Sequences essential for transposition at the termini of IS50

Method for efficient soluble expression and purification of recombinant hyperactive Tn5 transposase

Efficient preparation of libraries is the key step of next-generation sequencing (NGS) methods. Tn5 transposase enables simple, robust and highly efficient tagmentation-based library construction. Here, we report a simple and reliable expression and purification strategy based on fusing Tn5 to the small B1 immunoglobulin binding domain of Streptococcal protein G (GB1) and high affinity 10× His tag. The purified recombinant Tn5 showed high DNA tagmentation activity and ultra-low nucleic acid contamination. This method greatly cuts the costs of Tn5-based NGS library construction and is beneficial to the development of new NGS methods.

Large-Scale Low-Cost NGS Library Preparation Using a Robust Tn5 Purification and Tagmentation Protocol

Efficient preparation of high-quality sequencing libraries that well represent the biological sample is a key step for using next-generation sequencing in research. Tn5 enables fast, robust, and highly efficient processing of limited input material while scaling to the parallel processing of hundreds of samples. Here, we present a robust Tn5 transposase purification strategy based on an N-terminal His₆-Sumo3 tag. We demonstrate that libraries prepared with our in-house Tn5 are of the same quality as those processed with a commercially available kit (Nextera XT), while they dramatically reduce the cost of large-scale experiments. We introduce improved purification strategies for two versions of the Tn5 enzyme. The first version carries the previously reported point mutations E54K and L372P, and stably produces libraries of constant fragment size distribution, even if the Tn5-to-input molecule ratio varies. The second Tn5 construct carries an additional point mutation (R27S) in the DNA-binding domain. This construct allows for adjustment of the fragment size distribution based on enzyme concentration during tagmentation, a feature that opens new opportunities for use of Tn5 in customized experimental designs. We demonstrate the versatility of our Tn5 enzymes in different experimental settings, including a novel single-cell polyadenylation site mapping protocol as well as ultralow input DNA sequencing.

Predicting genome terminus sequences of Bacillus cereus-group bacteriophage using next generation sequencing data

Background

Most tailed bacteriophages (phages) feature linear dsDNA genomes. Characterizing novel phages requires an understanding of complete genome sequences, including the definition of genome physical ends.

Result

We sequenced 48 Bacillus cereus phage isolates and analyzed Next-generation sequencing (NGS) data to resolve the genome configuration of these novel phages. Most assembled contigs featured reads that mapped to both contig ends and formed circularized contigs. Independent assemblies of 31 nearly identical I48-like Bacillus phage isolates allowed us to observe that the assembly programs tended to produce random cleavage on circularized contigs. However, currently available assemblers were not capable of reporting the underlying phage genome configuration from sequence data. To identify the genome configuration of sequenced phage in silico, a terminus prediction method was developed by means of ‘neighboring coverage ratios’ and ‘read edge frequencies’ from read alignment files. Termini were confirmed by primer walking and supported by phylogenetic inference of large DNA terminase protein sequences.

Conclusions

The Terminus package using phage NGS data along with the contig circularity could efficiently identify the proximal positions of phage genome terminus. Complete phage genome sequences allow a proposed characterization of the potential packaging mechanisms and more precise genome annotation.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-017-3744-0) contains supplementary material, which is available to authorized users.

DNA Transposition at Work

DNA transposons are defined segments of DNA that are able to move from one genomic location to another. Movement is facilitated by one or more proteins, called the transposase, typically encoded by the mobile element itself. Here, we first provide an overview of the classification of such mobile elements in a variety of organisms. From a mechanistic perspective, we have focused on one particular group of DNA transposons that encode a transposase with a DD(E/D) catalytic domain that is topologically similar to RNase H. For these, a number of three-dimensional structures of transpososomes (transposase-nucleic acid complexes) are available, and we use these to describe the basics of their mechanisms. The DD(E/D) group, in addition to being the largest and most common among all DNA transposases, is the one whose members have been used for a wide variety of genomic applications. Therefore, a second focus of the article is to provide a nonexhaustive overview of transposon applications. Although several non-transposon-based approaches to site-directed genome modifications have emerged in the past decade, transposon-based applications are highly relevant when integration specificity is not sought. In fact, for many applications, the almost-perfect randomness and high frequency of integration make transposon-based approaches indispensable.

Cotranslational control of DNA transposition: a window of opportunity

Transposable elements are important in genome dynamics and evolution. Bacterial insertion sequences (IS) constitute a major group in number and impact. Understanding their role in shaping genomes requires knowledge of how their transposition activity is regulated and interfaced with the host cell. One IS regulatory phenomenon is a preference of their transposases (Tpases) for action on the element from which they are expressed (cis) rather than on other copies of the same element (trans). Using IS911, we show in vivo that activity in cis was ~200 fold higher than in trans. We also demonstrate that a translational frameshifting pause signal influences cis preference presumably by facilitating sequential folding and cotranslational binding of the Tpase. In vitro, IS911 Tpase bound IS ends during translation but not after complete translation. Cotranslational binding of nascent Tpase permits tight control of IS proliferation providing a mechanistic explanation for cis regulation of transposition involving an unexpected partner, the ribosome.

