Expression of proteins essential for IS1 transposition: specific binding of InsA to the ends of IS1

Copy-out-Paste-in Transposition of IS911: A Major Transposition Pathway

IS911 has provided a powerful model for studying the transposition of members of a large class of transposable element: the IS3 family of bacterial Insertion Sequences (IS). These transpose by a Copy-out-Paste-in mechanism in which a double-strand IS circle transposition intermediate is generated from the donor site by replication and proceeds to integrate into a suitable double strand DNA target. This is perhaps one of the most common transposition mechanisms known to date. Copy-out-Paste-in transposition has been adopted by members of at least eight large IS families. This chapter details the different steps of the Copy-out-Paste-in mechanism involved in IS911 transposition. At a more biological level it also describes various aspects of regulation of the transposition process. These include transposase production by programmed translational frameshifting, transposase expression from the circular intermediate using a specialized promoter assembled at the circle junction and binding of the nascent transposase while it remains attached to the ribosome during translation (co-translational binding). This co-translational binding of the transposase to neighboring IS ends provides an explanation for the longstanding observation that transposases show a cis-preference for their activities.

Bacterial insertion sequences: their genomic impact and diversity

Insertion sequences (ISs), arguably the smallest and most numerous autonomous transposable elements (TEs), are important players in shaping their host genomes. This review focuses on prokaryotic ISs. We discuss IS distribution and impact on genome evolution. We also examine their effects on gene expression, especially their role in activating neighbouring genes, a phenomenon of particular importance in the recent upsurge of bacterial antibiotic resistance. We explain how ISs are identified and classified into families by a combination of characteristics including their transposases (Tpases), their overall genetic organisation and the accessory genes which some ISs carry. We then describe the organisation of autonomous and nonautonomous IS‐related elements. This is used to illustrate the growing recognition that the boundaries between different types of mobile element are becoming increasingly difficult to define as more are being identified. We review the known Tpase types, their different catalytic activities used in cleaving and rejoining DNA strands during transposition, their organisation into functional domains and the role of this in regulation. Finally, we consider examples of prokaryotic IS domestication. In a more speculative section, we discuss the necessity of constructing more quantitative dynamic models to fully appreciate the continuing impact of TEs on prokaryotic populations.

The emerging diversity of transpososome architectures

DNA transposases are enzymes that catalyze the movement of discrete pieces of DNA from one location in the genome to another. Transposition occurs through a series of controlled DNA strand cleavage and subsequent integration reactions that are carried out by nucleoprotein complexes known as transpososomes. Transpososomes are dynamic assemblies which must undergo conformational changes that control DNA breaks and ensure that, once started, the transposition reaction goes to completion. They provide a precise architecture within which the chemical reactions involved in transposon movement occur, but adopt different conformational states as transposition progresses. Their components also vary as they must, at some stage, include target DNA and sometimes even host-encoded proteins. A very limited number of transpososome states have been crystallographically captured, and here we provide an overview of the various structures determined to date. These structures include examples of DNA transposases that catalyze transposition by a cut-and-paste mechanism using an RNaseH-like nuclease catalytic domain, those that transpose using only single-stranded DNA substrates and targets, and the retroviral integrases that carry out an integration reaction very similar to DNA transposition. Given that there are a number of common functional requirements for transposition, it is remarkable how these are satisfied by complex assemblies that are so architecturally different.

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.

Involvement of two domains with helix-turn-helix and zinc finger motifs in the binding of IS1 transposase to terminal inverted repeats

The insertion element IS1 has two open reading frames (ORFs), insA and insB, and produces a transframe protein InsAB, known as IS1 transposase, by translational frameshifting. The transposase binds to terminal inverted repeats (IRL and IRR) to promote IS1 transposition. Unless frameshifting occurs, IS1 produces InsA protein, which also binds to IRs and therefore acts as an inhibitor of transposition, as well as a transcriptional repressor of the promoter in IRL. A helix-turn-helix (HTH) motif present in both transposase and InsA is thought to be involved in IR-specific DNA binding. A comparison of transposases encoded by IS1 family elements reveals that the N-terminal regions contain four conserved cysteine residues, which appear to constitute a C(2)C(2) zinc finger (ZF) motif. This motif is also thought to be involved in IR-specific DNA binding. In this study, we show that IS1 transposases with an amino acid substitution in the HTH or ZF motif lose the ability to promote transposition. We also show that transposases, as well as InsA proteins with the same substitution, lose the ability to repress the activity of the IRL promoter, and that purified InsA mutant proteins lose the ability to bind to the IRL-containing fragment. Furthermore, we show that InsA protein co-ordinates Zn(II) with the four cysteine residues as ligands and loses the ability to bind to the IRL-containing fragment in the presence of an agent chelating Zn(II). These findings indicate that IS1 transposase has two domains with HTH and ZF motifs responsible for IR-specific DNA binding in promoting transposition. It is assumed that the two domains are needed for transposase to bind to each IR in an oriented manner in order to place a catalytic domain in the C-terminal region of the transposase to a region around the IR end, where the strand transfer reaction occurs in a transpososome.

