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.     

The influence of the PO1A1 mutation upon recombination in Escherichia coli K12.

Genetic recombination in Escherichia coli is a highly regulated process involving multiple gene products. We have investigated the role of DNA polymerase I in this process by studying the effect of the po1A1 mutation upon DNA transfer and conjugation in otherwise isogenic suppressor-free strains of E. coli K-12. It was found that the po1A1 mutation greatly reduces recombination in Hfr crosses (a factor of 20 in Pol+ x Po1A1 crosses and more than a factor of 100 in Po1A1 X Po1A1 crosses). However, since the po1A1 mutation reduces the strains capacity to act as a recipient for an F-prime and the analysis of recombination transfer gradients revealed no differences between Po1+ and Po1- strains, it is concluded that DNA polymerase I probably affects the transfer and/or stability of donor DNA rather than the recombinational process itself.     

Transduction, Restriction and Recombination Patterns in Escherichia Coli

Chromosomal DNA from several Escherichia coli reference (ECOR) strains was transduced by bacteriophage P1 into E. coli strain K12 W3110 trpA33. Recombination patterns of the transductants were determined by restriction fragment length polymorphism over a 40-kb region centering on a single marker (trpA(+)) in the tryptophan operon. These experiments demonstrate that transduction between different strains of E. coli can result in recombinational replacements that are small in comparison to the entrant molecule (replacements average 8-14 kb, whereas P1 packages ~ 100 kb) often in a series of discrete segments. The transduction patterns generated resemble the natureal mosaic sequence patterns of the ECOR strains described in previous work. Extensive polymorphisms in the restriction-modification systems of the ECOR strains are a possible explanation for the sequence patterns in nature. To test this possibility, two transductants were back-transduced into strain K12 W3110 trpA33. The resulting patterns were strikingly different from the original transductions. The size of the replacements was greater, and no multiple replacements were observed, suggesting a role for restriction-modification systems in the transduction patterns and perhaps for the mosaic sequence patterns in nature.     

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)。     

Replication of the deoxyribonucleic acid of multiple-drug-resistance factor in Escherichia coli.

1. It was shown that a system previously described for labelling R-factor DNA during transfer to an irradiated recipient strain of Escherichia coli did not allow high selectivity in the incorporation of thymine into R-factor DNA. 2. Lack of selectivity was shown to be due to cross-feeding from recipient to donor strain. 3. An improved system using a nalidixic acid-resistant recipient strain is described in which incorporation of thymine into the DNA of donor cells is minimized by addition of nalidixic acid after completion of transfer of the plasmid during conjugation.     

Mechanism of retrotransfer in conjugation: prior transfer of the conjugative plasmid is required.

Bacterial conjugation normally involves the unidirectional transfer of DNA from donor to recipient. Occasionally, conjugation results in the transfer of DNA from recipient to donor, a phenomenon known as retrotransfer. Two distinct models have been generally considered for the mechanism of retrotransfer. In the two-way conduction model, no transfer of the conjugative plasmid is required. The establishment of a single conjugation bridge between donor and recipient is sufficient for the transfer of DNA in both directions. In the one-way conduction model, transfer of the conjugative plasmid to the recipient is required to allow the synthesis of a new conjugation bridge for the transfer of DNA from recipient to donor. We have tested these models by the construction of a mutant of the self-transmissible, IncP plasmid RK2lac that allows the establishement of the conjugation bridge but is incapable of self-transfer. Four nucleotides of the nic region of the origin of transfer (oriT) were changed directly in the 67-kb plasmid RK2lac by a simple adaptation of the vector-mediated excision (VEX) strategy for precision mutagenesis of large plasmids (E. K.Ayres, V. J. Thomson, G. Merino, D. Balderes, and D. H. Figurski, J. Mol. Biol. 230:174-185, 1993). The resulting RK2lac oriT1 mutant plasmid mobilizes IncQ or IncP oriT+ plasmids efficiently but transfers itself at a frequency which is 10(4)-fold less than that of the wild type. Whereas the wild-type RK2lac oriT+ plasmid promotes the retrotransfer of an IncQ plasmid from Escherichia coli or Pseudomonas aeruginosa recipients, the RK2lac oriT1 mutant is severely defective in retrotransfer. Therefore, retrotransfer requires prior transfer of the conjugative plasmid to the recipient. The results prove that retrotransfer occurs by two sequential DNA transfer events.     

