Extrachromosomal elements as possible agents of adaptation and development

Inter-replicon Gene Flow Contributes to Transcriptional Integration in the Sinorhizobium meliloti Multipartite Genome

Integration of newly acquired genes into existing regulatory networks is necessary for successful horizontal gene transfer (HGT). Ten percent of bacterial species contain at least two DNA replicons over 300 kilobases in size, with the secondary replicons derived predominately through HGT. The Sinorhizobium meliloti genome is split between a 3.7 Mb chromosome, a 1.7 Mb chromid consisting largely of genes acquired through ancient HGT, and a 1.4 Mb megaplasmid consisting primarily of recently acquired genes. Here, RNA-sequencing is used to examine the transcriptional consequences of massive, synthetic genome reduction produced through the removal of the megaplasmid and/or the chromid. Removal of the pSymA megaplasmid influenced the transcription of only six genes. In contrast, removal of the chromid influenced expression of ∼8% of chromosomal genes and ∼4% of megaplasmid genes. This was mediated in part by the loss of the ETR DNA region whose presence on pSymB is due to a translocation from the chromosome. No obvious functional bias among the up-regulated genes was detected, although genes with putative homologs on the chromid were enriched. Down-regulated genes were enriched in motility and sensory transduction pathways. Four transcripts were examined further, and in each case the transcriptional change could be traced to loss of specific pSymB regions. In particularly, a chromosomal transporter was induced due to deletion of bdhA likely mediated through 3-hydroxybutyrate accumulation. These data provide new insights into the evolution of the multipartite bacterial genome, and more generally into the integration of horizontally acquired genes into the transcriptome.

Why Bacteriophage Encode Exotoxins and other Virulence Factors

This study considers gene location within bacteria as a function of genetic element mobility. Our emphasis is on prophage encoding of bacterial virulence factors (VFs). At least four mechanisms potentially contribute to phage encoding of bacterial VFs: (i) Enhanced gene mobility could result in greater VF gene representation within bacterial populations. We question, though, why certain genes but not others might benefit from this mobility. (ii) Epistatic interactions—between VF genes and phage genes that enhance VF utility to bacteria—could maintain phage genes via selection acting on individual, VF-expressing bacteria. However, is this mechanism sufficient to maintain the rest of phage genomes or, without gene co-regulation, even genetic linkage between phage and VF genes? (iii) Phage could amplify VFs during disease progression by carrying them to otherwise commensal bacteria colocated within the same environment. However, lytic phage kill bacteria, thus requiring assumptions of inclusive fitness within bacterial populations to explain retention of phage-mediated VF amplification for the sake of bacterial utility. Finally, (iv) phage-encoded VFs could enhance phage Darwinian fitness, particularly by acting as ecosystem-modifying agents. That is, VF-supplied nutrients could enhance phage growth by increasing the density or by improving the physiology of phage-susceptible bacteria. Alternatively, VF-mediated break down of diffusion-inhibiting spatial structure found within the multicellular bodies of host organisms could augment phage dissemination to new bacteria or to environments. Such phage-fitness enhancing mechanisms could apply particularly given VF expression within microbiologically heterogeneous environments, ie, ones where phage have some reasonable potential to acquire phage-susceptible bacteria.

Restriction and modification in group N streptococci: effect of heat on development of modified lytic bacteriophage

The appearance of lytic bacteriophage against newly introduced starter strains used during commercial cheese manufacture occurs rapidly, and their origin is not well understood. In this study, members of the group N streptococci were examined for the presence of bacteriophage restriction and modification systems. Two streptococcal phages from Streptococcus cremoris TR and Streptococcus lactis C2 (phage designations tr and c2) showed restricted lytic development on S. cremoris 799 and KH, respectively. Efficiency of plaquing was 1.9 x 10 for tr plaqued on 799 and 2.1 x 10 for c2 plaqued on KH. After passage through the restrictive hosts, these phages demonstrated high lytic ability for formerly restrictive hosts. Stress of the restrictive host strains at temperatures of 40 to 50 degrees C resulted in a significant increase in the efficiency of plaquing of restricted bacteriophages. Elevated temperatures are encountered during commercial cheese manufacture. The results suggested that the temporary loss of host restriction activity with the resulting modification of nonspecific bacteriophage may contribute directly to the appearance of lytic phage against new starter strains.