Presence of a characteristic D-D-E motif in IS1 transposase

Transposases encoded by various transposable DNA elements and retroviral integrases belong to a family of proteins with three conserved acidic amino acids, D, D, and E, constituting the D-D-E motif that represents the active center of the proteins. IS1, one of the smallest transposable elements in bacteria, encodes a transposase which has been thought not to belong to the family of proteins with the D-D-E motif. In this study, we found several IS1 family elements that were widely distributed not only in eubacteria but also in archaebacteria. The alignment of the transposase amino acid sequences from these IS1 family elements showed that out of 14 acidic amino acids present in IS1 transposase, three (D, D, and E) were conserved in corresponding positions in the transposases encoded by all the elements. Comparison of the IS1 transposase with other proteins with the D-D-E motif revealed that the polypeptide segments surrounding each of the three acidic amino acids were similar. Furthermore, the deduced secondary structures of the transposases encoded by IS1 family elements were similar to one another and to those of proteins with the D-D-E motif. These results strongly suggest that IS1 transposase has the D-D-E motif and thus belongs to the family of proteins with the D-D-E motif. In fact, mutant IS1 transposases with an amino acid substitution for each of the three acidic amino acids possibly constituting the D-D-E motif were not able to promote transposition of IS1, supporting this hypothesis. The D-D-E motif identified in IS1 transposase differs from those in the other proteins in that the polypeptide segment between the second D and third E in IS1 transposase is the shortest, 24 amino acids in length. Because of this difference, the presence of the D-D-E motif in IS1 transposase has not been discovered for some time.

Involvement of H-NS in transpositional recombination mediated by IS1

IS1, the smallest active transposable element in bacteria, encodes a transposase that promotes inter- and intramolecular transposition. Host-encoded factors, e.g., histone-like proteins HU and integration host factor (IHF), are involved in the transposition reactions of some bacterial transposable elements. Host factors involved in the IS1 transposition reaction, however, are not known. We show that a plasmid with an IS1 derivative that efficiently produces transposase did not generate miniplasmids, the products of intramolecular transposition, in mutants deficient in a nucleoid-associated DNA-binding protein, H-NS, but did generate them in mutants deficient in histone-like proteins HU, IHF, Fis, and StpA. Nor did IS1 transpose intermolecularly to the target plasmid in the H-NS-deficient mutant. The hns mutation did not affect transcription from the indigenous promoter of IS1 for the expression of the transposase gene. These findings show that transpositional recombination mediated by IS1 requires H-NS but does not require the HU, IHF, Fis, or StpA protein in vivo. Gel retardation assays of restriction fragments of IS1-carrying plasmid DNA showed that no sites were bound preferentially by H-NS within the IS1 sequence. The central domain of H-NS, which is involved in dimerization and/or oligomerization of the H-NS protein, was important for the intramolecular transposition of IS1, but the N- and C-terminal domains, which are involved in the repression of certain genes and DNA binding, respectively, were not. The SOS response induced by the IS1 transposase was absent in the H-NS-deficient mutant strain but was present in the wild-type strain. We discuss the possibility that H-NS promotes the formation of an active IS1 DNA-transposase complex in which the IS1 ends are cleaved to initiate transpositional recombination through interaction with IS1 transposase.

Metal-ion tolerance in Escherichia coli: analysis of transcriptional profiles by gene-array technology

Escherichia coli was adapted to grow in medium containing substantially elevated concentrations of either Zn(II), Cd(II), Co(II) or Ni(II). Whole-genome transcriptional profiles were generated from adapted strains and analysed for significant alteration in transcript abundance with reference to a wild-type strain. Similar alterations in specific message levels were observed for strains adapted to the four metal ions. One unexpected trend was the increase in transcript level of genes involved in transposition of IS elements, particularly insA. Subsequent expression of insA-7 from a heterologous promoter in E. coli conferred tolerance to Zn(II).

Integrating DNA: transposases and retroviral integrases

Transposable elements appear quite disparate in their organization and in the types of genetic rearrangements they promote. In spite of this diversity, retroviruses and many transposons of both prokaryotes and eukaryotes show clear similarities in the chemical reactions involved in their transposition. This is reflected in the enzymes, integrases and transposases, that catalyze these reactions and that are essential for the mobility of the elements. In this chapter, we examine the structure-function relationships between these enzymes and the different ways in which the individual steps are assembled to produce a complete transposition cycle.

Transposition of IS1 circles

BACKGROUND

IS1, the smallest active transposable element in bacteria, encodes transposase. IS1 transposase promotes transposition as well as production of miniplasmids from a plasmid carrying IS1 by deletion of the region adjacent to IS1. The IS1 transposase also promotes production of IS1 circles consisting of the entire IS1 sequence and a sequence, 6-9 bp in length, as a spacer between terminal inverted repeats of IS1. The biological significance of the generation of IS1 circles is not known.

