DNA sequences at the sites of three insertions of the transposable element Tn5 in the histidine operon of Salmonella

A novel Escherichia coli-derived mutation detected with the Big Blue cII mutant selectable assay

Transgenic mouse mutation detection systems allow investigation of the origins and mechanisms of mutation associated with exogenous and endogenous mutagen exposures in individual tissues and cell types. In the past, selection assays for transgenic mutants have been contaminated with nonmurine-derived mutations and assay validation is critical to ensure murine in vivo origins of mutations. This is critical in studies of spontaneous mutations and extrapolation to endogenous mammalian genes. Herein, we provide one measure of the contribution of Escherichia coli (E. coli)-derived mutations to the Big Blue(R) cII transgene mutant selection assay. We report the first direct evidence of an E. coli-derived cII mutation identified among mutations recovered in the cII selective assay. An E. coli transposable 5 (Tn5) element IS50R inverted repeat (1,534 bp) was identified at base pair 414 in the cII transgene and the insertion generated a 9 bp target site duplication typical of this type of transposition. The bacterial transposition occurred only once in the assay of 25 x 10(6) plaque forming units and sequencing of 1,177 cII mutants. The observed frequency of this type of mutation is 4 x 10(-8) in retrieved lambda phage and 8.5 x 10(-4) in harvested cII mutants and thus a very rare occurrence in typical analyses of spontaneous in vivo mutations. Given that the frequency of transposition is equal to, or an order of magnitude higher, than the frequency of point mutations in E. coli, this article provides excellent validation for the murine origins of mutations detected using the cII mutant selection assay.

DNA sequence bias during Tn5 transposition

Transposition is one of the primary mechanisms causing genome instability. This phenomenon is mechanistically related to other DNA rearrangements such as V(D)J recombination and retroviral DNA integration. In the Tn5 system, only one protein, the transposase (Tnp), is required for all of the catalytic steps involved in transposon movement. The complexity involved in moving multiple DNA strands within one active site suggests that, in addition to the specific contacts maintained between Tnp and its recognition sequence, Tnp also interacts with the flanking DNA sequence. Here, we demonstrate that Tnp interacts with the donor DNA region. Tnp protects the donor DNA from DNase I digestion, suggesting that Tnp is in contact with, or otherwise distorts, the donor DNA during synapsis. In addition, changes in the donor DNA sequence within this region alter the affinity of Tnp for DNA by eightfold during synapsis. In vitro selection for more stable synaptic complexes reveals an A/T sequence bias for this region. We further show that certain donor DNA sequences, which favor synapsis, also appear to serve as hot spots for strand transfer. The TTATA donor sequence represents the best site. Most surprising is the fact that this sequence is found within the Tnp recognition sequence. Preference for insertion into a site within the Tnp recognition sequence would effectively inactivate one copy of the element and form clusters of the Tn5 transposon. In addition, the fact that several donor DNA sequences, which favor synapsis, appear to serve as hot spots for transposon insertion suggest that similar criteria may exist for Tnp-donor DNA and Tnp-target DNA interactions.

Gene conversion in transposition of Escherichia coli element IS30

The mobile element IS30 has dual target specificity, since it can integrate adjacent to the inverted repeat (IR) of another IS30 copy or into hot-spot sequences characterized by a well-defined consensus showing no similarity to the ends of the element. The result of such integrations into these targets is different, as gene conversion events take place frequently during insertion next to an IR end, while this phenomenon has never been observed in targeting hot-spot sequences. Conversion events in IR-targeting cannot be explained exclusively by the activity of the transposase, but suggest the involvement of the homologous recombination and repair machinery of the host cell. Here, we show that the homology between the donor and target sequences is required for conversion and the starting point of the process is the site of integration. The frequency of conversion depends on the distance of mutations from the end of the targeted element. Remarkable bias is found in the role of donor and target DNA, since generally the donor sequence is converted depending on the target. Conversion was shown to occur also without formation of transposition products. All these data are consistent with the idea of the establishment, migration and resolution of a Holliday-like cruciform structure, which can be responsible for conversion events. To explain the variety of conversion products in IR-targeting, a molecular model has been proposed and discussed.