Conserved symbiotic plasmid DNA sequences in the multireplicon pangenomic structure of Rhizobium etli

Strains of the same bacterial species often show considerable genomic variation. To examine the extent of such variation in Rhizobium etli, the complete genome sequence of R. etli CIAT652 and the partial genomic sequences of six additional R. etli strains having different geographical origins were determined. The sequences were compared with each other and with the previously reported genome sequence of R. etli CFN42. DNA sequences common to all strains constituted the greater part of these genomes and were localized in both the chromosome and large plasmids. About 700 to 1,000 kb of DNA that did not match sequences of the complete genomes of strains CIAT652 and CFN42 was unique to each R. etli strain. These sequences were distributed throughout the chromosome as individual genes or chromosomal islands and in plasmids, and they encoded accessory functions, such as transport of sugars and amino acids, or secondary metabolism; they also included mobile elements and hypothetical genes. Sequences corresponding to symbiotic plasmids showed high levels of nucleotide identity (about 98 to 99%), whereas chromosomal sequences and the sequences with matches to other plasmids showed lower levels of identity (on average, about 90 to 95%). We concluded that R. etli has a pangenomic structure with a core genome composed of both chromosomal and plasmid sequences, including a highly conserved symbiotic plasmid, despite the overall genomic divergence.

A common genomic framework for a diverse assembly of plasmids in the symbiotic nitrogen fixing bacteria

This work centres on the genomic comparisons of two closely-related nitrogen-fixing symbiotic bacteria, Rhizobium leguminosarum biovar viciae 3841 and Rhizobium etli CFN42. These strains maintain a stable genomic core that is also common to other rhizobia species plus a very variable and significant accessory component. The chromosomes are highly syntenic, whereas plasmids are related by fewer syntenic blocks and have mosaic structures. The pairs of plasmids p42f-pRL12, p42e-pRL11 and p42b-pRL9 as well large parts of p42c with pRL10 are shown to be similar, whereas the symbiotic plasmids (p42d and pRL10) are structurally unrelated and seem to follow distinct evolutionary paths. Even though purifying selection is acting on the whole genome, the accessory component is evolving more rapidly. This component is constituted largely for proteins for transport of diverse metabolites and elements of external origin. The present analysis allows us to conclude that a heterogeneous and quickly diversifying group of plasmids co-exists in a common genomic framework.

Why bacteriophage encode exotoxins and other virulence factors

This study considers gene location within bacteria as a function of genetic element mobility. Our emphasis is on prophage encoding of bacterial virulence factors (VFs). At least four mechanisms potentially contribute to phage encoding of bacterial VFs: (i) Enhanced gene mobility could result in greater VF gene representation within bacterial populations. We question, though, why certain genes but not others might benefit from this mobility. (ii) Epistatic interactions-between VF genes and phage genes that enhance VF utility to bacteria-could maintain phage genes via selection acting on individual, VF-expressing bacteria. However, is this mechanism sufficient to maintain the rest of phage genomes or, without gene co-regulation, even genetic linkage between phage and VF genes? (iii) Phage could amplify VFs during disease progression by carrying them to otherwise commensal bacteria colocated within the same environment. However, lytic phage kill bacteria, thus requiring assumptions of inclusive fitness within bacterial populations to explain retention of phage-mediated VF amplification for the sake of bacterial utility. Finally, (iv) phage-encoded VFs could enhance phage Darwinian fitness, particularly by acting as ecosystem-modifying agents. That is, VF-supplied nutrients could enhance phage growth by increasing the density or by improving the physiology of phage-susceptible bacteria. Alternatively, VF-mediated break down of diffusion-inhibiting spatial structure found within the multicellular bodies of host organisms could augment phage dissemination to new bacteria or to environments. Such phage-fitness enhancing mechanisms could apply particularly given VF expression within microbiologically heterogeneous environments, ie, ones where phage have some reasonable potential to acquire phage-susceptible bacteria.

Shiga-toxin-converting bacteriophages

Shiga toxins (Stx) comprise a family of potent cytotoxins that are involved in severe human disease. Stx are mainly produced by Escherichia coli isolated from human and nonhuman sources, and by Shigella dysenteriae type 1. The genes encoding Stx are thought to be generally encoded in the genome of lambdoid prophages (Stx-converting bacteriophages; Stx phages). They share a unique position in the late region of the phage genome downstream of the late promoter PR'. This location suggests that expression of stx is controlled by a Q-like antiterminator. Therefore, induction of Stx-converting prophages appears to trigger increased production of Stx. Following induction, Stx phages can be transduced in vivo and in vitro into other bacteria. Stx phages play an important role in the expression of Stx and in lateral gene transfer and are therefore a contribution to the emergence of new Stx-producing E. coli (STEC) variants.