RESULTS

Plasmids carrying an IS1 circle with a spacer sequence 6-9 bp long transposed to target plasmids at a very high frequency when transposase was produced from a co-resident plasmid. The products were target plasmids with the donor plasmid inserted at the ends of IS1 in the IS1 circle. This insertion accompanied the removal of the spacer sequence and duplication of the sequence at the target site. IS1 circles with a much longer spacer sequence transposed less frequently. The SOS response was induced in cells harbouring a plasmid with an IS1 circle owing to transposase. IS1 circles could transpose in the strain deficient in H-NS, a nucleoid-associated DNA-binding protein known to be required for the transposition of IS1.

CONCLUSIONS

IS1 circles appear to act as intermediates for simple insertion into the target DNA via cleavage of the circles which induces the SOS response. H-NS may function in promoting the assembly of an active IS1 DNA-transposase complex at the terminal inverted repeats.

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.

Defining functional regions of the IS903 transposase

The insertion sequence IS903 encodes a 307 amino acid residue protein, transposase, that is essential for transposition. It is a multi-functional DNA-binding protein that specifically recognizes the 18 bp inverted repeats at the ends of the element and also recognizes DNa non-specifically when it captures a target site. In addition, transposase performs catalytic functions when it mediates the cleavage and religation steps of transposition. We have carried out deletion and mutational analyses to define functional domains of the transposase protein. The deletion studies delineate a 99 residue region of the protein (residues 31 to 129) that specifies binding to the inverted repeat. A slightly larger maltose-binding protein-transposase fusion that includes residues 22 to 139 (Tnp 22-139) binds as efficiently and with the same specificity as the full-length transposase protein. Tnp 22-139 also induces a DNA bend similar to that of the wild-type protein, and so we conclude that all binding and bending specificity is contained within the N-terminal domain of the protein. Unlike full-length transposase, Tnp 22-139 forms additional higher-order complexes in band-shift gels suggesting that the deletion has exposed a surface(s) capable of participating in protein-protein interactions. Six highly conserved residues in the C-terminal portion of the protein were mutated to alanine. Each mutant protein was binding-proficient but defective in transposition. The phenotype of these substitutions, and their alignment with residues shown to abolish catalysis of other transposases and integrases, suggest that these are residues responsible for catalytic steps in transposition of IS903; we believe three of these residues comprise the DDE motif, conserved in transposases and integrases. Our data are consistent with IS903 transposase being composed of two domains: an N-terminal domain primarily involved in DNA binding and a C-terminal domain that is involved in catalysis.

Genetic analyses of the interactions of the IS1-encoded proteins with the left end of IS1 and its insertion hotspot

Insertion sequence IS1 specifies the InsA, delta InsA-B'-InsB and InsA-B'-InsB protein species. These three proteins have the identical alpha-helix-turn-alpha-helix motif that is likely to be responsible for DNA binding. In fact, InsA binds to the ends of IS1, and regulates gene expression and transposition of IS1. delta InsA-B'-InsB and/or InsA-B'-InsB has been thought to possess a transposase-like activity. Here, I examined the actions of these proteins in vivo on the promoter (pinsL) in the left end of IS1. InsA repressed pinsL-driven gene expression, both in cis and in trans. delta InsA-B'-InsB inhibited it efficiently only when pinsL was located near the construct where delta InsA-B'-InsB is expressed. Furthermore, it has been shown that the possible -10 sequence of pinsL is required for delta InsA-B'-InsB to act on, but the -35 sequence where InsA binds specifically, is not. InsA-B'-InsB appeared not to work on a nearby pinsL. The cis-action of delta InsA-B'-InsB is consistent with the previous observation that the IS1 transposase acts preferentially in cis. Interestingly, delta InsA-B'-InsB acted on a nearby P3 promoter in the IS1 insertion hotspot, and on another promoter outside the hotspot. delta InsA-B'-InsB may generally interact with the regions in or around promoters owing to their low DNA helix stability. Note that IS1 transposes preferentially into A + T-rich DNA segments, and that DNA is unwound from the -10 region of a promoter in transcription. The cis-preference of delta InsA-B'-InsB would result in an overall reduction of transposition of IS1 and its defective copy in a cell, allowing stable existence of the element in its bacterial host.

Detection of an IS2-encoded 46-kilodalton protein capable of binding terminal repeats of IS2

The genome of the transposable element IS2 contains five open reading frames that are capable of encoding proteins greater than 50 amino acids; however, only one IS2 protein of 14 kDa had been detected. By replacing the major IS2 promoter located in the right terminal repeat of IS2 with the T7 promoter to express IS2 genes, we have detected another IS2 protein of 46 kDa. This 46-kDa protein was designated InsAB'. Analyses of the InsAB' sequence revealed motifs that are characteristic of transposases of other transposable elements. InsAB' has the ability to bind both terminal repeat sequences of IS2. It was shown to bind a 27-bp sequence (5'-GTTAAGTGATAACAGATGTCTGGAAAT-3', positions 1316 to 1290 by our numbering system [16 to 42 by the previous numbering system]) located at the inner end of the right terminal repeat and a 31-bp sequence (5'-TTATTTAAGTGATATTGGTTGTCTGGAGATT-3', positions 46 to 16 [1286 to 1316]), including the last 27 bp of the inner end and the adjacent 4 bp of the left terminal repeat of IS2. This result suggests that InsAB' is a transposase of IS2. Since there is no open reading frame capable of encoding a 46-kDa protein in the entire IS2 genome, this 46-kDa protein is probably produced by a translational frameshifting mechanism.

