Regulation of Tn5 by the right-repeat proteins: Control at the level of the transposition reaction?

The transposon Tn5 consists of inverted repeats, called IS50R and IS50L, each of which encode two proteins. We show here that the larger protein encoded on IS50R, protein 1, is absolutely required for transposition. Deletion or insertion mutants that fail to make this protein fail to promote gene movement. In addition, this protein acts in cis preferentially. We also show that the smaller protein encoded on IS50R, protein 2, is competent to inhibit transposition of a Tn5 freshly introduced into the cell on a λ phage. In contrast, the proteins from IS50L possess neither of these two activities. By assaying expression of proteins that are hybrids between β-galactosidase and IS50R proteins, we find that the regulation of transposition cannot be due to the inhibitor repressing synthesis of Tn5 proteins. Control experiments, in which we assay synthesis of IS50 proteins synthesized from a λ::IS50R that has been infected into cells carrying the transposition inhibitor, confirm this conclusion.     

Integration host factor plays a role in IS50 and Tn5 transposition.

In Escherichia coli, the frequencies of IS50 and Tn5 transposition are greater in Dam- cells than in isogenic Dam+ cells. IS50 transposition is increased approximately 1,000-fold and Tn5 transposition frequencies are increased about 5- to 10-fold in the absence of Dam methylation. However, in cells that are deficient for both integration host factor (IHF) and Dam methylase, the transposition frequencies of IS50 and Tn5 approximate those found in wild-type cells. The absence of IHF alone has no effect on either IS50 or Tn5 transposition. These results suggest that IHF is required for the increased transposition frequencies of IS50 and Tn5 that are observed in Dam- cells. It is also shown that the level of expression of IS50-encoded proteins, P1 and P2, required for IS50 and Tn5 transposition and its regulation does not decrease in IHF- or in IHF- Dam- cells. This result suggests that the effects of IHF on IS50 and Tn5 transposition are not at the level of IS50 gene expression. Finally, IHF is demonstrated to significantly retard the electrophoretic mobility of a 289-base-pair segment of IS50 DNA that contains a putative IHF protein-binding site. The physiological role of this IHF binding site remains to be determined.     

Compartmentalization of the proteins encoded by IS50R

IS50R is a transposable genetic element that serves as the right inverted repeat of the transposon Tn5. Earlier work has shown that IS50R encodes at least two proteins (called P1 and P2) involved in transposition. In this paper, we describe the localization properties of the proteins encoded on this repeat. Strains were constructed that overproduced either these two proteins or hybrids between beta-galactosidase and the IS50R proteins. An antiserum was raised against the hybrid proteins, and this was used to study the localization of P1 and P2. Based on studies in maxicells as well as in growing cells, we show that P1 and P2 are localized differently in the cell. P2 is a cytoplasmic protein, while P1 largely fractionates with the membrane.     

A derivative of Tn5 with direct terminal repeats can transpose

The 5.7 kb⁴ transposable kanamycin resistance determinant Tn5 contains 1.5 kb terminal inverted repeats which we here call arms. Tn5's arms contain the genes and sites necessary for Tn5 transposition, and are not homologous to previously described transposable elements. To determine whether one or both arms is a transposable (IS) element, we transposed Tn5 to pBR322 and used restriction endonuclease digestion and ligation in vitro to generate plasmid derivatives designated pTn5-DR1 and pTn5-DR2 in which Tn5's arms were present in direct rather than in inverted orientation. Analysis of transposition products from dimeric forms of the pTn5-DR1 plasmid to phage λ showed that the outside and inside termini of right and of left arms could function in transposition. We conclude that both of Tn5's arms are transposable elements and name them IS50L (left) and IS50R (right). IS50R, which encodes transposase, was used several-fold more frequently than IS50L, which contain an ochre mutant allele of transposase: this implies that Tn5's transposase acts preferentially on the DNA segment which encodes it. Analysis of transpositions of the amp^rkan^r element Tn5-DR2 to the lac operon showed that Tn5-DR2, like Tn5 wild-type, exhibits regional preference without strict site specificity in the choice of insertion sites.     

