Nucleotide sequence of insertion sequence IS3411, which flanks the citrate utilization determinant of transposon Tn3411.

The nucleotide sequences of insertion sequences IS3411L (left) and IS3411R (right), present as direct terminal repeats in the citrate utilization of citrate utilization transposon Tn3411, and of IS3411 (generated by intramolecular recombination between IS3411L and IS3411R) were determined. The three IS3411 elements (IS3411R, IS3411L, and IS3411) were 1,309 base pairs long and identical in DNA sequence. IS3411 had 27-base-pair terminal inverted repeats with three bases mismatched and one long open reading frame (240 amino acids) that was proposed to be a transposase. Three polypeptides of 29,000, 27,000, and about 10,000 molecular weight, determined by IS3411, were identified in minicells. Since Tn3411 generates a 3-base-pair repeat upon integration, the nucleotide sequences of IS3411 were compared with those of IS3.     

IS50-mediated inverse transposition: specificity and precision

The IS50 elements, which are present as inverted repeats in the kanamycin-resistance transposon, Tn5, can move in unison carrying with them any interstitial DNA segment. In consequence, DNA molecules such as a lambda::Tn5 phage genome are composed of two overlapping transposons - the kan segment bracketed by IS50 elements (Tn5), and lambda bracketed by IS50 elements. During direct transposition, mediated by IS50 "O" (outside) ends, the kan gene is moved and the lambda vector is left behind. During inverse transposition, mediated by the "I" (inside) ends of the IS50 elements, the lambda vector segment is moved and the kan gene is left behind. Direct transposition is several orders of magnitude more frequent than inverse transposition (Isberg and Syvanen, 1981; Sasakawa and Berg, 1982). We assessed the specificity and precision of the rare events mediated by pairs of I ends by mapping and sequencing independent inverse transpositions from a lambda::Tn5 phage into the amp and tet genes of plasmid pBR322. Using restriction analyses, 32 and 40 distinct sites of insertion were found among 46 and 72 independent inverse transpositions into the amp and tet genes, respectively. Eleven sites were used in two or more insertion events, and the two sites in tet used most frequently corresponded to major hotspots for the insertion of the Tn5 (by direct transposition). The sequences of 22 sites of inverse transposition (including each of the sites used more than once) were determined, in eleven cases by analyzing both pBR322-IS50 junctions, and in eleven others by sequencing one junction. The sequence of the "I" end of IS50 was preserved and 9-bp target sequence duplications were present in every case analyzed. GC pairs were found at each end of the target sequence duplication in ten of the eleven sites used more than once, and also in seven of the other eleven sites. Our data indicate that transposition mediated by pairs of "I" ends is similar in its specificity and precision to the more frequent transposition mediated by IS50 "O" ends.     

Identification of citrate utilization transposon Tn3411 from a naturally occurring citrate utilization plasmid.

We have isolated a new transposon, Tn3411, encoding citrate-utilizing ability, from a naturally occurring citrate utilization (Cit) plasmid, pOH3001. Citrate transposon Tn3411 was transposed from pOH3001 to lambda b519 b515 cI857 S7 (abbreviated lambda bb) phage, and further from the resulting lambda bb:Tn3411 to a vector plasmid, pBR322, in recA-deficient strains. The Cit+ plasmids (pOH2 and pOH3) constructed by the integration of Tn3411 into pBR322 were examined by restriction endonuclease and heteroduplex analysis. The results obtained were as follows: (i) Tn3411 was 7.4 kilobases long and flanked by small inverted repeats, and it contained one more pair of inverted repeats at the opposite orientation in the internal region, thus making alternate repeats; and (ii) the Cit+ structure gene was located on the fragment (5.5 kilobases) between two SalI cleavage sites on Tn3411.     

Structural instability of co-integrates formed during interaction of plasmid R57 with pB322 and RP1. Possible role of IS1 element in the degradation of co-integrates

