Transposon-specified site-specific recombination

Scale-Free Biology: Integrating Evolutionary and Developmental Thinking

When the history of life on earth is viewed as a history of cell division, all of life becomes a single cell lineage. The growth and differentiation of this lineage in reciprocal interaction with its environment can be viewed as a developmental process; hence the evolution of life on earth can also be seen as the development of life on earth. Here, in reviewing this field, some potentially fruitful research directions suggested by this change in perspective are highlighted. Variation and selection become, for example, bidirectional information flows between scales, while the notions of "cooperation" and "competition" become scale relative. The language of communication, inference, and information processing becomes more useful than the language of causation to describe the interactions of both homogeneous and heterogeneous living systems at any scale. Emerging scale-free theoretical frameworks such as predictive coding and active inference provide conceptual tools for reconceptualizing biology as the study of a unified, multiscale dynamical system.

Linkage of a novel mercury resistance operon with streptomycin resistance on a conjugative plasmid in Enterococcus faecium

It has been shown that the mercury in dental amalgam and other environmental sources can select for mercury resistant bacteria and that this can lead to an increase in resistance to antibiotics. To understand more about this linkage we have investigated the genetic basis for mercury and antibiotic resistance in a variety of oral bacteria. In this study we have cloned and sequenced the mer operon from an Enterococcus faecium strain which was resistant to mercury, tetracycline, and streptomycin. This strain was isolated, in a previous investigation, from a cynomolgus monkey post-installation of amalgam fillings. The mer operon was contained within a putative transposon (Tnmer1) of the ISL3 family. This element was located on a streptomycin resistant plasmid, pPPM1000, which shares homology with pRE25.

Sequence of a transposon identified as Tn1000 (gamma delta)

We report the complete sequence of a transposon found in a cosmid clone of a human DNA sequence. The transposon is identified as the Escherichia coli transposon Tn1000 (also known as gamma delta) on the basis of the identity of the restriction map of the new sequence with that previously recorded for Tn1000 and homology between parts of the new sequence and that of published fragments of Tn1000 sequence. The transposon, which comprises 5,981 nucleotides including two 35 bp inverted terminal repeat sequences (ITRs), contains three open reading frames. The sequence of the resolvase coding region (tnpR) is identical to that published by others. A second reading frame can be identified as the tnpA gene, coding for the transposase, on the grounds of its strong homology with the corresponding gene from transposon Tn3. The third reading frame has the potential to code for a protein of unknown function containing 698 amino acids.

Plasmid-borne cadmium resistance genes in Listeria monocytogenes are present on Tn5422, a novel transposon closely related to Tn917

The complete (6,449-bp) nucleotide sequence of the first-described natural transposon of Listeria monocytogenes, designated Tn5422, was determined. Tn5422 is a transposon of the Tn3 family delineated by imperfect inverted repeats (IRs) of 40 bp. It contains two genes which confer cadmium resistance (M. Lebrun, A. Audurier, and P. Cossart, J. Bacteriol. 176:3040-3048, 1994) and two open reading frames that encode a transposase (TnpA) and a resolvase (TnpR) of 971 and 184 amino acids, respectively. The cadmium resistance genes and the transposition genes are transcribed in opposite directions and are separated by a putative recombination site (res). The structural elements presumed to be involved in transposition of Tn5422 (IRs, transposase, resolvase, and res) are very similar to those of Tn917, suggesting a common origin. The transposition genes were not induced by cadmium. Analysis of sequences surrounding Tn5422 in nine different plasmids of L. monocytogenes indicated that Tn5422 is a functional transposon, capable of intramolecular replicative transposition, generating deletions. This transposition process is probably the reason for the size diversity of the L. monocytogenes plasmids. Restriction analysis and Southern hybridization revealed the presence of Tn5422 in all the plasmid-mediated cadmium-resistant L. monocytogenes strains tested but not in strains encoding cadmium resistance on the chromosome.