Comparative survival of free shiga toxin 2-encoding phages and Escherichia coli strains outside the gut

The behavior outside the gut of seeded Escherichia coli O157:H7, naturally occurring E. coli, somatic coliphages, bacteriophages infecting O157:H7, and Shiga toxin 2 (Stx2)-encoding bacteriophages was studied to determine whether the last persist in the environment more successfully than their host bacteria. The ratios between the numbers of E. coli and those of the different bacteriophages were clearly lower in river water than in sewage of the area, whereas the ratios between the numbers of the different phages were similar. In addition, the numbers of bacteria decreased between 2 and 3 log units in in situ survival experiments performed in river water, whereas the numbers of phages decreased between 1 and 2 log units. Chlorination and pasteurization treatments that reduced by approximately 4 log units the numbers of bacteria reduced by less than 1 log unit the numbers of bacteriophages. Thus, it can be concluded that Stx2-encoding phages persist longer than their host bacteria in the water environment and are more resistant than their host bacteria to chlorination and heat treatment.

Accessory DNA in the genomes of representatives of the Escherichia coli reference collection

Different strains of the Escherichia coli reference collection (ECOR) differ widely in chromosomal size. To analyze the nature of the differential gene pool carried by different strains, we have followed an approach in which random amplified polymorphic DNA (RAPD) was used to generate several PCR fragments. Those present in some but not all the strains were screened by hybridization to assess their distribution throughout the ECOR collection. Thirteen fragments with various degrees of occurrence were sequenced. Three of them corresponded to RAPD markers of widespread distribution. Of these, two were housekeeping genes shown by hybridization to be present in all the E. coli strains and in Salmonella enterica LT2; the third fragment contained a paralogous copy of dnaK with widespread, but not global, distribution. The other 10 RAPD markers were found in only a few strains. However, hybridization results demonstrated that four of them were actually present in a large selection of the ECOR collection (between 42 and 97% of the strains); three of these fragments contained open reading frames associated with phages or plasmids known in E. coli K-12. The remaining six fragments were present in only between one and four strains; of these, four fragments showed no similarity to any sequence in the databases, and the other two had low but significant similarity to a protein involved in the Klebsiella capsule synthesis and to RNA helicases of archaeal genomes, respectively. Their percent GC, dinucleotide content, and codon adaptation index suggested an exogenous origin by horizontal transfer. These results can be interpreted as reflecting the presence of a large pool of strain-specific genes, whose origin could be outside the species boundaries.

Prevalence of broad-host-range lytic bacteriophages of Sphaerotilus natans, Escherichia coli, and Pseudomonas aeruginosa

Two bacteriophage collections were examined with regard to their ability to form plaques on multiple bacterial host species. Nine of 10 phages studied were found to be broad-host-range bacteriophages. These phages fell into two groups. Group 1, the SN series, was isolated from sewage treatment plant samples with Sphaerotilus natans ATCC 13338 as a host. The DNAs of these bacteriophages contained modified bases and were insensitive to cleavage by type I and II restriction endonucleases. The efficiency of plating of these bacteriophages was changed only slightly on the alternate host. Group 2, the BHR series, was isolated by a two-host enrichment protocol. These bacteriophages were sensitive to restriction, and their efficiency of plating was dramatically reduced on the alternate host. Our results suggest that a multiple-host enrichment protocol may be more effective for the isolation of broad-host-range bacteriophages by avoiding the selection bias inherent in single-host methods. At least two of the broad-host-range bacteriophages mediated generalized transduction. We suggest that broad-host-range bacteriophages play a key role in phage ecology and gene transfer in nature.

Rhizobium gone native: unexpected plasmid stability of indigenous Rhizobium leguminosarum

Lateral transfer of bacterial plasmids is thought to play an important role in microbial evolution and population dynamics. However, this assumption is based primarily on investigations of medically or agriculturally important bacterial species. To explore the role of lateral transfer in the evolution of bacterial systems not under intensive, human-mediated selection, we examined the association of genotypes at plasmid-encoded and chromosomal loci of native Rhizobium, the nitrogen-fixing symbiont of legumes. To this end, Rhizobium leguminosarum strains nodulating sympatric species of native Trifolium were characterized genetically at plasmid-encoded symbiotic (sym) regions (nodulation AB and nodulation CIJT loci) and a repeated chromosomal locus not involved in the symbiosis with legumes. Restriction fragment length polymorphism analysis was used to distinguish genetic groups at plasmid and chromosomal loci. The correlation between major sym and chromosomal genotypes and the distribution of genotypes across host plant species and sampling location were determined using chi2 analysis. In contrast to findings of previous studies, a strict association existed between major sym plasmid and chromosomal genetic groups, suggesting a lack of successful sym plasmid transfer between major Rhizobium chromosomal types. These data indicate that previous observations of sym plasmid transfer in agricultural settings may seriously overestimate the rates of successful conjugation in systems not impacted by human activities. In addition, a nonrandom distribution of Rhizobium genotypes across host plant species and sampling site demonstrates the importance of both factors in shaping Rhizobium population dynamics.