Anatomy of a preferred target site for the bacterial insertion sequence IS903

Like many transposons the bacterial insertion sequence IS903 was thought to insert randomly. However, using both genetic and statistical approaches, we have derived a target site for IS903 that is used 84% of the time. Computational and genetic analyses of multiple IS903 insertion sites predicted a preferred target consisting of a 21 bp palindromic pattern centered on the 9 bp target duplication generated during transposition. Here we show that targeting can be dissected into four components: the 5 bp flanking sequences, the most important sequences required for site-specific insertion; the 7 bp palindromic core within the target duplication; the dinucleotide pair at the transposon-target junction; and the local DNA context. Finally, using a substrate with multiple target sites we show that a target site is more likely found by a local bind-and-slide model and not by extended DNA tracking.

Tn5/IS50 target recognition

This communication reports an analysis of Tn5/IS50 target site selection by using an extensive collection of Tn5 and IS50 insertions in two relatively small regions of DNA (less than 1 kb each). For both regions data were collected resulting from in vitro and in vivo transposition events. Since the data sets are consistent and transposase was the only protein present in vitro, this demonstrates that target selection is a property of only transposase. There appear to be two factors governing target selection. A target consensus sequence, which presumably reflects the target selection of individual pairs of Tn5/IS50 bound transposase protomers, was deduced by analyzing all insertion sites. The consensus Tn5/IS50 target site is A-GNTYWRANC-T. However, we observed that independent insertion sites tend to form groups of closely located insertions (clusters), and insertions very often were spaced in a 5-bp periodic fashion. This suggests that Tn5/IS50 target selection is facilitated by more than two transposase protomers binding to the DNA, and, thus, for a site to be a good target, the overlapping neighboring DNA should be a good target, too. Synthetic target sequences were designed and used to test and confirm this model.

Terminal inverted repeats of insertion sequence IS30 serve as targets for transposition

In the present study, we demonstrate that the terminal inverted repeats of the Escherichia coli insertion sequence IS30 are functional target sites for the transposition of the (IS30)2 dimer, which represents an intermediate structure in the transposition of IS30. Comparative analysis of various target regions revealed that the left and right ends differ in their "attractivity." In our experiments, the joined left and right ends, i.e., the (IS30)2 intermediate structure, was found to be the most preferred target. It was also shown that flanking sequences can influence the target activity of the terminal repeats. The functional part of the target region was localized in the inverted repeats by means of mutational analysis, and it corresponds to the binding site of IS30 transposase. Insertion of 1 bp into the right inverted repeat resulted in unusual target duplication accompanied by gene conversion. The choice of the terminal inverted repeats as targets in transposition leads to the reconstruction of the (IS30)2 structure, which may induce a cascade of further rearrangements. Therefore, this process can play a role in the evolution of the genome.

The non-random pattern of insertion of IS2 into the hemB gene of Escherichia coli

The hemB gene of Escherichia coli has been identified as a hot spot for the insertion of the transposable element IS2. The insertional specificity of IS2 is still unclear. This study reports on the attempt to sequence a statistically significant number of insertions in hemB, in order to determine whether there might be a basis for future studies to determine a molecular basis of IS2 insertional specificity. The results indicate that IS2 inserts in a non-random manner into a 240 bp segment at the 5' end of the gene (region I). Twenty-one of 24 insertions occurred in region I. Three insertions have been identified in the two middle 250 bp segments of the 975 bp gene, and none in the 3' terminal segment. A seventeen bp sequence showing 88.2% identity with a segment of IS2, 221 bp from the 3' terminus has been identified in region I. Four instances of repeated insertion between the same pair of nucleotides have been observed at four different sites.

