Conjugational transfer of genes determining plant virulence in Erwinia amylovora.

A stable virulent donor strain (EA 178R1-99) of Erwinia amylovora can transfer, by conjugation during a 3-h mating period, the gene or genes which determine(s) plant virulence to avirulent recipient strains (EA178-M64S1 and EA178-M173S1) of Escherichia amylovora. The virulence of over 200 recombinant clones was tested; they all were as virulent on immature Bartlett pear fruits (and, in the smaller series of strains tested, also, on Pyracantha twigs) as was the parent donor strain. Although the avirulent recipeint strains are amino acid auxotrophs, addition of the required amino acids to the inocula in plant virulence trials does not of itself restore virulence. Two small series of prototrophic revertant clones were selected from the auxotrophic avirulent recipient strains; only nine of the 21 prototrophic revertant clones regained virulence, whereas the other 12 prototrophic revertant clones remained avirulent, again suggesting a lack of parallelism between nutritional status and virulence in this system. Preliminary interrupted mating trials, carried out at 15-min intervals over 3 h, show that ser is transferred during the first 15 min, that pro starts entering at about 75 min (and with a higher frequency later), and that lac (originating from an integrated Escherichia coli F'lac) enters toward the end of the 3-h mating period and at a reduced frequency compared to the other markers. The gene or genes which determine(s) plant virulence in this Escherichia amylovora donor strain appear(s) to be transferred readily and seemingly completely to recipient strains during the first 15 min of a 3-h mating period. Exposure of the virulent donor strain to acridine orange or ethidium bromide does not result in loss of virulence, suggesting (but, of course, not proving conclusively) that the determinant(s) of virulence in Escherichia amylovora might be chromosomal rather than extrachromosomal.     

Isolation and characterization of Hfr strains of Erwinia amylovora

Hfr strains (Hfr 159 and its derivatives, Hfr 160 and Hfr 161) were constructed from Erwinia amylovora ICPB EA178 by introducing an Escherichia coli F'his+ plasmid and then selecting for integration of F'his+ after treatment with acridine orange. The Hfr strains were relatively stable upon repeated transfers on nonselective media. Interrupted mating experiments and analyses of inheritance of unselected markers showed that his+ is transferred by Hfr 159 as the proximal marker at a relatively high frequency (about 5 x 10(-4) recombinants per input donor cell), followed by ilv+, orn+, arg+, pro+, rbs+, met+, trp+, leu+, ser+, and thr+ (not necessarily in that precise order). The donor strains, previously constructed in E. amylovora by integration of F'lac+ from E. coli transfer cys+ as the proximal marker followed by ser+. Further analysis of one of those earlier donor strains, Hfr99, showed that ser+ is followed by arg+, orn+, met+, pro+, leu+, ilv+, rbs+, his+, trp+, and thr+ (not necessarily in that precise order). Thus, the Hfr strains constructed by integration of F'his+ are different, in terms of origin and direction of transfer, from those derived from integration of F'lac+. The applicability of these Hfr strains to mapping the genes on the E. amylovora chromosome is indicated.     

Conjugative Transfer of Chromosomal Genes between Fluorescent Pseudomonads in the Rhizosphere of Wheat