Homology among nearly all plasmids infecting three Bacillus species

We have surveyed naturally occurring plasmids in strains of Bacillus subtilis and the closely related species B. mojavensis and B. licheniformis. Previous studies have failed to find host-benefitting functions for plasmids of these species, suggesting that these plasmids are nonmutualistic. Only one type of plasmid was found in each plasmid-bearing strain, suggesting that most of the plasmids infecting these Bacillus species are in the same incompatibility group. A sample of 18 plasmids from these species ranged in size from 6.9 to 16 kb, with all but 6 plasmids falling into three size groups. These groups differed in the sizes of their host ranges and geographical ranges. All but 1 of the 18 plasmids from these three host species are homologous with one another. The cryptic plasmids from these three species are far less diverse than are plasmids (from other species) that are known to benefit their bacterial hosts. The low-level diversity among these cryptic plasmids is consistent with the hypothesis that host-benefitting adaptations play an important role in fostering the coexistence of plasmid populations, but other explanations for the low-level plasmid diversity are possible. Comparison of the phylogenies of the plasmids with those of their hosts suggests that Bacillus plasmids are horizontally transferred in nature at a low rate similar to that found for the colicin plasmids of Escherichia coli.

Nucleotide polymorphism in colicin E1 and Ia plasmids from natural isolates of Escherichia coli

We examined DNA sequence polymorphism for the colicin gene clusters of seven ColE1 and six ColIa plasmids obtained from natural isolates of Escherichia coli. These gene clusters harbor levels of nucleotide diversity ranging from 0.006 (ColIa) to 0.054 (ColE1). This level of diversity is similar to that observed for chromosomally encoded E. coli genes. However, the variance associated with these estimates is severalfold higher for the plasmid-encoded genes. This increased variance may be due to the differing plasmid population sizes. The pattern of colicin gene cluster polymorphism suggests that the two colicins are evolving in different fashions. ColE1 accumulates polymorphism at an elevated rate in the central domain of the colicin protein, while ColIa polymorphism is distributed evenly along the gene cluster. Comparison of the patterns of divergence between colicin and related proteins of ColIa and Ib and patterns of polymorphism within ColIa suggest that this gene cluster is not evolving in a neutral fashion. These data lend support to the hypothesis that colicin gene clusters may evolve under the influence of diversifying selection.

Macroevolution of plasmids: a model for plasmid speciation

A new evolutionary model for diversification in plasmid incompatibility groups (plasmid speciation) is suggested. The model is based on the formation of plasmid cointegrates from two compatible plasmids. The existence of plasmid cointegrates is well known, however, their potential key role in plasmid macroevolution has not yet been recognized. In a hypothesis presented here, one of the rep genes is supposed to be relaxed from selection in plasmid cointegrates and thus becomes free to accumulate mutations. These mutations can lead to a change in incompatibility specificity. Evidence supporting this hypothesis comes from the common occurrence of multi-replicon plasmids in nature as well as from experimental studies on plasmid cointegrate formation. A more speculative extension of this model hypothesizes an evolutionary scenario for origin of the eubacterial single-replicon genome and the eukaryotic multi-replicon genome, as well as the place of plasmids and viruses in this picture.

Genetic changes accompanying increased fitness in evolving populations of Escherichia coli

Two populations of Escherichia coli, each initiated with a single clone containing a derivative of the plasmid pBR322, were maintained for long periods in glucose-limited continuous culture. In both populations, after an extensive number of generations had elapsed, clones were isolated in which the transposon Tn3 from the plasmid had integrated into the bacterial chromosome. In both cases examined, the transpositions were shown to increase relative fitness approximately 6-7%, in the environment in which the populations were maintained. The loci of integration were mapped to approximately 13.2 min (population 1) and approximately 32.8 min (population 2).

Modular transposition and the dynamical structure of eukaryote regulatory evolution

This paper examines a model in which transposable elements provide a modular architecture for the cellular genome, complemented by cellular recombinational transformations, arising in turn as a dynamical consequence of this modular structure. It is proposed that the ecology of transposable elements in a given organism is a function of recombinational protocols of the evolving cellular genome. In mammals this is proposed to involve coordinated meiosis-phased activation of LINEs, SINEs and retrogenes complemented by endogenous retroviral transfer between cells.