Copy Number Control of Tn5 Transposition

Transposition of Tn5 in Escherichia coli strains containing one or multiple copies of the transposable element was investigated. It was found that the overall frequency of transposition within a cell remained constant regardless of the number of copies of Tn5 present in that cell. Experiments measuring the transposition frequency of differentially marked Tn5s confirmed that the frequency of transposition of an individual Tn5 decreased proportionally with the total number of copies of the element present in a cell. The IS50R -encoded function, protein 2, which has previously been shown to be an inhibitor of transposition, is sufficient to mediate this inhibitory effect. The concentration of protein 2 in a cell appears to modulate the transposition of individual Tn5 elements in such a way that the overall transposition of Tn5 in a cell remains constant.     

dnaA, an essential host gene, and Tn5 transposition.

Mutations in dnaA, an essential gene in Escherichia coli, decrease the frequency of transposition of Tn5. An insertion mutation in the dnaA gene does not affect Tn5 gene expression. Therefore, the DnaA protein plays a role either in the transposition reaction itself or in some type of cellular regulation of transposition. Analysis of a mutation in the DnaA box, found at the outside end of IS50, is consistent with a direct interaction of the protein through these bases. IS50 transposition, which utilizes only one end containing a DnaA box, is not affected by dnaA mutations. Overproduction of the DnaA protein does not increase transposition frequencies in wild-type cells, even when the transposase is also overproduced.     

Structure and stability of transposon 5-mediated cointegrates

We have determined the structure of a set of independently derived, Tn5-mediated cointegrates and examined the stability of several examples. A variety of cointegrate structures was found, including those mediated by the entire compound transposon, and those mediated by a single flanking IS50 element, which was always IS50-R, and never IS50-L. IS50-R but not IS50-L is reported to code for a protein(s) required for transposition. This finding confirms that IS50-L is relatively inactive and suggests that the active transposition protein(s) acts largely in cis on IS50-R. Another class of cointegrate was created by inverse transposition of Tn5 (using the inside ends of the flanking elements). In addition, we found an unexpectedly large set of cointegrates, in which the joint between the two plasmids was not adjacent to the transposon. All cointegrates analysed were found to be stable. This suggests that Tn5, unlike the transposon Tn3, does not transpose via an obligate cointegrate intermediate. This finding is compared to previous results with Tn5 and Tn9, and is discussed in terms of current models of transposition.     

Transposon Tn554 encodes three products required for transposition.

Tn554 is a high-frequency, site-specific, transposable element having integrative properties resembling those of lysogenic bacteriophages. Nucleotide sequence analysis indicates that Tn554 has three transposition genes, designated tnpA, tnpB and tnpC. Mutations in each of these were complemented efficiently in trans by clones containing internal fragments of Tn554; thus the products of these genes function in trans. Elements carrying deletions of the Tn554 termini could not be complemented. The product of tnpC is not absolutely required for transposition, since deletion mutations encompassing 80% of tnpC, as well as frameshift mutations located near the amino terminus of tnpC, transposed at frequencies as high as 2% of that observed with wild-type Tn554. However, such mutations affected the orientation of insertion. With wild-type Tn554 insertion occurs in a single orientation regardless of the orientation of the donor. In tnpC mutants insertion orientation was dictated by the orientation of Tn554 in the donor molecule. A mutant lacking the carboxy-terminal 59 residues of tnpB also exhibited altered insertion orientation. Thus it appears that the tnpC gene product is required for correct orientation of the element upon insertion and that this protein may interact with the carboxy-terminal portion of the tnpB gene product.     

Characterization of the Tn5 transposase and inhibitor proteins: a model for the inhibition of transposition.

Tn5 is a composite transposon consisting of two IS50 sequences in inverted orientation with respect to a unique, central region encoding several antibiotic resistances. The IS50R element encodes two proteins in the same reading frame which regulate the transposition reaction: the transposase (Tnp), which is required for transposition, and an inhibitor of transposition (Inh). The inhibitor is a naturally occurring deletion variant of Tnp which lacks the N-terminal 55 amino acids. In this report, we present the purification of both the Tnp and Inh proteins and an analysis of their DNA binding properties. Purified Tnp, but not Inh, was found to bind specifically to the outside end of Tn5. Inh, however, stimulated the binding activity of Tnp to outside-end DNA and was shown to be present with Tnp in these bound complexes. Inh was also found to exist as a dimer in solution. These results indicate that the N-terminal 55 amino acids of Tnp are required for sequence-specific binding. They also suggest that Inh inhibits transposition by forming mixed oligomers with Tnp which still bind to the ends of the transposon but are defective for later stages of the transposition reaction.     

