugative streptococcal plasmid, pAMbeta1. All Prt transconjugants from matings involving either donor contained enlarged recombinant Prt plasmids. UC317-derived transconjugants were separable into different classes based on the presence of differently sized cointegrate plasmids and on segregation of the pCI301-derived Lac and Prt markers. All UC205-derived transconjugants harbored a single enlarged plasmid that was a cointegrate between pCI203 and pAMbeta1. The identification of prt genes on pCI301 and pCI203 derivatives was achieved by a combination of restriction enzyme and hybridization analyses.     

High copy number plasmid vectors for use in lactic streptococci

Abstract A 3.8 kb DNA fragment from plasmid pBD64 which encoded chloramphenicol and kanamycin resistance genes, but had no replication region, was used as a replicator probe to select for the replication region of the cryptic lactic streptococcal plasmid pSH71 using Bacillus subtilis as host. Three of the resultant recombinant plasmids, pCK1, pCK17 and pCK21 are described. They are vectors in Streptococcus lactis and can be used to clone Bgl II-compatible fragments into their kanamycin resistance gene. All the plasmids have single sites for restriction endonucleases Ava I, Bam HI, Eco RI, Pvu II and Xba I, while plasmids pCK17 and pCK21 have single sites for Cla I.     

Gene transfer in the gastrointestinal tract.

The maximum in vivo transfer rate of plasmid pAMbeta1 in the gut was 0.03 transconjugant per recipient cell, and this rate could be simulated in vitro only by forced filter mating. Transfer was not detected in liquid culture matings. Our findings demonstrate that in vitro methods, such as forced filter mating and liquid mating, underestimate the in vivo rates of gene transfer.     

Chromosomal integration of plasmid DNA by homologous recombination in Enterococcus faecalis and Lactococcus lactis subsp. lactis hosts harboring Tn919.

Integration of pCI192, a pBR322-derived vector plasmid containing homology to the chromosomally located conjugative transposon Tn919 was observed in two strains that harbor Tn919, namely, Enterococcus faecalis GF590 and Lactococcus lactis subsp. lactis CH919. Hybridization analysis indicated that single-copy integration of the plasmid had occurred at low frequency. The Tn919::plasmid structure was conjugated from an E. faecalis donor to a L. lactis recipient, although at lower frequencies than was Tn919. Segregation of the tetracycline and chloramphenicol resistance markers during conjugation was observed. The integration strategy described allows for DNA manipulations to be performed in an easily manipulated model host strain with the subsequent transfer of integrated structures by conjugation to any strain capable of receiving Tn919. The results indicate that homologous recombination events may be used to introduce plasmid-encoded genes to the lactococcal chromosome.     

Plasmid transfer between Bacillus thuringiensis subsp. israelensis strains in laboratory culture, river water, and dipteran larvae

Plasmid transfer between strains of Bacillus thuringiensis subsp. israelensis was studied under a range of environmentally relevant laboratory conditions in vitro, in river water, and in mosquito larvae. Mobilization of pBC16 was detected in vitro at a range of temperatures, pH values, and available water conditions, and the maximum transfer ratio was 10(-3) transconjugant per recipient under optimal conditions. Transfer of conjugative plasmid pXO16::Tn5401 was also detected under this range of conditions. However, a maximum transfer ratio of 1.0 transconjugant per recipient was attained, and every recipient became a transconjugant. In river water, transfer of pBC16 was not detected, probably as a result of the low transfer frequency for this plasmid and the formation of spores by the introduced donor and recipient strains. In contrast, transfer of plasmid pXO16::Tn5401 was detected in water, but at a lower transfer ratio (ca. 10(-2) transconjugant per donor). The number of transconjugants increased over the first 7 days, probably as a result of new transfer events between cells, since growth of both donor and recipient cells in water was not detected. Mobilization of pBC16 was not detected in killed mosquito larvae, but transfer of plasmid pXO16::Tn5401 was evident, with a maximum rate of 10(-3) transconjugant per donor. The reduced transfer rate in insects compared to broth cultures may be accounted for by competition from the background bacterial population present in the mosquito gut and diet or by the maintenance of a large population of B. thuringiensis spores in the insects.     

Chromosomal integration of plasmid DNA by homologous recombination in Enterococcus faecalis and Lactococcus lactis subsp. lactis hosts harboring Tn919.