Conjugal transfer of chromosomal DNA in Mycobacterium smegmatis

The genus Mycobacterium includes the major human pathogens Mycobacterium tuberculosis and Mycobacterium leprae . The development of rational drug treatments for the diseases caused by these and other mycobacteria requires the establishment of basic molecular techniques to determine the genetic basis of pathogenesis and drug resistance. To date, the ability to manipulate and move DNA between mycobacterial strains has relied on the processes of transformation and transduction. Here, we describe a naturally occurring conjugation system present in Mycobacterium smegmatis , which we anticipate will further facilitate the ability to manipulate the mycobacterial genome. Our data rule out transduction and transformation as possible mechanisms of gene transfer in this system and are most consistent with conjugal transfer. We show that recombinants are not the result of cell fusion and that transfer occurs from a distinct donor to a recipient. One of the donor strains is mc²155, a highly transformable derivative that is considered the prototype laboratory strain for mycobacterial genetics; the demonstration that it is conjugative should increase its genetic manipulability dramatically. During conjugation, extensive regions of chromosomal DNA are transferred into the recipient and then integrated into the recipient chromosome by multiple recombination events. We propose that DNA transfer is occurring by a mechanism similar to Hfr conjugation in Escherichia coli .     

Lethal zygosis in recombination-deficient mutants of Escherichia coli.

Use of nonselective medium for plating cells following mating has revealed that Rec recipient strains of E. coli may be killed as a result of conjugation. Sensitivity of RecA-, RecB-, and RecC- recipients increases with ratio of donor: recipient cells in mating mixtures and with time of mating. A Rec+ recipient shows no lethal zygosis in these experiments performed without aeration. Cell contact does not seem to be responsible for the sensitivity of Rec- strains, since lethality is prevented when cell contact is permitted but DNA transfer is not. Thus, an event(s) occuring subsequent to entry of donor DNA appears to cause lethality in Rec- recipients.     

Use of cloned DNA methylase genes to increase the frequency of transfer of foreign genes into Xanthomonas campestris pv. malvacearum.

In vitro-packaged cosmid libraries of DNA from the bacterium Xanthomonas campestris pv. malvacearum were restricted 200- to 1,000-fold when introduced into Mcr+ strains of Escherichia coli compared with restriction in the Mcr- strain HB101. Restriction was predominantly associated with the mcrBC+ gene in E. coli. A plasmid (pUFR052) encoding the XmaI and XmaIII DNA methylases was isolated from an X. campestris pv. malvacearum library by a screening procedure utilizing Mcr+ and Mcr- E. coli strains. Transfer of plasmids from E. coli strains to X. campestris pv. malvacearum by conjugation was enhanced by up to five orders of magnitude when the donor cells contained pUFR052 as well as the plasmid to be transferred. Subcloning of pUFR052 revealed that at least two regions of the plasmid were required for full modification activity. Use of such modifier plasmids is a simple, novel method that may allow the efficient introduction of genes into any organism in which restriction systems provide a potent barrier to such gene transfer.     

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.     

Structure of Recombinants from Conjugational Crosses between Escherichia Coli Donor and Mismatch-Repair Deficient Salmonella Typhimurium Recipients

To get more insight into the control of homologous recombination between diverged DNA by the Mut proteins of the long-patch mismatch repair system, we have studied interspecies Escherichia coli/Salmonella typhimurium recombination. Knowing that the same recombination pathway (RecABCD) is responsible for intraspecies and interspecies recombination, we have now studied the structure (replacement vs. addition-type or other rearrangement-type recombinants) of 81 interspecies recombinants obtained in conjugational crosses between E. coli donor and mutL, mutS, mutH, mutU or mut(+) S. typhimurium recipients. Taking advantage of high interspecies sequence divergence, a physical analysis was performed on one third of the E. coli Hfr genome, which was expected to be transferred to S. typhimurium F(-) recipients during 40 min before interruption of the mating. Probes specific for each species were hybridized on dot blots of genomic DNA, or on colonies, and the composition of the rrn operons was determined from purified genomic DNA. With very few exceptions, the structure of these interspecies recombinants corresponds to replacements of one continuous block of the recipient genome by the corresponding region of the donor genome.     