Highly structured sequence homology between an insertion element and the gene in which it resides

The recessive allele for soybean seed lectin results from the insertion of a DNA segment (designated Tgm1) into the coding region of the gene. The termini of Tgm1 display structural features characteristic of a transposable element. The complete sequence of Tgm1 contains 3550 base pairs (bp) and can be divided into three regions (left arm, mid-section, and right arm). No large open reading frames were found, but an extensive, highly structured border with homology to the lectin gene was revealed. The left border (726 bp) comprising most of the left arm and extreme right border (144 bp) of the right arm consist of various forms of a basic 54-bp repeating unit. This 54-bp unit is comprised of a stem-loop structure and interhairpin sequence that occurs 13 times in the left arm and 2 times in the right arm of Tgm1. Progressively degenerate forms of this repeating unit appear toward the termini of Tgm1, but the dyad symmetry remains highly conserved. Seven nucleotides (A-C-A-T-C-G-G and its complement) maintained within the stem also appear as a subset of inverted repeats found at nearly equal distances from the target site in the lectin gene. Together with the inverted repeat termini and a duplication in the left arm, this 7-bp sequence occurs a total of 33 times in Tgm1. We infer that the dyad symmetries containing this sequence are involved in target gene selection. The repeating unit format of Tgm1 describes a distinct class of eukaryotic elements that includes representatives known to be mobile in snapdragon and maize.

Transposon Tn5

Tn5 was one of the first transposons to be identified ( 10 ). As a result of Tn5's early discovery and its simple macromolecular requirements for transposition, the Tn5 system has been a very productive tool for studying the molecular mechanism of DNA transposition. These studies are of broad value because they offer insights into DNA transposition in general, because DNA transposition is a useful model with which to understand other types of protein-DNA interactions such as retroviral DNA integration and the DNA cleavage events involved in immunoglobulin gene formation, and because Tn5-derived tools are useful adjuncts in genetic experimentation.

Functional coupling between the two active sites during Tn 10 transposition buffers the mutation of sequences critical for DNA hairpin processing

DNA processing reactions often involve multiple components acting in concert to achieve the desired outcome. However, it is usually difficult to know how the components communicate and cooperate to orchestrate an ordered series of events. We address this question in the context of the Tn 10 transposition reaction, in which the DNA cleavage and joining events occur within a higher-order complex containing a transposase dimer, two transposon ends and the DNA-bending host-factor IHF (Integration Host Factor). Previously it was shown that the complex is asymmetric. The a side consists of an IHF protomer initially immobilized by a DNA-loop, but subsequently used to promote conformational changes required for the cleavage steps. The beta side of the complex was considered to fulfil a more passive role. Here we show that the a side of the complex promotes coupled conformational changes at both transposon ends, while the a and beta sides communicate and cooperate to dominate different phases of the transposition reaction. Together, these effects provide for a robust response to critical changes in the transposon end. These findings also explain the intriguing genetic phenotypes of a series of previously reported Tn10 mutants and have consequences for the evolution of new elements.

Loss of transposase-DNA interaction may underlie the divergence of mariner family transposable elements and the ability of more than one mariner to occupy the same genome

Mariners are a large family of eukaryotic DNA-mediated transposable elements that move via a cut-and-paste mechanism. Several features of the evolutionary history of mariners are unusual. First, they appear to undergo horizontal transfer commonly between species on an evolutionary timescale. They can do this because they are able to transpose using only their own self-encoded transposase and not host-specific factors. One consequence of this phenomenon is that more than one kind of mariner can be present in the same genome. We hypothesized that two mariners occupying the same genome would not interact. We tested the limits of mariner interactions using an in vitro transposition system, purified mariner transposases, and DNAse I footprinting. Only mariner elements that were very closely related to each other (ca. 84% identity) cross-mobilized, and then inefficiently. Because of the dramatic suppression of transposition between closely related elements, we propose that to isolate elements functionally, only minor changes might be necessary between elements, in both inverted terminal repeat and amino acid sequence. We further propose a mechanism to explain mariner diversification based on this phenomenon.

Tn5 in vitro transposition

This communication reports the development of an efficient in vitro transposition system for Tn5. A key component of this system was the use of hyperactive mutant transposase. The inactivity of wild type transposase is likely to be related to the low frequency of in vivo transposition. The in vitro experiments demonstrate the following: the only required macromolecules for most of the steps in Tn5 transposition are the transposase, the specific 19-bp Tn5 end sequences, and target DNA; transposase may not be able to self-dissociate from product DNAs; Tn5 transposes by a conservative "cut and paste" mechanism; and Tn5 release from the donor backbone involves precise cleavage of both 3' and 5' strands at the ends of the specific end sequences.