Interactions between the repressor and the early operator region of bacteriophage Mu

The repressor of bacteriophage Mu, c, binds to three operator sites, O1, O2, and O3, overlapping two divergent promoters, which regulate the lytic and lysogenic pathways. Its binding to this operator region generates several complexes, which were analyzed by DNase I protection experiments. We demonstrate that c first binds to two 11-base pair partially repeated sequences in O2 that could represent "core" binding sites for the repressor. This initial interaction serves as an organizer of a more complex nucleoprotein structure in which O2, O1, and O3 become successively occupied. The quaternary structure of the repressor was also investigated. Size exclusion chromatography and protein-protein crosslinking experiments with chemicals that possess linking arms of various lengths indicate that the repressor oligomerizes in solution. A model is proposed describing the successive interactions of c with the operator sites O2, O1, and O3 leading to the elaboration of a higher order structure in which the early lytic functions are repressed.

The insE open reading frame of IS1 is not required for formation of cointegrates

The role of the insE open reading frame in transposition of IS1 was reexamined by using an insE nonsense mutation that does not alter the amino acid sequence of InsA inhibitor or InsAB transposase. The mutant was active in all strains tested, showing that insE is not essential for formation of cointegrates.

Mutagenesis of the IS1 transposase: importance of a His-Arg-Tyr triad for activity

Inspection of the primary sequence of the IS1 transposase suggested that it carries residues which are characteristic of the active site of integrases of the bacteriophage lambda family (Int). In particular, these include a highly conserved triad: His-Arg-Tyr. The properties of mutants made at each of these positions were investigated in vivo. The results of several different assays confirm that each is important for transposase activity. Moreover, as in the case of members of the Int family, different mutations of the His residue exhibited different effects. In a particular, His-to-Leu mutation resulted in complete inactivation whereas the equivalent His-to-Gln mutation retained low but significant levels of activity.

Characterization of IS1221 from Mycoplasma hyorhinis: expression of its putative transposase in Escherichia coli incorporates a ribosomal frameshift mechanism

Seven complete and two partial copies of IS1221 variants from Mycoplasma hyorhinis and Mycoplasma hyopneumoniae characterized to date have established a consensus IS1221 as a 1513 bp element with unique structural characteristics resembling the IS3 family of bacterial insertion sequences. Each IS1221 copy contains highly conserved 28 bp imperfect terminal inverted repeats and three distinctive internal inverted repeats (LIR, RIR and IIR). IIR is located within the coding region of the element and it is proposed that it plays a critical role in the regulation of putative transposase expression. Consensus IS1221 and one particular copy, G1135.2, contain a single long open reading frame (ORF). Two potential initiation codons are present at nucleotide 46 (AUG46) and nucleotide 397 (AUG397) and both are preceded by strong ribosome-binding sites. Both initiation codons can be used efficiently in an Escherichia coli T7 expression system. The LIR has a negative regulatory effect on translation initiation from AUG46. A-1 translational frameshift event is shown to be involved in expression of the IS1221 ORF and results in the production of 20 kDa and 6 kDa truncated proteins from the respective upstream initiation codons of the IS1221 ORF. Base substitution and deletion mutations in sequences resembling characterized motifs in documented examples of translational frameshifting resulted in a significant increase in the full-length products and a corresponding decrease in the truncated products from the IS1221 ORF. In contrast to the usual -1 frameshift regulatory event in the IS3 family, which produces a transframe fusion product as the active transposase, IS1221 may have evolved a high-frequency -1 frameshift mechanism that produces a truncated product from the upstream coding domain and thereby results in the regulated low-level production of the full-length presumptive transposase.

DNA-binding domain of the RepE initiator protein of mini-F plasmid: involvement of the carboxyl-terminal region

The RepE initiator protein (251 residues) is essential for mini-F replication in Escherichia coli and exhibits two major functions: initiation of DNA replication from ori2 and autogenous repression of repE transcription. Whereas the initiation is mediated by RepE monomers that bind to the ori2 iterons (direct repeats), the autogenous repression is mediated by dimers that bind to the repE operator, which contains an inverted repeat sequence related to the iterons. We now report that the binding of RepE to these DNA sites is primarily determined by the C-terminal region of this protein. The mutant RepE proteins lacking either the N-terminal 33 (or more) residues or the C-terminal 7 (or more) residues were first shown to be defective in binding to both the ori2 and the operator DNAs. However, direct screening and analysis of mutant RepEs which are specifically affected in binding to the ori2 iterons revealed that the mutations (mostly amino acid substitutions) occur exclusively in the C-terminal region (residues 168 to 242). These mutant proteins exhibited reduced binding to ori2 and no detectable binding to the operator. Thus, whereas truncation of either end of RepE can destroy the DNA-binding activities, the C-terminal region appears to represent a primary DNA-binding domain of RepE for both ori2 and the operator. Analogous DNA-binding domains seem to be conserved among the initiator proteins of certain related plasmids.