DNA transfer and DNA synthesis during bacterial conjugation

Summary Mutant strains ofEscherichia coli, which were thermosensitive with respect to DNA replication, were used for conjugation experiments at 37°C and 42°C. Inhibition of DNA synthesis in the donor strain has no influence on the yield of recombinats. Inhibition of DNA synthesis in the recipient strain is accompanied by a complete loss of recombinant formation. Both are also true for homosexual crosses. Temporary inhibition of DNA synthesis in the recipient cell during conjugation effects reversible inhibition of DNA transfer.It is concluded that DNA transfer depends on DNA synthesis in the recipient strain, whereas DNA synthesis in the donor strain seems to be unnecessary.     

Structural homologies among type I restriction-modification systems.

Structural homologies among different restriction systems of Escherichia coli and several Salmonella species have been investigated by immunological methods using antibodies prepared against two subunits of the E. coli K12 restriction enzyme, and by DNA hybridization experiments using different fragments of the E. coli K12 hsd genes as probes. The results with both techniques show a strong homology between the E. coli K12 and B restriction-modification systems, weaker but nevertheless marked homology between E. coli K12 and the Salmonella systems SB, SP, and SQ and, surprisingly, no homology between the E. coli K12 and A systems.     

Recombination properties of P1 dlac.

The P1 dlac prophage plasmid of Escherichia coli K-12 has been utilized as the recipient DNA substrate in experiments with lambda plac5 transduction and with Hfr and F' conjugation. The P1 dlac plasmid does not recombine with lambda plac5 at the elevated levels seen for the F42lac plasmid. Recombination between lambda plac5 and P1 dlac is essentially indistinguishable from recombination between lambda plac5 and a chromosomal lac gene in tems of both level of recombination and recombination pathway (RecBC, RecE, and RecF) dependence. The initiation of recombination between P1 dlac and lac genes from an Hfr or F' donor is severalfold more efficient than it is for a recipient chromosomal lac gene.     

Increased fertility of Corynebacterium glutamicum recipients in intergeneric matings with Escherichia coli after stress exposure.

Corynebacterial recipient cells exposed to heat, organic solvents, pH shifts, or detergents show an increased fertility in subsequent interspecific matings with Escherichia coli. This effect is independent of de novo protein biosynthesis and seems to be due to a direct inactivation of a restriction system active against foreign DNA that enters the cell by IncP-mediated conjugation.     

Plant transformation by coinoculation with a disarmed Agrobacterium tumefaciens strain and an Escherichia coli strain carrying mobilizable transgenes

Transformation of Nicotiana tabacum leaf explants was attempted with Escherichia coli as a DNA donor either alone or in combination with Agrobacterium tumefaciens. We constructed E. coli donor strains harboring either the promiscuous IncP-type or IncN-type conjugal transfer system and second plasmids containing the respective origins of transfer and plant-selectable markers. Neither of these conjugation systems was able to stably transform plant cells at detectable levels, even when VirE2 was expressed in the donor cells. However, when an E. coli strain expressing the IncN-type conjugation system was coinoculated with a disarmed A. tumefaciens strain, plant tumors arose at high frequencies. This was caused by a two-step process in which the IncN transfer system mobilized the entire shuttle plasmid from E. coli to the disarmed A. tumefaciens strain, which in turn processed the T-DNA and transferred it to recipient plant cells. The mobilizable plasmid does not require a broad-host-range replication origin for this process to occur, thus reducing its size and genetic complexity. Tumorigenesis efficiency was further enhanced by incubation of the bacterial strains on medium optimized for bacterial conjugation prior to inoculation of leaf explants. These techniques circumvent the need to construct A. tumefaciens strains containing binary vectors and could simplify the creation of transgenic plants.     