The conjugative plasmid R57 determines resistance to ampicillin and chloramphenicol. Earlier it was shown that R57 encodes site-specific recA-independent recombinase, which acts in cis and resolves IS1-mediated cointegrates arising in the Escherichia coli recA cells between R57 and pBR322. In the present work the properties of the cointegrates between R57 and pBR322 or RP1 arising in the E. coli rec+ strains were studied. It was found that the cointegrates between R57 and pBR322, obtained by mating of the respective biplasmid donors of E. coli rec+ and the rec+ recipients, lost as a result of deletion a large DNA segment of R57 containing determinant Cmr. The resulting hybrid replicons preserved determinants Apr and Tcr of pBR322 and the R57 conjugative properties and were structurally identical. By using plasmid RP1ts12, which is temperature-sensitive in replication, it was demonstrated that in cells rec+ the cointegrates between R57 and RP1 are extremely unstable. On storage they undergo structural degradation mainly affecting the RP1 replicon. The degradation products of the hydrid complex had lost their RP1 genes but preserved the R57 functional determinants. For elucidation of the observed phenomena the properties of the IS1-mediated cointegrates between pBR322:Tn9 and plasmid pBR3.1--deletion derivative of RP1 were studied. It was found that insertion of IS1 sometimes resulted in formation of unstable cointegrates capable of resolving and loosing determinant Cmr with a high frequency. It was suggested that IS1 encodes the site-specific recombinase responsible for resolution of the IS1-mediated cointegrates and deletion generation. Expression of this recombinase appears to be dependent on structure of the insertion sites. The possible role of IS1 and recombinase encoded by it in resolution and structural instability of the cointegrates between R57 and pBR322 or RP1 is discussed.     

Genetic evidence for absence of transposition functions from the internal part of Tn981 a relative of Tn9

Summary Inverse transposition of the DNA of pBR322 was found to be mediated by the small transposon Tn981 a relative of Tn9 flanked by direct repeats of IS1. Since the resulting structure IS1:: pBR322::IS1 (Tn983) is transposed in a second step in the absence of Tn981, it is concluded that all the functions necessary for transposition of IS1 flanked transposons are coded for by IS1 itself or the E. coli chromosome, respectively.     

Four different integrative recombination events involved in the mobilization of the gonococcal 5.2 kb beta-lactamase plasmid pSJ5.2 in Escherichia coli

We identified and characterized four different recombination mechanisms involved in the cointegrative transfer of the Neisseria gonorrhoeae beta-lactamase plasmid pSJ5.2 by the gonococcal 41 kb tet(M) and the Gram negative self-transmissible plasmids N3 and R64 drd-33 using an Escherichia colirecA-background. Mobilization of pSJ5.2 by the tet(M) plasmid occurred by cointegration through a replicative transposition of two IS1 elements inserted upstream from the beta-lactamase gene of pSJ5.2 and creating a IS1::beta-lactamase hybrid promoter. Two types of recombinational events occurred within the 1.8 kb BamH1-HindIII fragment of pSJ5.2 with the N3 and R64 plasmids. A non-homologous recombination was found at coordinates 1817 and 2849 of pSJ5.2 with sequences from R64. A non-homologous recombination combined with an IS26-mediated one-ended transposition was found at coordinates 1817 and 3010 of pSJ5.2 with N3. In both recombinational events, a deletion of over 1 kb of pSJ5.2 occurred. The fourth recombination event was detected in the 1.0 kb BamH1-HindIII fragment of pSJ5.2 by homologous recombination between DNA from the truncated Tn3 resolvase gene of pSJ5.2 and the resolvase sequences from R64 and N3.     

Evidence for Campbell's mechanism for fine excision of Tn9 type transposons in Escherichia coli K12]

The plasmid-transposon Tn9-322 was constructed by inverted transposition from the pBR322::Tn9 plasmid. The precise excision of the Tn9-322 transposon from the proB gene site can proceed by the Campbell's model. This fact was demonstrated by appearance of the plasmid-transposons after their precise excision. They contain two IS1 elements flanking a short direct repeat of the target DNA. The recombinational mechanism of precise excision of Tn9 type transposons seems not to be alternative but looks as an additional one to a well-known slippage mechanism proved for Tn5 and Tn10.     

R-prime site-directed transposon Tn7 mutagenesis of the photosynthetic apparatus in Rhodopseudomonas capsulata

Site-directed mutagenesis of the photosynthetic apparatus (PSA) genes in Rhodopseudomonas capsulata is presented utilizing a transposon Tn7 mutagenized R-prime. The R-prime, pRPS404, bears most of the genes necessary for the differentiation of the photosynthetic apparatus. Mutagenesis of the R-prime with Tn7 in Escherichia coli, conjugation into R. capsulata, and homologous recombination with the wild-type alleles efficiently generates photosynthetic apparatus lesions. Wild-type alleles are lost spontaneously and the Tn7-induced lesions are revealed by subsequent intramolecular recombination between IS21 insertion elements that bracket the prime sequences in direct repeat. The molecular nature of the intermediates involved in the transposition, recombination and deletion have been investigated by Southern hybridization analysis. The spontaneous loss of wild-type alleles after homologous recombination with the chromosome may be of general use to other prokaryotic site-directed transposon mutagenesis schemes. The IS21-mediated deletion of the prime DNA is dependent on the RecA protein in E. coli, generating the parental R-factor bearing one IS21 element.A genetic-physical map exists for a portion of the prime photosynthetic apparatus DNA. When Tn7 is inserted into a bacteriochlorophyll gene in the Rprime and then crossed into R. capsulata, mutants are produced that accumulate a bacteriochlorophyll precursor, which is in excellent agreement with the existing genetic-physical map. This corroborates our mutagenesis scheme. Mutants arising from Tn7 insertions outside of the genetic map have been isolated. Light harvesting II mutations have been isolated; one mutant lacks only the 14,000 M_r, polypeptide.     