Bacteria released in large numbers for biocontrol or bioremediation purposes might exchange genes with other microorganisms. Two model systems were designed to investigate the likelihood of such an exchange and some factors which govern the conjugative exchange of chromosomal genes between root-colonizing pseudomonads in the rhizosphere of wheat. The first model consisted of the biocontrol strain CHA0 of Pseudomonas fluorescens and transposon-facilitated recombination (Tfr). A conjugative IncP plasmid loaded with transposon Tn5, in a CHA0 derivative carrying a chromosomal Tn5 insertion, promoted chromosome transfer to auxotrophic CHA0 recipients in vitro. A chromosomal marker (pro) was transferred at a frequency of about 10(sup-6) per donor on wheat roots under gnotobiotic conditions, provided that the Tfr donor and recipient populations each contained 10(sup6) to 10(sup7) CFU per g of root. In contrast, no conjugative gene transfer was detected in soil, illustrating that the root surface stimulates conjugation. The second model system was based on the genetically well-characterized strain PAO of Pseudomonas aeruginosa and the chromosome mobilizing IncP plasmid R68.45. Although originally isolated from a human wound, strain PAO1 was found to be an excellent root colonizer, even under natural, nonsterile conditions. Matings between an auxotrophic R68.45 donor and auxotrophic recipients produced prototrophic chromosomal recombinants at 10(sup-4) to 10(sup-5) per donor on wheat roots in artificial soil under gnotobiotic conditions and at about 10(sup-6) per donor on wheat roots in natural, nonsterile soil microcosms after 2 weeks of incubation. The frequencies of chromosomal recombinants were as high as or higher than the frequencies of R68.45 transconjugants, reflecting mainly the selective growth advantage of the prototrophic recombinants over the auxotrophic parental strains in the rhizosphere. Although under field conditions the formation of chromosomal recombinants is expected to be reduced by several factors, we conclude that chromosomal genes, whether present naturally or introduced by genetic modification, may be transmissible between rhizosphere bacteria.     

Mechanism of conjugation and recombination in bacteria. XXI. Role of F factor genes in post-conjugational recombination in Escherichia coli K-12

Temperature sensitive dnaA recipient crossed at the restrictive temperature with HfrH, free from contaminating F+ cells, forms recombinants almost as proficiently as at the permissive temperature. The merozygotes are able to synthesize DNA at 42 degrees C, although the recipient and donor cells do not incorporate 3H-thymine. A substantial fraction of Lac+ recombinants, irrespective of the mating temperature, is temperature resistant (42 C-R); 15% from among those mated at 35 C and 30% from those mated at 42 C. The presence of dnaA mutation in these Lac+ 42 C-R recombinants was ascertained by co-transduction with ilv. Cell division at 42 C is inhibited in the Lac 42 C-R recombinants by acridine orange. The presence of F factor DNA in these recombinants was demonstrated directly by DNA: DNA hybridization. Suppression of dnaA mutation in Lac+ 42 degrees C-R recombinants and their sensitivity to acridine orange at 42 degrees C suggests that at least part of the F factor is integrated into the recombinant chromosome. A large fraction of the Lac+ 42 degrees C-R recombinants (up to 80%) is sensitive to male phage R17 and fertile. In crosses with HfrC there is a marked decrease of recombination frequency at 42 degrees C in the dnaA recipient. The fraction of Lac+ 42 degrees C-R recombinants is low (up to 10%) and the 42 degrees C-R recombinants are neither sensitive to male phage nor fertile. The results are discussed on the basis of the previously proposed model of post-conjugational recombination.     

Genetic Transfer of Episomic Elements Among Erwinia Species and Other Enterobacteria: F′lac+

The episomic element F'lac(+) was transferred, probably by conjugation, from Escherichia coli to Lac(-) strains of Erwinia herbicola, Erwinia amylovora, and Erwinia chrysanthemi (but not to several other Erwinia spp. In preliminary trials). The lac genes in the exconjugants of the Erwinia spp. showed varying degrees of stability depending on the strain (stable in E. herbicola strains Y46 and Y74 and E. amylovora strain EA178, but markedly unstable in E. chrysanthemi strain EC16). The lac genes and the sex factor (F) were eliminated from the exconjugants by treatment with acridine orange, thus suggesting that both lac and F are not integrated in the Erwinia exconjugants. All of the tested Lac(+) exconjugants of E. herbicola strains Y46 and Y74 and E. amylovora strain EA178, but not of E. chrysanthemi strain EC 16, were sensitive to the F-specific phage M13. The heterogenotes (which harbored F'lac(+)) of E. herbicola strains Y46 and Y74, E. amylovora strain EA178, and E. chrysanthemi strain EC16 were able to transfer lac genes by conjugation to strains of E. herbicola, E. amylovora, E. chrysanthemi, Escherichia coli, and Shigella dysenteriae. The frequency of such transfer from Lac(+) exconjugants of Erwinia spp. was comparable to that achieved by using E. coli F'lac(+) as donors, thus indicating the stability, expression, and restriction-and-modification properties of the sex factor (F) in Erwinia spp.     