Gene Replacement with Linear DNA Fragments in Wild-Type Escherichia Coli: Enhancement by Chi Sites

During conjugation and transduction of Escherichia coli even numbers of recombinational exchanges are required for replacement of a gene on the circular chromosome. We studied gene replacement using a related method of gene transfer (transformation with 6.5-kb linear DNA fragments) as an experimental model for conjugation and transduction. Two properly situated Chi sites, 5' GCTGGTGG 3', stimulated gene replacement ~50-fold, more than the sum of the stimulation by the individual Chi sites. Gene replacement was dependent on RecA and RecB functions. Similar results were obtained with an alternative experimental model in which linear DNA fragments were generated from phage λ by intracellular EcoRI restriction following infection. Dual Chi site-stimulation of these RecA-, RecB-dependent recombination events thus did not depend upon the mode of delivery of the linear DNA into the cells. A single DNA fragment with two Chi sites was sufficient for gene replacement. These results support a one Chi-one exchange hypothesis (``long chunk' gene replacement), stemming from studies with purified RecBCD enzyme, and argue against models in which Chi converts RecBCD enzyme to a state capable of promoting multiple exchanges on one DNA molecule. These results also provide a method for gene targeting in wild-type E. coli and suggest a method for gene targeting in other organisms.     

Effect of Iododeoxyuridine upon Conjugation and the Fate of Transferred Deoxyribonucleic Acid in Escherichia coli K-12

The incorporation of 5-iododeoxyuridine (IUdR) into Escherichia coli K-12 deoxyribonucleic acid (DNA) has been found to decrease significantly the viability of female strains A288 and JC411(r) but to have only minor effect upon their ability to act as conjugational recipients and to perform recombination after conjugation. In contrast, IUdR incorporation into male strain HfrC appears to interfere with both chromosome transfer and genetic recombination. By using IUdR to densitylabel female DNA, and carrying out large-scale matings with (3)H-thymidine-labeled male cells, we examined the fate of transferred DNA. After a 30-min mating, the T6-sensitive male cells were lysed, and the DNA of the merozygotes and remaining female cells was isolated. Initial centrifugation of this DNA in a CsCl gradient showed that the male and female DNA species were associated. The nature of this association of the parental DNA species was determined by formaldehyde denaturation followed by CsCl centrifugation. Denaturation of DNA isolated immediately after T6 lysis gave a peak of radioactivity banding at the density of light single-stranded DNA. However, denaturation of DNA isolated after T6 lysis and dilution of the cells into fresh medium, exhibited peaks of radioactivity banding at positions corresponding to single-stranded, density-labeled DNA. The results indicate that recombination after conjugation in E. coli takes place by a breakage-and-reunion mechanism. The process of recombination can be separated into two stages. In the first stage, the donor and recipient DNA molecules become associated. The second stage consists of the formation of phosphodiester bonds between the donor and recipient segments comprising the recombinant molecule.     

Action of various surface-active substances on the genetic transmission of R-plasmids in E. coli]

The effect of 4 groups of surface active-substances (SAS) on conjugation and transduction transfer of plasmid RIdrd from the donor of E. coli J 5-3 to the recipient of E. coli C600 was studied. It was shown that the anionic SAS (8 compounds) had the highest inhibitory effect. They completely inhibited both the conjugation and the transduction transfer of R-plasmids. The amphoteric SAS, i. e. tego-51 and ampholan had the same effect only on the transduction R-transfer. The conjugation R-transfer was inhibited by the above compounds to a significant extent but not completely, i. e. by 70.8 and 361.9 times respectively. The effect of the non-ionogenic preparations, i. e. sintanol DT-7 was even less (the inhibition coefficients of 54.8 and 22.8 on conjuction and transduction respectively). The cationic SAS, i. e. catamine AB and HIPC-200 had no effect on the genetic R-transfer. It was shown that the anionic SAS had a phagocytic effect on phage Plks. It is of interest to note that the anionic SAS, i. e. sintanol NP-3 effectively suppressed the conjugation transfer even in a concentration of 100 gamma/ml which was 1000 times lower than the subbacteriostatic one. The effectiveness of the anionic SAS did not depend on the length of the dydrocarbon chain and was the same in separate homologues and their mixtures. The high inhibitory activity of most of the SAS and especially the anionic ones with respect to both the conjugation and the transduction R-transfer was of interest.     

Antigenic properties of genetic recombinants of serologically typed E. coli]

The conjugation between the typed strains of E. coli belonging to various serological groups and conjugation between typed and untyped E. coli strains were studied. Genetic determinant controlling the synthesis of the O100 antigen proved to be closely linked with histidine locus. Among recombinants obtained in crossing the typed E. coli strains there were such belonging to the serological type different from the serological types of donor and recipient cells.