Two domains in the terminal inverted-repeat sequence of transposon Tn3

Transposable Elements: Classification, Identification, and Their Use As a Tool For Comparative Genomics

Most genomes are populated by hundreds of thousands of sequences originated from mobile elements. On the one hand, these sequences present a real challenge in the process of genome analysis and annotation. On the other hand, they are very interesting biological subjects involved in many cellular processes. Here we present an overview of transposable elements biodiversity, and we discuss different approaches to transposable elements detection and analyses.

The Tn3-family of Replicative Transposons

Transposons of the Tn3 family form a widespread and remarkably homogeneous group of bacterial transposable elements in terms of transposition functions and an extremely versatile system for mediating gene reassortment and genomic plasticity owing to their modular organization. They have made major contributions to antimicrobial drug resistance dissemination or to endowing environmental bacteria with novel catabolic capacities. Here, we discuss the dynamic aspects inherent to the diversity and mosaic structure of Tn3-family transposons and their derivatives. We also provide an overview of current knowledge of the replicative transposition mechanism of the family, emphasizing most recent work aimed at understanding this mechanism at the biochemical level. Previous and recent data are put in perspective with those obtained for other transposable elements to build up a tentative model linking the activities of the Tn3-family transposase protein with the cellular process of DNA replication, suggesting new lines for further investigation. Finally, we summarize our current view of the DNA site-specific recombination mechanisms responsible for converting replicative transposition intermediates into final products, comparing paradigm systems using a serine recombinase with more recently characterized systems that use a tyrosine recombinase.

Protein-DNA interactions define the mechanistic aspects of circle formation and insertion reactions in IS2 transposition

BACKGROUND

Transposition in IS3, IS30, IS21 and IS256 insertion sequence (IS) families utilizes an unconventional two-step pathway. A figure-of-eight intermediate in Step I, from asymmetric single-strand cleavage and joining reactions, is converted into a double-stranded minicircle whose junction (the abutted left and right ends) is the substrate for symmetrical transesterification attacks on target DNA in Step II, suggesting intrinsically different synaptic complexes (SC) for each step. Transposases of these ISs bind poorly to cognate DNA and comparative biophysical analyses of SC I and SC II have proven elusive. We have prepared a native, soluble, active, GFP-tagged fusion derivative of the IS2 transposase that creates fully formed complexes with single-end and minicircle junction (MCJ) substrates and used these successfully in hydroxyl radical footprinting experiments.

RESULTS

In IS2, Step I reactions are physically and chemically asymmetric; the left imperfect, inverted repeat (IRL), the exclusive recipient end, lacks donor function. In SC I, different protection patterns of the cleavage domains (CDs) of the right imperfect inverted repeat (IRR; extensive in cis) and IRL (selective in trans) at the single active cognate IRR catalytic center (CC) are related to their donor and recipient functions. In SC II, extensive binding of the IRL CD in trans and of the abutted IRR CD in cis at this CC represents the first phase of the complex. An MCJ substrate precleaved at the 3' end of IRR revealed a temporary transition state with the IRL CD disengaged from the protein. We propose that in SC II, sequential 3' cleavages at the bound abutted CDs trigger a conformational change, allowing the IRL CD to complex to its cognate CC, producing the second phase. Corroborating data from enhanced residues and curvature propensity plots suggest that CD to CD interactions in SC I and SC II require IRL to assume a bent structure, to facilitate binding in trans.

CONCLUSIONS

Different transpososomes are assembled in each step of the IS2 transposition pathway. Recipient versus donor end functions of the IRL CD in SC I and SC II and the conformational change in SC II that produces the phase needed for symmetrical IRL and IRR donor attacks on target DNA highlight the differences.

Transposable elements and their identification

Most genomes are populated by thousands of sequences that originated from mobile elements. On the one hand, these sequences present a real challenge in the process of genome analysis and annotation. On the other hand, there are very interesting biological subjects involved in many cellular processes. Here, we present an overview of transposable elements (TEs) biodiversity and their impact on genomic evolution. Finally, we discuss different approaches to the TEs detection and analyses.