Tn5 transposase mutants that alter DNA binding specificity

Tn5 transposase (Tnp) binds to Tn5 and IS50 end inverted repeats, the outside end (OE) and the inside end (IE), to initiate transposition. We report the isolation of four Tnp mutants (YH41, TP47, EK54 and EV54) that increase the OE-mediated transposition frequency and enhance the binding affinity of Tnp for OE DNA. In addition, two of the Tnp mutants (TP47 and EK54) appear to be change-of-specificity mutants, since they alter the recognition of OE versus IE relative to the wild-type Tnp. EK54 enhances OE recognition but decreases IE recognition. TP47 enhances both OE and IE recognition but with a much greater enhancement for IE than for OE. This change-of-specificity effect of TP47 is observed only when TP47 Tnp is synthesized in cis to the DNA that contains the ends. We propose that Lys54 makes a favorable interaction with an OE-specific nucleotide pair(s), while Pro47 may cause a more favorable interaction with an IE-specific nucleotide pair(s) than it does with the corresponding OE-specific nucleotide pair(s). A model to explain the preference of TP47 Tnp for the IE in cis but not in trans is proposed.

DNA binding and phasing analyses of Tn5 transposase and a monomeric variant

Both full-length Tn 5 transposase and a COOH-terminal truncated monomeric form of the protein,n369, have been shown to specifically bind end sequences at comparable affinities. In addition, both proteins distort the target sequence in a similar manner, as determined by a circular permutation assay. In this study,nEK54, a derivative ofn369 with a single amino acid substitution that significantly enhances binding activity, is used in further binding and bending studies along with full-length transposase. Phasing analysis has shown that distortion of the end sequences upon binding of full-length transposase and nEK54 protein is due in part to a protein-induced bend oriented towards the major groove. Because the center of transposase-induced bending maps to the extreme leftward end of the 19 bp consensus sequence, we examined the possibility that optimal protein binding requires additional upstream nucleotide contacts. Experiments presented here show that 9-10 nucleotides are needed upstream of +1 of the 19 bp sequence for efficient binding and this requirement can be met by either single-stranded or double-stranded DNA.

Localization of functional domains in the Escherichia coli coprogen receptor FhuE and the Pseudomonas putida ferric-pseudobactin 358 receptor PupA

Transport of ferric-siderophores across the outer membrane of gram-negative bacteria is mediated by specific outer membrane receptors. To localize the substrate-binding domain of the ferric-pseudobactin 358 receptor, PupA, of Pseudomonas putida WCS358, we constructed chimeric receptors in which different domains of PupA were replaced by the corresponding domains of the related ferric-pseudobactin receptors PupB and PupX, or the coprogen receptor FhuE of Escherichia coli. None of the chimeric proteins composed of pseudobactin receptor domains facilitated growth on any of the original substrates, or they showed only an extremely low efficiency. However, these receptors enabled cells of Pseudomonas BN8 to grow on media supplemented with uncharacterized siderophore preparations. These siderophore preparations were isolated from the culture supernatant of WCS358 cells carrying plasmids that contain genes of Pseudomonas B10 required for the biosynthesis of pseudobactin B10. Hybrid proteins that contained at least the amino-terminal 516 amino acids of mature FhuE were active as a receptor for coprogen and interacted with the E. coli TonB protein. A chimeric PupA-FhuE protein, containing the amino-terminal 94 amino acids of mature PupA, was also active as a coprogen receptor, but only in the presence of Pseudomonas TonB. It is concluded that the carboxy-terminal domain of ferric-pseudobactin receptors is important, but not sufficient, for ligand interaction, whereas binding of coprogen by the FhuE receptor is not dependent on this domain. Apparently, the ligand-binding sites of different receptors are located in different regions of the proteins. Furthermore, species-specific TonB binding by the PupA receptor is dependent on the amino-terminal domain of the receptor.

DNA length, bending, and twisting constraints on IS50 transposition

Transposition is a multistep process in which a transposable element DNA sequence moves from its original genetic location to a new site. Early steps in this process include the formation of a transposition complex in which the end sequences of the transposable element are brought together in a structurally precise fashion through the action of the element-encoded transposase protein and the cleavage of the element free from the adjoining DNA. If transposition complex formation must precede DNA cleavage (or nicking), then changing the length of the donor DNA between closely spaced ends should have dramatic effects on the frequency of the transposition. This question has been examined by studying the effects of altering donor DNA length on IS50 transposition. Donor DNA < or = 64 bp severely impaired transposition. Donor DNA > or = 200 bp demonstrated high transposition frequencies with only modest length dependencies. Constructs with donor DNA lengths between 66 and 174 bp demonstrated a dramatic periodic effect on transposition (periodicity approximately 10.5 bp).

