Role of surface exclusion genes in lethal zygosis in Escherichia coli K12 mating

Summary We find that diaminopimelic acid in the recipient membrane is released into the medium during bacterial matings, indicating that membrane damage was inflicted on the recipient by the donor, probably for forming a channel for DNA transfer. When the damage is extensive, as in matings with an excess of Hfr bacteria, the F^- bacteria are killed (lethal zygosis). The transfer of a large amount of DNA in Hfr matings appears to enhance the killing. In analogous F⁺xF^- (Nal^r) matings, on the other hand, killing of F^- bacteria does not occur unless F plasmid transfer is inhibited by a substance like nalidixic acid. The F^- bacteria are killed, suggesting that F plasmids contain genes that express immunity to lethal zygosis in the recipient. For example, bacteria containing surface exclusion-deficient mutants of F plasmids, such as traS ^- and traT ^-, induce lethal zygosis in F^- bacteria and are susceptible to it. Various tra ^- polar mutants that abolish surface exclusion are also susceptible to lethal zygosis when mated with Hfr bacteria. Kinetic experiments indicate that in F⁺ (wild type) x F^- matings, immunity to lethal zygosis is expressed in the F^- recipient within 1/4 division time, whereas a complete expression of surface exclusion requires more than 1 division time. Thus, a complete change in all receptor sites seems to be required for the expression of surface exclusion.     

Quantification and Modeling of Plasmid Mobilization on Seeds and Roots

Mobilization frequencies of the nonconjugative plasmid pMON5003 were quantified using Escherichia coli TB1(pRK2013) as donor of a helper plasmid, E. coli M182 (pMON5003) as donor of the nonconjugative plasmid, and Pseudomonas fluorescens as recipient. Initial mating experiments were conducted in nutrient and minimal salts media and pea seed exudates. Mobilization rates were higher during early stationary growth of donors, helpers, and recipients. Numbers of transconjugants were higher in biparental matings when donors contained both conjugative and nonconjugative plasmids, versus tri-parental matings. A mathematical model was developed to predict a nonconjugative plasmid transfer rate parameter (δ), estimating the proportion of conjugative matings in which a plasmid is mobilized. Values of δ ranged from 8 × 10⁻³ to 7.9 × 10⁻¹. Transfer frequencies for pMON5003 from E. coli to P. fluorescens on pea seeds and roots were determined. Transconjugants (P. fluorescens 2-79 (pMON5003)) were isolated from seeds, roots, and soil, but mobilization frequencies were lower than in liquid media.     

Exclusion in IncI-type Escherichia coli conjugations: the stage of conjugation at which exclusion operates

The stage at which exclusion operates in matings between donors belonging to the I-type incompatibility group (IncI) was investigated. Mating between Escherichia coli cells harbouring the I-type plasmid R144 and E. coli cells harbouring the R144-derived recombinant plasmid pRAH308, which causes a hundredfold exclusion, was performed on a membrane filter to test whether mating aggregate formation was disturbed. Besides, level and kinetics of the formation of mating aggregates in mixtures of R144⁺ donor cells and recipient cells carrying plasmid pRAH308 (exclusion-proficient) was compared with the aggregate formation in mixtures of the donor cells and exclusion-deficient recipient cells. Results from these experiments revealed that the exclusion by pRAH308 does not operate at the level of aggregate formation, but acts at the stage of DNA transfer. The exclusion phenomenon by the recombinant plasmid pRAH308 appeared to be representative for exclusion caused by plasmid R144, since essentially identical results were obtained if plasmid R144 was used as exclusion-determining factor.     