Tn5 insertion specificity is not influenced by IS50 end sequences in target DNA

The bacterial transposon Tn5 inserts into dozens of sites in a gene, some of which are used preferentially (hotspots). Features of certain sites and precedents provided by several other transposons had suggested that sequences in target DNA corresponding to the ends of Tn5 or of its component IS50 elements might facilitate transposition to these sites. We tested this possibility using derivatives of plasmid pBR322 carrying IS50 I or O end sequences. Tn5 inserted frequently into an IS50 I end at the major hotspot in pBR322, but not into either an I end or an O end 230 bp away from this hotspot. Adenine (dam) methylation at GATC sequences in the I end segment interferes with its use as the end of a transposon, but a dam- mutation did not affect Tn5 insertion relative to an I end sequence in target DNA. These results support models in which the ability of Tn5 to find its preferred sites depends on several features of DNA sequence and conformation, and in which target selection is distinct from recognition of the element ends during transposition.

Transcriptional occlusion of transposon targets

In Salmonella typhimurium, insertion of transposons Tn5, Tn10 and bacteriophage Mu is inhibited by transcription of some target sequences. The transcription effects on Tn5 are large when the lac operon is a target but are limited to a slight effect on the hisG gene of the his operon. The Tn10 element shows target occlusion in both operons. Phage Mu has been shown previously to be inhibited for insertion into the lac operon. In the his operon Mu is only inhibited for insertion into the hisG gene. The variability of the inhibition effect from one sequence to another suggests site or regional specificity for transcription effects. Reducing the probability of insertion into transcribed sequences may be of selective importance to transposons since it reduces the risk of killing the host while maintaining the ability to transpose.

Identification of the Klebsiella pneumoniae glnB gene: nucleotide sequence of wild-type and mutant alleles

The glnB gene of Klebsiella pneumoniae, which encodes the nitrogen regulation protein PII, has been cloned and sequenced. The gene encodes a 12429 dalton polypeptide and is highly homologous to the Escherichia coli glnB gene. The sequences of a glnB mutation which causes glutamine auxotrophy and of a Tn5 induced Gln+ suppressor of this mutation were also determined. The glutamine auxotrophy was deduced to be the result of a modification of the uridylylation site of PII, and the suppression was shown to be caused by Tn5 insertion in glnB. The 3' end of an open reading frame of unknown function was identified upstream of glnB and may be part of an operon containing glnB. Potential homologues of glnB encoding polypeptides extremely similar in sequence to PII were identified upstream of published sequences of the glutamine synthetase structural gene (glnA) in Rhizobium leguminosarum, Bradyrhizobium japonicum and Azospirillum brasilense.

DNA sequence of Rhizobium trifolii nodulation genes reveals a reiterated and potentially regulatory sequence preceding nodABC and nodFE

The Rhizobium trifolii nod genes required for host-specific nodulation of clovers are located on 14 kb of Sym (symbiotic) plasmid DNA. Analysis of the nucleotide sequence of a 3.7 kb portion of this region has revealed open reading frames corresponding to the nodABCDEF genes. A DNA sequencing technique, using primer extension from within Tn5, has been used to determine the precise locations of Tn5 mutations within the nod genes and the phenotypes of the corresponding mutants correlate with their mapped locations. The predicted nodA and nodB genes overlap by four nucleotides and the nod F and nodE genes overlap by a single nucleotide, suggesting that translational coupling may ensure the synthesis of equimolar amounts of these gene products. The nodABC and nodFE genes constitute separate transcriptional units and each is preceded by a conserved 76-bp sequence which may be involved in the regulation of expression of these genes.

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.

Nonrandom insertion of Tn5 into cloned human adenovirus DNA

The bacterial transposable element Tn5 displays regional selectivity in target sites for transposition. To examine this integration specificity of Tn5, we have mapped 57 insertion events in a plasmid pXC1 containing a eukaryotic viral DNA fragment as a target for Tn5 insertional mutagenesis. We found a nonrandom distribution of integration sites in pXC1, suggesting preferred targets for transposition. However, DNA sequence analysis of seven mutants revealed no target site sequence specificity for Tn5 insertion. We demonstrated that the majority of these insertions mapped downstream from a fortuitous promoter sequence which was present and active in this cloned insert in pXC1. Furthermore, when this promoter region was removed, Tn5 was able to transpose into previously unused upstream target sequences. Our data suggest that transcriptional activity may influence Tn5 transposition.

