黑暗链霉菌DNA转移系统的建立

研究了黑暗链霉菌的基因转移系统,探索了通过PEG介导的原生质体转化、接合转移向黑暗链霉菌中转入外源DNA的可能性。多次尝试用质粒pIJ702转化黑暗链霉菌9904原生质体均未成功。对原生质体进行“热处理”后转化、利用单链DNA转化等都不能将质粒导入黑暗链霉菌中,表明黑暗链霉菌对外源DNA有很强的限制修饰作用。利用接合转移将具有oriT的大肠杆菌链霉菌穿梭质粒pHZ132转入大肠杆菌ET12567(pUZ8002)中,获得供体菌ET12567(pUZ8002,pHZ132)。将供体菌与预萌发的黑暗链霉菌9904的孢子进行接合转移,成功地将pHZ132转入黑暗链霉菌9904中。质粒pHZ132经黑暗链霉菌自身修饰后也可转入黑暗链霉菌9904菌株的原生质体中,转化率约为103/μg DNA(pHZ132)。     

Conjugative plasmid transfer from Enterococcus faecalis to Escherichia coli.

The possibility of transfer of genetic information by conjugation from gram-positive to gram-negative bacteria was investigated with a pBR322-pAM beta 1 chimeric plasmid, designated pAT191. This shuttle vector, which possesses the tra functions of the streptococcal plasmid pAM beta 1, was conjugatively transferred from Enterococcus faecalis to Escherichia coli with an average frequency of 5 x 10(-9) per donor colony formed after mating.     

IncP plasmids are most effective in mediating conjugation between Escherichia coli and streptomycetes

Mobilizable shuttle plasmids containing the origin of transfer (oriT) region of plasmid F (IncFI), ColIb-P9 (IncI1), and RP4/RP1 (IncPalpha) were constructed to test the ability of the cognate conjugation system to mediate gene transfer from Escherichia coli to Streptomyces. The conjugative system of the IncPalpha plasmids was shown to be most effective in conjugative transfer, giving peak values of (2.7 +/- 0.2) x 10(-2) S. lividans TK24 exconjugants per recipient cell. To assess whether the mating-pair formation system or the DNA-processing apparatus of the IncPalpha plasmids is crucial in conjugative transfer, an assay with an IncQ-based mobilizable plasmid (RSF1010) specifying its own DNA-processing system was developed. Only the IncPalpha plasmid mobilized the construct to S. lividans indicating that the mating-pair formation system is primarly responsible for the promiscuous transfer of the plasmids between E. coli and Streptomyces. Dynamic of conjugative transfer from E. coli to S. lividans was investigated and exconjugants starting from the first hour of mating were obtained.     

Plasmid transfer by conjugation from Escherichia coli to Gram-positive bacteria

Abstract We have developed a vector strategy that allows transfer of plasmid DNA by conjugation from Escherichia coli to various Gram-positive bacteria in which transformation via natural competence has not been demonstrated. The prototype vector constructed, pAT187, contains the origins of replication of pBR322 and of the broad host range streptococcal plasmid pAMβ1, a kanamycin resistance gene known to be expressed in both Gram-negative and Gram-positive bacteria, and the origin of transfer of the IncP plasmid RK2. This shuttle plasmid can be mobilised efficiently by the self-transferable IncP plasmid pRK212.1 co-resident in the E. coli donors, and was successfully transferred by filter matings at frequencies of 2 × 10⁻⁸ to 5 × 10⁻⁷ to Enterococcus faecalis, Streptococcus lactis, Streptococcus agalactiae, Bacillus thuringiensis, Listeria monocytogenes and Staphylococcus aureus .     