Frequency dependent selection: I. Rare male phenomenon in D. subobscura dependent on the proportion of Amy genotypes and substrate composition

Analysis of the rare male mating advantage in D. subobscura, as a type of frequency dependent selection on maltose and starch media, was done by applying different statistical approaches (χ², cross-product ratio, variance and regression analysis). They reveal that mating occurs at random when proportions of prospective mates are equal, and that mating success of the males homozygous for Amy-locus genotypes (S/S and F/F) depends on their proportion. Regression analysis showed that the F/F males are sexually more active (have higher vigour) than S/S males. Rare male effect is one-sided and appears in F/F males that partake in more heterogamic matings. Comparison of the number of observed and expected homo- and heterogamic matings shows that homogamic matings are more frequent. Multifactorial analysis of variance shows that the number of matings are different for nine pairs of lines and four possible mating types (S_fS_m, S_fF_m, F_fS_m, F_fF_m). The rare male phenomenon is not dependent on different food composition, but is associated with variations in individual genotypes.     

Development of High-Frequency Delivery System for Transposon Tn919 in Lactic Streptococci: Random Insertion in Streptococcus lactis subsp. diacetylactis 18-16

The conjugative transposon Tn919, originally isolated in Streptococcus sanguis FC1, is capable of low-frequency transfer (10⁻⁷ and 10⁻⁸ per recipient) on membrane filters to a wide number of streptococcal recipients including the industrially important lactic streptococci. The introduction of pMG600 (Lac⁺ Lax⁻; a lactose plasmid capable of conjugative transfer at high frequencies and which, in certain hosts, confers an unusual clumping phenotype) into a Streptococcus lactis CH919 donor, generating S. lactis CH001, resulted in a significant improvement in the transfer frequency of Tn919 to S. lactis CK50 (1.25 × 10⁻⁴ per recipient). In addition, these matings could be performed on agar surfaces, allowing the recovery of a greater number of recipients than with filter matings. Tn919 also transferred at high frequency to S. lactis subsp. diacetylactis 18-16S but not to Streptococcus cremoris strains. Insertion in 18-16S transconjugants generated from filter matings with an S. lactis CH919 donor was random, occurring at different sites on the chromosome and also in plasmid DNA. Thus, the conditions necessary for the practical exploitation of Tn919 in the targeting and cloning of genes from a member of the lactic streptococci, namely, high-frequency delivery and random insertion in host DNA, were achieved.     

Molecular Studies on Entry Exclusion in Escherichia coli Minicells

Minicells produced by abnormal cell division in a strain of Escherichia coli (K-12) have been employed here to investigate the phenomenon of "entry exclusion." When purified minicells from strains containing F' or R factors, or both, are mated with radioactive thymidine-labeled Hfr or R(+) donors, the recipient minicells can be conveniently separated from normal-sized donors following mating, and the products of conjugation can be analyzed in the absence of donors and of further growth of the recipients. Transmissible plasmids or episomes are transferred less efficiently to purified minicells derived from strains carrying similar or related elements than to strains without them. Measurement of deoxyribonucleic acid (DNA) degradation and determination of weight-average molecular weights following transfer indicate that degradation of transferred DNA or transfer of smaller pieces cannot account for the comparative reduction in transfer to entry-excluding recipients. Therefore, we conclude that entry exclusion operates to prevent the physical entry of DNA into recipients expressing the exclusion phenotype. The R-produced repressor (product of the drd(+) gene), which represses fertility (i.e., ability to act as donor), reduces exclusion mediated by R or F factor, or both, in matings between strains carrying homologous elements. Furthermore, the data suggest that the presence of the F pilus or F-like R pilus on recipient cells ensures maximum expression of the exclusion phenotype but is not essential for its expression. In contrast to previous suggestions, we found no evidence for a reduction of entry exclusion attributable to the DNA temperature-sensitive chromosomal mutation dnaB(TS).     

Chromosome Transfer and Recombinant Formation with Deoxyribonucleic Acid Temperature-Sensitive Strains of Escherichia coli

Haploid recombinant yield is reduced in matings conducted at 42.5 C between deoxyribonucleic acid (DNA) temperature-sensitive [dna⁻(TS)] recipients unable to synthesize DNA at 42.5 C and any of the three major donor types (Hfr, F⁺, F′) of Escherichia coli. No such reduction is observed in matings conducted at 42.5 C when the dna⁻(TS) mutation is in the donor parent. Evidence is presented which indicates that chromosome transfer from donors to recipients unable to replicate DNA at 42.5 C during vegetative growth occurs at normal frequencies when the mating is conducted at 42.5 C. It is concluded that some stage in haploid recombinant formation is adversely affected in dna⁻(TS) recipients mated at the temperature restrictive for DNA synthesis.     