Specificity of Tn5 insertions into a 36-bp DNA sequence repeated in tandem seven times

The target junction sequences of six independent Tn5 insertions into a 36-bp tandemly repeated DNA segment have been determined. In all instances Tn5 preferentially inserts near one end of the tandem repeat, but in four out of six cases the insertion is between different nucleotides. The target sequence shares some similarity (8 out of 11 bp) with the ends of Tn5. All six insertions are accompanied by duplication of 9 bp of target DNA. The data imply that, even though Tn5 appears to insert randomly on a macro scale, at the nucleotide sequence level insertion into target DNA, which has limited similarity to the Tn5 end reactive sequences, may be a preferred event.

Plasmid insertion mutagenesis and lac gene fusion with mini-mu bacteriophage transposons

Small bacteriophage Mu transposable elements containing the lac operon structural genes were constructed to facilitate the isolation and use of Mu insertions and lac gene fusions. These mini-Mu elements have selectable genes for either ampicillin or kanamycin resistance and can be used to form both transcriptional and translational lac gene fusions. Some of the mini-Mu-lac elements constructed are deleted for the Mu A and B transposition genes and form stable insertions that cannot undergo transposition unless complemented for these functions. A procedure was developed for selecting mini-Mu insertions specifically into plasmids, including commonly used high-copy-number cloning vectors such as pBR322. Mu insertions in pBR322 were found to be distributed around the plasmid, but insertions in certain regions occurred more frequently than in others.

The use of transposon Tn5 mutagenesis in the rapid generation of correlated physical and genetic maps of DNA segments cloned into multicopy plasmids--a review

The properties of transposon Tn5 that render it useful for in vivo mutagenesis of cloned DNA sequences are reviewed. Transposition frequency, insertional specificity, polarity and stability of Tn5 insertion mutations are among the topics discussed. Examples are cited from the published literature which illustrate the applications of Tn5 mutagenesis to the analysis of cloned prokaryotic and eukaryotic genes. A methods section is included which outlines precisely how to carry out transposon Tn5 mutagenesis analysis of cloned DNA segments.

Mechanism of F factor-enhanced excision of transposon Tn5

The reversion of lac:: Tn5 insertion mutations was used to examine the control of excision of the kanamycin-resistance transposon Tn5 in Escherichia coli. Earlier work which showed that the fertility factor F enhances Tn5 excision had led another group to suggest that this is due to the product of a putative transposable element-specific "recombination" gene in the F factor which can act on Tn5 located anywhere in the genome. We show, however, that Tn5 is excised from sites in the lac operon of F'lac plasmids several orders of magnitude more efficiently than from the same sites in the chromosomes of F-, F+ or homozygous lac:: Tn5[F'lac:: Tn5] strains. Thus F enhances Tn5 excision, but only if F and Tn5 are in cis in the same DNA molecule. Bacterial crosses showed that transfer of F'lac:: Tn5 plasmids by conjugation stimulates Tn5 excision, and that transfer is frequent even within F' populations. These results suggest that the ability of F to enhance excision is the consequence of DNA transfer in conjugation.

Insertion sites and the terminal nucleotide sequences of the Tn4 transposon

The nucleotide sequences at the ends of the Tn4 transposon (mercury spectinomycin and sulfonamide resistance) have been determined. They are inverted repeated sequences of 38 nucleotides with three mismatched base pairs. These sequences are strongly homologous with the terminal sequences of Tn501 (mercury resistance) but less so with those of Tn3 (ampicillin resistance). The Tn4 transposon generates pentanucleotide members (Tn3, Tn1000, Tn501, Tn551, IS2) with the exception of Tn1721 and bacteriophage Mu. Among the three Tn4 insertion sites examined here, two of them occurred near a nonanucleotide sequence in perfect homology with part of the terminal inverted-repeat sequence of Tn4 and the third insertion occurred near a sequence of partial homology to one end of Tn4. All three insertions were in the same orientation such that IRb is proximal to its homologous sequence on the recipient DNA.