Integration of pCI192, a pBR322-derived vector plasmid containing homology to the chromosomally located conjugative transposon Tn919 was observed in two strains that harbor Tn919, namely, Enterococcus faecalis GF590 and Lactococcus lactis subsp. lactis CH919. Hybridization analysis indicated that single-copy integration of the plasmid had occurred at low frequency. The Tn919::plasmid structure was conjugated from an E. faecalis donor to a L. lactis recipient, although at lower frequencies than was Tn919. Segregation of the tetracycline and chloramphenicol resistance markers during conjugation was observed. The integration strategy described allows for DNA manipulations to be performed in an easily manipulated model host strain with the subsequent transfer of integrated structures by conjugation to any strain capable of receiving Tn919. The results indicate that homologous recombination events may be used to introduce plasmid-encoded genes to the lactococcal chromosome.     

Plasmid transfer in Pediococcus spp.: intergeneric and intrageneric transfer of pIP501

Transfer of the broad-host-range resistance plasmid pIP501 from Streptococcus faecalis to Pediococcus pentosaceus and Pediococcus acidilactici occurred between cells immobilized on nitrocellulose filters in the presence of DNase. Expression of the pIP501-linked erythromycin and chloramphenicol resistance determinants was observed in transconjugants. Intrageneric transfer of pIP501 from a P. pentosaceus donor to various pediococcal recipients occurred at frequencies of 10(-4) to 10(-7) transconjugants per input donor cell. Intergeneric transfer of plasmid pIP501 from P. pentosaceus to S. faecalis, Streptococcus sanguis (Challis), and Streptococcus lactis was observed. Similar mating experiments showed no evidence for the transfer of the broad-host-range R-plasmid pAM beta 1 to Pediococcus spp. recipients.     

Plasmid transfer in Pediococcus spp.: intergeneric and intrageneric transfer of pIP501.

Transfer of the broad-host-range resistance plasmid pIP501 from Streptococcus faecalis to Pediococcus pentosaceus and Pediococcus acidilactici occurred between cells immobilized on nitrocellulose filters in the presence of DNase. Expression of the pIP501-linked erythromycin and chloramphenicol resistance determinants was observed in transconjugants. Intrageneric transfer of pIP501 from a P. pentosaceus donor to various pediococcal recipients occurred at frequencies of 10(-4) to 10(-7) transconjugants per input donor cell. Intergeneric transfer of plasmid pIP501 from P. pentosaceus to S. faecalis, Streptococcus sanguis (Challis), and Streptococcus lactis was observed. Similar mating experiments showed no evidence for the transfer of the broad-host-range R-plasmid pAM beta 1 to Pediococcus spp. recipients.     

Improved cloning vectors and transformation procedure for Lactococcus lactis

Four shuttle vectors (pMIG 1, 2, 2H and 3) have been constructed based on the broad host-range plasmid pCK1. All the pMIG vectors possess a multiple cloning site containing 12 or more unique restriction enzyme sites, and are stably maintained at either high or low copy number in Lactococcus lactis and in Escherichia coli. By cloning the E. coli pUC replicon into one of these vectors a plasmid was constructed which can replicate to high copy number in recA strains of E. coli. The broad host-range of the pCK1 replicon may enable these cloning vectors to be used in a number of Gram-positive bacteria. One of these vectors was used to optimize an electroporation procedure for transformation of a commonly used plasmid-cured strain MGI363 of L. lactis which routinely yielded 1 times 10⁷ to 5 times 10⁷ transformants μg^-1 supercoiled DNA using stored, snap-frozen cells. This transformation efficiency was obtained by growing the cells in medium containing the cell wall weakening agent glycine, to an upper limit of 2·5% w.v. Although growth of L. lactis strain MGI363 was inhibited by the use of 0·5 mol 1^-1 sucrose as an osmotic stabilizer, the presence of sucrose in the electroporation buffer was critical for high transformation efficiency. Other variables which were tested for their effect on the efficiency of transformation were cell concentration, DNA concentration, pulse time and field strength. These results provide a model procedure which can be followed to optimize conditions for the genetic transformation of various strains of L. lactis.     

Genetic construction of nisin-producing Lactococcus lactis subsp. cremoris and analysis of a rapid method for conjugation.