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.     

Location of plasmid-mediated citrate utilization determinant in R27 and incidence in other H incompatibility group plasmids.

Citrate utilization (Cit+) is encoded by a specific subgroup of incompatibility HI plasmids, viz., IncHI1 plasmids. Only one IncHI1 plasmid, pRG1271, which originated in a Mexican typhoid outbreak in 1972, did not specify Cit+. All other Cit+ plasmids hybridized to a Cit+ probe, a 2-kilobase BglII fragment derived from the Cit+ transposon Tn3411. The position of the Cit+ determinant was mapped to a 13.5-kilobase ApaI fragment within the prototype IncHI1 plasmid R27. No other functions have been mapped within this region. Citrate utilization mediated by IncHI1 was observed only after a prolonged lag period of approximately 150 h, and certain Escherichia coli strains, e.g., E. coli K-12 J53-1, were not able to utilize citrate specified by the H plasmids. Most E. coli strains harboring the multicopy Cit+ plasmid pOH2, a derivative of pBR322, required only 18 to 24 h to express the Cit+ phenotype, but E. coli J53-1 (pOH2) required at least 72 h for expression.     

Location of plasmid-mediated citrate utilization determinant in R27 and incidence in other H incompatibility group plasmids

Citrate utilization (Cit+) is encoded by a specific subgroup of incompatibility HI plasmids, viz., IncHI1 plasmids. Only one IncHI1 plasmid, pRG1271, which originated in a Mexican typhoid outbreak in 1972, did not specify Cit+. All other Cit+ plasmids hybridized to a Cit+ probe, a 2-kilobase BglII fragment derived from the Cit+ transposon Tn3411. The position of the Cit+ determinant was mapped to a 13.5-kilobase ApaI fragment within the prototype IncHI1 plasmid R27. No other functions have been mapped within this region. Citrate utilization mediated by IncHI1 was observed only after a prolonged lag period of approximately 150 h, and certain Escherichia coli strains, e.g., E. coli K-12 J53-1, were not able to utilize citrate specified by the H plasmids. Most E. coli strains harboring the multicopy Cit+ plasmid pOH2, a derivative of pBR322, required only 18 to 24 h to express the Cit+ phenotype, but E. coli J53-1 (pOH2) required at least 72 h for expression.     

IS1-mediated tandem duplication of plasmid pBR322. Dependence on recA and on DNA polymerase I

Transposable-element-mediated fusion of the conjugal plasmid pOX38::Tn9 with pBR322 results in the appearance of cointegrates composed of a single copy of each plasmid, and cointegrates which carry a single copy of pOX38 but multiple tandem copies of pBR322. These plasmids are separated by directly repeated copies of the transposable element. We demonstrate here that such multimers can be generated from monomeric cointegrates, probably by unequal crossing over between the flanking Tn9(IS1) elements. Their appearance is thus not necessarily associated with the original transposition (fusion) event. Our study demonstrates that the process of duplication is strongly dependent on the homologous recombination system of Escherichia coli, since it is undetectable by our methods in recA- strains. It is also strongly dependent on the presence of a functional DNA polymerase I in the cell. The major pathway(s) for this duplication thus appears to rely on both the homologous recombination system and the replication of the duplicated segment.     

pλCM System: Observations on the Roles of Transposable Elements in Formation and Breakdown of Plasmids Derived from Bacteriophage Lambda Replicons