Patterns of mobilization of the Proteus mirabilis chromosome by R plasmids.

R plasmids R40a, Rip69, R447b, R769 belonging to incompatibility groups A-C, M, N, V, respectively, were investigated for chromosomal mobilizing ability in Proteus mirabilis. Plasmids R40a, Rip69 and R447b mediated polarized transfer of markers in a clockwise direction from origins near tyr-1, metF and ser-2, respectively, on the linkage map. The recovery frequency per donor cell of proximal markers approached 1 x 10(-4) for these three plasmids and the efficiency of chromosomal transfer was higher than that of the previously studied plasmid D. The plasmid-guided chromosomal trajectories overlap and it was possible to complement results obtained with plasmid D to assemble a time-of-entry chromosomal map and directly establish the circularity of the linkage group. The map comprises a length of 93 min in terms of transfer time. Plasmid R769 had a different pattern of chromosome transfer. This plasmid produced recombinants for all markers at frequencies of about 4 x 10(-6) per donor. It effected multiple and more or less simultaneous entry of markers and produced recombination over lengths of chromosome rarely corresponding to more than 10 min on the linkage map.     

Mobilization of the Proteus mirabilis chromosome by R plasmid R772.

The P-1 incompatibility group plasmid R772 can mobilize the chromosome of Proteus mirabilis strain PM5006. The decreasing gradient of recombinant recovery frequencies found for markers which were increasingly distal to 0 min with plasmid D donors was not found with R772. Instead, it produced recombinants for all markers at frequencies of about 5 X 10(-5) per donor. This is about 10-fold lower than the plasmid transfer frequency. Recombinants were stable and recombination was only detected over short segments of the chromosome which corresponded to about 10 min on the D plasmid map of the chromosome. All recombinants had inherited R772 and expressed all properties of the plasmid. Attempts to isolate variant plasmids with increased frequencies of recombinant formation were unsuccessful.     

Conjugational transfer systems of Rhodopseudomonas capsulata mediated by R plasmids

Plasmids RP1, R68.45 and RP4::Mu cts 61 were transferred into Rhodopseudomonas capsulata from Escherichia coli. The frequency of intraspecies transfer of these plasmids in R. capsulata was 10^-4–10^-5 per donor. The plasmids also mobilized chromosomal genes at a low frequency. Phototrophic recombinants from matings between recipient strains defective in the photosynthetic-apparatus and wild type donors were obtained at a frequency of 10^-7–10^-8 per donor.     

Isolation of a hybrid F' factor-carrying Escherichia coli lactose region and Salmonella typhimurium histidine region, F42-400 (F' ts114 lac+, his+): its partial characterization and behavior in Salmonella typhimurium.