Bacterial transposases and retroviral integrases

Transposable genetic elements have adopted two major strategies for their displacement from one site to another within and between genomes. One involves passage through an RNA intermediate prior to synthesis of a DNA copy while the other is limited uniquely to DNA intermediates. For both types of element, recombination reactions involved in integration are carried out by element-specific enzymes. These are called transposases in the case of DNA elements and integrases in the case of the best-characterized RNA elements, the retroviruses and retrotransposons. In spite of major differences between these two transposition strategies, one step in the process, that of insertion, appears to be chemically identical. Current evidence suggests that the similarities in integration mechanism are reflected in amino acid sequence similarities between the integrases and many transposases. These similarities are particularly marked in a region which is thought to form part of the active site, namely the DDE motif. In the light of these relationships, we attempt here to compare mechanistic aspects of retroviral integration with transposition of DNA elements and to summarize current understanding of the functional organization of integrases and transposases.

Is the IS1 transposase, InsAB', the only IS1-encoded protein required for efficient transposition?

The transposase of the bacterial insertion sequence IS1 is normally expressed by inefficient translational frameshifting between an upstream reading frame which itself specifies a transposition inhibitor, InsA, and a second consecutive reading frame located immediately downstream. A fused-frame mutant which carries an additional base pair inserted at the point of frameshifting was constructed. This mutant exhibits high transposition activity and should express the transposase, InsAB', constitutively without frameshifting. Unexpectedly, a second protein species was observed to be expressed from this mutant. We demonstrate here that this protein, InsA*, results from continued frameshifting on the modified frameshift motif. The protein retains the activities of the repressor InsA. Its elimination, by further modification of the frameshift motif, results in a further increase in various transposition activities of IS1. These results support the hypothesis that a single IS1-encoded protein, InsAB', is necessary for transposition.

Isolation of a novel IS3 group insertion element and construction of an integration vector for Lactobacillus spp

An insertion sequence (IS) element from Lactobacillus johnsonii was isolated, characterized, and exploited to construct an IS-based integration vector. L. johnsonii NCK61, a high-frequency conjugal donor of bacteriocin production (Laf+) and immunity (Lafr), was transformed to erythromycin resistance (Emr) with the shuttle vector pSA3. The NCK61 conjugative functions were used to mobilize pSA3 into a Laf- Lafs EMs recipient. DNA from the Emr transconjugants transformed into Escherichia coli MC1061 yielded a resolution plasmid with the same size as that of pSA3 with a 1.5-kb insertion. The gram-positive replication region of the resolution plasmid was removed to generate a pSA3-based suicide vector (pTRK327) bearing the 1.5-kb insert of Lactobacillus origin. Plasmid pTRK327 inserted randomly into the chromosomes of both Lactobacillus gasseri ATCC 33323 and VPI 11759. No homology was detected between plasmid and total host DNAs, suggesting a Rec-independent insertion. The DNA sequence of the 1.5-kb region revealed the characteristics of an IS element (designated IS1223): a length of 1,492 bp; flanking, 25-bp, imperfect inverted repeats; and two overlapping open reading frames (ORFs). Sequence comparisons revealed 71.1% similarity, including 35.7% identity, between the deduced ORFB protein of the E. coli IS element IS150 and the putative ORFB protein encoded by the Lactobacillus IS element. A putative frameshift site was detected between the overlapping ORFs of the Lactobacillus IS element. It is proposed that, similar to IS150, IS1223 produces an active transposase via translational frameshifting between two tandem, overlapping ORFs.

Translational frameshifting in the control of transposition in bacteria

The expression of an increasing number of genes of both prokaryotic and eukaryotic origin has been shown to be regulated at the translational level by programmed (sequence-specific) ribosomal frameshifting. Among these are the bacterial insertion sequences IS1 and two members of the widely distributed IS3-family, IS150 and IS911. Frameshifting provides a means of specifying several proteins with different functions using a minimum of genetic information. In this review, we survey present understanding of the way in which frameshifting is integrated into the overall control of transposition activity in these elements.