Precise and nearly-precise excision of the symmetrical inverted repeats of Tn5; common features of recA-independent deletion events in Escherichia coli

The transposon Tn5 contains a unique central region bordered by 1.5-kb inverted repeats. The in vitro deletion of the centre of Tn5, with a restriction endonuclease (XhoI) which cuts within the inverted repeats leads to the production of a palindrome on subsequent ligation. This palindromic region is unstable on subsequent transformation into Escherichia coli (Collins, 1981). Precise excision of the Tn5 region plus one copy of the bracketing 9-bp direct repeat occurred in about one-third of the transformants. The rest of the transformants contain only remnants of the inverted repeat. Sequence analysis indicated that deletion had occurred between short direct repeats. The precise excision of these "nearly precise" excision products continued with high frequency and was found to be affected by mutations that interfere with the normal precise excision of transposons. In a recB, sbcB host precise excision was markedly reduced. A common mechanism is proposed for all recA-independent deletions occurring in E. coli.

Cloning and characterization of the Escherichia coli chromosomal region surrounding the dnaG Gene, with a correlated physical and genetic map of dnaG generated via transposon Tn5 mutagenesis

A 24 kilobase pair region of the E. coli chromosome surrounding the dnaG gene has been cloned and characterized. A lambda phage library was constructed by ligating a Sau3A( decreases GATC) partial DNA digest of the entire E. coli chromosome into the lambda BamHI(G decreases GATCC) cloning vector charon 28. Partial digestion was performed to generate overlapping chromosomal fragments and to allow one to walk along the chromosome. This library was probed with a nick-translated plasmid (pRRBl) containing the rpoD gene, which maps adjacent to dnaG at 66 min. Four bacteriophages: lambda 3, lambda 4, lambda 5, lambda 6 that hybridized to the probe were isolated from the 2,500 plaques screened. One phage recombinant lambda 4, was shown to contain the dnaG gene. Three recombinant plasmids containing dnaG: pGL444, pGL445, pBS105, were constructed via subcloning of lambda 4 using different restriction of fragments. Plasmids pGL444 and pBS10 5 were subjected to transposon Tn5 mutagenesis and 88 Tn5 inserts into the cloned region were isolated. The location of the Tn5 inserts were mapped by restriction enzyme analysis of the plasmids and the insertion mutations were checked for ability to complement of dnaGts chromosomal marker at nonpermissive 40 degrees C. In this manner a correlated physical and genetic map of dnaG was determined. A large number of Tn5 inserts map to a specific 900 b.p. region which we propose may be involved in the regulation of dnaG gene expression.

Four-base codons ACCA, ACCU and ACCC are recognized by frameshift suppressor sufJ

The frameshift suppressor sufJ acts to correct a set of +1 frameshift mutations having very different sequences at their mutant sites. This suppressor acts by reading a 4 base codon located near, but not at, the site of each suppressible mutation. Suppression thus necessitates out-of-phase translation of the short stretch of mRNA between the site of action of the suppressor tRNA and the site of the frameshift mutation. We have identified the site read by sufJ by mutationally creating a series of such sites in the neighborhood of a previously nonsuppressible frameshift mutation. Each of the newly generated sites was formed by base substitution. Four independently generated sites were analyzed by DNA sequencing. At each site the quadruplet codon ACCX was generated (where X is A, U or C). Thus sufJ is able to read a 4 base codon in which any of three bases is acceptable in the fourth position. This is the first frameshift suppressor that does not read a run of three repeated bases in the first three positions of its codon.