Episome F' ts114 lac+ (F42-114) was transferred into Salmonella typhimurium carrying an F'his+ (FS400) episome, and fused episome F' ts114 lac+, his+ (F42-400) was obtained. Episome F42-400 could be transferred to S. typhimurium, Escherichia coli and Klebsiella pneumoniae. Identification of the episome was based on: (i) temperature sensitivity of the Lac+ and His+ phenotypes; (ii) the fact that F- segregants, obtained after temperature curing or acridine orange curing, were simultaneously Lac- and His-; and (iii) linkage of lac+ with his+ in episomal transfers to E. coli and S. typhimurium. The frequency of episome transfer was influenced by the genotype of the donor. Plasmid LT2, prevalent in S. typhimurium LT2 strains, was suggested to be responsible for the low fertility of S. typhimurium donors. Episome F42-400 was capable of chromosome mobilization, and the extent of chromosome mobilization was not influenced by the presence or absence of the histidine region on the donor chromosome. Growth in a defined medium with acridine orange was able to cure F42-400. The frequency of curing was increased (the frequency of His+ cells was 0.0001%) if the cells were grown at 40 C in the presence of acridine orange. Selection for temperature-resistant Lac+, His+ derivatives in a strain without histidine deletion yielded Hfr strains. However, similar and stronger selections in strains without the chromosomal histidine region failed to yield Hfr strains. Our inability to obtain Hfr's in strains without the chromosomal histidine region was explained by assuming that the episome F42-400 has lost the F sites involved in integration into the S. typhimurium chromosome.     

Chromosomal mapping in Erwinia carotovora subsp. carotovora with the IncP plasmid R68::Mu.

Conjugational gene transfer was established in Erwinia carotovora subsp. carotovora SCRI193 by using plasmid R68::Mu c+ to mobilize the chromosome into multiply mutant recipients. It was observed that although the plasmid alone mobilized markers randomly at a frequency of ca. 10(-5) chromosomal recombinants per donor, the presence of a Mu prophage on the chromosome of the donor increased the frequency of mobilization of markers adjacent to the prophage by up to 10-fold. Using this system it was possible to order 17 chromosomal mutations. The behavior of Mu in E. carotovora subsp. carotovora was also studied.     

Cysteine biosynthesis in Saccharomyces cerevisiae: mutation that confers cystathionine beta-synthase deficiency.

The cys2-1 mutation of Saccharomyces cerevisiae was originally thought to confer cysteine dependence through a serine O-acetyltransferase deficiency. In this study, we show that cys2-1 strains lack not only serine O-acetyltransferase but also cystathionine beta-synthase. However, a prototrophic strain was found to be serine O-acetyltransferase deficient because of a mutation allelic to cys2-1. Moreover, revertants obtained from cys2-1 strains had serine O-acetyltransferase but not cystathionine beta-synthase, whereas transformants obtained by treating a cys2-1 strain with an S. cerevisiae genomic library had cystathionine beta-synthase but not serine O-acetyltransferase. From these observations, we conclude that cys2-1 (serine O-acetyltransferase deficiency) accompanies a very closely linked mutation that causes cystathionine beta-synthase deficiency and that these mutations together confer cysteine dependence. This newly identified mutation is named cys4-1. These results not only support our previous hypothesis that S. cerevisiae has two functional cysteine biosynthetic pathways but also reveal an interesting gene arrangement of the cysteine biosynthetic system.     

High-frequency fusion of Streptomyces parvulus or Streptomyces antibioticus protoplasts induced by polyethylene glycol.

Conditions were established for the regeneration of protoplasts of Streptomyces parvulus and Streptomyces antibioticus to the mycelial form. Regeneration was accomplished with a hypertonic medium that contained sucrose, CaCl2, MgCl2, and low levels of phosphate. High-frequency fusion of protoplasts derived from auxotrophic strains of S. parvulus or S. antibioticus was induced by polyethylene glycol 4,000 (42%, wt/vol). The frequency of genetic transfer by the fusogenic procedure varied with the auxotrophic strains examined. Fusion with auxotrophic strains of S. parvulus resulted in the formation of true prototrophic recombinants. Similar studies with S. antibioticus revealed that both stable prototrophic recombinants and heterokaryons were formed.     

Locus of the Pseudomonas aeruginosa toxin A gene.