Evidence that the cis preference of the Tn5 transposase is caused by nonproductive multimerization

The transposase (Tnp) of the bacterial transposon Tn5 acts 50- to 100-fold more efficiently on elements located cis to the site of its synthesis compared with those located in trans. In an effort to understand the basis for this cis preference, we have screened for Tnp mutants that exhibit increased transposition activity in a trans assay. Two mutations in the carboxyl terminus were isolated repeatedly. The EK345 mutation characterized previously increases Tnp activity eightfold both in cis and in trans. The novel LP372 mutation, however, increases Tnp activity 10-fold specifically in trans. Combining both mutations increases Tnp activity 80-fold. Interestingly, the LP372 mutation maps to a region shown previously to be critical for interaction with Inh, an inhibitor of Tn5 transposition, and results in reduced inhibition activity by both Tnp and Inh. Tnp also inhibits Tn5 transposition in trans, and this has been suggested to occur by the formation of inactive Tnp multimers. Because Inh and (presumably) Tnp inhibit Tn5 transposition by forming defective multimers with Tnp, the inhibition defect of the trans-active LP372 mutant suggests that the cis preference of Tnp may also be attributable to nonproductive Tnp-Tnp multimerization. In addition, we show that increasing the synthesis of EK345/LP372 Tnp, but not wild-type Tnp, leads to very high levels of transposition, presumably because this altered Tnp is defective in the inhibitory activity of the wild type protein.

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.

Isolation and characterization of a new chromosomal virulence gene of Agrobacterium tumefaciens

A mutant (strain B119) of Agrobacterium tumefaciens with a chromosomal mutation was isolated by transposon (Tn5) mutagenesis. The mutant exhibited growth rates on L agar and minimal medium (AB) plates similar to those of the parent strain (strain A208 harboring a nopaline-type Ti plasmid). The mutant was avirulent on all host plants tested: Daucus carota, Cucumis sativus, and Kalanchoe diagremontiana. The mutant was not impaired in attachment ability to carrot cells. The mutant had one insertion of Tn5 in its chromosome. The avirulent phenotype of B119 was shown to be due to the Tn5 insertion in the chromosome by the marker exchange technique. A wild-type target chromosomal segment (3.0 kb) which included the site of mutation was cloned and sequenced. Two open reading frames, ORF-1 (468 bp) and ORF-2 (995 bp), were identified in the 3.0-kb DNA segment. Tn5 was inserted in the middle of ORF-2 (acvB gene). Introduction of the acvB gene into the mutant B119 strain complemented the avirulent phenotype of the strain. Homology search found no genes homologous to acvB, although it had some similarity to the open reading frame downstream of the virA gene on the Ti plasmid. Thus, the acvB gene identified in this study seems to be a new chromosomal virulence gene of A. tumefaciens.

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.

Induction of the SOS response in Escherichia coli inhibits Tn5 and IS50 transposition

In response to DNA damage or the inhibition of normal DNA replication in Escherichia coli, a set of some 20 unlinked operons is induced through the RecA-mediated cleavage of the LexA repressor. We examined the effect of this SOS response on the transposition of Tn5 and determined that the frequency of transposition is reduced 5- to 10-fold in cells that constitutively express SOS functions, e.g., lexA(Def) strains. Furthermore, this inhibition is independent of recA function, is fully reversed by a wild-type copy of lexA, and is not caused by an alteration in the levels of the Tn5 transposase or inhibitor proteins. We isolated insertion mutations in a lexA(Def) background that reverse this transposition defect; all of these mapped to a new locus near 23 min on the E. coli chromosome.

Construction of a physical map of the chromosome of Shigella flexneri 2a and the direct assignment of nine virulence-associated loci identified by Tn5 insertions

To establish the molecular basis of the chromosomal virulence genes of Shigella flexneri 2a (YSH6000), a Notl restriction map of the chromosome was constructed by exploiting Notl-linking clones, partial Notl digestion and DNA probes from various genes of Escherichia coli K-12. The map revealed at least three local differences in the placements of genes between YSH6000 and E. coli K-12. Using the additional Notl sites introduced by Tn5 insertion, nine virulence loci identified previously by random Tn5 insertions were physically mapped on the chromosome. To demonstrate the versatility of the Notl map in direct assignment of the virulence loci tagged by Tn5 to a known genetic region in E. coli K-12, the major class of avirulent mutants defective in the core structure of lipopolysaccharide (LPS) was examined for the sites of Tn5 insertions. The two Notl segments created by the Tn5 insertion in the Notl fragment were analysed by Southern blotting with two DNA probes for the 5' and 3' flanking regions of the rfa region, and shown to hybridize separately with each of them, confirming the sites of Tn5 in the rfa locus. This approach will facilitate direct comparison genetically mapped Tn5 insertion mutations of S. flexneri with genes physically determined in E. coli K-12.

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.