The existence conditions for bacterial plasmids: Theory and reality

Bacteria abound with conjugative and nonconjugative plasmids that often carry genes determining a number of environmental adaptations. Plasmids may also encode genes that enable them to transmit themselves infectiously to new host cells, by conjugation or mobilization. The question of whether plasmids can be maintained in a bacterial community as parasitic DNA, that is, while conferring a selective disadvantage to their host, serves as a basic hypothesis in theoretical studies of the population biology of plasmids. The conditions necessary for the establishment and maintenance of plasmids have been determined analytically for the simplest possible models. Based on these a priori conditions, on some reconsiderations and extensions of these models, and on recent estimates of transfer rates of liquid and surface bacterial populations, it will be argued that within a bacterial population, a parasitic lifestyle is unlikely for most naturally occurring plasmids. This result raises anew the problem of how cryptic plasmids are maintained and why plasmids encode costly and elaborate genes for horizontal transfer.

Organization of the bacterial chromosome

Recent progress in studies on the bacterial chromosome is summarized. Although the greatest amount of information comes from studies on Escherichia coli, reports on studies of many other bacteria are also included. A compilation of the sizes of chromosomal DNAs as determined by pulsed-field electrophoresis is given, as well as a discussion of factors that affect gene dosage, including redundancy of chromosomes on the one hand and inactivation of chromosomes on the other hand. The distinction between a large plasmid and a second chromosome is discussed. Recent information on repeated sequences and chromosomal rearrangements is presented. The growing understanding of limitations on the rearrangements that can be tolerated by bacteria and those that cannot is summarized, and the sensitive region flanking the terminator loci is described. Sources and types of genetic variation in bacteria are listed, from simple single nucleotide mutations to intragenic and intergenic recombinations. A model depicting the dynamics of the evolution and genetic activity of the bacterial chromosome is described which entails acquisition by recombination of clonal segments within the chromosome. The model is consistent with the existence of only a few genetic types of E. coli worldwide. Finally, there is a summary of recent reports on lateral genetic exchange across great taxonomic distances, yet another source of genetic variation and innovation.

Direct involvement of IS26 in an antibiotic resistance operon

The plasmid pBWH77, originally found in an isolate of Klebsiella pneumoniae, harbors a new antibiotic resistance operon containing two resistance genes transcribed from an IS26-hybrid promoter, as shown by nucleotide sequencing, mRNA mapping, and the effect of inserting a transcription terminator within the promoter-proximal gene. The nucleotide sequence of this region revealed that the operon (IAB) is made up of three sections that are closely related to previously described genetic elements. The -35 region of the promoter, together with the adjacent sequence, is identical to sequences of the IS26 element. One of the resistance genes, aphA7, which is located next to the hybrid promoter, confers assistance to neomycin and structurally related aminoglycosides. This aphA7 gene is highly homologous to aphA1 of Tn903, with five nucleotide differences. The second gene, blaS2A, encodes an evolved SHV-type beta-lactamase with a pI of 7.6 that confers resistance to the broad-spectrum cephalosporins cefotaxime and ceftizoxime. The deduced amino acid sequence of SHV-2A shows that amino acid 238 is a serine, a residue reported to confer resistance to cefotaxime. We discuss how the operon may have evolved by a combination of insertion sequence-mediated genetic rearrangements and acquisitive evolution. Using phylogenetic parsimony, we show that aphA7 in the IAB operon evolved from an ancestral form similar to aphA1 in Tn903 and that blaS2A evolved from an ancestral form similar to blaS1.

Molecular clocks and evolutionary relationships: possible distortions due to horizontal gene flow

This paper discusses recent evidence suggesting that genetic information from one species occasionally transfers to another remotely related species. Besides addressing the issue of whether or not the molecular data are consistent with a wide-spread influence of horizontal gene transfer, the paper shows that horizontal gene flow would not necessarily preclude a linear molecular clock or change the rate of molecular evolution (assuming the neutral allele theory). A pervasive influence of horizontal gene transfer is more than just consistent with the data of molecular evolution, it also provides a unique explanation for a number of possibly conflicting phylogenies and contradictory clocks. This phenomenon might explain why some protein clocks are linear while the superoxide dismutase clock is not, how the molecular data on the phylogeny of apes and Australian song birds are not necessarily in conflict with those based on morphology, and, finally, why the mycoplasmas have an accelerated molecular clock.

Bacterial evolution

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Naturally occurring TOL plasmids in Pseudomonas strains carry either two homologous or two nonhomologous catechol 2,3-oxygenase genes

Structural genes for catechol 2,3-oxygenase (C23O) were cloned from the TOL plasmids pWW5, pWW14, pWW74, pWW84, and pWW88 isolated from Pseudomonas strains of diverse geographical origins. Each pKT230-based C23O+ recombinant plasmid carried a 2.05-kilobase XhoI insert which showed strong homology in Southern hybridizations with the xylE gene from the archetype TOL plasmid pWW0. Fragments were mapped for restriction endonuclease sites and were classified into two closely related groups on the basis of restriction maps. C23O structural genes were located on cloned fragments by a combination of subcloning and site-specific mutagenesis. All five TOL plasmids examined yielded clones whose maps differed from that of xylE of pWW0 by only a single XbaI site, but in addition plasmids pWW5, pWW74, and pWW88 carried a second, homologous C23O gene with seven further restriction site differences. The remaining plasmids, pWW14 and pWW84, carried a second nonhomologous C23O gene related to the second C23O gene (C23OII) of TOL plasmid pWW15 described previously (H. Keil, M. R. Lebens, and P. A. Williams, J. Bacteriol. 163:248-255, 1985). Thus, each naturally occurring TOL plasmid in this study appears to carry genes for two meta cleavage dioxygenases.