Movable genetic elements and antibiotic resistance in enterococci

The enterococci possess genetic elements able to move from one strain to another via conjugation. Certain enterococcal plasmids exhibit a broad host range among gram-positive bacteria, but only when matings are performed on solid surfaces. Other plasmids are more specific to enterococci, transfer efficiently in broth, and encode a response to recipient-produced sex pheromones. Transmissible non-plasmid elements, the conjugative transposons, are widespread among the enterococci and determine their own fertility properties. Drug resistance, hemolysin, and bacteriocin determinants are commonly found on the various transmissible enterococcal elements. Examples of the different systems are discussed in this review.

A facile and reversible method to decrease the copy number of the ColE1-related cloning vectors commonly used in Escherichia coli

We report a technique which uses the cointegrate intermediate of transposon Tn1000 transposition as a means to lower the copy number of ColE1-type plasmids. The transposition of Tn1000 from one replicon to another is considered a two-step process. In the first step, the transposon-encoded TnpA protein mediates fusion of the two replicons to produce a cointegrate. In the second step, the cointegrate is resolved by site-specific recombination between the two transposon copies to yield the final transposition products: the target replicon with an integrated transposon plus the regenerated donor replicon. Using in vitro techniques, the DNA sequence of the Tn1000 transposon was altered so that cointegrate formation occurs but resolution by the site-specific recombination pathway is blocked. When this transposon was resident on an F factor-derived plasmid, a cointegrate was formed between a multicopy ColE1-type target plasmid and the conjugative F plasmid. Conjugational transfer of this cointegrate into a polA strain resulted in a stable cointegrate in which replication from the ColE1 plasmid origin was inhibited and replication proceeded only from the single-copy F factor replication origin. We assayed isogenic strains which harbored plasmids encoding chloramphenicol acetyltransferase to measure the copy number of such F factor-ColE1-type cointegrate plasmids and found that the copy number was decreased to the level of single-copy chromosomal elements. This method was used to study the effect of copy number on the expression of the fabA gene (which encodes the key fatty acid-biosynthetic enzyme beta-hydroxydecanoylthioester dehydrase) by the regulatory protein encoded by the fadR gene.

Up-promoter mutations in the positively-regulated mer promoter of Tn501

Transcription from the mer promoter of transposon Tn501 is repressed by MerR (the product of the merR gene) in the absence of Hg2+, and activated by MerR in the presence of Hg2+. In the absence of MerR, the mer promoter has weak constitutive activity. The DNA sequence of the mer promoter shows candidate -35 and -10 sequences at the unusually high spacing of 19 base-pairs. We have selected for spontaneous mutations in the mer promoter that confer an up-promoter phenotype. Four different mutants have been isolated. Three of these are single base-pair deletions between the -10 and -35 sequences. A fourth removes the -10 sequence entirely, and places a second potential -10 sequence 17 base-pairs from the -35 sequence. None of these mutant promoters are induced by MerR in the presence of Hg2+. Two of them are repressed by MerR irrespective of the presence or absence of Hg2+. Models for the mode of action of the MerR protein are discussed in the light of these results. Our data support a mechanism in which the MerR protein in the presence of Hg2+ acts to change the conformation of DNA in the mer promoter.

Nucleotide sequences required for Tn3 transposition immunity

The Tn3 transposon inserts at a reduced frequency into a plasmid already containing a copy of Tn3, a phenomenon known as transposition immunity. The cis-acting site on Tn3 responsible for immunity was mapped by deletions from each side to be within the terminal 38-base-pair sequence that is inversely repeated at the ends of Tn3. Two palindromic sequences are present in the essential part of this region. Some deletions conferred only partial immunity, and others conferred negative immunity. Multiple copies of partially immune ends conferred additional immunity. No other part of Tn3 was necessary for immunity.

Transposition of Tn1000: in vivo properties

Transposition mediated by the Tn1000 transposase was investigated by using transposon variants carrying synthetic or wild-type termini but no intact Tn1000 genes. Transposon Tn1001, whose only homologies to Tn1000 are in its 38-base-pair terminal inverted repeats, transposed at the same rate as Tn1005, an artificial construct carrying wild-type Tn1000 termini and approximately 1 kilobase of flanking Tn1000 DNA at each end, when transposase was supplied in trans. The majority of the transpositions into pOX38 gave rise to cointegrates, but approximately 10% of the products expressed phenotypes of direct transpositions. The expression and temperature dependence of the tnpA gene product were examined by studying transposition of Tn1001 to bacteriophage lambda. The temperature optimum for transposition was 37 degrees C, and the transposase was stable for up to 2 h at this temperature.