Virulence-associated chromosomal loci of Shigella flexneri identified by random Tn5 insertion mutagenesis

Shigellae are the causative agents of bacillary dysentery and are capable of invading epithelial cells, multiplying therein and spreading into adjacent cells. To identify genes on the chromosome associated with the virulence phenotype, 9114 independent Tn5 insertion mutants were isolated in a virulent strain of Shigella flexneri. By using an in vitro assay for intercellular spread or an animal infection model, the Serény test, 50 chromosomal Tn5 mutants with reduced virulence were identified. The 50 mutants were characterized with respect to their virulence phenotypes, including three different mutations that affect invasion of epithelial cells, bacterial metabolism and structure of lipopolysaccharide. Mutants with reduced invasive ability were further characterized and it was found that two of them had decreased levels of IpaB, C and D antigens as well as the mRNA for the ipaBCD operon encoded by the large virulence plasmid, suggesting that positive regulatory elements for the ipaBCD operon are encoded by the chromosome. Assignment of the 50 Tn5 insertions of the mutants to the 19 NotI restriction fragments of the chromosomal DNA has permitted the identification of at least nine virulence-associated chromosomal loci.

Intramolecular transposition by a synthetic IS50 (Tn5) derivative

We report the formation of deletions and inversions by intramolecular transposition of Tn5-derived mobile elements. The synthetic transposons used contained the IS50 O and I end segments and the transposase gene, a contraselectable gene encoding sucrose sensitivity (sacB), antibiotic resistance genes, and a plasmid replication origin. Both deletions and inversions were associated with loss of a 300-bp segment that is designated the vector because it is outside of the transposon. Deletions were severalfold more frequent than inversions, perhaps reflecting constraints on DNA twisting or abortive transposition. Restriction and DNA sequence analyses showed that both types of rearrangements extended from one transposon end to many different sites in target DNA. In the case of inversions, transposition generated 9-bp direct repeats of target sequences.

Rhizobium meliloti lipopolysaccharide and exopolysaccharide can have the same function in the plant-bacterium interaction

A fix region of Rhizobium meliloti 41 involved both in symbiotic nodule development and in the adsorption of bacteriophage 16-3 was delimited by directed Tn5 mutagenesis. Mutations in this DNA region were assigned to four complementation units and were mapped close to the pyr-2 and pyr-29 chromosomal markers. Phage inactivation studies with bacterial cell envelope preparations and crude lipopolysaccharides (LPS) as well as preliminary characterization of LPS in the mutants indicated that these genes are involved in the synthesis of a strain-specific LPS. Mutations in this DNA region resulted in a Fix- phenotype in AK631, an exopolysaccharide (EPS)-deficient derivative of R. meliloti 41; however, they did not influence the symbiotic efficiency of the parent strain. An exo region able to restore the EPS production of AK631 was isolated and shown to be homologous to the exoB region of R. meliloti SU47. By generating double mutants, we demonstrated that exo and lps genes determine similar functions in the course of nodule development, suggesting that EPS and LPS may provide equivalent information for the host plant.

Tn5supF, a 264-base-pair transposon derived from Tn5 for insertion mutagenesis and sequencing DNAs cloned in phage lambda

We constructed a derivative of transposon Tn5 called Tn5supF for insertion mutagenesis and sequencing DNAs cloned in phage lambda. This element carries a supF amber-suppressor tRNA gene. Its insertion into lambda can be selected by plaque formation by using nonsuppressing (sup0) Escherichia coli for amber mutant lambda phage and sup0 dnaB-amber E. coli for nonamber lambda phage. Tn5supF is just 264 base pairs long. It transposes efficiently and inserts quasi-randomly into DNA targets. The unique sequences near its termini can be used as primer binding sites for dideoxynucleotide DNA sequencing, thus permitting the direct sequencing of DNAs cloned in phage lambda without subcloning.

An unusual wheat insertion sequence (WIS1) lies upstream of an alpha-amylase gene in hexaploid wheat, and carries a "minisatellite" array

Comparison of the 5' flanking regions of three alpha-amylase genes from chromosome 6B of hexaploid wheat by heteroduplex and sequence analysis revealed the presence of a 1.6 kb stem-loop insertion sequence (WIS1) in one of them. Polymorphism among hexaploid wheat varieties suggests the relatively recent insertion/excision of this sequence from its present position. The complete sequence of the stem-loop insertion shows that it has many of the features found in transposable elements, including target site duplication and terminal inverted repeats. One unusual feature is a tandem array of direct repeats comprising a wheat "minisatellite" sequence. Both the insertion sequence and the minisatellite are found at multiple locations in the wheat genome, but the functional significance of their association in WIS1 is unknown. The minisatellite arrays share a common core structure, and long arrays are polymorphic between different hexaploid varieties.

Cloning of a surface protein antigen gene from serotype c Streptococcus mutans

The structural gene for a 190 kD protein antigen (PAc) of Streptococcus mutans MT8148 (serotype c) was cloned into the plasmid vector pUC118. SDS-polyacrylamide gel electrophoresis and Western immunoblotting showed that the Escherichia coli harbouring the chimaeric plasmid produced multiple polypeptides of 190-210 kD. Immunodiffusion analysis revealed that the cloned PAc had the same specific determinants as S. mutans PAc. The cloned pac gene was mapped, and its transcriptional orientation was determined by characterizing deletion mutants of the chimaeric plasmid. Southern blot analysis with the cloned gene sequence as a probe revealed the presence of a homologous sequence in DNAs from serotypes e and f S. mutans. PAc-defective mutants were constructed by inserting an erythromycin-resistance gene into the pac gene. The cell-surface hydrophobicity of the mutants was lower than that of the parent strain.