Insertion sequences

Insertion sequences (ISs) constitute an important component of most bacterial genomes. Over 500 individual ISs have been described in the literature to date, and many more are being discovered in the ongoing prokaryotic and eukaryotic genome-sequencing projects. The last 10 years have also seen some striking advances in our understanding of the transposition process itself. Not least of these has been the development of various in vitro transposition systems for both prokaryotic and eukaryotic elements and, for several of these, a detailed understanding of the transposition process at the chemical level. This review presents a general overview of the organization and function of insertion sequences of eubacterial, archaebacterial, and eukaryotic origins with particular emphasis on bacterial elements and on different aspects of the transposition mechanism. It also attempts to provide a framework for classification of these elements by assigning them to various families or groups. A total of 443 members of the collection have been grouped in 17 families based on combinations of the following criteria: (i) similarities in genetic organization (arrangement of open reading frames); (ii) marked identities or similarities in the enzymes which mediate the transposition reactions, the recombinases/transposases (Tpases); (iii) similar features of their ends (terminal IRs); and (iv) fate of the nucleotide sequence of their target sites (generation of a direct target duplication of determined length). A brief description of the mechanism(s) involved in the mobility of individual ISs in each family and of the structure-function relationships of the individual Tpases is included where available.

Molecular genetic analysis of transposase-end DNA sequence recognition: cooperativity of three adjacent base-pairs in specific interaction with a mutant Tn5 transposase

Transposition of Tn5 and IS50 requires the specific binding of transposase (Tnp) to the end inverted repeats, the outside end (OE) and the inside end (IE). OE and IE have 12 identical base-pairs and seven non-identical base-pairs. Previously we described the isolation of a Tnp mutant, EK54, that shows an altered preference for OE versus IE compared to wild-type (wt) Tnp. EK54 enhances OE recognition and decreases IE recognition both in DNA binding and in overall transposition. Here we report that base-pairs 10, 11 and 12 of the OE are critical for the specific recognition by EK54 Tnp. These three adjacent base-pairs act cooperatively; all three must be present in order for EK54 Tnp to interact very favorably with the end DNA. The existence of only one or two of these three base-pairs decreases binding of EK54 Tnp. The combined use of EK54 Tnp and a new OE/IE mosaic end sequence containing the OE base-pairs 10, 11 and 12 gives rise to an extraordinarily high transposition frequency. Just as the Tnp is a multifunctional protein, the nucleotides in the 19 bp Tn5 ends also affect other functions besides Tnp binding. Furthermore, the fact that we were able to isolate end sequence variants that transpose at a higher frequency than the natural ends (OE and IE) with wt Tnp reveals yet another way in which the wt transposition frequency is depressed, i.e. by keeping the end sequences suboptimal.

The organization of the outside end of transposon Tn5

The end sequences of the IS50 insertion sequence are known as the outside end (OE) and inside end. These complex ends are related but nonidentical 19-bp sequences that serve as substrates for the activity of the Tn5 transposase. Besides providing the binding site of the transposase, the end sequences of a transposon contain additional types of information necessary for transposition. These additional properties include but are not limited to host protein interaction sites and sites that program synapsis and cleavage events. In order to delineate the properties of the IS50 ends,the base pairs involved in the transposase binding site have been defined. This has been approached through performing a variety of in vitro analyses: a ++hydroxyl radical missing-nucleoside interference experiment, a dimethyl sulfate interference experiment, and an examination of the relative binding affinities of single-site end substitutions. These approaches have led to the conclusion that the transposase binds to two nonsymmetrical regions of the OE, including positions 6 to 9 and 13 to 19. Proper binding occurs along one face of the helix, over two major and minor grooves, and appears to result in a significant bending of the DNA centered approximately 3 bp from the donor DNA-OE junction.

Genetic analysis of the terminal 8-bp inverted repeats of transposon Tn7

Mutations in the terminal 8-bp (5'-T1G2T3G4G5G6C7G8-3') of the inverted repeats of the bacterial transposon, Tn7, were analysed by measuring Tn7 transposition to the attachment site, attTn7. The mutation, C2, present at either end of Tn7 reduces transposition only threefold, but in the double mutant, with C2 at both ends of Tn7, no transposition is detected. C6 mutations have no effect on transposition frequency. Replacement with 5'-A3C4G5C6G7C8-3' at the right end of Tn7 apparently abolishes transposition; yet in the double mutant, where the inverted repeats are restored by substituting this sequence at both ends of Tn7, transposition is partially rescued. This suggests that the mechanism of Tn7 transposition requires communication between the two ends. Tn7 transposition has always been seen to generate a 5-bp target duplication. This is presumed to result from a staggered cut, plus repair synthesis during transposition. We found that two of our right-end mutants, C2 and C6, sometimes yielded a 6-bp target duplication. This observation implies that cleavage of the target site might also involve interaction with the donor ends which, when mutant, relax the specificity for target-site cleavage.