The genetics and biochemistry of mercury resistance

The ability of bacteria to detoxify mercurial compounds by reduction and volatilization is conferred by mer genes, which are usually plasmid located. The narrow spectrum (Hg2+ detoxifying) Tn501 and R100 determinants have been subjected to molecular genetic and DNA sequence analysis. Biochemical studies on the flavoprotein mercuric reductase have elucidated the mechanism of reduction of Hg2+ to Hg0. The mer genes have been mapped and sequenced and their protein products studied in minicells. Based on the deduced amino acid sequences, these proteins have been assigned a role in a mechanistic scheme for mercury flux in resistant bacteria. The mer genes are inducible, with regulatory control being exerted at the transcriptional level both positively and negatively. Attention is now focusing on broad-spectrum resistance involving detoxification of organomercurials by an additional enzyme, organomercurial lyase. Lyase genes have recently been cloned and sequencing studies are in progress.

The nucleotide sequence of the tnpA gene completes the sequence of the Pseudomonas transposon Tn501

The nucleotide sequence of the gene (tnpA) which codes for the transposase of transposon Tn501 has been determined. It contains an open reading frame for a polypeptide of Mr = 111,500, which terminates within the inverted repeat sequence of the transposon. The reading frame would be transcribed in the same direction as the mercury-resistance genes and the tnpR gene. The amino acid sequence predicted from this reading frame shows 32% identity with that of the transposase of the related transposon Tn3. The C-terminal regions of these two polypeptides show slightly greater homology than the N-terminal regions when conservative amino acid substitutions are considered. With this sequence determination, the nucleotide sequence of Tn501 is fully defined. The main features of the sequence are briefly presented.

Tn1721-encoded resolvase: structure of the tnpR gene and its in vitro functions

A 760 base pair nucleotide sequence of transposon Tn1721 containing the resolvase (tnpR) gene has been determined. A 186 triplet open reading frame was assigned to tnpR, and the allocation of -35 and -10 promoter boxes was supported by mapping transcription initiation at 70 base pairs upstream of tnpR. Expression of tnpR under tac promoter control generated sufficient resolvase protein for enzyme purification and for in vitro studies. Purified Tn1721 resolvase requires supercoiling and two directly oriented resolution (res) sites. The enzyme resolves cointegrate substrates containing repeat copies of Tn1721 res, of Tn21 res, of Tn21 res/Tn1721 res, but not of Tn3 res.

Genetic analysis of Tn7 transposition

The purpose of this work was to localize the DNA regions necessary for the transposition of Tn7. Several deletions of Tn7 were constructed by the excision of DNA fragments between restriction sites. The ability of these deleted Tn7s to transpose onto the recipient plasmid RP4 was examined. All the deleted Tn7s isolated in this work had lost their transposing capability. The possibility of complementing them was studied using plasmids containing all or part of Tn7. Two deleted Tn7s could not be complemented by an entire Tn7 indicating that a DNA sequence greater than the 42 bp terminal sequence is needed for recognition of the transposon by a transposition function. Four other deleted Tn7s could be complemented by Tn7. One of these was studied intensively in complementation experiments using different parts of Tn7 to obtain transposition. The results obtained allow us to propose that all genes needed for transposition of Tn7 onto plasmids are contained in a DNA segment of between 6.0 and 7.4 kb. Furthermore, one essential function must be contained in a DNA fragment longer than 2.5 kb on the right-hand end of Tn7. The classification of Tn7 with regard to the other transposable elements is discussed.