Tn5tac1, a derivative of transposon Tn5 that generates conditional mutations

Conditional lethal mutations are valuable for analyzing essential genes. We describe here a derivative of the bacterial transposon Tn5 called Tn5tac1 and its use in an innovative strategy for making mutations with conditional phenotypes. The 4.6-kilobase Tn5tac1 element contains a strong, regulatable, outward-facing promoter (Ptac) near one end and is polar on the expression of distal genes when the inducer of Ptac [isopropyl beta-D-thiogalactoside (IPTG)] is absent. Our results show that two unusual conditional mutant phenotypes can result from Tn5tac1 insertion in Escherichia coli: one is corrected by IPTG while the other is induced by IPTG. The broad host range of Tn5 and the conditional nature of these mutant phenotypes makes Tn5tac1 well suited for identifying essential genes in diverse bacterial species.

Mutational analysis of insertion sequence 50 (IS50) and transposon 5 (Tn5) ends

Insertion sequence 50 (IS50) transposition utilizes a 19-base-pair "outside" end and a 19-base-pair "inside" end in inverted orientation relative to each other, whereas transposon 5 (Tn5) transposition utilizes two inverted outside ends. The frequency of transposition events that involve an inside end is regulated 1000-fold by the host dam methylase system. The end sequence requirements for transposition and its regulation by dam methylase were analyzed in Escherichia coli by generating random single base pair mutations in either an IS50 inside end or outside end placed in inverted orientation with respect to an unmutagenized outside end. The mutations were then isolated, assayed for transposition phenotype, and sequenced. Mutations were isolated at 15 of the 19 sites in the outside end. All of these mutations except those at position 4 decreased transposition. Mutations at position 4 (which is the only nonidentical base pair in a region of homology between the outside and inside ends) had no effect on transposition. Mutations were isolated at 11 of the 19 sites in the inside end. All of these mutations, including one at position 4, decreased transposition in dam- cells. Mutations at position 10 (within a dam recognition sequence) and 2 (not within a dam recognition sequence) reduced the magnitude of dam regulation. A mutation within a dam recognition sequence adjacent to the required 19 base pairs of the inside end did not reduce the magnitude of dam regulation.

Identification of base pairs in the outside end of insertion sequence IS50 that are needed for IS50 and Tn5 transposition

Short DNA sequences at ends of transposable elements are needed as sites for transposition. Previous deletion mapping showed that, in Tn5 and its component IS50 elements, these essential sites are about 19 base pairs long. To determine which positions are important in transposition, we made one or more sequence changes at each position in the IS50 outside (O) end and assayed the effects of these changes on transposition. Our results indicate that the specific base pairs at 18 of the 19 positions are important in transposition. A 9-base-pair segment in the O end corresponds to a binding site for the Escherichia coli DnaA protein. Comparisons of effects of mutations at different positions in this site, and also measurements of Tn5 transposition in dnaA- cells, indicate that DnaA protein participates in O-end-mediated transposition.

Genetic analysis of the interaction of the insertion sequence IS903 transposase with its terminal inverted repeats

The insertion sequence IS903 has perfect, 18-base-pair terminal repeats that are the presumed binding sites of its transposase. We have isolated mutations throughout this inverted repeat and analyzed their effect on transposition. We show that every position in the inverted repeat (with the possible exception of position 4) is important for efficient transposition. Furthermore, various substitutions at a single position can have a wide range of effects. Analysis of these hierarchical effects suggests that transposase contacts the minor groove in the region from position 13 to position 16 but makes major groove (or more complex) interactions with the outer portion of the inverted repeat. Our data indicate that the transposase exhibits relaxed specificity for the "second" end of a transposed segment; the defect in transposition of virtually all mutant inverted repeats can be rescued by a wild-type end. However, this rescue exhibits a pronounced position effect; in most cases, it is efficient only when the wild-type end is close to the 3' end of the transposase gene. This confirms the cis-acting nature of the transposase protein and suggests the initial transposase-inverted repeat interaction is the rate-limiting step in transposition. From the behavior of transposons with one mutant and one wild-type end, we infer that the inverted repeat contains two functional domains--one for initial complex formation with transposase and the other for effective completion of transpositional recombination. To support this hypothesis we show that an end with a mutation in one domain can significantly rescue an end with a mutation in the other domain.

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.

Transposition of IS91 does not generate a target duplication

We determined the DNA sequences surrounding the junctions of IS91 in two insertion derivatives: pSU234 (pACYC184::IS91) and pSU240 (pBR322::IS91). The termini of IS91 consist of two imperfect inverted repeats eight base pairs long. Their sequence is 5'-TCGAGTAGG. . . CCTATCGA-3'. Insertion of IS91 did not generate direct repetitions in the target DNAs.