The requirements for conjugal DNA synthesis in the donor strain during flac transfer.

Although neither rifampicin nor spectinomycin had any effect on the frequency of Flac transfer by a sensitive donor, rifampicin but not spectinomycin prevented donor conjugal DNA synthesis as measured in matings between a dnaB donor and a tdk recipient. An untranslated RNA species is therefore probably required for this synthesis, although transfer took place even in its absence. Donor conjugal DNA synthesis was abolished in a dnaE donor, showing that DNA polymerase III is responsible for this process; again, plasmid DNA transfer was not affected.Flac mutants lacking the F pilus gave neither donor conjugal DNA synthesis nor plasmid DNA transfer, probably because they could not receive a “mating signal” to activate the transfer process. The products of traI and traM were also required both for donor conjugal DNA synthesis and for physical transfer of plasmid DNA, probably being involved in the conversion of covalently closed circular plasmid DNA into the open circular form that is the substrate for the independent although normally simultaneous synthesis and transfer steps. In contrast, donor conjugal DNA synthesis took place at a normal rate in both piliated traG and traN mutants, and at a reduced rate in traD mutants, although in no case was there physical transfer of plasmid DNA. These gene products are therefore required for DNA transfer to the recipient, and in addition, the absence of the traD product may hinder DNA synthesis.Based upon these results, a scheme for the processing of DNA during conjugation is presented.     

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

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

Molecular studies of FIme resistance plasmids, particularly in epidemic Salmonella typhimurium.

Summary The molecular sizes of F₁ me resistance plasmids from strains of Salmonella typhimurium, S. wien and S. typhi were within the range 87.9–102.6×10⁶ daltons. DNA reassociation studies indicated that the plasmids from these hosts had at least 80% of their nucleotide sequences in common. A high proportion of F₁ me plasmids cannot mediate their own transfer. The non-autotransferring property of such plasmids is the result of DNA deletion; a non-autotransferring F₁ me plasmid was about 10×10⁶ daltons shorter than autotransferring representatives of the group, and its DNA showed 100% homology with them. Plasmids of the F₁ me group are incompatible with the F factor and with F₁R factors. F₁ me plasmids are incompatible with the fi ⁺ MP10 plasmid of S. typhimurium, whereas F and F₁ factors are compatible with MP10 (Anderson et al., 1977). There was no significant DNA homology between members of the F₁ me group and MP10, and these plasmids may share only a small region of DNA responsible for their incompatibility. The F₁ me R factors examined had 29–37% DNA homology with the F factor, and 50–58% homology with the F₁ resistance plasmid, R162. Molecular examination therefore supports the genetic differentiation of members of the F₁ me group from other F-like plasmids. Both types of investigation can thus be used in epidemiological studies of bacterial strains carrying resistance or other plasmids.     

Mating variation by DNA inversions of shufflon in plasmid R64

Gene organization of the 54-kb transfer region of IncI1 plasmid R64 was deduced from the DNA sequence. Forty-eight ORFs were found in this region. A unique DNA rearrangement designated shufflon is located at the downstream region of an operon responsible for synthesis of thin pilus. The shufflon of R64 consists of four DNA segments, designated as A, B, C, and D, which are flanked and separated by seven 19-bp repeat sequences. Site-specific recombination mediated by the product of the rci gene between any two inverted repeats results in a complex DNA rearrangement. An analysis of open reading frames revealed that the shufflon is a biological switch to select one of seven C-terminal segments of the pilV genes. The products of pilV genes were shown to be components of thin pilus which was required for liquid mating.Seven R64 derivatives where the pilV genes were fixed in the seven C-terminal segments were constructed and their transfer frequencies in liquid mating were measured using various bacterial strains as recipients. Transfer frequencies of R64 in liquid mating strongly depended on the combination of C-terminal segments of the pilV genes in donor cells and bacterial strains of recipient cells, suggesting that the shufflon determines the recipient specificity in liquid mating of plasmid R64.     

