Early Stages of Conjugation in Escherichia coli

We initiated these studies to learn more about the initial events during bacterial conjugation and to optimize conditions for their occurrence. We found that cells in donor cultures grown anaerobically prior to mating have (i) a higher mean number of F pili per cell, (ii) longer F pili, (iii) a higher probability of forming specific pairs with F(-) cells, and (iv) a faster rate of initiation of chromosome transfer than cells grown aerobically. The growth medium for the donor culture also influences these same parameters: a rich medium is superior to a completely synthetic medium. Starvation of donor cells in buffered saline or for a required amino acid results in (i) a loss of F pili, (ii) a loss in the ability of donor-specific phages to adsorb, (iii) a loss of ability to form specific pairs with F(-) cells and to yield recombinants, and (iv) an increase in recipient ability. These changes occur as a function of starvation time, and at rates which are dependent on the conditions of prior growth and starvation of the donor culture. Either treatment provides a rapid method for the production of F(-) phenocopies from donor cultures. Resynthesis of F pili by cells within a starved donor culture commences very soon after restoration of normal growth conditions, but full restoration of donor ability, as measured by recombinant yield, occurs at a slower rate. We found, along with other investigators, that F pili are essential for specific pair formation. We also found, however, that the presence of F pili is not sufficient for display of donor ability, nor is the absence of F pili enough for cells to exhibit recipient ability. This suggests, therefore, that one or more components, in addition to F pili, are necessary for the conversion of specific pairs to effective pairs (or for chromosome mobilization, or both) and for preventing donor cells from acting as recipients. On the basis of our results, we suggest optimal conditions for achieving high mating efficiencies.     

DNA transfer occurs during a cell surface contact stage of F sex factor-mediated bacterial conjugation.

Donor bacteria containing JCFL39, a temperature-sensitive traD mutant of the F sex factor, were used at the nonpermissive temperature to accumulate stable mating pairs with recipient cells. At this stage in conjugation, extracellular F pili were removed by treatment with 0.01% sodium dodecyl sulfate. Upon then shifting to the permissive temperature for JCFL39, transfer of the F plasmid was observed. The mating pairs that were accumulated with JCFL39 at the nonpermissive temperature were readily observed by electron microscopy in wall-to-wall contact with the recipient bacteria. These results demonstrate that the traD product, which is known to be required in transferring DNA to a recipient bacterium, acts after the stage at which extracellular F pili are required. In addition, we concluded that DNA transfer takes place while donor and recipient cells are in surface contact and not necessarily through an extended F pilus as envisioned in some models of bacterial conjugation.     

Inhibition of Formation of Escherichia coli Mating Pairs by f1 and MS2 Bacteriophages as Determined with a Coulter Counter

The effect of male-specific filamentous deoxyribonucleic acid (f1) and isometric ribonucleic acid (MS2) bacteriophages on the formation of mating pairs in Escherichia coli conjugation was examined directly in the Coulter counter. When a sufficient multiplicity of infection (MOI) was used, the f1 phage immediately and completely inhibited the formation of mating pairs. On the other hand, the MS2 phage at a relatively high MOI also inhibited the formation of mating pairs significantly although not completey. The inhibitory effect of MS2 phage was dependent on the time of addition and the MOI used. At relatively low MOI (<20), the MS2 phage showed some inhibitory effect when added to a male culture prior to mixing with females, whereas no effect was observed when phages were added after mating pair formation had already commenced. At a high MOI (>400) MS2 phage disrupted the mating pairs already formed. Some preformed mating pairs were resistant to the high MOI of MS2 phages, however, and the "sensitive" (to high MOI) mating pairs seem to mature into "resistant" mating pairs as a function of time. We conclude that the tip of an F pilus is the specific attachment site for mating. The following process of mating pair formation has been formulated by deduction. (i) The sides of F pili weakly contact female cells, (ii) then the tips of F pili attach to the specific receptor sites to form initial mating pairs, and (iii) those pairs mature into mating pairs that are resistant to the high MOI of MS2 phages. The high MOI of MS2 prevents the first step, whereas f1 phages affect the second step-the binding between the tips of F pili and the receptor sites.     