Genetic rearrangements of a Rhizobium phaseoli symbiotic plasmid

Different structural changes of the Sym plasmid were found in a Rhizobium phaseoli strain that loses its symbiotic phenotype at a high frequency. These rearrangements affected both nif genes and Tn5 mob insertions in the plasmid, and in some cases they modified the expression of the bacterium's nodulation ability. One of the rearrangements was more frequent in heat-treated cells, but was also found under standard culture conditions; other structural changes appeared to be related to the conjugal transfer of the plasmid.

A model for transposon-based eucaryote regulatory evolution

This paper presents a compact model of the role of transposable elements in eucaryote evolution which, although forward looking, is consistent with both experimental results and theories of gene regulation. The model postulates that a principal factor in the emergence of the eucaryotes was the development of a symbiotic relationship between reverse transcribing transposable elements and RNA based gene regulation, which we will call structural symbiosis. Thus, although transposable elements follow their own evolutionary protocol, structural homologies between "cellular" and "viral" genomes result in selective mutagenesis, a situation where transposon mutations are permitted because they can result in phenotypic mutations of the regulatory process with reduced probability of deleterious mutation of structural genes. The incorporation of this scheme into the life cycle of higher organisms results in two forms of integral evolution. Exogenous, in which differing species in an ecosystem share genetic information through viral transfer, and endogenous in which somatically induced regulatory mutations can be mapped back into the germ line.

Conversion by corynephages and its role in the natural history of diphtheria

The conversion of non-toxinogenic Corynebacterium diphtheriae to toxinogeny has been reviewed. The biology of converting phage and the relationship of converting phages to nonconverting phages are summarized. The significance of these findings to the natural history and evolution of diphtheria is assessed.

Transfer and stability of drug resistance plasmids inEscherichia coli K12

Mating experiments between pairs of strains ofEscherichia coli containing either the compatible plasmids TP120 (Inc N) and R1 (Inc FII) or the incompatible plasmids TP125 (Inc B) and TP113 (Inc B) were undertaken in mixed continuous-flow cultures and in dialysis sacs suspended in pond water. Plasmid transfer was readily demonstrated between strains carrying compatible plasmids TP120 and R1 in both continuous-flow culture and pond water. In mixed cultures of strains carrying plasmids TP125 and TP113, transfer was only observed in continuous-flow culture systems. Strains ofE. coli containing aggregates of plasmids TP120 and R1 were shown to be stable over 5 months continuous cultivation under carbon limited conditions at a growth rate of 0.1 hours(-1) in the presence of drugs which select for the maintenance of both plasmids. In the strains containing plasmid aggregates, a gene dosage effect was observed with respect to the levels of resistance to drugs whose resistance was encoded by both plasmids. Chemostat experiments showed that no cointegrate plasmids were found from the strains ofE. coli initially containing both plasmid TP120 and plasmid R1.

Plasmid pattern analysis of natural bacterial isolates and its epidemiological implication

Natural isolates of Escherichia coli, Salmonella typhimurium, Klebsiella pneumoniae, and Providencia stuartii were analysed to determine their plasmid content. This data allowed the identification of nosocomial strains of K. pneumoniae and P. stuartii and helped in the differentiation of epidemic strains of E. coli 0111 and S. typhimurium. Phenotypically similar isolates of S. typhimurium could be shown to be of independent origin using plasmid pattern analysis. The dissemination of a particular plasmid through different strains of S. typhimurium resulted in a simulation of a very widely distributed epidemic strain, because the plasmid interfered with the phage type of its host strain in addition to determining resistance properties. Plasmid pattern analysis disclosed two independently existing but interacting epidemic processes: a bacterial 'epidemic' strain may become disseminated over a large territory and may predominate there for a long time; a single plasmid, however, may also become distributed through many different bacterial strains and may spread over a large territory. Plasmid pattern analysis provides a valuable and universal epidemiological laboratory method.