Genetic organization of transposon Tn10

Transposon Tn10 is 9300 bp in length, with 1400 bp inverted repeats at its ends. The inverted repeats are structurally intact IS-like sequences (Ross et al., 1979). Analysis of deletion mutants and structural variants of Tn10, reported below, shows that the two IS10 segments contain all of the Tn10-encoded genetic determinants, both sites and functions, that are required for transposition. Furthermore, the two repeats (IS10-Right and IS10-Left) are not functionally equivalent: IS10-Right is fully functional and is capable by itself of promoting normal levels of Tn10 transposition; IS10-Left functions only poorly by itself, promoting transposition at a very low level when IS10-Right is inactivated. Complementation analysis shows that IS10-Right encodes at least one function, required for Tn10 transposition, which can act in trans and which works at the ends of the element. Also, all of the sites specifically required for normal Tn10 transposition have been localized to the outermost 70 bp at each end of the element; there is no evidence that specific sites internal to the element play an essential role. Finally, Tn10 modulates its own transposition in such a way that transposition-defective point mutants, unlike deletion mutants, are not complemented by functions provided in trans; and wild-type Tn10, unlike deletion mutants, is not affected by functions provided in trans from a "high hopper" Tn10 element.     

Fis plays a role in Tn5 and IS50 transposition.

The Fis (factor for inversion stimulation) protein of Escherichia coli was found to influence the frequency of transposon Tn5 and insertion sequence IS50 transposition. Fis stimulated both Tn5 and IS50 transposition events and also inhibited IS50 transposition in Dam-bacteria. This influence was not due to regulation by Fis of the expression of the Tn5 transposition proteins. We localized, by DNase I footprinting, one Fis site overlapping the inside end of IS50 and give evidence to strongly suggest that when Fis binds to this site, IS50 transposition is inhibited. The Fis site at the inside end overlaps three Dam GATC sites, and Fis bound efficiently only to the unmethylated substrate. Using a mobility shift assay, we also identified another potential Fis site within IS50. Given the growth phase-dependent expression of Fis and its differential effect on Tn5 versus IS50 transposition in Dam-bacteria, we propose that the high levels of Fis present during exponential growth stimulate transposition events and might bias those events toward Tn5 and away from IS50 transposition.     

Phenotypic reversion of an IS1-mediated deletion mutation: a combined role for point mutations and deletions in transposon evolution

We have physically characterised a deletion mutant of the R plasmid R100 which has lost all of the antibiotic resistances, including chloramphenicol resistance (Cmr), coded by its IS1-flanked r-determinant. The deletion was mediated by one of the flanking IS1 elements and terminates within the carboxyl terminus of the Cmr gene. DNA sequence analysis showed that the mutated gene would produce a protein 20 amino acids longer than the wild-type due to fusion with an open reading frame in the IS element. Surprisingly for a deletion mutation, rare, spontaneous Cmr revertants could be recovered. Two of the four revertants studied had frame shifts due to the insertion of a single AT base pair at the same position; the revertants would code for a protein five amino acids shorter than the wild-type. The other two revertants had acquired duplications of the 34-bp inverted terminal repeat sequences of the IS1 element and would direct the synthesis of a protein six amino acids longer than the wild-type. The reverted Cmr markers were still capable of transposition. These observations suggest a role for point mutations and small DNA rearrangements in the formation of new gene organisations produced by mobile genetic elements.     

Excision and Transposition of Tn5 as an Sos Activity in Escherichia Coli

Excision and transposition of the Tn5 element in Escherichia coli ordinarily appear to occur by recA-independent mechanisms. However, recA(Prtc) genes, which encode RecA proteins that are constitutively activated to the protease state, greatly enhanced excision and transposition; both events appeared to occur concomitantly and without destruction of the donor DNA. The recombinase function of the RecA protein was not required. Transposition was accompanied by partial, and occasionally full, restoration of the functional integrity of the gene vacated by the excised Tn5. The stimulation of transposition was inhibited by an uncleavable LexA protein and was strongly enhanced by an additional role of the RecA(Prtc) protein besides its mediation of LexA cleavage. To account for the enhanced transposition, we suggest that (i) there may be a LexA binding site within the promoter for the IS50 transposase, (ii) activated RecA may cleave the IS50 transposition inhibitor, and (iii) the transposase may be formed by RecA cleavage of a precursor molecule.     