Use of gel retardation to analyze protein-nucleic acid interactions

Protein-nucleic acid interactions are crucial in the regulation of many fundamental cellular processes. The nature of these interactions is susceptible to analysis by a variety of methods, but the combination of high analytical power and technical simplicity offered by the gel retardation (band shift) technique has made this perhaps the most widely used such method over the last decade. This procedure is based on the observation that the formation of protein-nucleic complexes generally reduces the electrophoretic mobility of the nucleic acid component in the gel matrix. This review attempts to give a simplified account of the physical basis of the behavior of protein-nucleic acid complexes in gels and an overview of many of the applications in which the technique has proved especially useful. The factors which contribute most to the resolution of the complex from the naked nucleic acid are the gel pore size, the relative mass of protein compared with nucleic acid, and changes in nucleic acid conformation (bending) induced by binding. The consequences of induced bending on the mobility of double-strand DNA fragments are similar to those arising from sequence-directed bends, and the latter can be used to help characterize the angle and direction of protein-induced bends. Whether a complex formed in solution is actually detected as a retarded band on a gel depends not only on resolution but also on complex stability within the gel. This is strongly influenced by the composition and, particularly, the ionic strength of the gel buffer. We discuss the applications of the technique to analyzing complex formation and stability, including characterizing cooperative binding, defining binding sites on nucleic acids, analyzing DNA conformation in complexes, assessing binding to supercoiled DNA, defining protein complexes by using cell extracts, and analyzing biological processes such as transcription and splicing.

Nonautonomous transposable elements in prokaryotes and eukaryotes

Defective (nonautonomous) copies of transposable elements are relatively common in the genomes of eukaryotes but less common in the genomes of prokaryotes. With regard to transposable elements that exist exclusively in the form of DNA (nonretroviral transposable elements), nonautonomous elements may play a role in the regulation of transposition. In prokaryotes, plasmid-mediated horizontal transmission probably imposes a selection against nonautonomous elements, since nonautonomous elements are incapable of mobilizing themselves. The lower relative frequency of nonautonomous elements in prokaryotes may also reflect the coupling of transcription and translation, which may bias toward the cis activation of transposition. The cis bias we suggest need not be absolute in order to militate against the long-term maintenance of prokaryotic elements unable to transpose on their own. Furthermore, any cis bias in transposition would also decrease the opportunity for trans repression of transposition by nonautonomous elements.

Programmed translational frameshifting and initiation at an AUU codon in gene expression of bacterial insertion sequence IS911

The proteins expressed by insertion sequence IS911, a member of the widespread IS3 family of elements, have been analyzed. The results indicate that three major species are produced from two consecutive reading frames. A protein of Mr 11,500, ORFA, is synthesized from an upstream reading frame. A larger protein, ORFAB, uses the same initiation codon and is produced by a -1 programmed translational frameshift between orfA and a downstream frame, orfB, whose amino acid sequence shows significant homology with retroviral integrase proteins. The orfB frame is also expressed independently in two alternative forms: the first uses a rare AUU initiation codon in the orfB phase whereas the second appears to initiate in the orfA phase and is produced by a -1 frameshift mechanism similar to that used in ORFAB expression. A specific IS911 integration reaction using a minimal active junction composed of 51 base-pairs of the right inverted repeat and a flanking phase lambda sequence resembling a second end in inverted orientation has been developed to analyze the functions of these proteins by transcomplementation in vivo. The orfA and orfB frames are shown to be essential and production of ORFAB is shown to stimulate integration in this system, suggesting that this fusion protein is the IS911 transposase.

Unusual codon bias occurring within insertion sequences in Escherichia coli

The large open reading frames of insertion sequences from Escherichia coli were examined for their spatial pattern of codon usage bias and distribution of rarely used codons. There is a bias in codon usage that is generally lower toward the terminal ends of the coding regions, which is reflected in the occurrence of an excess of nonpreferred codons in the 3' portions of the coding regions as compared with the 5' portions. In contrast, typical chromosomal genes have a lower codon usage bias toward the 5' ends of the coding regions. These results imply that the selective forces reflected in codon usage bias may differ according to position within the coding sequence. In addition, these constraints apparently differ in important ways between genes contained in insertion sequences and those in the chromosome.

Functional similarities between retroviruses and the IS3 family of bacterial insertion sequences?

Members of the IS3 family of insertion sequences are found in a wide range of bacteria. At least 10 members of this family carry two major open reading frames: a small upstream frame (0 phase), and a longer downstream frame in the -1 phase. The downstream frame shows significant similarity at the amino acid level. A highly conserved region of this frame also exhibits notable similarity with a region of the integrase (endonuclease) domain of retroviruses. Although the overall transposition mechanism of the insertion sequence and retroviral elements is certainly different, the two groups may share additional common features, including a -1 frameshift resulting in the production of a fusion protein.

Transposition in Shigella dysenteriae: isolation and analysis of IS911, a new member of the IS3 group of insertion sequences

Twenty-nine clear-plaque mutants of bacteriophage lambda were isolated from a Shigella dysenteriae lysogen. Three were associated with insertions in the cI gene: two were due to insertion of IS600, and the third resulted from insertion of a new element, IS911. IS911 is 1,250 base pairs (bp) long, carries 27-bp imperfect terminal inverted repeats, and generates 3-bp duplications of the target DNA on insertion. It was found in various copy numbers in all four species of Shigella tested and in Escherichia coli K-12 but not in E. coli W. Analysis of IS911-mediated cointegrate molecules indicated that the majority were generated without duplication of IS911. They appeared to result from direct insertion via one end of the element and the neighboring region of DNA, which resembles a terminal inverted repeat of IS911. Nucleotide sequence analysis revealed that IS911 carries two consecutive open reading frames which code for potential proteins showing similarities to those of the IS3 group of elements.