Transduction with phage derived from a 2-year-old lysate of lambda cam105 (lambda::Tn9) gave rise to chloramphenicol-resistant (Cm(r)) transductants harboring a plasmid (plambdaCM1) formed from lambda cam105 by a Tn9-mediated adjacent deletion to position 36.07 kilobases in the N cistron of lambda. The plambdaCM element can replicate as a plasmid, insert into the bacterial genome, or reproduce lytically as a phage on cells that provide N function. The feasibility of obtaining high titers in encapsidated form and the ease of synchronous introduction into and recovery from bacterial populations make plambdaCM very suitable for quantitative studies of recombination involving transposable elements. Replicon fusions between plambdaCM1 and RSF1596 (pMB8::Tn3Delta596) occur by duplication of either IS1 (at low rate in the absence of TnpA activity) or Tn3Delta596 (in the presence of TnpA activity). At 24 or 32 degrees C, the rate of increase of TnpA-mediated fusions per plambdaCM is about 2% per cell doubling. RSF103 contains the deleted Tn1DeltaAp (which lacks intact beta-lactamase and TnpR resolvase coding sequences) adjacent to a streptomycin resistance (Sm(r)) determinant. We observed that Tn1DeltaAp mediates insertions of external RSF103 sequences into the R388 plasmid. R388::Tn1DeltaAp plasmids show transposition immunity in cells lacking TnpR activity. Using the plambdaCM system, we isolated adjacent transpositions of the RSF103 Sm(r) determinant. The resulting plambdaCM-Sm cosmids contain Sm(r) genetic material flanked by direct repeats of Tn1DeltaAp, and all are deleted for some RSF103 or plambdaCM sequences. The plambdaCM-Sm constructs will fuse into R388 by duplication of a single Tn1DeltaAp element. In the presence of tnpR(+) (but not tnpR) Tn1 or Tn3 elements, all Tn1DeltaAp-mediated complex replicons break down completely and rapidly to simple Tn1DeltaAp inserts. The equilibrium for resolution is at least 10(5):1, and resolution is more than 90% complete after 40 min of exposure to a tnpR(+) cytoplasm. In the absence of TnpR, Rec, and Red activities, Tn1DeltaAp-mediated complex replicons yield simple Tn1DeltaAp inserts at a lower rate. The presence of intact RSF103 replication determinants between direct Tn1DeltaAp repeats appears to accelerate this precise TnpR- and Rec-independent breakdown.     

Tn5-mediated transposition of plasmid DNA after transduction to Myxococcus xanthus.

After coliphage P1-mediated transfer of Tn5-containing plasmid DNA from Escherichia coli to Myxococcus xanthus, transductants were identified which contained plasmid sequences integrated at many sites on the bacterial chromosome. The unaltered plasmid DNA sequences in these transductants were apparently flanked by intact Tn5 or IS50 sequences. These results suggest that Tn5-mediated transposition has occurred and provide a method for integrating plasmid DNA into the M. xanthus chromosome without the requirement for homologous recombination.     

Amplification of drug resistance genes flanked by inversely repeated IS1 elements: involvement of IS1-promoted DNA rearrangements before amplification.

Tn2653 contains one copy of the tet gene and two copies of the cat gene derived from plasmid pBR325 and is flanked by inverted repeats of IS1. Transposed onto the P1-15 prophage, it confers a chloramphenicol resistance phenotype to the Escherichia coli host. Because the prophage is perpetuated as a plasmid at about one copy per host chromosome, the host cell is still tetracycline sensitive even though P1-15 is carrying one copy of the tet gene. We isolated P1-15::Tn2653 mutants conferring a tetracycline resistance phenotype, in which the whole transposon and variable flanking P1-15 DNA segments were amplified. Amplification was most probably preceded by IS1-mediated DNA rearrangements which led to long direct repeats containing Tn2653 sequences and P1-15 DNA. Subsequent recombination events between these direct repeats led to amplification of a segment containing the tetracycline resistance gene in tandem arrays.     

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.     

Dissociation of unstable cointegrate plasmids formed during transposition of IS1 element: the role of IS1 encoded recombinase

The properties of IS1/Tn9'-mediated cointegrates between plasmids pDK57 (pBR322:: :: Tn9') and pRP3.1--the deletion derivative of RP1 were investigated. It was found that IS1/Tn9'-mediated integration of pDK57 into the active transcribed regions of pRP3.1 (in particular kan and tet genes) leads to formation of unstable cointegrates capable of resolving in E. coli K-12 rec+ and recA cells. The structure of dissociation products of unstable cointegrates was studied. According to the data received in rec+ cells, the unstable cointegrates mainly produced plasmids pDK57 and pBR322::IS1--Cms-derivative of pDK57 as resolution products. In recA cells the cointegrates dissociate in different ways, and this process leads to the formation of not only pDK57 and pBR322::IS1, but also to the production of the deletion derivatives of these plasmids as well as to the derivatives of pDK57 and pBR322::IS1, containing duplications of IS1 or separate parts of Tn9'. It was concluded that the IS1-specific recombinase is involved in the dissociation (resolution) of unstable IS1/Tn9'-mediated cointegrates. This recombinase recognizes the sites localized in both inverted termini of IS1 as well as in the adjacent DNA segments. Hence, it is possible, that the IS1 recombinase is involved also in the generation of IS1-adjacent delations.