Specification of surface mating systems among conjugative drug resistance plasmids in Escherichia coli K-12

Representative plasmids for most incompatibility groups in Escherichia coli K-12 were transferred to a "bald" strain to compare transfer frequencies for liquid and solid media. Standard broth matings were used for a liquid environment, but for solid surface mating, conjugation was allowed to take place on nutrient plates before washing off the cells for transconjugant selection on plates containing appropriate drugs. Plasmids that determine rigid pili transferred at least 2,000x better on plates than in broth. Some plasmids that determine thick flexible pili transferred 45 to 470x better, whereas others transferred equally well in both environments, as did plasmids of the I complex, which determine thin flexible pili. These results clearly distinguished a number of surface mating systems where most plasmids were derepressed for transfer and determined conjugative pili constitutively. The temperature-independent IncH2 plasmid R831b transferred best on plates, but other IncH plasmids transferred equally well in broth. This inconsistency led to the reclassification of R831b as IncM.     

Transfer of R factors to and between genetically marked sublines of Rhizobium japonicum.

Plasmids R1822 and pRD1 of the P-1 incompatibility group, for which Rhizobium japonicum had not previously been shown to serve as host, were introduced into a strain of R. japonicum. Acquisition of R68 and R68.45 plasmids by this Rhizobium was equivocal. Transfer of R1822 from Pseudomonas aeruginosa and of pRD1 from Escherichia coli to R. japonicum was unambiguous, because the exconjugants subsequently cotransferred the three R-factor resistance determinants (kanamycin, tetracycline, and penicillin) between genetically marked sublines of strain I-110. Under optimal conditions the transfer of R1822 and pRD1 occurred at frequencies of approximately 10(-3) in plate matings of strains bearing as many as five dissimilar genetic markers. In matings with R1822 on membrane filters, recombinants were formed at incidences as high as 4%.     

Transfer of R factors to and between genetically marked sublines of Rhizobium japonicum.

Plasmids R1822 and pRD1 of the P-1 incompatibility group, for which Rhizobium japonicum had not previously been shown to serve as host, were introduced into a strain of R. japonicum. Acquisition of R68 and R68.45 plasmids by this Rhizobium was equivocal. Transfer of R1822 from Pseudomonas aeruginosa and of pRD1 from Escherichia coli to R. japonicum was unambiguous, because the exconjugants subsequently cotransferred the three R-factor resistance determinants (kanamycin, tetracycline, and penicillin) between genetically marked sublines of strain I-110. Under optimal conditions the transfer of R1822 and pRD1 occurred at frequencies of approximately 10(-3) in plate matings of strains bearing as many as five dissimilar genetic markers. In matings with R1822 on membrane filters, recombinants were formed at incidences as high as 4%.     

Effect of Zn2+ on Bacterial Conjugation: Increase in Ability of F− Cells to Form Mating Pairs

Incubation of F(-) cells at 37 C with 10(-3) M Zn(2+) before mating was found to increase the ability of F(-) cells to form mating pairs when mated. This increased pair-forming ability is persistent, at least for the duration of mating. The F(-) cells with increased pair-forming ability obtained by the 10(-3) M Zn(2+) treatment can form mating pairs efficiently with males from which F pili were removed or inactivated with 10(-3) M Zn(2+).     

Evidence for a Conjugation-Like Mechanism of DNA Transfer in Helicobacter pylori

Many strains of Helicobacter pylori are naturally competent for transformation in vitro. Since there is a high degree of genetic variation among H. pylori strains, we sought to determine whether mechanisms of DNA exchange other than transformation exist in these organisms. Studies were done with H. pylori cells that each were resistant to two different antibiotics; the procedure used involved mating of cells on plates or in broth, in the absence or presence of DNase. In each experiment, such matings produced progeny with the markers of both parents. Examination of the full resistance profile and random arbitrarily primed DNA PCR (RAPD-PCR) profiles of the progeny indicated that DNA transfer was bidirectional. DNase treatment reduced but did not eliminate transfer; only the presence of both DNase and a membrane separating the cells did so. For progeny derived from matings in the presence of DNase, antibiotic resistance and RAPD profiles indicated that transfer was unidirectional. DNase-treated cell-free supernatants also did not transform, ruling out transduction. These experiments indicate that both a DNase-sensitive mechanism (transformation) and a DNase-resistant conjugation-like mechanism involving cell-to-cell contact may contribute to DNA transfer between H. pylori cells.     

Development in Electrofused Conjugants of Tetrahymena thermophila

Electric shock can create parabiotic fusions of living Tetrahymena cells. In this study, cells were mated and successful pairs were electrofused with either vegetatively growing cells or other mating pairs. In particular, we electrofused pairs from normal [diploid x diploid] matings with vegetatively dividing cells in G- or M-phase of the cell cycle. We also fused [diploid x diploid] conjugants with mating pairs involving an aneuploid partner [diploid x "star"], which typically undergo an abortive conjugal pathway termed genomic exclusion. Using such parabiotic fusions we identified and characterized two developmentally critical landmarks: 1) the "abort" signal, which is initiated in pairs with nuclear defects (this first becomes evident soon after the completion of Meiosis I or the beginning of Meiosis II); and 2) the "terminal commitment point", a developmental stage in normal [diploid x diploid] pairs after which conjugation no longer responds to a parabiotically transmitted abort signal (this correlates with the onset of the second postzygotic nuclear division). Finally we demonstrate that a conjugal-arrest-activity varies with the vegetative cell cycle, reaching its highest level of activity during M-phase and dropping just after cytokinesis.     