The gene for Pseudomonas aeruginosa toxin A has been mapped in the late region of the chromosome of strain PAO. Strain PAO-PR1, which produces parental levels of toxin A antigen that is enzymatically inactive and nontoxic, was used as the donor for R68.45 plasmid-mediated genetic exchange. Strain PAO-PR1 (toxA1) was mated with toxin A-producing strains, and exconjugates for selected prototrophic markers were tested for the transfer of toxA1. The toxA1 gene was located between cnu-9001 and pur-67 at approximately 85 min on the PAO chromosome.     

Transducing activity of the temperate SM bacteriophage of Pseudomonas aeruginosa

The temperate bacteriophage SM is not serologically related to the known transducing phages F116, G101, B3 of Pseudomonas aeruginosa. The strains with auxotrophic mutations within the wide ranges of the genetic map of P. aeruginosa strain PAO1 were used for studying the transducing activity of the SM phage. All of the 7 bacterial markers tested are transduced with SM phage grown on a prototrophic donor strain. The frequency of transduction of separate bacterial markers using the wild type SM phage is 2.3 to 4.6 X 10(-8). Linked ilv202+ - met28+ markers are cotransduced with SM phage at a frequency of about 1.5%.     

Genetic recombination in Micromonospora rosaria by protoplast fusion.

Auxotrophic strains of Micromonospora rosaria were isolated by N-methyl-N'-nitro-N'-nitrosoguanidine mutagenesis and used in intraspecific recombination by protoplast fusion. High-frequency fusion of protoplasts of M. rosaria strains was induced by polyethylene glycol (molecular weight, 1,000) (PEG 1,000). The optimum concentration of PEG 1,000 for fusion of M. rosaria was 50% (wt/vol). PEG 4,000 was slightly better than PEG 1,000 at concentrations lower than 50% (wt/vol). The recombinant frequency did not increase after treatment with PEG 1,000 (50% [wt/vol]) for longer than 20 min. Under these conditions, fusion with many auxotrophic strains of M. rosaria resulted in a high frequency of formation of true recombinants (sometimes more than 10%). Additionally, when ros (rosamicin nonproducing) strains were crossed by protoplast fusion; about 5% of the resultant prototrophic recombinants were shown to have the ros+ (rosamicin producing) characteristic restored. Rosamicin production by M. rosaria colonies was clearly distinguished by the broth overlay method. The results of fusion experiments between ros and ros+ strains indicated that either the chromosomal mutation or pleiotrophic effect of some auxotrophic markers is involved.     

Genetic recombination in Micromonospora rosaria by protoplast fusion

Auxotrophic strains of Micromonospora rosaria were isolated by N-methyl-N'-nitro-N'-nitrosoguanidine mutagenesis and used in intraspecific recombination by protoplast fusion. High-frequency fusion of protoplasts of M. rosaria strains was induced by polyethylene glycol (molecular weight, 1,000) (PEG 1,000). The optimum concentration of PEG 1,000 for fusion of M. rosaria was 50% (wt/vol). PEG 4,000 was slightly better than PEG 1,000 at concentrations lower than 50% (wt/vol). The recombinant frequency did not increase after treatment with PEG 1,000 (50% [wt/vol]) for longer than 20 min. Under these conditions, fusion with many auxotrophic strains of M. rosaria resulted in a high frequency of formation of true recombinants (sometimes more than 10%). Additionally, when ros (rosamicin nonproducing) strains were crossed by protoplast fusion; about 5% of the resultant prototrophic recombinants were shown to have the ros+ (rosamicin producing) characteristic restored. Rosamicin production by M. rosaria colonies was clearly distinguished by the broth overlay method. The results of fusion experiments between ros and ros+ strains indicated that either the chromosomal mutation or pleiotrophic effect of some auxotrophic markers is involved.     