A Tn21 terminal sequence within Tn501: complementation of tnpA gene function and transposon evolution

The prokaryotic mercury-resistance transposon Tn501 contains a sequence, 80 nucleotides from one end, which is identical with an inverted terminal repeat (IR) of Tn21. This Tn21 IR sequence is used when Tn21 complements a TnpA- derivative of Tn501, but not when Tn501 is used for the complementation. Complementation by Tn1721 shows a preference for the normal Tn501 IRs. The element (Tn820) transposed when Tn21 is used to complement a Hg- TnpR- TnpA- Res- deletion mutant of Tn501 contains the Tn21 IR sequence at one terminus and a Tn501 IR at the other. Transposition of Tn820 can be complemented by Tn501 and Tn1721, but at a much lower frequency than transposition of the parental element (Tn819) which has two Tn501 IRs. The relationship between the transposition functions of Tn501, Tn21 and Tn1721, and available nucleotide sequence data suggest that Tn501 evolved by the transposition of a Tn21-like element into another transposable element (similar to that found within Tn1721) followed by deletion of the Tn21-like transposition functions.

Tn501 insertion mutagenesis in Pseudomonas aeruginosa PAO

Transposon insertion mutagenesis of the Pseudomonas aeruginosa PAO chromosome with Tn1 and Tn501 was carried out using a mutant plasmid of R68::Tn501 temperature-sensitive for replication and maintenance. This method consists of three steps. Firstly, the temperature-independent, drug-resistant clones were selected from the strain carrying this plasmid. In the temperature-independent clones, the plasmid was integrated into the chromosome by Tn1- or Tn501-mediated cointegrate formation. Secondly, such clones were cultivated at a permissive temperature to provoke the excision of the integrated plasmid from the chromosome. Excision occurred by the reciprocal recombination between the two copies of Tn1 or Tn501 flanking the integrated plasmid, leaving one Tn1 or Tn501 insertion on the chromosome. Thirdly, the excised plasmid was cured by cultivating these isolates at a non-permissive temperature without selection for the drug resistance. Using this method, we isolated 1 Tn1-induced and 43 Tn501-induced auxotrophic mutations in this organism. Genetic mapping allowed us to identify two new genes, pur-8001 and met-8003. The Tn501-induced auxotrophic mutations were distributed non-randomly among auxotrophic genes, and the reversion of the mutations by precise excision of the Tn501 insertion occurred very rarely.

DNA sequences of and complementation by the tnpR genes of Tn21, Tn501 and Tn1721

DNA sequences that encode the tnpR genes and internal resolution (res) sites of transposons Tn21 and Tn501, and the res site and the start of the tnpR gene of Tn1721 have been determined. There is considerable homology between all three sequences. The homology between Tn21 and Tn501 extends further than that between Tn1721 and Tn501 (or Tn21), but in the homologous regions, Tn1721 is 93% homologous with Tn501, while Tn21 is only 72-73% homologous. The tnpR genes of Tn21 and Tn501 encode proteins of 186 amino acids which show homology with the tnpR gene product of Tn3 and with other enzymes that carry out site-specific recombination. However, in all three transposons, and in contrast to Tn3, the tnpR gene is transcribed towards tnpA gene, and the res site is upstream of both. The res site of Tn3 shows no obvious homology with the res regions of these three transposons. Just upstream of the tnpR gene and within the region that displays common homology between the three elements, there is a 50 bp deletion in Tn21, compared to the other two elements. A TnpR- derivative of Tn21 was complemented by Tn21, Tn501 and Tn1721, but not by Tn3.

Transposon Tn1721: site-specific recombination generates deletions and inversions

Transposon Tn1721 contains genes for transposase (tnpA), resolvase (tnpR) and a resolution site (res). The closely linked loci were localized within a 3.8 kb region their order being res - tnpR - tnpA with res at the translational start of tnpR. Genes tnpR and tnpA have identical transcriptional polarity but independent promoters. The tnpR promoter had 40% of lac promoter efficiency its activity being autoregulated by binding of resolvase to res, as shown by fusion to the galactokinase gene. The weak tnpA promoter was only detectable in the transposase-mediated transposition reaction. Resolvase-catalyzed, site-specific recombination was analyzed in hybrid plasmids with either direct or inverted repeats of res. The rate of the reaction was dependent on the relative orientation of the two sites and on the provision of tnpR in cis or in trans. Direct repeats were rapidly resolved leading to deletions of intervening DNA, if the tnpR gene was provided in cis, but required approximately 60 generations for completion of the reaction, if tnpR was located on a second plasmid (in trans). The reaction involving inverted repeats of res (leading to inversion of intervening DNA) was only detectable if tnpR was furnished in cis. After 50 generations about 10% of plasmid DNA showed the inversion. The reaction was reversible.