Substrate specificity of Ty1 integrase

Integration of the Saccharomyces cerevisiae retrotransposon Ty1 requires the element-encoded integrase (IN) protein, which is a component of cytoplasmic virus-like particles (VLPs). Using purified recombinant Ty1 IN and an oligonucleotide integration assay based on Ty1 long terminal repeat sequences, we have compared IN activity on substrates having either wild-type or altered donor ends. IN showed a marked preference for blunt-end substrates terminating in an A:T pair over substrates ending in a G:C pair or a 3' dideoxyadenosine. VLP activity on representative substrates also showed preference for donor strands which have an adenosine terminus. Staggered-end substrates showed little activity when nucleotides were removed from the end of the wild-type donor strand, but removal of one nucleotide from the complementary strand did not significantly diminish activity. Removal of additional nucleotides from the complementary strand reduced activity to minimal detection levels. These results suggest that the sequence specificity of Ty1 IN is not stringent in vitro. The absence of Ty1 IN-mediated 3' dinucleotide cleavage, a characteristic of retroviral integrases, was demonstrated by using selected substrates. In addition to the forward reaction, both recombinant IN and VLP-associated IN carry out the reverse disintegration reaction with long terminal repeat-based dumbbell substrates. Disintegration activity exhibits sequence preferences similar to those observed for the forward reaction.

Catabolic transposons

The structure and function of transposable elements that code for catabolic pathways involved in the biodegradation of organic compounds are reviewed. Seven of these catabolic transposons have structural features that place them in the Class I (composite) or Class II (Tn3-family) bacterial elements. One is a conjugative transposon. Another three have been found to have properties of transposable elements but have not been characterized sufficiently to assign to a known class. Structural features of the toluene (Tn4651/Tn4653) and naphthalene (Tn4655) elements that illustrate the enormous potential for acquisition, deletion and rearrangement of DNA within catabolic transposons are discussed. The recently characterized chlorobenzoate (Tn5271) and chlorobenzene (Tn5280) catabolic transposons encode different aromatic ring dioxygenases, however they both illustrate the constraints that must be overcome when recipients of catabolic transposons assemble and regulate complete metabolic pathways for environmental pollutants. The structures of the chlorobenzoate catabolic transposon Tn5271 and the related haloacetate dehalogenase catabolic element of plasmid pUO1 are compared and a hypothesis for their formation is discussed. The structures and activities of catabolic transposons of unknown class coding for the catabolism of halogenated alkanoic acids (DEH) and chlorobiphenyl (Tn4371) are also reviewed.

DNA binding domains in Tn3 transposase

Various segments of Tn3 transposase were fused individually to beta-galactosidase, and the resulting fusion proteins were examined for their DNA binding ability by a nitrocellulose filter binding assay. Analyses of a series of the fusion proteins revealed that the N-terminal segment of the transposase (amino acid positions 1-242; the transposase gene encodes 1004 residues in all) had specific DNA binding ability for the 38 bp terminal inverted repeat (IR) sequence, and the central segment (amino acid positions 243-632) had non-specific DNA binding ability. Further analyses of each of the two regions revealed that the N-terminal segment could be divided into at least two subsegments (amino acid positions 1-86 and 87-242), neither of which had specific DNA binding ability, but which both possessed non-specific DNA binding ability. The central segment included two subsegments (amino acid positions 243-289 and 439-505) with non-specific DNA binding ability. These results and other observations suggest that Tn3 transposase has several domains including those responsible for non-specific DNA binding, and a combination of two or more domains gives rise to specific DNA binding activity. The C-terminal segment of the transposase (amino acid positions 633-1004), which is very well conserved among transposases encoded by Tn3 family transposons, had no DNA binding ability. This segment may represent the main part of the catalytic domain responsible for the initiation step of transposition.