Shuttle vectors containing a multiple cloning site and a lacZ alpha gene for conjugal transfer of DNA from Escherichia coli to gram-positive bacteria

The mobilizable shuttle cloning vectors, pAT18 and pAT19, are composed of: (i) the replication origins of pUC and of the broad-host-range enterococcal plasmid pAM beta 1; (ii) an erythromycin-resistance-encoding gene expressed in Gram- and Gram+ bacteria; (iii) the transfer origin of the IncP plasmid RK2; and (iv) the multiple cloning site and the lacZ alpha reporter gene of pUC18 (pAT18) and pUC19 (pAT19). These 6.6-kb plasmids contain ten unique cloning sites that allow screening of derivatives containing DNA inserts by alpha-complementation in Escherichia coli carrying the lacZ delta M15 deletion, and can be efficiently mobilized by self-transferable IncP plasmids co-resident in the E. coli donors. Plasmids pAT18, pAT19 and recombinant derivatives have been successfully transferred by conjugation from E. coli to Bacillus subtilis, Bacillus thuringiensis, Listeria monocytogenes, Enterococcus faecalis, Lactococcus lactis, and Staphylococcus aureus at frequencies ranging from 10(-6) to 10(-9). The presence of a restriction system in the recipient dramatically affects (by three orders of magnitude) the efficiency of conjugal transfer of these vectors from E. coli to Gram+ bacteria.     

Interspecific recombination between Escherichia coli and Salmonella typhimurium occurs by the RecABCD pathway.

Interspecific recombination in conjugation between Escherichia coli and Salmonella typhimurium is several orders of magnitude lower than intraspecies recombination and is dependent on the RecA function. This low efficiency is due to a 20% divergence in the DNA sequence. The methyl-directed (mut H,L,S dependent) mismatch repair system appears to control the fidelity of homologous recombination; inactivating one of the Mut functions increases the interspecies recombination at least by 10(3)-fold. The interspecific recombination in mutS or mutL mutants is only approximately 10-fold lower than recombination in homospecific crosses as found after correction for the efficiency of mating and DNA transfer by zygotic induction experiments. The interspecific recombination is dependent on the RecABCD pathway: it was abolished in a recA mutant and decreased approximately 10(3)-fold in a recC mutant.     

Acceptance and transfer of plasmid Rts1 by bacteria of the genus Erwinia]

The ability of 13 Erwinia strains to accept, to inherit and to transmit the Rts1 factor by conjugation was studied. 11 strains accepted the Rts1 factor from Escherichia coli K-12 CSH-2 with the frequency of about 10(-7)--10(-3). The Rts1 factor was genetically stable in the Erwinia cells and was not eliminated by acriflavine and under the temperature of 37 and 42 degrees C. All the R+ exconjugants were characterized with more high degree of the resistance of kanamycin than E. coli cells harbouring the same R factor. Erwinia strains harbouring the Rts1 plasmid transferred it by conjugation into homologic (Erwinia) and heterologic (E. coli) bacteria. The study of kinetics of the transfer of the Rts1 factor in different mating systems showed that the transfer of this plasmid from R+ Erwinia into R- Erwinia and R- E. coli--in the liquid medium. It is concluded that Erwinia can be the host and the donor of the Rts1 factor.     

Thermosensitive Replication of a Kanamycin Resistance Factor

A strain of Proteus vulgaris isolated from the urinary tract of a patient with postoperative pyelonephritis and resistant to sulfonamide, streptomycin, tetracycline, and kanamycin (KM) was found to transfer only KM resistance by cell-to-cell conjugation. The genetic determinant controlling the transferable KM resistance was considered to be an R factor and was designated R (KM). Successive transfer of KM resistance was demonstrated also from Escherichia coli 20S0, which received the R (KM) factor, to other substrains of E. coli K-12 or Salmonella typhimurium LT-2. The transfer of the R (KM) factor was strongly affected by the temperature at which the mating culture was kept. The transfer frequency of R (KM) at 25 C was about 10(5) times higher than at 37 C. The R (KM) factor was spontaneously eliminated from the host bacterial cells when P. vulgaris was cultured at 42 C, but no elimination occurred at 25 C. This elimination of the R (KM) factor at elevated temperature was also observed when the R (KM) factor infected E. coli and S. typhimurium. On the other hand, a normal R factor could not be eliminated from the same E. coli host strain by cultivation at the higher temperature. We consider the thermosensitive transfer and the spontaneous elimination of the R (KM) factor at higher temperature to depend upon thermosensitive replication of the R (KM) factor.     

Biotic and abiotic factors affecting plasmid transfer in Escherichia coli strains.

