Mick Chandler

Bacterial insertion sequences: their genomic impact and diversity

Abstract 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.

ISsaga is an ensemble of web-based methods for high throughput identification and semi-automatic annotation of insertion sequences in prokaryotic genomes

Insertion sequences (ISs) play a key role in prokaryotic genome evolution but are seldom well annotated. We describe a web application pipeline, ISsaga (http://issaga.biotoul.fr/ISsaga/issaga_index.php), that provides computational tools and methods for high-quality IS annotation. It uses established ISfinder annotation standards and permits rapid processing of single or multiple prokaryote genomes. ISsaga provides general prediction and annotation tools, information on genome context of individual ISs and a graphical overview of IS distribution around the genome of interest.

Phylogenetic evidence for extensive lateral acquisition of cellular genes by Nucleocytoplasmic large DNA viruses

BackgroundNucleo-Cytoplasmic Large DNA viruses (NCLDV), a diverse group that infects a wide range of eukaryotic hosts, exhibit a large heterogeneity in genome size (between 100 kb and 1.2 Mb) but have been suggested to form a monophyletic group on the basis of a small subset of approximately 30 conserved genes. NCLDV were proposed to have evolved by simplification from cellular organism although some of the giant NCLDV have clearly grown by gene accretion from a bacterial origin.ResultsWe demonstrate here that many NCLDV lineages appear to have undergone frequent gene exchange in two different ways. Viruses which infect protists directly (Mimivirus) or algae which exist as intracellular protists symbionts (Phycodnaviruses) acquire genes from a bacterial source. Metazoan viruses such as the Poxviruses show a predominant acquisition of host genes. In both cases, the laterally acquired genes show a strong tendency to be positioned at the tip of the genome. Surprisingly, several core genes believed to be ancestral in the family appear to have undergone lateral gene transfers, suggesting that the NCLDV ancestor might have had a smaller genome than previously believed. Moreover, our data show that the larger the genome, the higher is the number of laterally acquired genes. This pattern is incompatible with a genome reduction from a cellular ancestor.ConclusionWe propose that the NCLDV viruses have evolved by significant growth of a simple DNA virus by gene acquisition from cellular sources.

The regulatory role of the IS 1‐encoded InsA protein in transposition

We show here that the protein InsA, which is encoded by IS 1 and binds specifically to the terminal inverted repeats of this insertion sequence, negatively regulates IS 1 transposition activity. We demonstrate that it inhibits both IS 1‐mediated cointegrate formation and transposition of a synthetic IS 1‐based transposon (‘omegon’Ω‐on). These results also indicate that the Ω‐on which does not itself encode IS 1 transposition functions can be complemented in trans, presumably by the copies of IS 1 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 IS 1‐encoded genes both in cis or in trans. The experiments involving Ω‐on transposition raise the possibility that InsA inhibits transposition directly by competition with the transposase for their cognate site within the ends of IS 1.

Functional organization of the ends of IS 1: specific binding site for an IS1‐encoded protein

The IS 1‐encoded protein InsA binds specifically to both ends of IS 1, and acts as a repressor of IS1 gene expression and may be a direct inhibitor of the transposition process. We show here, using DNasel ‘foot‐printing’ and gel retardation, that the InsA binding sites are located within the 24/25bp minimal active ends of IS1 and that InsA induces DNA bending upon binding. Conformational modification of the ends of IS 1 as a result of binding of the host protein integration host factor (IHF) to its site within the minimal ends has been previously observed. Using a collection of synthetic mutant ends we have mapped some of the nucleotide sequence requirements for InsA binding and for transposition activity. We show that sequences necessary for InsA binding are also essential for transposition activity. We demonstrate that InsA and IHF binding sites overlap since some sequence determinants are shared by both InsA and IHF. The data suggest that these ends contain two functional domains: one for binding of InsA and IHF, and the other for transposition activity. A third region, when present, may enhance transposition activity with an intact right end. This ‘architecture’ of the ends of IS 1 is remarkably similar to that of IS elements IS10, IS50 and IS903.