Transposon Tn10: genetic organization, regulation, and insertion specificity

Transposon Tn10 is a composite element in which two individual insertion sequence (IS)-like sequences cooperate to mediate transposition of the intervening material. The two flanking IS10 elements are not identical; IS10-right is responsible for functions required to promote transposition, and IS10-left is defective in transposition functions. We suggest that the two IS10 elements were originally identical in sequence and have subsequently diverged. IS10-right is compactly organized with structural gene(s), promoters, and sites important for transposition and (presumably) its regulation all closely linked and, in some cases, overlapping. IS10 has a single major coding region that almost certainly encodes an essential transposition function. A pair of opposing promoters flank the start of this coding region. One of these promoters is responsible for expression in vivo of transposon-encoded transposition functions. We propose that the second promoter is involved in modulation of Tn10 transposition. Genetic analysis suggests that transposon-encoded function(s) may be preferentially cis-acting. Insertion of Tn10 into particular preferred target sites is due primarily to the occurrence of a particular six-base pair target DNA sequence. The properties of this sequence suggest that symmetrically disposed subunits of a single protein may be responsible for both recognition and cleavage of target DNA during insertion.     

Evolution of Transposons: Natural Selection for Tn5 in ESCHERICHIA COLI K12

A novel in vivo effect of the transposable element Tn5 has been observed in chemostats when certain isogenic Tn5 and non-Tn5 strains of Escherichia coli compete for a limiting carbon source in the absence of kanamycin. The Tn5-bearing strain has a more rapid growth rate and increases in frequency from 50% to 90% within the first 15 to 20 generations. The effect occurs when Tn5 is inserted at a variety of chromosomal locations or when the element is carried by an episome, but it is strain specific, having been observed in two out of three strains examined. (For reasons unknown, the effect has not been observed with derivatives of strain CSH12.) Although the growth-rate advantage of Tn5 is independent of nutrient concentration and generation time, it can be reduced by prior adaptation of the strains to limiting conditions, and the amount of reduction is proportional to the length of prior adaptation. The growth-rate effect is evidently not caused by beneficial mutations induced by Tn5 transposition, as Tn5-bearing strains selected in chemostats retain their initial Tn5 position and copy number. However, the effect does not occur in Tn5-112, a transpositionless deletion mutation missing the transposase-coding region of the right-hand IS sequence flanking the element. Since Tn5-112 retains a functional kanamycin-phosphotransferase gene, this gene is not responsible for the growth-rate effect. Thus, the effect evidently requires transposase function, but it does not involve actual transposition of the intact element. Altogether, these data provide a mechanism for the maintenance of Tn5 in bacterial populations in the absence of kanamycin, and they suggest a model for the proliferation and the maintenance of IS sequences and transposable elements in the absence of other identifiable selection pressures.     

Use of a Tn5 derivative that creates lacZ translational fusions to obtain a transposition mutant

We constructed a derivative of Tn5, Tn5 ORFlac, that is capable of creating lacZ translational fusions upon transposition. Lac- strains carrying this construct formed red papillae when plated on MacConkey-lactose media. Lac+ cells isolated from independent papillae expressed distinct beta-galactosidase fusion proteins, suggesting that the Lac+ phenotype resulted from transposition. In support of this, analysis of plasmids carrying Tn5 ORFlac prepared from these cells indicated that the Lac+ phenotypes arose as a result of intermolecular rearrangements. Furthermore, a derivative of Tn5 ORFlac that contains an ochre mutation in the transposase gene formed papillae only in a supB strain. Tn5 ORFlac is useful for obtaining mutants that affect Tn5 transposition and for creating lacZ fusions. We used the papillation phenotype to isolate a spontaneous revertant of IS50L that promotes transposition at a 3.6-fold higher rate than IS50R. The mutation altered the amino acid sequence of both transposase and inhibitor.