Plasmids from Staphylococcus aureus replicate in yeast Saccharomyces cerevisiae

It is known that some plasmids, such as RP4, can replicate in many Gram-negative bacteria. Certain small Staphylococcus aureus plasmids have an even broader host range, being able to replicate in not only phylogenetically distant Gram-positive bacteria such as Bacillus subtilis or Streptococcus pneumoniae, but also in the Gram-negative bacterium Escherichia coli. Here we have examined whether these plasmids can also replicate in a lower eukaryote, the yeast Saccharomyces cerevisiae. For this purpose we constructed hybrids between a S. aureus plasmid pC194 and an E. coli plasmid YIp5, which carries a ura-3 gene easy to select for in yeast but cannot replicate in this host. We found that the hybrids transformed yeast with high efficiency (as did hybrids between YIp5 and three other S. aureus plasmids); were maintained extrachromosomally in yeast; and were not modified during residence in yeast. We conclude from this evidence that S. aureus plasmids can replicate in yeast, which raises the questions of whether the replication signals used by prokaryotes and eukaryotes are similar, and how far up the phylogenetic tree the organisms still able to be hosts to S. aureus plasmids may be.

Discontinuity of homology of Escherichia coli and Salmonella typhimurium DNA in the lac region

Partial homology of Salmonella typhimurium DNA to Escherichia coli DNA was demonstrated by Southern hybridization blots to exist on either side of the lac operon of E. coli but no homology was detected between S. typhimurium DNA and about 12 kb of E. coli DNA including the lac genes as well as about 5 kb of E. coli DNA between lac and proC. Thus portions of DNA seem to have been either added to the E.coli genome or deleted from the S. typhimurium genome since their divergence from a common ancestor. Although an IS1 element was located near the lac operon of E. coli, the insertional element was shown not to be near any of the junctures of discontinuity of E. coli--S. typhimurium homology near lac.

Staphylococcal plasmids that replicate and express erythromycin resistance in both Streptococcus pneumoniae and Escherichia coli

Plasmid pSA5700 from Staphylococcus aureus coding for erythromycin (EmR) and chloramphenicol (CmR) resistance was transformed into Streptococcus pneumoniae. High-copy-number and EmR constitutive mutants of this plasmid were isolated. Transformation frequencies in S. pneumoniae as high as 70% were obtained with a constitutive plasmid as donor DNA, into a recipient cell containing a resident, inducible, high-copy-number plasmid. With the aid of these high frequencies, the site of constitutive mutations could be mapped via a simple marker rescue technique that uses purified restriction endonuclease-generated fragments. One of the EmR constitutive mutants, pFB9, a plasmid originating from a Gram-positive host, was shown to replicate and express EmR and CmR in a Gram-negative organism, Escherichia coli. Four derivatives of pFB9 containing large (0.6-0.9 megadalton) insertion sequences that arose spontaneously in E. coli demonstrated unusual transforming activity, as well as enhanced EmR, in E. coli. The inserted elements mapped to the region in front of the EmR gene. Three of these inserted elements had the size and restriction patterns of insertion sequence IS1, IS2, and IS5. Plasmid pFB9 and derivatives are useful for isolation of new insertion sequences and for comparison of gene expression and illegitimate recombination between Gram-positive and Gram-negative species.

The density distribution of gene loci over the genetic map of Escherichia coli: its structural, functional and evolutionary implications

A quantitative analysis was carried out on the dispersion of gene loci over the E. coli genetic map. Therefore, the map was divided into regions characterized by an homogeneous gene density. This created a distribution pattern of gene loci that contained a symmetry axis located near to the origin of DNA replication. The pattern could be subdivided into a set of 22 functional domains containing gene loci whose products revealed a biochemical or functional relatedness. A correlation was found between the boundary positions of these domains and the distribution of F plasmid- and DNA insertion sites over the E. coli chromosome. The structural, functional and evolutionary implications of these findings are discussed.

Similar amino acid sequences: chance or common ancestry?

The systemic comparison of every newly determined amino acid sequence with all other known sequences may allow a complete reconstruction of the evolutionary events leading to contemporary proteins. But sometimes the surviving similarities are so vague that even computer-based sequence comparisons procedures are unable to validate relationships. In other cases similar sequences may appear in totally alien proteins as a result of mere chance or, occasionally, by the convergent evolution of sequences with special properties.

Replication of plasmids from Staphylococcus aureus in Escherichia coli

Plasmid pBR322 derives from plasmid ColE1 and does not replicate in Escherichia coli strains lacking DNA polymerase I. Hybrids between pBR322 and a plasmid isolated from Staphylococcus aureus, pC194, replicate in such E. coli strains, provided that the pC194 replication region is intact. Inactivation of the pBR322 replication region does not interfere with the replication of hybrids in E. coli. Hybrids between pBR322 and two other plasmids from S. aureus, pT127 and pUB112, and replicate at the restrictive temperature in E. coli having thermosensitive DNA polymerase I. Similar hybrids involving pC221 and pHV400, plasmids from S. aureus and Bacillus subtilis, respectively, do not replicate under such conditions. These results show that some plasmids from a Gram-positive bacterium, S. aureus, can replicate in a Gram-negative one, E. coli.