The influence of biotic and abiotic factors on plasmid transfer between Escherichia coli strains in terms of the variation in the number of transconjugants formed and the variation in transfer frequency was investigated. The density of parent cells affected the number of transconjugants, reaching a maximum when the cell density was on the order of 10(8) CFU ml-1. As the donor-to-recipient ratios varied from 10(-4) to 10(4), the number of transconjugants varied significantly (P less than 0.001), reaching a maximum with donor-to-recipient ratios between 1 and 10. The concentration of total organic carbon in the mating medium affects both the number of transconjugants and the transfer frequency, being significantly higher (P less than 0.001) when the total organic carbon concentration was higher than 1,139 mg of C liter-1. However, the transconjugants were detected even with less than 1 mg of C liter-1. Linear regression of log10 transconjugants versus mating temperature showed a highly significant regression line (P less than 0.001). Neither the transfer frequency nor the transconjugant number varied significantly in the range of pHs assayed. We can conclude that plasmid transfer by conjugation can take place within a wide range of conditions, even in such adverse conditions as the absence of nutrients and low temperatures.     

Biotic and abiotic factors affecting plasmid transfer in Escherichia coli strains.

The influence of biotic and abiotic factors on plasmid transfer between Escherichia coli strains in terms of the variation in the number of transconjugants formed and the variation in transfer frequency was investigated. The density of parent cells affected the number of transconjugants, reaching a maximum when the cell density was on the order of 10(8) CFU ml-1. As the donor-to-recipient ratios varied from 10(-4) to 10(4), the number of transconjugants varied significantly (P less than 0.001), reaching a maximum with donor-to-recipient ratios between 1 and 10. The concentration of total organic carbon in the mating medium affects both the number of transconjugants and the transfer frequency, being significantly higher (P less than 0.001) when the total organic carbon concentration was higher than 1,139 mg of C liter-1. However, the transconjugants were detected even with less than 1 mg of C liter-1. Linear regression of log10 transconjugants versus mating temperature showed a highly significant regression line (P less than 0.001). Neither the transfer frequency nor the transconjugant number varied significantly in the range of pHs assayed. We can conclude that plasmid transfer by conjugation can take place within a wide range of conditions, even in such adverse conditions as the absence of nutrients and low temperatures.     

Structural and functional stability of IncP plasmids during stepwise transmission by trans-kingdom mating: promiscuous conjugation of Escherichia coli and Saccharomyces cerevisiae

In order to establish a gene transfer system for yeast by promiscuous conjugation, we constructed plasmid pAY101 which contained an oriT sequence derived from RK2 (IncP) and the yeast TRP1 and ARS1 genes. A conjugation mixture consisted of yeast Saccharomyces cerevisiae, E. coli harboring pAY101, and E. coli carrying a helper plasmid with mob and tra. In the conjugation mixture a tryptophan-requiring yeast mutant (trp1) was converted to be prototrophic for tryptophan at a frequency of about 10(-5) to 10(-3) per recipient cell. This E. coli-yeast conjugation system required the mob, tra, oriT, TRP1 and ARS1 genes. The mob and tra genes were trans-acting elements as in an E. coli conjugation system. The mobilization was inhibited by nalidixic acid as in a typical bacterial conjugation. DNA analysis indicated that the plasmid pAY101 was transferred from E. coli to S. cerevisiae, and retained its original structure and function in yeast host cells.     

Influence of lipopolysaccharide and protein in the cell envelope on recipient capacity in conjugation of Salmonella typhimurium.