Regions associated with the stable maintenance of plasmid pSC101 and its tetracycline resistance

Two regions tentatively called unsA and unsR were identified on pSC101. One, unsA, corresponds to less than 650 bp of the N-terminal in the tetracycline resistance structural gene and seems to inhibit stable maintenance of pSC101. The other, unsR, is defined within the 1 kb XhoI-EcoRI region located upstream of the tetracycline resistance structural gene and is a regulatory gene clearly distinct from tetR (Unger et al. 1984); it serves as a suppressor of the unsA function.

Localization of action of the IS50-encoded transposase protein

The movement of the bacterial insertion sequence IS50 and of composite elements containing direct terminal repeats of IS50 involves the two ends of IS50, designated O (outside) and I (inside), which are weakly matched in DNA sequence, and an IS50 encoded protein, transposase, which recognizes the O and I ends and acts preferentially in cis. Previous data had suggested that, initially, transposase interacts preferentially with the O end sequence and then, in a second step, with either an O or an I end. To better understand the cis action of transposase and how IS50 ends are selected, we generated a series of composite transposons which contain direct repeats of IS50 elements. In each transposon, one IS50 element encoded transposase (tnp+), and the other contained a null (tnp-) allele. In each of the five sets of composite transposons studied, the transposon for which the tnp+ IS50 element contained its O end was more active than a complementary transposon for which the tnp- IS50 element contained its O end. This pattern of O end use suggests models in which the cis action of transposase and its choice of ends is determined by protein tracking along DNA molecules.

Molecular alteration of the 140-megadalton plasmid associated with loss of virulence and Congo red binding activity in Shigella flexneri

A plasmid of about 140 megadaltons has been associated with the invasiveness of Shigella flexneri. Upon subculturing in liquid media of fully virulent isolates of Shigella flexneri 2a YSH6000, which contains only a 230-kilobase-pair (kbp) plasmid in addition to 3.3- and 4.2-kbp cryptic plasmids characteristic to all S. flexneri strains, loss of invasiveness, loss of Congo red binding activity (Pcr), and complete loss of, or a deletion, or even a single-site IS insertion in the plasmid occurred simultaneously. This was ascribed to the fact that, once a noninvasive Pcr- cell has emerged, it overgrows the wild type as a consequence of its selective advantage in artificial media. A deletion map of the 230-kbp plasmid was made by analyzing SalI digests of 39 deletion derivatives plus 1 formed by insertion of an IS1-like element in independently isolated, noninvasive Pcr- mutants. Of 39 deletion derivatives, 16 belonged to a single type, and 6 belonged to another, suggesting deletion hot spots. The deletion map was confirmed and extended by analyzing 359 SalI-generated partial digests of the wild-type plasmid cloned into pBR322. Three copies of IS1-like elements were found on three different SalI fragments by Southern hybridization. Segments required for the Pcr+ phenotype seemed to occur at several different locations in the plasmid. Each of 28 representative Pcr- mutants were negative by the Sereny test. Hence, many, or possibly all, Pcr determinants were required for full virulence.

Gene organization and target specificity of the prokaryotic mobile genetic element IS26

The 820-bp mobile genetic element IS26 loses its ability to promote transpositional cointegration (1) by short deletions near the middle of the element causing shifts in both reading frames ORFI (left to right) and ORFII (right to left) and (2) by deletions causing substitutions of the C-terminus of ORFI but not affecting ORFII. The 702-bp ORFI is thus likely to code for the IS26 transposase. An 82-bp long sequence from the left end of IS26 contains a promoter-like structure in front of the start of ORFI at coordinate 64. In appropriately constructed plasmids, this sequence promotes the expression of the galK structural gene. The observation provides additional evidence for the functional relevance of ORFI. Neither the presence nor the absence of an intact IS26 element on the same plasmid affects measurably the degree of the galK gene expression by the IS26 promoter. Sequence comparison of 14 independent integration sites of IS26 and its relatives reveals no striking rules for target selection by the element, and the distrubtion of integration sites of IS26 on small multicopy plasmids is nearly random and independent of the local AT-content.