Interactions Between Light and Gas Vacuoles in Halobacterium salinarium Strain 5: Effect of Ultraviolet Light

The potential light shielding by intracellular gas vacuoles in Halobacterium salinarium strain 5 was examined by looking at the ultraviolet light inactivation curves of both wild-type cells and mutants which are defective in the production of gas vacuoles. Whereas strains defective in gas vacuole production were slightly more sensitive to ultraviolet inactivation, no significant differences in ultraviolet sensitivity were seen, indicating that these subcellular inclusion bodies are not effective as light-shielding organelles. In addition, it was shown that ultraviolet light acts as a plasmid-curing agent in Halobacterium .

On procaryotic gene expression in eucaryotic systems

Numerous types of interaction between pro- and eucaryotes exist in nature, from the endosymbiosis of some bacteria with unicellular organisms and insects to the complex systems of bacterial flora associated with the skin and intestines of animals and man, and nitrogen-fixation and crown-gall tumor induction in plants. Until recently, such interactions were not thought to include genetic transfer, but an increasing body of evidence points to the probability of similar naturally-occurring exchanges with wide-ranging implications for evolution and genetic manipulation. Experiments to elucidate the possible effects of procaryotic genes in eucaryotic systems have included in vitro and in vivo studies with both plant and animal systems, for instance the translation of bacterial messenger RNAs in the wheat germ and rabbit reticulocyte systems and the introduction of bacterial genes into plant protoplasts, animal cells and whole organisms. In the present paper we have tried to summarize the results of experiments involving the uptake, replication, transcription, translation and integration of procaryotic genes in various eucaryotic systems and to discuss the implications of such findings for basic research as well as for possible biomedical applications. Awareness of the possibility of procaryotic-eucaryotic genetic interactions may help to elucidate unresolved questions in pathology, such as possible involvement of the intestinal flora in carcinogenesis, as well as to provide valuable probes of eucaryotic control mechanisms and new approaches in agricultural genetic engineering.

Interspecies homology of nitrogenase genes

Cloned nitrogen fixation (nif) genes from Klebsiella pneumoniae hybridize to DNA from 19 out of 19 widely divergent nitrogen-fixing bacterial strains but do not hybridize to DNA from 10 different non-nitrogen-fixing species. K. pneumoniae nif DNA fragments that hybridize to DNA from other species contain part of the three structural genes that code for nitrogenase polypeptides. We have utilized this homology to clone an EcoRI restriction endonuclease fragment from Rhizobium meliloti that hybridizes to the K. pneumoniae nif structural genes. Some of the species whose DNA hybridizes with K. pneumoniae nif DNA have been postulated to have diverged from K. pneumoniae 3 x 10(9) years ago. Nitrogenase genes are the only known example of such highly conserved prokaryotic translated genes. Nitrogenase genes are either extraordinarily conserved in evolution or have been exchanged between different nitrogen-fixing species relatively recently in evolutionary time.

Selection and recombination in populations containing tandem multiplet genes

Computer simulation for selective conditions that may apply in nature yielded three generalizations for prokaryotic organisms with recombinant mechanisms. (1) Selective forces can suffice to maintain a tandem gene family with the nearly optimum number of genes with little variance within the population. (2) Tandem genes will occur within the population unless the population is frequently cloned or unless the function due to a single copy is capable of over-providing the needs of the organism. (3) Even when there is no selective advantage or disadvantage due to extra gene copies, the population distribution becomes more skewed with time; and organisms with only single copies of the gene comprise a progressively larger fraction of the total. This may be the case with genes that function under strong cellular regulation. Evolutionary implications of these calculations are that the occurrence of unequal recombination of tandem genes would greatly slow evolution via duplication of genetic material. This difficulty and its possible resolutions are discussed.

Genetic exchange in Bacillus subtilis in soil

Genetically labelled strains of Bacillus subtilis have been shown to exchange blocks of linked genes while growing together in soil. After eight days of incubation, 79% of unselected colony-forming units exhibited a phenotype containing markers from both parents; the parental strains were not detected after the first day of incubation. High frequencies of transformation were also obtained by adding genetically labelled deoxyribonucleic acid to single-strain soil cultures. Observed linkage of genetic markers was greater in soil transformation than in standard laboratory procedures. The results indicate that transformation may play an important role in the adaptation of the Bacilli to their natural habitat.