Structuring the bacterial genome: Y1-transposases associated with REP-BIME sequences

REPs are highly repeated intergenic palindromic sequences often clustered into structures called BIMEs including two individual REPs separated by short linker of variable length. They play a variety of key roles in the cell. REPs also resemble the sub-terminal hairpins of the atypical IS200/605 family of insertion sequences which encode Y1 transposases (TnpAIS200/IS605). These belong to the HUH endonuclease family, carry a single catalytic tyrosine (Y) and promote single strand transposition. Recently, a new clade of Y1 transposases (TnpAREP) was found associated with REP/BIME in structures called REPtrons. It has been suggested that TnpAREP is responsible for REP/BIME proliferation over genomes. We analysed and compared REP distribution and REPtron structure in numerous available E. coli and Shigella strains. Phylogenetic analysis clearly indicated that tnpAREP was acquired early in the species radiation and was lost later in some strains. To understand REP/BIME behaviour within the host genome, we also studied E. coli K12 TnpAREP activity in vitro and demonstrated that it catalyses cleavage and recombination of BIMEs. While TnpAREP shared the same general organization and similar catalytic characteristics with TnpAIS200/IS605 transposases, it exhibited distinct properties potentially important in the creation of BIME variability and in their amplification. TnpAREP may therefore be one of the first examples of transposase domestication in prokaryotes.

Truncated forms of IS911 transposase downregulate transposition

IS911 naturally produces transposase (OrfAB) derivatives truncated at the C‐terminal end (OrfAB‐CTF) and devoid of the catalytic domain. A majority species, OrfAB*, was produced at higher levels at 42°C than at 30°C suggesting that it is at least partly responsible for the innate reduction in IS911 transposition activity at higher temperatures. An engineered equivalent of similar length, OrfAB[1–149], inhibited transposition activity in vivo or in vitro when produced along with full‐length transposase. We isolated several point mutants showing higher activity than the wild‐type IS911 at 42°C. These fall into two regions of the transposase. One, located in the N‐terminal segment of OrfAB, lies between or within two regions involved in protein multimerization. The other is located within the C‐terminal catalytic domain. The N‐terminal mutations resulted in reduced levels of OrfAB* while the C‐terminal mutation alone appeared not to affect OrfAB* levels. Combination of N‐ and C‐terminal mutations greatly reduced OrfAB* levels and transposition was concomitantly high even at 42°C. The mechanism by which truncated transposase species are generated and how they intervene to reduce transposition activity is discussed. While transposition activity of these multiply mutated derivatives in vivo was resistant to temperature, the purified OrfAB derivatives retained an inherent temperature‐sensitive phenotype in vitro. This clearly demonstrates that temperature sensitivity of IS911 transposition is a complex phenomenon with several mechanistic components. These results have important implications for the several other transposons and insertion sequences whose transposition has also been shown to be temperature‐sensitive.

A model for the molecular organisation of the IS911 transpososome

Tight regulation of transposition activity is essential to limit damage transposons may cause by generating potentially lethal DNA rearrangements. Assembly of a bona fide protein-DNA complex, the transpososome, within which transposition is catalysed, is a crucial checkpoint in this regulation. In the case of IS911, a member of the large IS3 bacterial insertion sequence family, the transpososome (synaptic complex A; SCA) is composed of the right and left inverted repeated DNA sequences (IRR and IRL) bridged by the transposase, OrfAB (the IS911-encoded enzyme that catalyses transposition). To characterise further this important protein-DNA complex in vitro, we used different tagged and/or truncated transposase forms and analysed their interaction with IS911 ends using gel electrophoresis. Our results allow us to propose a model in which SCA is assembled with a dimeric form of the transposase. Furthermore, we present atomic force microscopy results showing that the terminal inverted repeat sequences are probably assembled in a parallel configuration within the SCA. These results represent the first step in the structural description of the IS911 transpososome, and are discussed in comparison with the very few other transpososome examples described in the literature.

Control of IS911 target selection: how OrfA may ensure IS dispersion

IS911 transposition involves a closed circular insertion sequence intermediate (IS‐circle) and two IS‐encoded proteins: the transposase OrfAB and OrfA which regulates IS911 insertion. OrfAB alone promotes insertion preferentially next to DNA sequences resembling IS911 ends while the addition of OrfA strongly stimulates insertion principally into DNA targets devoid of the IS911 end sequences. OrfAB shares its N‐terminal region with OrfA. This includes a helix–turn–helix (HTH) motif and the first three of four heptads of a leucine zipper (LZ). OrfAB binds specifically to IS911 ends via its HTH whereas OrfA does not. We show here: that OrfA binds DNA non‐specifically and that this requires the HTH; that OrfA LZ is required for its multimerization; and that both motifs are essential for OrfA activity. We propose that these OrfA properties are required to assemble a nucleoprotein complex committed to random IS911 insertion. This control of IS911 insertion activity by OrfA in this way would assure its dispersion.

Clamping Down on Transposon Targeting

The sliding beta clamp subunit of the DNA replication machinery in the bacterium Escherichia coli coordinates multiple functions in the cell beyond genome duplication. In this issue, Parks et al. (2009) find that the beta clamp interacts with the transposition protein TnsE to target the Tn7 transposon to discontinuously replicating DNA at the replication fork.