Evidence for a role of translational frameshifting in the expression of transposition activity of the bacterial insertion element IS1

The bacterial insertion element IS1 contains two essential open reading frames, insA and insB, arranged in tandem. We have introduced a number of site-specific mutations into the region including the 3'-terminal region of insA, the region between insA and insB, and the ATG codon at the start of insB. Relative transposition activities of mutant and wild-type elements were determined using a modified in vivo cointegration assay. The results support the hypothesis that a translational (-1) frameshift occurring in the 3'-terminal region of insA and linking insB to insA is responsible for the synthesis of the active IS1 transposition enzyme. Further results with IS1 elements containing internal deletions are in agreement with a role of the normally terminated insA product as an inhibitor of transposition.

The regulatory role of the IS1-encoded InsA protein in transposition

We show here that the protein InsA, which is encoded by IS1 and binds specifically to the terminal inverted repeats of this insertion sequence, negatively regulates IS1 transposition activity. We demonstrate that it inhibits both IS1-mediated cointegrate formation and transposition of a synthetic IS1-based transposon ('omegon'; omega-on). These results also indicate that the omega-on which does not itself encode IS1 transposition functions can be complemented in trans, presumably by the copies of IS1 resident in the Escherichia coli chromosome. Using insA-lacZ gene fusions, we show that at least part of this effect can be explained by the ability of InsA to repress expression of IS1-encoded genes both in cis or in trans. The experiments involving omega-on transposition raise the possibility that InsA inhibits transposition directly by competition with the transposase for their cognate site within the ends of IS1.

Tn4527, a Tp Sp/Sm transposon related to Tn7 and flanked by IS1

Tn4527 was isolated from a Salmonella typhimurium strain obtained in Brazil. Its size is 19.6 kb and it carries resistance to trimethoprim, spectinomycin, and streptomycin, as in the case of Tn7 (14 kb). A restriction analysis of the transposon shows regions of similarity to Tn7 mixed with extra DNA. The 2.6-kb and 2.2-kb HindIII fragments of Tn7, which encode transposition-related proteins, show homology to Tn4527. In contrast to Tn7, Tn4527 is flanked by direct repeats, which seem to be IS1's, as they have appropriate restriction sites and hybridize both to IS1 and to internal IS1 oligonucleotides.

Functional domains of bacteriophage Mu transposase: properties of C-terminal deletions

We have generated a series of 3' deletions of a cloned copy of the bacteriophage Mu transposase (A) gene. The corresponding truncated proteins, expressed under the control of the lambda PI promoter, were analysed in vivo for their capacity to complement a super-infecting MuAam phage, both for lytic growth and lysogeny, and for their effect on growth of wild-type Mu following infection or induction of a lysogen. Using crude cell extracts, we have also examined binding properties of these proteins to the ends of Mu. The results allow us to further define regions of the protein important in replicative transposition, establishment of lysogeny and DNA binding.

Regulation of IS1 transposition by the insA gene product

The IS1 element contains two adjacent genes called insA and insB, both required for IS1 transposition and IS1-mediated plasmid cointegration. These two genes are transcribed polycistronically from the promoter in the left terminal inverted repeat of IS1 (insL). We constructed overexpression systems of these genes with the tac promoter, which are regulated by an exogenous inducer, isopropyl-beta-D-thiogalactopyranoside (IPTG). Then we have examined, under various conditions of induction with IPTG, how overexpression of these genes affects IS1 transposition, using an assay based on plasmid cointegration. When the insA and insB genes were organized identically to the wild-type IS1 genes and simultaneously expressed using low concentrations of IPTG, activity of a mutant IS1 in cis was restored, but not in trans. Higher IPTG concentrations resulted in lower transposition activity. Expression in trans of insA and insB results in a 50 to 100-fold reduction of the frequency of cointegration mediated by wild-type IS1. Such a reduction is also observed when only the insA gene is overexpressed in trans. Overexpression of either mutant insA or insB does not affect the cointegration event. Tests with the insA-lacZ fusion gene showed that the InsA product inhibits the expression of IS1 genes directed by its own promoter in insL. These results suggest that the InsA product regulates IS1 transposition by inhibiting expression of IS1 transposition genes in addition to acting as part of a transposase complex.

The Escherichia coli protein, Fis: specific binding to the ends of phage Mu DNA and modulation of phage growth

We show, using gel retardation, that crude Escherichia coli cell extracts contain a protein which binds specifically to DNA fragments carrying either end of the phage Mu genome. We have identified this protein as Fis, a factor involved in several site-specific recombinational switches. Furthermore, we show that induction of a Mucts62 prophage in a fis lysogen occurs at a lower temperature than that of a wild-type strain, and that spontaneous induction of Mucts62 is increased in the fis mutant. DNasel footprinting using either crude extracts or purified Fis indicate that binding on the left end of Mu occurs at a site which overlaps a weak transposase binding site. Thus, Fis may modulate Mu growth by influencing the binding of transposase, or other proteins, to the transposase binding site(s), in a way similar to its influence on Xis binding in phage lambda.