Conjugal Transfer of Bacteriophage Resistance Determinants on pTR2030 into Streptococcus cremoris Strains

Agar surface conjugal matings were used to introduce heat-sensitive phage resistance (Hsp⁺) determinants carried on the conjugal plasmid pTR2030 into Streptococcus cremoris KH, HP, 924, and TDM1. Lactose-fermenting (Lac⁺) transconjugants were selected from matings of Lac⁻ variants of S. cremoris KH, HP, 924, and TDM1 with Streptococcus lactis ME2 or a high-frequency donor, S. lactis T-EK1 (pTR1040, Lac⁺; pTR2030, Hsp⁺). For all of the S. cremoris strains examined, select Lac⁺ transconjugants were completely resistant to plaquing by their homologous lytic phages. In all cases the plaquing efficiencies were less than 10⁻⁹. Acquisition of a 30-megadalton plasmid (pTR2030) in the S. cremoris phage-resistant transconjugants was demonstrated by direct plasmid analysis, by hybridization with ³²P-labeled probes, or by conjugal transfer of pTR2030 out of the phage-resistant transconjugants into a plasmid-cured recipient, S. lactis LM2302. Acid production, coagulation ability, and proteolytic activity of phage-resistant transconjugants in milk were comparable to those of their phage-sensitive parents. Further, S. cremoris phage-resistant transconjugants were not attacked by phage in starter culture activity tests, which included a 40°C incubation period. The results demonstrated that phage resistance determinants on pTR2030 could be conjugally transferred to a variety of S. cremoris strains and confer resistance to phage under conditions encountered during cheese manufacture. Phage-resistant transconjugants of S. cremoris M43 and HP were also constructed without the use of antiblotic markers to select conjugal recipients from mating mixtures.     

The Virulence Plasmid of Salmonella typhimurium Is Self-Transmissible

Most isolates of Salmonella enterica serovar Typhimurium contain a 90-kb virulence plasmid. This plasmid is reported to be mobilizable but nonconjugative. However, we have determined that the virulence plasmid of strains LT2, 14028, and SR-11 is indeed self-transmissible. The plasmid of strain SL1344 is not. Optimal conjugation frequency requires filter matings on M9 minimal glucose plates with a recipient strain lacking the virulence plasmid. These conditions result in a frequency of 2.9 × 10⁻⁴ transconjugants/donor. Matings on Luria-Bertani plates, liquid matings, or matings with a recipient strain carrying the virulence plasmid reduce the efficiency by up to 400-fold. Homologs of the F plasmid conjugation genes are physically located on the virulence plasmid and are required for the conjugative phenotype.     

Conjugal Deoxyribonucleic Acid Replication by Escherichia coli K-12: Stimulation in dnaB(ts) Donors by Minicells

R64-11(+) donor cells that are thermosensitive for vegetative DNA replication will synthesize DNA at the restrictive temperature when recipient minicells are present. This is conjugal DNA replication because it is R64-11 DNA that is being synthesized and there is no DNA synthesis if minicells that cannot be recipients of R64-11 DNA are used. The plasmid DNA present in the donor cells before mating is transferred to recipient minicells within the first 20 min of mating, but additional copies of plasmid DNA synthesized during the mating continue to be transferred for at least 90 min. However, the transfer of R64-11 DNA to minicells is not continuous because the plasmid DNA in minicells is the size of one R64-11 molecule or smaller, and there are delays between the rounds of plasmid transfer. DNA is synthesized in minicells during conjugation, but this DNA has a molecular weight much smaller than that of R64-11. Thus, recipient minicells are defective and are not able to complete the synthesis of a DNA strand complementary to the single-stranded R64-11 DNA received from the donor cell.     

Transferable lincosamide-macrolide resistance in Bacteroides.