Interaction between colicinogenic factor V and the integrated F factor in an Hfr strain of Escherichia coli

Kahn, Phyllis L. (Princeton University, Princeton, N.J.), and Donald R. Helinski. Interaction between colicinogenic factor V and the integrated F factor in an Hfr strain of Escherichia coli. J. Bacteriol. 90:1276-1282. 1965.-The production of colicin V by strains of Escherichia coli is determined by a colicinogenic factor, colV. The colV factor possesses a genetic determinant of fertility, F(v). V(+)F(v) (+) cells are characteristically susceptible to a male-specific phage, mu, and able to transfer the colV factor and chromosomal markers to recipient cells. The present work describes an interaction of the colV factor with the chromosome of the Hfr strain, HfrH. A colV-containing HfrH strain, designated HfrHV(+)F(v) (+)(l), was isolated and shown to be insensitive to phage mu and impaired in its fertility properties. Loss of the colV factor by this strain, either spontaneous or induced by acridine orange, resulted in a further 10(3)- or 10(4)-fold loss in fertility. This additional loss of fertility was restored by reinfection of these strains with the colV factor. The colV interaction with the HfrH chromosome also can result in defects in the fertility properties of the colV factor. Altered colV factors were found in recombinants isolated from a cross between the HfrHV(+)F(v) (+)(l) strain and F(-) recipients. It is postulated that in the HfrHV(+)F(v) (+)(l) strain an interaction of the colV episome with the integrated F region of the chromosome occurs, with a resulting modification of the fertility properties of the HfrH strain. This interaction can also result in a defect in certain properties of the colV factor.     

Plasmid R68.45 and S-a transduction by the temperate bacteriophage 59 of Erwinia carotovora 268

Temperature bacteriophage 59 of Erwinia carotovera 268 had transduced extrachromosomal DNA: plasmids of R68.45 and S-a. Before plasmid transduction experiments the suitable donor strains of indicator culture Erwinia horticola 450 harbouring R68.45 and S-a were created. The frequency of plasmid R68.45 transfer from Pseudomonas putida to E. horticola 450-8 by conjugation was equal to 5 x 10(-8) per a donor cell and in the case of S-a--from E. coli C600 for the same recipient cells--was 2 x 10(-6). Bacteriophage 59 has transduced only separate markers of plasmid R68.45, since plasmid S-a is probably transduced by the phage as an intact unit.     

Transmission of F'lac plasmid from Escherichia coli K-12 to bacteria of the genus Erwinia]

The F'lac plasmid was transferred by conjugation from Escherichia coli K-12 W1655 to 21 lac- strains of Erwinia spp. (5.2 . 10(-6) to 6.8 . 10(-2) lac+ exconjugants per donor cell). Erw. herbicola and Erw. chrysanthemi were the better recipients than others. The degree of the stability of lac+ genes in Erwinia exconjugants depends on the strains. Stable exconjugants of Erwinia, which harbored F'lac plasmid, were able to utilize lactose, to transfer lac genes by conjugation to Erwinia spp. and E. coli, and were sensitive to the F-specific phages f1, f2, Qbeta. The F'lac plasmid was eliminated from the exconjugants by the treatment with acridine orange, which indicates that this genetic element is not integrated into the Erwinia chromosome.     

Integration of R91-5::Tn501 into the Pseudomonas putida PPN chromosome and genetic circularity of the chromosomal map

Derivatives of the Pseudomonas aeruginosa plasmid R91-5, loaded with the transposon Tn501, were transferred to P. putida PPN. Over 90% of exconjugants, which arose at a frequency of ca. 10(-6) per donor cell, exhibited high-frequency (greater than 10(-2) per donor cell) polarized transfer of chromosomal markers. In one instance it was demonstrated by transduction that the plasmid had been inserted into a gene required for serine biosynthesis. The integrated nature of the plasmid in this and other P. putida (R91-5::Tn501) derivatives was supported by the failure to detect covalently closed circular DNA in these strains. The transfer origins of six different Hfr donors have been characterized genetically, and time-of-entry kinetics obtained from interrupted matings have enabled the construction of a circular genetic map 103 min in length and containing 35 markers. The genetic map of P. putida PPN shows significant differences in marker order to that of P. aeruginosa PAO.