ISR1, a transposable DNA sequence resident in Rhizobium class IV strains, shows structural characteristics of classical insertion elements

ISR1 is a small transposable element, identified in Rhizobium class IV strains by its high frequent mutagenic insertion into plasmid RP4. Hybridization studies showed that ISR1 is present in, multiple copies in Rhizobium class IV strains. Nucleotide sequence analysis revealed that ISR1 has a length of 1260 bp and is characterized by perfect inverted repeats of 13 nucleotides followed by a stretch of 28/29 nucleotides with imperfect homology. The insertion under study generated a target site duplication of 4 bp. ISR1 carries a large open reading frame, encoding a putative polypeptide of 278 amino acids (ORFA*), and three smaller ones in antiparallel direction (ORFs A1, A2, A3). Two of them are completely covered by the large open reading frame. No significant homology to 17 other known insertion sequence elements could be detected, either at nucleotide or at amino acid levels.

Trimethoprim resistance transposon Tn4003 from Staphylococcus aureus encodes genes for a dihydrofolate reductase and thymidylate synthetase flanked by three copies of IS257

Trimethoprim resistance mediated by the Staphylococcus aureus multi-resistance plasmid pSK1 is encoded by a structure with characteristics of a composite transposon which we have designated Tn4003. Nucleotide sequence analysis of Tn4003 revealed it to be 4717 bp in length and to contain three copies of the insertion element IS257 (789-790 bp), the outside two of which are flanked by directly repeated 8-bp target sequences. IS257 has imperfect terminal inverted repeats of 27-28 bp and encodes for a putative transposase with two potential alpha-helix-turn-alpha-helix DNA recognition motifs. IS257 shares sequence similarities with members of the IS15 family of insertion sequences from Gram-negative bacteria and with ISS1 from Streptococcus lactis. The central region of the transposon contains the dfrA gene that specifies the S1 dihydrofolate reductase (DHFR) responsible for trimethoprim resistance. The S1 enzyme shows sequence homology with type I and V trimethoprim-resistant DHFRs from Gram-negative bacteria and with chromosomally encoded DHFRs from Gram-positive and Gram-negative bacteria. 5' to dfrA is a thymidylate synthetase gene, designated thyE.

Mutational analysis of the open reading frames in the transposable element IS1

IS1 is one of the smallest transposable elements found in bacteria (768 bp). It contains eight overlapping open-reading-frames (ORFs) greater than 50 codons, designated insA to insG and insB'. To determine which of the ORFs actually code for proteins involved in transposition, we have introduced amber codons into each ORF by site-directed mutagenesis which make neutral changes in the overlapping ORFs. Each mutant IS1 was then tested for its ability to mediate cointegrate formation in Su+ and Su- backgrounds. The mutant elements were also tested for trans-complementation in an IS1-free Salmonella background. Our results show that the products of the insA and insB genes are the only ones essential for cointegrate formation. We suggest that other ORFs may, however, encode accessory proteins.

Tn7 transposition: two transposition pathways directed by five Tn7-encoded genes

The bacterial transposon Tn7 is capable of high-frequency transposition to a specific site in the Escherichia coli chromosome, attTn7, and of low-frequency transposition to sites other than attTn7. Using an in vitro insertional mutagenesis procedure, we have identified and characterized five tns (Tn seven) genes that are essential for Tn7 transposition. Three of these genes, tnsA, tnsB, and tnsC, are required, but are not sufficient, for all Tn7 transposition events. In addition, tnsD is specifically required for transposition to attTn7, whereas tnsE is specifically required for transposition to other sites. Thus, Tn7 is an elaborate transposon that encodes two distinct but overlapping transposition pathways.

Artificial transposable elements in the study of the ends of IS1

We have constructed artificial IS1-based transposons by attaching synthetic oligodeoxynucleotides, corresponding to the sequence of the ends of IS1, to a selectable DNA segment ['omega' fragment; Prentki and Krisch, Gene 29 (1984) 303-313]. These transposons were used to examine the sequence requirements at the ends for IS1 transposition. We show here that a 24- to 28-bp sequence from the left or right ends of IS1 is capable of transposition when present at both ends of the omega fragment in the correct orientation. Transposition activity requires the presence of an intact IS1 in cis on the same plasmid molecule. In trans, however, neither resident genomic copies of IS1, nor copies carried by a compatible, high-copy-number plasmid present in the same cell, complement the artificial transposons efficiently. Transposition frequencies in the presence of a cis-complementing IS1 are, however, similar to those of the naturally occurring IS1-based transposon, Tn9. In addition, transposition results in a 9-bp duplication in the target DNA molecule as is usually the case for insertion of the intact IS1. Using this system, we have obtained evidence indicating that the activity of a synthetic IS1 end is not determined exclusively by its sequence, but can be strongly enhanced by a second, wild-type end used in the transposition event. The data also show that single base pair mutations can exhibit a cumulative effect in reducing transposition activity.