Inter- and intraspecies transfer of resistance to clindamycin, lincomycin, and erythromycin in the strict anaerobe, Bacteroides, is described. This lincosamide-macrolide resistance was found to be specified by a 27 × 10⁶-dalton plasmid, designated pBF4, originally identified in a clinical Bacteroides fragilis isolate. Transfer of this plasmid to a strain of Bacteroides uniformis was demonstrated to occur by a deoxyribonuclease insensitive process which required cell-to-cell contact. Chloroform sterilized donor cell supernatants or filtrates of donor cells did not mediate resistance transfer. Transfer of the antibiotic resistance and pBF4 plasmid deoxyribonucleic acid (DNA) were always coincident. Drug resistant progeny recovered from such matings were able to transfer the pBF4 plasmid and its associated resistance markers to a suitable B.fragilis recipient strain. Compared to interspecies matings, resistance transfer was 100- to 1000-fold greater between isogenic donor and recipient strains, suggesting the possibility of a host controlled restriction-modification system.     

Genetic Analysis of the Role of the Transfer Gene, traN, of the F and R100-1 Plasmids in Mating Pair Stabilization during Conjugation

Mating pair stabilization occurs during conjugative DNA transfer whereby the donor and recipient cells form a tight junction which requires pili as well as TraN and TraG in the donor cell. The role of the outer membrane protein, TraN, during conjugative transfer was examined by introduction of a chloramphenicol resistance cassette into the traN gene on an F plasmid derivative, pOX38, to produce pOX38N1::CAT. pOX38N1::CAT was greatly reduced in its ability to transfer DNA, indicating that TraN plays a greater role in conjugation than previously thought. F and R100-1 traN were capable of complementing pOX38N1::CAT transfer equally well when wild-type recipients were used. F traN, but not R100-1 traN, supported a much lower level of transfer when there was an ompA mutation or lipopolysaccharide (LPS) deficiency in the recipient cell, suggesting receptor specificity. The R100-1 traN gene was sequenced, and the gene product was found to exhibit 82.3% overall similarity with F TraN. The differences were mainly located within a central region of the proteins (amino acids 162 to 333 of F and 162 to 348 of R100-1). Deletion analysis of F traN suggested that this central portion might be responsible for the receptor specificity displayed by TraN. TraN was not responsible for TraT-dependent surface exclusion. Thus, TraN, and not the F pilus, appears to interact with OmpA and LPS moieties during conjugation, resulting in mating pair stabilization, the first step in efficient mobilization of DNA.     

R-Plasmid Transfer to and from Escherichia coli Strains Isolated from Human Fecal Samples

Strains of Escherichia coli recently isolated from human feces were examined for the frequency with which they accept an R factor (R1) from a derepressed fi⁺ strain of E. coli K-12 and transfer it to fecal and laboratory strains. Colicins produced by some of the isolates rapidly killed the other half of the mating pair; therefore, conjugation was conducted by a membrane filtration procedure whereby this effect was minimized. The majority of fecal E. coli isolates accepted the R factor at lower frequencies than K-12 F⁻, varying from 10⁻² per donor cell to undetectable levels. The frequencies with which certain fecal recipients received the R-plasmid were increased when its R⁺ transconjugant was either cured of the R1-plasmid and remated with the fi⁺ strain or backcrossed into the parental strain. The former suggests the loss of an incompatibility plasmid, and the latter suggests the modification of the R1-plasmid deoxyribonucleic acid (DNA). In general, the fecal R⁺E. coli transconjugants were less effective donors for K-12 F⁻ and heterologous fecal strains than was the fi⁺ K-12 strain, whereas the single strain of Citrobacter freundii examined was generally more competent. Passage of the R1-plasmid to strains of salmonellae reached mating frequencies of 10⁻¹ per donor cell when the recipient was a Salmonella typhi previously cured of its resident R-plasmid. However, two recently isolated strains of Salmonella accepted the R1-plasmid from E. coli K-12 R⁺ or the R⁺E. coli transconjugants at frequencies of 5 × 10⁻⁷ or less.     