Chlorobenzoate catabolic transposon Tn5271 is a composite class I element with flanking class II insertion sequences

The structure of a transposon specifying the biodegradation of chlorobenzoate contaminants is described. Tn5271 is a 17-kilobase (kb) transposon that resides in the plasmid or chromosome of Alcaligenes sp. strain BR60 and allows this organism to grow on 3- and 4-chlorobenzoate. The transposon is flanked by a directly repeated sequence of 3201 base pairs (bp), which in turn is flanked by 110-bp inverted repeats. The 3.2-kb repeated sequence, designated IS1071, exists in multiple copies in the genome of Alcaligenes sp. strain BR60 and is involved in recombination of the catabolic genes into the chromosome of this strain. Sequence analysis revealed that the inverted repeat of IS1071 and the derived amino acid sequence of the single open reading frame within IS1071 are related to the inverted repeats and transposase (TnpA) proteins of the class II (Tn3 family) transposable elements. The absence of a resolvase gene within IS1071 suggests that this element is capable of determining the first step in class II transposition only. This was confirmed by observations on the IS1071-dependent formation of stable cointegrates in a recombination-deficient Escherichia coli. These results support an evolutionary scheme in which the class II transposable elements descended from simple insertion sequences.

Functional analysis of the two domains in the terminal inverted repeat sequence required for transposition of Tn3

Bacterial transposon Tn3 has a 38-bp terminal inverted repeat (IR) sequence. The IR sequence has been divided into two domains, A and B, of which domain B is bound by transposase, and domain A is not Here, we defined the two domains more precisely by constructing three IR mutants with a 2-bp substitution at relevant sites within the IR sequence, followed by examination of the binding of transposase to the fragments containing these IR mutants: domain A was located at bp 1-11, whereas domain B was at bp 12-38. To see if the two domains in the IR are functionally distinct, we constructed mini-Tn3 derivatives flanked by two IRs with various 2-bp substitutions within domain A or B, and analyzed their ability to mediate cointegration. The mini-Tn3 derivatives flanked by IR(A+ B+) and IR(A- B+) [or IR(A+ B-)] and those flanked by IR(A-B+) and IR(A+ B-) mediate cointegration more efficiently than the mini-Tn3 derivatives flanked by two IR(A- B+)s or by two IR(A+ B-)s. These results and others presented here indicate that the two domains of IR are functionally distinct in promoting cointegration.

The Haemophilus influenzae capsulation gene cluster: a compound transposon

The population of capsulate Haemophilus influenzae is divided into two phylogenetic divisions. Here we show that in division I strains the capsulation (cap) gene cluster lies between direct repeats of a novel insertion sequence (IS)-like element, IS1016. cap has apparently been mobilized in the chromosome as a compound transposon by IS1016, and the repeats have provided a molecular substrate for reversible cap gene amplification, with augmentation of capsule production, through unequal homologous recombination. Such amplification has occurred in serotype b strains, but in these a large direct repeat of cap genes has become fixed in the population. We have found a 1.2 kb deletion at one end of this duplicated capb locus, removing most of one copy of the polysaccharide export gene bexA. We have shown that this makes capsulation dependent on preservation of the direct repeat structure in order to avoid recombination-mediated loss of the other copy of bexA. Type b strains with this cap configuration are disseminated worldwide and currently cause nearly all invasive Haemophilus infections, leading us to speculate that the 1.2 kb deletion occurred in an ancestral type b strain and conferred significant biological advantage.

Site-specific transposition of insertion sequence IS630

IS630 is a 1.15-kilobase sequence in Shigella sonnei that, unlike many mobile elements, seems not to mediate cointegration between different replicons. To assess its transposition, we constructed composite elements containing inverted copies of IS630 flanking a drug resistance gene. We found that these composite elements transposed to plasmid ColE1 in Escherichia coli. DNA sequencing showed that transposition was, in all cases, to the dinucleotide sequence 5'-TA-3'. There were two preferred insertion sites which corresponded to the TA sequences in the inverted repeats of a 13-base-pair stem region of the [rho]-dependent transcription terminator. IS630 is flanked by TA, and nucleotide substitution by in vitro mutagenesis at these ends did not affect transposition activity of a composite element or its ability to insert preferentially into TA within the 13-base-pair inverted repeat sequences or to duplicate the target sequence.

Tn3 transposition immunity is conferred by the transposase-binding domain in the terminal inverted-repeat sequence of Tn3

A series of mutant terminal inverted repeats (IRs), having 2 bp substitutions at various sites within the 38-bp IR sequence of the ampicillin-resistance transposon Tn3, were tested for transposition immunity to Tn3. Mutations within region 1-10 in the IR did not affect transposition immunity, while mutations within region 13-38 inactivated the immunity function. These two regions corresponded to domain A which was not bound specifically by Tn3 transposase and to domain B which was bound by the transposase, respectively. This indicates that specific binding of transposase to domain B within the IR sequence is responsible for transposition immunity.