In crosses of Salmonella typhimurium FfinP301 lac+ to F- strains of S. typhimurium in broth, recipient strains which were rough mutants affected in the outer core region of the lipopolysaccharide gave an average of 1.4 Lac+ transconjugants per donor cell and over 50% of the donor and recipient cells in mating aggregates, whereas smooth recipient strains gave 0.08 Lac+ transconjugants and few cells in mating aggregates. Strains with mutations affecting the inner core of the lipopolysaccharide were usually poor recipients. When cells were mated on Millipore membrane filters, both smooth and rough strains gave ca. 1.0 Lac+ transconjugants per donor cell. Plasmids in Inc groups FI, FII, M, J, and I beta gave more transconjugants with rough than smooth strains, but there were no difference in crosses with plasmids in Inc groups T, L, P, N, and W. Strains with mutations in the ompA gene (deficient in Omp Ap = 33K = II* = conjugation protein) yielded only 0.02 Lac+ transconjugants per donor cell and few cells in mating aggregates. There was no indication of a deficiency of Omp Ap in smooth strains compared with rough strains. Reduced fertility of smooth recipients may occur because the O side chains of the lipopolysaccharide shield the recipient and reduce the frequency of stabilization of mating aggregates. However, gradient-of-transmission experiments indicated that once these mating aggregates are stabilized, they are equally stable in both smooth and rough recipients. Fertility was high in crosses of S. typhimurium Flac+ to Escherichia coli K-12 F- (0.75 Lac+ transconjugants per donor cell; over 50% of the cells in mating aggregates). In crosses of E. coli K-12 Flac+ to S. typhimurium smooth F-, ca. 10(-5) Lac+ transconjugants per donor cell were obtained; in crosses to rough recipient strains, fertility was increased 14-fold, and when the recipient was defective in the SA and LT host restriction systems, fertility was increased in additional 100-fold. Thus, both the lipopolysaccharide and the protein in the cell envelope of S. typhimurium were shown to be important in the recipient function in F-mediated conjugation.     

High efficiency intergeneric conjugal transfer of plasmid DNA from Escherichia coli to methyl DNA-restricting streptomycetes

Many streptomycetes, including S. coelicolor A3(2), possess a potent methyl-specific restriction system which can present an effective barrier to the introduction of heterologous DNA. We have compared the efficiency of intergeneric conjugal transfer of different types of plasmids to S. coelicolor and S. lividans 66 using two E. coli donors: the standard, methylation proficient strain S17-1. and the methylation deficient donor, ET12567(pUB307). We demonstrate that the methylation deficient donor can yield > 10⁴-fold more S. coelicolor exconjugants than the standard donor. In the case of pSET152 derivatives, which integrate into the host chromosome by site-specific recombination, up to 10% of streptomycete spores in the conjugation mixture inherit the plasmid. The conjugation procedure is efficient enough to obtain exconjugants with 'suicide' delivery plasmids and therefore provides a simple route for conducting gene disruptions in methyl DNA-restricting streptomycetes, and possibly other bacteria.     

Intergeneric conjugal gene transfer from Escherichia coli to the sweet potato pathogen Streptomyces ipomoeae

Aims:  To develop an effective gene transfer system for Streptomyces ipomoeae , the causative agent of soil rot disease of sweet potatoes.
Methods and Results:  Of the several methods investigated, introduction of genes into S. ipomoeae could only be achieved using intergeneric conjugation from Escherichia  coli . However, even results for that method varied greatly and were dependent on using particular media for S. ipomoeae spore preparation and conjugation. Transconjugant to recipient ratios as great as 4·1 × 10⁻⁵ were achieved when International Streptomyces Project Medium 4 was used for both sporulation and conjugation protocols. Both site-specifically integrating and autonomously replicating plasmids could be introduced and maintained in S. ipomoeae, and plasmids could be introduced with approximate equivalent frequencies from either methyl-proficient or methyl- deficient E. coli donors; the latter result indicates a likely absence of relevant methyl-specific restriction in S. ipomoeae .
Conclusions:  Efficient transfer of genes into S. ipomoeae was achieved here by using an optimized intergeneric mating procedure.
Significance and Impact of the Study:  The described protocol will facilitate further genetic manipulation of this agriculturally important pathogen.     

Improved method for conjugative transfer by filter mating of Streptococcus pneumoniae.

The frequency of conjugation during filter mating of pneumococcus was increased 10- to 100-fold when the filter was embedded in agar during incubation instead of being on the surface. The major effect was not due to protection from oxygen. The factor of increase was similar for transfer of plasmids and of chromosomal insertions of drug resistance elements.     

Gene transfer system for Rhodopseudomonas viridis.