DNA sequence at the end of IS1 required for transposition

The insertion sequence IS1 belongs to a class of bacterial transposable genetic elements that can form compound transposons in which two copies of IS1 flank an otherwise non-transposable segment of DNA. IS1 differs from other known elements of this class (such as IS10, IS50 and IS903) in several respects. It is one of the smallest known insertion elements, exhibits a relatively complex array of open reading frames, is present in the chromosomes of various Enterobacteria, in some cases in many copies, and its insertion can result in the duplication of either 8 or 9 base pairs (bp) in the target DNA. Furthermore, although, like other members of the compound class, it seems to undergo direct transposition, IS1 also promotes replicon fusion (co-integrate formation) at a relatively high frequency. Like all other elements studied to date, the integrity of the extremities of IS1 are essential for efficient transposition. We have constructed a test system to determine the minimal DNA sequences at the extremities of IS1 required for transposition. Sequential deletions of the end sequences reveal that 21-25 bp of an isolated extremity are sufficient for transposition. A specific sequence 13-23 bp from the ends, defining the edge of the minimal sequence, is implicated as an essential site. The sites, symmetrically arrayed at both ends of IS1, correspond to the apparent consensus sequence of the known binding sites for the Escherichia coli DNA-binding protein (called integration host factor or IHF) which is required for the site-specific recombination that leads to integration of bacteriophage lambda into the bacterial genome. The sites at the ends of IS1 may thus bind a host protein, such as JHF or a related protein, that is involved in regulating the transposition apparatus.

Vector insertion mutagenesis of Rhizobium sp. strain ORS571: direct cloning of mutagenized DNA sequences

When the limited-host-range plasmid pVP2021 carrying Tn5 was mobilized into Rhizobium sp. strain ORS571 and stable acquisition of Tn5 was selected, ORS571 plasmid-genome cointegrates were exclusively obtained; direct Tn5 transposition was never observed. In every case, genomic cointegrates exhibited an additional (third) IS50 element that bordered VP2021 DNA sequences but maintained a single Tn5 element. Genomic cointegrates containing IS50 triplications were stable; neither phenotypic reversion nor resolution was detectable. Auxotrophic mutant strains (vector insertion mutants) were identified at expected frequencies among derivatives carrying ostensibly random genomic pVP2021 insertions; N2 fixation (Nif)-defective vector insertion mutants were observed among these derivatives at a frequency of 10(-3). The presence of integrated pVP2021 in ORS571 nif::VP2021 mutant genomes enabled VP2021 to constitute an endogenous cloning vector. After EcoRI or KpnI digestions, genomic nif::pVP2021 DNA sequences contiguous with integrated pVP2021 were directly cloned as new replicons without addition of an exogenous vector. Recombinant plasmids derived from two such nif::pVP2021 mutants hybridized to previously analyzed ORS571 Nif DNA sequences. Recombinant plasmid DNA and ORS571 Nif region DNA were found to be colinear; pVP2021 insertions could be accurately mapped. pVP2021 insertion-mutagenesis thus allows the direct cloning of ORS571 gene sequences for which mutant phenotypes can be selected or screened.

Location and analysis of nucleotide sequences at one end of a putative lac transposon in the Escherichia coli chromosome

A segment of Escherichia coli DNA that contained a discontinuity of homology with Salmonella typhimurium DNA was isolated. The segment, 1,430 base pairs long, was derived from one end of the lac "loop," a region of about 12 kilobase pairs of E. coli DNA, including the lac operon which has no detectable homology with S. typhimurium DNA (K. Lampel and M. Riley, Mol. Gen. Genet. 186:82-86, 1982). The nucleotide sequence of the 1,430-base-pair segment of DNA was determined. The location of the junction of discontinuity of homology within the segment was established by hybridization experiments. Nucleotide sequences at or near the junction were determined to be similar to sequences that are involved in site-specific inversion in S. typhimurium, E. coli, phage P1, and phage Mu. Similar sequences are also present within the terminal inverted repeat sequences of transposon Tn5 and at the V-D-J joining sequences of eucaryotic immunoglobulin genes. Therefore, the lac operon, together with flanking DNA, may have been inserted into the E. coli chromosome at one time via a site-specific recombination event. Rearrangement events of this kind undoubtedly have played a significant role in the evolutionary divergence of chromosomal DNAs.

Essential sites at transposon Tn 10 termini

We describe here point and deletion mutations that define which sequences at the termini of Tn10 are essential for transposition. We conclude that at least 13 and no more than 27 base pairs of terminal IS10 sequence are absolutely required at each end. These sequences correspond closely to the terminal inverted repeats of IS10. Sequences between base pairs 27 and 70 at each terminus and certain non-IS10 sequences can also influence transposition, but to a lesser degree. We also describe properties of many function-defective Tn10 transposition mutants and one exceptional Tn10 mutant.

Transposable element IS50 improves growth rate of E. coli cells without transposition

Insertion sequence IS50R, which encodes the transposase and an inhibitor of transposition of the kanamycin-resistance transposon Tn5, increases the growth rate of E. coli K12 cells relative to that of their otherwise isogenic counterparts during competition in continuous culture. Most clones isolated from chemostats in which selection had occurred retain their original number of copies of IS50R at their original genomic locations, implying that the increased growth rate is not mediated by transposition. The selective advantage due to a single IS50R element averages about 5% per hour. When the number of copies of IS50R is small, the growth-rate advantage is approximately proportional to the number of copies of IS50R. These results imply that IS50R has effects on cells that are independent of both position and transposition and may be important in the initial selection leading to the appearance of such elements in bacterial populations.