Functions of F pili in mating-pair formation and male bacteriophage infection studies by blending spectra and reappearance kinetics

The extent of removal at various blending speeds (blending spectrum) and the kinetics of reappearance after blending of the ability of male Escherichia coli bacteria to form mating pairs, to adsorb and be infected by ribonucleic acid male phage, and to adsorb and be infected by deoxyribonucleic male phage were identical to the blending spectrum and reappearance kinetics of microscopically visible F pili. The same results were obtained with an Hfr (high-frequency recombinant), F', or resistance transfer factor (RTF) fi(+) mating system. Blending did not affect the viability, growth rate, ability to adsorb T4 phage, or ability to produce new F pili at any of the speeds used. It can be concluded that microscopically visible F pili are an absolute requirement for all three functions. Three classes of F pili have been found in bacterial cultures: attached, adsorbed, and free. Bacteria with adsorbed F pili in addition to attached ones were proportionately more susceptible to male phage infection, suggesting that adsorbed F pili may be at least partially functional. Free F pili did not compete with bacteria for phage. Some implications of the virus-like nature of F-pilus outgrowth for the mechanisms of mating and male phage infection are discussed.     

Genetic system in Pseudomonas alcaligenes NCIB 9867

Abstract Genetic transfer of both auxotrophic and catabolic markers was detected in filter matings of mutant strains of Pseudomonas alcaligenes NCIB 9867. Bidirectional transfer of auxotrophic markers was demonstrated in most of the crosses. Strains could either act as donors or recipients. Polarized transfer of auxotrophic markers was observed in some crosses. There was low co-inheritance of both 2,5X⁺ catabolic marker and auxotrophic markers. No evidence could be presented indicating the involvement of the indigenous 33-kb plasmid in the genetic transfer process. Partial sensitivity to DNase was observed in some of the crosses. Maximum frequency of recombinant formation obtained with mating cultures from stationary growth phase suggested an influence of physiological states on genetic transfer. As transfer did not appear to be due to classical transformation or to be plasmid-mediated, the likely mechanism could involve the release of DNA upon intimate cell-to-cell contact. The gene transfer system may be useful for linkage analysis of closely linked genes.     

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.     

Social variables and divergent selection for mating behaviour of male chickens (Gallus domesticus)

Heterosexual or unisexual contact of juvenile males from two lines divergently selected for male mating frequency, and a control line had little, if any influence on their subsequent mating behaviour. The interaction of lines x social environments for mating behaviour was not significant, showing that lines responded in a similar manner to the environments. It is hypothetized that selection for low cumulative number of completed matings (CNCM) was primarily for higher neural thresholds, whereas selection for high CNCM affected loci operative after neural thresholds are attained. The magnitude of the sexual component of a court was found to be dependent on the genetic background of the population, being less in the low mating than in the high mating line.     

Conjugational junctions: morphology of specific contacts in conjugating Escherichia coli bacteria.

F-plasmid-mediated bacterial conjugation was studied with hfr (traDts) and tra I mutant Escherichia coli donor strains. This allowed us to observe a statistically significant number of conjugation-specific contacts by video and electron microscopy. Single mating events between E. coli were observed in real time by video-enhanced light microscopy. Conjugation in vivo takes place by initial contact formation via pili, followed by direct and transient wall-to-wall contact, during which DNA is transferred and disaggregated. Electron microscopic observations of the contact zone between donor and recipient bacteria were made by thin sectioning of mating pairs that were arranged in monolayers. We defined the conjugation-specific contact found in stabilized mating pairs as the conjugational junction. Within this junction no specific substructure such as plasma bridges by fusion could be detected during transfer of DNA.     

Induced variations in microorganisms

Genetic transfer of markers has been found to occur through a sexual cycle between intact cells in a mixed culture of two different genotypes. When rS (radiosensitive and streptomycin resistant) and Rs (radioresistant and streptomycin sensitive) cells ofRhizobium trifolii were brought into varying periods of cellular contact, the cell mixture yielded RS recombinants. The recombination frequency was higher in young mating cultures than in aged ones. Except for the acquisition of the R and S markers, the recombinants did not differ appreciably from the parental strains in other characters.     