A gene transfer system for Rhodopseudomonas viridis was established which uses conjugation with Escherichia coli S17-I as the donor and mobilizable plasmids as vectors. Initially, plasmids of the incompatibility group P1 (pRK290 and pRK404) were used. The more effective shuttle vectors between E. coli and R. viridis, pKV1 and pKVS1, were derived from plasmid pBR322 and showed the highest conjugation frequency (10(-2] thus far demonstrated in purple bacteria. It was also demonstrated that Rhizobium meliloti can be used as a donor for conjugation with R. viridis. From a genomic cosmid library of R. viridis constructed in the vector pHC79, clones that coded for subunits H (puh operon), L, M and cytochrome c (puf operon) of the photosynthetic reaction center were isolated and characterized. For linkage of the two operons on the genome, cosmids that overlapped with the operon-carrying clones were identified. The relative positions of the two operons could not be determined, but the operons must be more than 100 kilobase pairs apart. Thus, the genomic organization of the reaction center in R. viridis is different from that of Rhodobacter capsulatus, for which a distance of about 39 kilobase pairs was determined. From a spontaneous mutant of R. viridis that is resistant to the herbicide terbutryn, the puf operon was cloned in pKVS1 and transferred by conjugation into R. viridis wild-type cells. The resulting exconjugants were resistant to the herbicide, which demonstrated that the puf operon on pKVS1 constructions was functionally expressed in R. viridis.     

Transformation using in vivo and in vitro methylation in Streptomyces griseus

Streptomyces griseus does not readily take up foreign DNA isolated from other Streptomyces species or Escherichia coli, presumably due to its unique restriction-modification systems that function as a barrier for interspecific DNA transfer. To efficiently transform S. griseus by avoiding the restriction barriers, we methylated incoming DNA in vivo and in vitro and treated protoplasts with heat prior to transformation. Whereas heat treatment of protoplasts or methylation of the E. coli-Streptomyces shuttle vectors (pXE4 and pKK1443) did not prominently improve the transformation efficiency, HpaII methylation of the vectors from any E. coli strains tested in this study highly increased the transformation efficiency. The highest transformation efficiency was observed when the shuttle vectors were isolated from the dam, hsd strain of E. coli (GM161) and methylated by AluI and HpaII methyltransferases, and the efficiency was approximately the same as that of the vectors from S. griseus. We identified several restriction-modification systems that decrease the transformation efficiency. This research also led us to understand methylation profiles and restriction-modification systems in S. griseus.     

Conservation and transfer of Escherichia coli genetic segments by partial diploid Hfr strains of Salmonella typhosa

Heterozygous, partial diploid hybrids were obtained in a Salmonella typhosa Hfr strain by using it as the recipient in a mating with the Escherichia coli Hfr donor WR2004 (O...proA...leu). Three of these S. typhosa Hfr hybrids were observed to mobilize and transfer the diploid E. coli genes, at high frequencies, to an E. coli recipient. The gradient of transfer frequencies of E. coli markers from these S. typhosa Hfr hybrids was similar to that observed with E. coli Hfr WR2004, from which they were derived. Interrupted matings with one of these S. typhosa Hfr hybrids, designated WR4272, showed the entry times for the proA, thr(-)leu, and argB E. coli diploid markers to be identical to the times obtained for these markers with E. coli Hfr WR2004. Also, the pattern of unselected inheritance of the diploid E. coli markers of S. typhosa Hfr hybrid WR4272 was similar to that observed with the chromosomal markers of E. coli Hfr WR2004. It was concluded that S. typhosa Hfr hybrid WR4272 contains, in addition to its Salmonella genome, a physically continuous E. coli chromosomal segment which is genetically complete from proA to at least the strA locus. The two other S. typhosa Hfr hybrids, on the basis of transmission frequency gradients, appeared to contain a continuous E. coli diploid segment complete from proA through the fuc locus. Other classes of S. typhosa Hfr hybrids, derived from mating with E. coli Hfr WR2010 (O...tna...xyl), were also observed to transfer E. coli genes at high frequency.     

Plasmid associated with diplococcin production in Streptococcus

The ability to produce diplococcin (Dip+) was transferred by conjugation from Streptococcus cremoris 346 to two plasmid-free S. cremoris recipients at a high frequency (10(-1) per donor). Dip+ transconjugants from each mating gained a 54-megadalton plasmid. Spontaneous loss of this plasmid restored the Dip- phenotype.     

Plasmid associated with diplococcin production in Streptococcus.

The ability to produce diplococcin (Dip+) was transferred by conjugation from Streptococcus cremoris 346 to two plasmid-free S. cremoris recipients at a high frequency (10(-1) per donor). Dip+ transconjugants from each mating gained a 54-megadalton plasmid. Spontaneous loss of this plasmid restored the Dip- phenotype.