Conjugation was used to construct nisin-producing Lactococcus lactis subsp. cremoris strains. Recipients were obtained by electroporation of L. lactis subsp. cremoris strains with the drug resistance plasmid pGK13 or pGB301. A method, direct-plate conjugation, was developed in which donor and recipient cells were concentrated and then combined directly on selective media. This method facilitated transfer of the nisin-sucrose (Nip+ Suc+) phenotype from the donor strain, L. lactis subsp. lactis 11454, to three L. lactis subsp. cremoris recipient strains. Nip+ Suc+ L. lactis subsp. cremoris transconjugants were obtained at frequencies which ranged from 10(-7) to 10(-8) per donor CFU. DNA-DNA hybridization to transconjugant DNAs, performed with an oligonucleotide probe synthesized to detect the nisin precursor gene, showed that this gene was transferred during conjugation but was not associated with detectable plasmid DNA. Further investigation indicated that L. lactis subsp. cremoris Nip+ Suc+ transconjugants retained the recipient strain phenotype with respect to bacteriophage resistance and acid production in milk. Results suggested that it would be feasible to construct nisin-producing L. lactis subsp. cremoris strains for application as mixed and multiple starter systems. Additionally, the direct-plate conjugation method required less time than filter or milk agar matings and may also be useful for investigations of conjugal mechanisms in these organisms.     

High-frequency conjugation system facilitates biofilm formation and pAMbeta1 transmission by Lactococcus lactis

The importance of conjugation as a mechanism to spread biofilm determinants among microbial populations was illustrated with the gram-positive bacterium Lactococcus lactis. Conjugation triggered the enhanced expression of the clumping protein CluA, which is a main biofilm attribute in lactococci. Clumping transconjugants further transmitted the biofilm-forming elements among the lactococcal population at a much higher frequency than the parental non-clumping donor. This cell-clumping-associated high-frequency conjugation system also appeared to serve as an internal enhancer facilitating the dissemination of the broad-host-range drug resistance gene-encoding plasmid pAMbeta1 within L. lactis, at frequencies more than 10,000 times higher than those for the non-clumping parental donor strain. The implications of this finding for antibiotic resistance gene dissemination are discussed.     

Genetic construction of nisin-producing Lactococcus lactis subsp. cremoris and analysis of a rapid method for conjugation

Conjugation was used to construct nisin-producing Lactococcus lactis subsp. cremoris strains. Recipients were obtained by electroporation of L. lactis subsp. cremoris strains with the drug resistance plasmid pGK13 or pGB301. A method, direct-plate conjugation, was developed in which donor and recipient cells were concentrated and then combined directly on selective media. This method facilitated transfer of the nisin-sucrose (Nip+ Suc+) phenotype from the donor strain, L. lactis subsp. lactis 11454, to three L. lactis subsp. cremoris recipient strains. Nip+ Suc+ L. lactis subsp. cremoris transconjugants were obtained at frequencies which ranged from 10(-7) to 10(-8) per donor CFU. DNA-DNA hybridization to transconjugant DNAs, performed with an oligonucleotide probe synthesized to detect the nisin precursor gene, showed that this gene was transferred during conjugation but was not associated with detectable plasmid DNA. Further investigation indicated that L. lactis subsp. cremoris Nip+ Suc+ transconjugants retained the recipient strain phenotype with respect to bacteriophage resistance and acid production in milk. Results suggested that it would be feasible to construct nisin-producing L. lactis subsp. cremoris strains for application as mixed and multiple starter systems. Additionally, the direct-plate conjugation method required less time than filter or milk agar matings and may also be useful for investigations of conjugal mechanisms in these organisms.     

Linear plasmidlike DNA in the plant pathogenic fungus Fusarium oxysporum f. sp. conglutinans.

Double-stranded, 1.9-kilobase-pair (kbp) DNA molecules were found in 18 strains representing three pathogenic races of Fusarium oxysporum f. sp. conglutinans. The DNA element (pFOXC1) from a race 1 strain and the DNA element (pFOXC2) from a race 2 strain were shown by restriction endonuclease mapping to be linear. pFOXC2 was found in mitochondrial preparations and appears to have blocked 5' termini, as it was sensitive to 3'----5' exonuclease III but insensitive to 5'----3' lambda exonuclease. The major 1.8-kbp BglII restriction endonuclease fragment of pFOXC2 was cloned in plasmid pUC12. The recombinant plasmid (pCK1) was not homologous to the mitochondrial or nuclear genomes from F. oxysporum f. sp. conglutinans. This suggests that pFOXC2 is self-replicating. pCK1 was homologous to all 1.9-kbp DNA elements of race 2 but was not homologous to those of race 1 or race 5. All race 1 and 5 elements were also shown to share common DNA sequences.     