Fine structure of transposition genes on Tn2603 and complementation of its tnpA and tnpR mutations by related transposons

The fine structure of the genes tnpA, tnpR and res of Tn2603 required for its own transposition, was determined. The order of the genes was tnpA-tnpR-res from the right end of the right hand side region in Tn2603, the tnpA and tnpR encoded gene products having molecular weights of 110,000 and 21,000, respectively. The 110,000 molecular weight polypeptides was absolutely required for replicon fusion as the first stage of transposition, and named transposase. On the other hand, the 21,000 molecular weight polypeptide was necessary for resolution of the cointegrate as the second stage of transposition, and named resolvase. We also examined the ability of various transposons, assumed to be closely related, to complement the tnpA and tnpR mutations of Tn2603. The results indicated that the mercury resistance transposon, Tn2613, and Tn501, can complement both genes, but TnAs and gamma delta cannot at all. Tn501 had much less efficiency of complementation for tnpA than Tn2613. We have also discovered that the transposition frequency of transposons in the tn2613 family systematically depend on their size of transposon.

Transposon insertion and subsequent donor formation promoted by Tn501 in Bordetella pertussis

The mercuric chloride resistance transposon, Tn501, was introduced into Bordetella pertussis by using the chimeric plasmid pUW942, which is unable to replicate in this species. Tn501 insertions which conferred a thiamine requirement were the predominant insertion class. In many cases, the mercuric chloride-resistant transconjugants were also resistant to the other plasmid markers, but failure to detect plasmid DNA in these isolates indicated that integration of the entire plasmid into the chromosome had occurred. One such insertion was further characterized. Southern hybridization with a Tn501-specific probe indicated that chromosomal DNA from one strain containing the integrated plasmid had two copies of Tn501 and an intervening copy of the plasmid associated with the chromosome. The presence of the plasmid was unstable, and derivatives which had lost all of the plasmid markers except mercuric chloride resistance were obtained. These strains had a single copy of Tn501 and had lost all of the rest of the plasmid-specific sequences. Strains containing the plasmid in the integrated state could act as genetic donors and mobilize chromosomal genes.

Transposon-encoded site-specific recombination: nature of the Tn3 DNA sequences which constitute the recombination site res

The tnpR gene of transposon Tn3 encodes a site-specific recombination enzyme that acts at res, a DNA region adjacent to tnpR, to convert co-integrate intermediates of interreplicon transposition to the normal transposition end-products. We have used two complementary approaches to study the nature of the Tn3 recombination region, res. Firstly, the DNA-binding sites for tnpR protein were determined in DNase I protection experiments. These identified a 120-bp region between the tnpA and tnpR genes that can be subdivided into three separate protein-binding sites. Genetic dissection experiments indicate that few, if any, other sequences in addition to this 120-bp region are required for res function. Moreover, we have shown that the two directly repeated res regions within a molecule are unequal partners in the recombination reaction: a truncated res region, which is unable to recombine with a second identical res region, can recombine efficiently with an intact res region. This demonstration, along with the observation that tnpR/res recombination acts efficiently on directly repeated res regions within a molecule but inefficiently both on inverted res regions in the same molecule and in the fusion reaction between res regions in different molecules, leads us to propose that one-dimensional diffusion (tracking) of tnpR protein along DNA is used to locate an initial res region, and then to bring a second directly repeated res region into a position that allows recombination between the res regions.

Cointegrate formation by Tn5, but not transposition, is dependent on recA

We have studied the effect of the recA-dependent homologous recombination system of Escherichia coli on both Tn5-mediated cointegrate formation and Tn5 transposition. We demonstrate here that, whereas transposition of Tn5 is independent of the recA gene product (as has been shown by other workers), Tn5-mediated cointegrate formation is strongly dependent on recA. The structures of both the simple transposition products and the cointegrates formed in a recA- background seem to be the same as those produced in a recA+ background. These results provide strong evidence that Tn5 does not transpose via an obligate cointegrate intermediate and suggest that the recA effect on cointegrate formation is exerted during the process of transposition.