Measuring the rate of conjugal plasmid transfer in a bacterial population using quantitative PCR

Horizontal transfer of genes between species is an important mechanism for bacterial genome evolution. In Escherichia coli, conjugation is the transfer from a donor (F⁺) to a recipient (F⁻) cell through cell-to-cell contact. We demonstrate what we believe to be a novel qPCR method for quantifying the transfer kinetics of the F plasmid in a population by enumerating the relative abundance of genetic loci unique to the plasmid and the chromosome. This approach allows us to query the plasmid transfer rate without the need for selective culturing with unprecedented single locus resolution. We fit the results to a mass action model where the rate of plasmid growth includes the lag time of newly formed F⁺ transconjugants and the recovery time between successive conjugation events of the F⁺ donors. By assaying defined mixtures of genotypically identical donor and recipient cells at constant inoculation densities, we extract an F plasmid transfer rate of 5 × 10⁻¹⁰ (cells/mL · min)⁻¹. We confirm a plasmid/chromosome ratio of 1:1 in homogenous F⁺ populations throughout batch growth. Surprisingly, in some mixture experiments we observe an excess of F plasmid in the early saturation phase that equilibrates to a final ratio of one plasmid per chromosome.     

Efficient transfer of conjugative plasmids by multipoint inoculation and some observations on host range and prevalence of R plasmids.

The conjugational transfer of R plasmids was demonstrated using a simple manually operated multipoint inoculator apparatus (MIP) allowing rapid inoculation and later dilution and plating of 25 mating mixtures simultaneously. Forty-five R plasmids belonging to groups F, I, N, and others originally recovered in Escherichia coli K-12 were studied in this as well as in other hosts. The semiquantitative MIP conjugation method was more efficient than conventional matings, particularly when performed in two steps employing E. coli K-12 as intermediate host. Both as donor and as recipient, E. coli K-12 was the most “suitable” general host of the set of plamids studied, although with many plasmids the degree of expression of their transfer functions varied with the host. The expression of fertility in parental bacteria as well as factors in the new host not studied appeared to be of greater importance for the conjugational transfer of a plasmid than the host-specified restriction of plasmid deoxyribonucleic acid by the recipient strain. The MIP conjugation method was successfully used also during screening for transferable R plasmids in gram-negative bacteria present in urine and fecal specimens of humans. The use of a restrictionless mutant instead of a restricting K-12 recipient enabled the detection of additional plasmids. The labor and media-saving MIP conjugation method thus also offers efficiency and is very practical for the performance of large numbers of plasmid matings, for example, in studies of compatibilty, host range, and mobilization of plasmids, as well as for screening purposes.     

Heterotrophic bacteria of the freshwater neuston and their ability to act as plasmid recipients under nutrient deprived conditions

Significantly higher numbers of Gram-negative heterotrophic bacteria were present at the air-water interface (neston) of freshwater lakes than in the bulk water. Neuston bacteria were distinguished as a population distinct from bacteria in the bulk water by a higher incidence of pigmented colony types and significantly greater levels of multiple resistance to antibiotics and heavy metals. The incidence of plasmids in 236 neuston and 229 bulk water strains were similar (14 and 16.2%, respectively). Nine of 168 plasmid-free strains and 2 of 14 plasmid carrying strains, isolated from both bulk water and neuston, acted as recipients of plasmid R68.45 in plate matings with aPseudomonas aeruginosa donor strain PAO4032 at 21°C, but at frequencies below that of matings with a restriction-minus recipient strain ofP. aeruginosa, strain PAO1168. In a model system composed of nutrient-free synthetic lake water, plasmid R68.45 was shown to transfer betweenP. aeruginosa strains at frequencies between 10⁻³ and 10⁻⁵. Transconjugants were detected about 100 times more frequently at the interface than in the bulk water, which in part reflected a greater enrichment of the donor at this site. None of the aquatic isolates were able to act as recipients of plasmid R68.45 in this model system with strain PAO4032 as donor. The results suggest that under nutrient deprived conditions, the spread of plasmid R68.45 and similar plasmids by lateral transfer into this particular aquatic population would be a rare event.