Conjugal plasmid transfer between lactococci on solid surface matings and during cheese making

Abstract The concept of deliberate use of genetically enginereed microorganisms in dairy products requires a clear understanding of their behaviour and of the dissemination of introduced DNA in these strains. Thus, transfer of a self-transmissible plasmid and a non-self-transmissible but mobilizable plasmid from an engineered strain of Lactococcus lactis subsp. lactis IL 1403 to wild-type strains of L. lactis subsp. lactis and subsp. cremoris of technological interest was studied on standard solid surface matings and in cheese during manufacture. On solid surface matings, transfer of the conjugative plasmid occurred at frequencies ranging from < 2.3 × 10⁻⁹ to 2.8 × 10⁻⁴. Mobilization of the non-conjugative plasmid was observed at a lower frequency (ca. 10⁻⁵) in only one recipient which was then selected along with another recipient strain (presenting intermediate transfer frequencies) for making Camembert cheese. During cheese making, only the transfer of the self-transmissible plasmid was observed. It occurred in the early stages of manufacturing. The transfer frequencies were 7.0 × 10⁻⁸ or 7.6 × 10⁻¹ 1, depending upon the recipient strain. These were about 3 to 4 orders of magnitude lower than on solid surface matings. Mobilization of the non-conjugative plasmid was never detected in cheese.     

Conjugal Transfer of Lactose-Fermenting Ability Among Streptococcus cremoris and Streptococcus lactis Strains

Streptococcus cremoris C3 was found to transfer lactose-fermenting ability to LM2301, a Streptococcus lactis C2 lactose-negative streptomycin-resistant (Lac⁻ Str^r) derivative which is devoid of plasmid deoxyribonucleic acid (DNA); to LM3302, a Lac⁻ erythromycin-resistant (Ery^r) derivative of S. lactis ML3; and to BC102, an S. cremoris B₁ Lac⁻ Ery^r derivative which is devoid of plasmid DNA. S. cremoris strains R1, EB₇, and Z8 were able to transfer lactose-fermenting ability to LM3302 in solid-surface matings. Transduction and transformation were ruled out as mechanisms of genetic transfer. Chloroform treatment of donor cells prevented the appearance of recombinant clones, indicating that viable cell-to-cell contact was responsible for genetic transfer. Transfer of plasmid DNA was confirmed by agarose gel electrophoresis. Transconjugants recovered from EB₇ and Z8 matings with LM3302 exhibited plasmid sizes not observed in the donor strains. Transconjugants recovered from R1, EB₇, and Z8 matings with LM3302 were able to donate lactose-fermenting ability at a high frequency to LM2301. In S. cremoris R1, EB₇, and Z8 matings with LM2301, streptomycin resistance was transferred from LM2301 to the S. cremoris strains. The results confirm genetic transfer resembling conjugation between S. cremoris and S. lactis strains and present presumptive evidence for plasmid linkage of lactose metabolism in S. cremoris.     

Transfer of plasmid-mediated antibiotic resistance from streptococci to lactobacilli.

The transmissible plasmid pAMbeta1, which codes for erythromycin and lincomycin resistance, was conjugally transferred from a Lancefield group F Streptococcus to a strain of Streptococcus avium. Both organisms served as pAMbeta1 donors for three strains of Lactobacillus casei. Introduction of pAMbeta1 into one of the L. casei strains caused the organism to lose its native 6.7 X 10(6)-dalton plasmid. Loss of the native plasmid produced no alterations in the organism's growth characteristics or fermentation pattern.     

Partial characterization of the genetic basis for sucrose metabolism and nisin production in Streptococcus lactis