The F pilus of Escherichia coli appears to support stable DNA transfer in the absence of wall-to-wall contact between cells.

Separation of HfrC-F- mating pairs of Escherichia coli by a filter 6 microns thick with straight-through pores 0.01 to 0.1 micron in diameter did not prevent DNA transfer. We conclude that the F pilus alone is capable of acting as a stable conduit for cell-to-cell DNA transfer.     

Mating success of wild type and sepia mutants Drosophila melanogaster in different choice.

Mating behaviour of red-eyed (wt) and brown-eyed (sepia) Drosophila melanogaster was studied under light conditions. Mating success was directly observed in mating vials and techniques usually applied in the studies of sexual selection ("female choice" and "multiple choice"). The comparison of sexual activity of mutant and wild types clearly indicates that they are not equally successful in matings. Sepia eye colour mutation decreases sexual activity of Drosophila melanogaster males, influences the preference ability of females and decreases the number of progeny from homogamic mating of the se x se type, as well as from heterogamic copulations in which sepia females take part. Non-random mating of wild type males and sepia females (in "multiple-choice" situation), with genetically and phenotypically different individuals, could be another mechanism for conservation of genetic polymorphism in natural populations.     

Mechanism of Action of Nalidixic Acid on Conjugating Bacteria

When nalidixic acid, a specific and effective inhibitor of cellular deoxyribonucleic acid synthesis, is added to conjugating bacteria at any time during mating, it stops genetic transfer provided the donor bacterium is sensitive to the drug. When this inhibition is released by the removal of the nalidixic acid, transfer does not resume at the point on the chromosome where it was stopped, but begins again at the transfer origin. Curves relating the effects of various low doses of nalidixic acid to the frequency of recombination reveal that several "hits" are necessary to inhibit recombination for early markers. The number of required "hits" decreases as the distance of the marker from the transfer origin increases. Transfer between drug-resistant cells may also be inhibited by nalidixic acid. The effect of high drug doses on matings between resistant cells is similar to that of low drug doses on matings with a sensitive male.     

Conjugal Transfer of Genetic Information in Group N Streptococci

Streptococcus lactis strains ML3 and C₂O and S. lactis subsp. diacetylactis strains DRC3, 11007, and WM₄ were found to transfer lactose-fermenting ability to LM0230, an S. lactis C2 lactose-negative (Lac⁻) derivative which is devoid of plasmid deoxyribonucleic acid (DNA). Lactose-positive streptomycin-resistant (Lac⁺ Str^r) recombinants were found when the Lac⁺ Str^s donor was mixed with Lac⁻ Str^r LM0230 in solid-surface matings. Transduction and transformation were ruled out as the mechanism of genetic exchange in strains ML3, DRC3, 11007, and WM₄, nor was reversion responsible for the high number of Lac⁺ Str^r recombinants. Furthermore, chloroform treatment of the donor prevented the appearance of recombinants, indicating that transfer of lactose-fermenting ability required viable cell-to-cell contact. Strain C₂O demonstrated transduction as well as conjugation. Transfer of plasmid DNA during conjugation for all strains was confirmed by demonstrating the presence of plasmid DNA in the transconjugants by using agarose gel electrophoresis. In some instances, a cryptic plasmid was transferred in conjunction with the lactose plasmid by using strains DRC3, 11007, and WM₄. In S. lactis C2 × LM0230 matings, the Str^r marker was transferred from LM0230 to C2, suggesting conjugal transfer of chromosomal DNA. The results confirm conjugation as another mechanism of genetic exchange occurring in dairy starter cultures.     

How Pronghorn Females Avoid Inbreeding Depression

After a bottleneck in a closed population of pronghorn (Antilocapra americana), some inbred matings occurred, and we detected significant inbreeding depression. But inbred matings occurred less frequently than would be expected by chance. Pronghorn females chose mates after a sampling period and had complete control of the mating decision. Therefore, to discover the behavioral mechanism by which females avoided mating with close kin, we studied female movements and courtship sequences. When females moved from one harem to another in the sampling process, they did not shift to harem males of lower coancestry as they approached estrus. Rather, females progressed more slowly through the later courtship stages when the harem male was related vs. unrelated. Also, the rates of male courtship acts were higher within unrelated vs. related pairs. Some females appeared to use multiple mating as an inbreeding avoidance strategy. Our results suggested that inbreeding avoidance by female pronghorn occurred primarily by reactions to the late stages of male courtship, rather than by spatial avoidance of related males.