We attempted to identify the genetic loci for sucrose-fermenting ability (Suc+), nisin-producing ability (Nip+), and nisin resistance (Nisr) in certain strains of Streptococcus lactis. To obtain genetic evidence linking the Suc+ Nip+ Nisr phenotype to a distinct plasmid, both conjugal transfer and transformation were attempted. A conjugation procedure modified to protect the recipients against the inhibitory action of nisin allowed the conjugal transfer of the Suc+ Nip+ Nisr marker from three Suc+ Nip+ Nisr donors to various recipients. The frequency of transfer ranged from 1.7 x 10(-4) to 5.6 x 10(-8) per input donor, depending on the mating pair. However, no additional plasmid DNA was apparent in these transconjugants. Transformation of S. lactis LM0230 to the Suc+ Nip+ Nisr phenotype by using the plasmid pool of S. lactis ATCC 11454 was not achieved, even though other plasmids present in the pool were successfully transferred. However, two results imply the involvement of plasmid DNA in coding for the Suc+ Nip+ Nisr phenotype. The Suc+ Nip+ Nisr marker was capable of conjugal transfer to a recipient deficient in host-mediated homologous recombination (Rec-), and the Suc+ Nip+ Nisr marker exhibited bilateral plasmid incompatibility with a number of lactose plasmids found in S. lactis. Although our results indicate that the Suc+ Nip+ Nisr phenotype is plasmid encoded, no physical evidence linking this phenotype to a distinct plasmid was obtained.     

Partial characterization of the genetic basis for sucrose metabolism and nisin production in Streptococcus lactis.

We attempted to identify the genetic loci for sucrose-fermenting ability (Suc+), nisin-producing ability (Nip+), and nisin resistance (Nisr) in certain strains of Streptococcus lactis. To obtain genetic evidence linking the Suc+ Nip+ Nisr phenotype to a distinct plasmid, both conjugal transfer and transformation were attempted. A conjugation procedure modified to protect the recipients against the inhibitory action of nisin allowed the conjugal transfer of the Suc+ Nip+ Nisr marker from three Suc+ Nip+ Nisr donors to various recipients. The frequency of transfer ranged from 1.7 x 10(-4) to 5.6 x 10(-8) per input donor, depending on the mating pair. However, no additional plasmid DNA was apparent in these transconjugants. Transformation of S. lactis LM0230 to the Suc+ Nip+ Nisr phenotype by using the plasmid pool of S. lactis ATCC 11454 was not achieved, even though other plasmids present in the pool were successfully transferred. However, two results imply the involvement of plasmid DNA in coding for the Suc+ Nip+ Nisr phenotype. The Suc+ Nip+ Nisr marker was capable of conjugal transfer to a recipient deficient in host-mediated homologous recombination (Rec-), and the Suc+ Nip+ Nisr marker exhibited bilateral plasmid incompatibility with a number of lactose plasmids found in S. lactis. Although our results indicate that the Suc+ Nip+ Nisr phenotype is plasmid encoded, no physical evidence linking this phenotype to a distinct plasmid was obtained.     

Effect of growth phase and parental cell survival in river water on plasmid transfer between Escherichia coli strains.

We evaluated the transfer to and from Escherichia coli of endogenously isolated plasmid material from the River Butrón during the growth of three donor strains and two recipient strains as well as after the survival of these parental cells in river water. Transfer frequency varied greatly during the growth of donor cells, with minimum values in the exponential phase; frequency remained constant, however, during the growth of recipient strains. After survival in river water, donor cells lost their ability for plasmid transfer before any other physiological variations in the cells caused by environmental stress were detected. Under the same conditions and during equal periods, however, no variation in the ability of recipient cells to receive and express plasmid material was observed.     

Identification of a new gene (secA) and gene product involved in the secretion of envelope proteins in Escherichia coli

Bacteroides fragilis TMP10, which is clindamycin-erythromycin resistant (Clnr) and tetracycline resistant (Tetr), contains several plasmids and is capable of transferring drug resistance markers to suitable recipients. We were able to separate a 14.6-kilobase self-transmissible Clnr plasmid, pBFTM10, from the other plasmids of TMP10 in a tetracycline-sensitive recipient strain, B. fragilis TM4000. All Clnr transconjugants acquired an unaltered pBFTM10 and became plasmid donor strains. Transfer is proposed to occur by conjugation since it required to cell-to-cell contact of filter matings and was insensitive to DNase, but sensitive to chloroform treatment of donor cells. The efficiency of transfer of pBFTM10 in a Tets background (TM4003) was not affected by pretreatment of donor cells with clindamycin. A spontaneously occurring Clns derivative, pBFTM10 delta 1, suffered a deletion of DNA, which included a 4.4-kilobase EcoRI fragment. A complex interaction between the autonomous plasmid pBFTM10 and a tetracycline transfer element also present in strain TMP10 was observed since pretreatment of this donor with tetracycline or clindamycin resulted in a marked increase in transfer of both tetracycline and clindamycin resistance.