Bacterial Interspersed Mosaic Elements (Bimes) Are a Major Source of Sequence Polymorphism in Escherichia Coli Intergenic Regions Including Specific Associations with a New Insertion Sequence

A significant fraction of Escherichia coli intergenic DNA sequences is composed of two families of repeated bacterial interspersed mosaic elements (BIME-1 and BIME-2). In this study, we determined the sequence organization of six intergenic regions in 51 E. coli and Shigella natural isolates. Each region contains a BIME in E. coli K-12. We found that multiple sequence variations are located within or near these BIMEs in the different bacteria. Events included excisions of a whole BIME-1, expansion/deletion within a BIME-2 and insertions of non-BIME sequences like the boxC repeat or a new IS element, named IS1397. Remarkably, 14 out of 14 IS1397 integration sites correspond to a BIME sequence, strongly suggesting that this IS element is specifically associated with BIMEs, and thus inserts only in extragenic regions. Unlike BIMEs, IS1397 is not detected in all E. coli isolates. Possible relationships between the presence of this IS element and the evolution of BIMEs are discussed.     

Active site sharing and subterminal hairpin recognition in a new class of DNA transposases

Many bacteria harbor simple transposable elements termed insertion sequences (IS). In Helicobacter pylori, the chimeric IS605 family elements are particularly interesting due to their proximity to genes encoding gastric epithelial invasion factors. Protein sequences of IS605 transposases do not bear the hallmarks of other well-characterized transposases. We have solved the crystal structure of full-length transposase (TnpA) of a representative member, ISHp608. Structurally, TnpA does not resemble any characterized transposase; rather, it is related to rolling circle replication (RCR) proteins. Consistent with RCR, Mg2+ and a conserved tyrosine, Tyr127, are essential for DNA nicking and the formation of a covalent intermediate between TnpA and DNA. TnpA is dimeric, contains two shared active sites, and binds two DNA stem loops representing the conserved inverted repeats near each end of ISHp608. The cocrystal structure with stem-loop DNA illustrates how this family of transposases specifically recognizes and pairs ends, necessary steps during transposition.     

Y1转座酶关联转座子在大肠杆菌和沙门氏菌基因组中的分布和结构特征

Y1转座酶关联转座子(Y1ATs)的活性催化位点为一个酪氨酸,能够切割和连接单链DNA,在原核生物分布广泛。为探究Y1转座酶关联转座子在大肠杆菌(Escherichia coli, E. coli)与沙门氏菌(Salmonella enterica, S. ente)基因组中系统进化特性,通过Hmmsearch程序对Y1转座酶关联转座子进行了挖掘分析。结果表明,Y1转座酶关联转座子广泛分布于96.84%大肠杆菌基因组和80.4%沙门氏菌基因组。根据序列比对和蛋白结构域预测将Y1转座酶关联转座子分为10类,均隶属于IS200/IS605超家族,其中11 645个属于IS200家族,4 811个属于IS605家族。IS200家族广泛分布于S. ente基因组中(72.24%),而IS605家族广泛分布于E. coli基因组中(89.38%)。IS200拷贝数以及完整拷贝数显著高于IS605。IS200家族仅含有一个Y1转座酶编码区,而IS605家族含两个开放阅读框,分别编码Y1转座酶和TnpB蛋白。IS200家族的Y1氨基酸序列高度保守(95.3%),而IS605家族的Y1和TnpB具有较高遗传多样性,为研究转座子在原核生物的遗传进化模式提供重要参考。IS200家族具有高度保守的Y1转座酶,且完整拷贝数比例较高,提示该类转座子可能具有转座活性,对其活性的挖掘有利于研制转座子介导的新型高效基因编辑工具。     

The processing of repetitive extragenic palindromes: the structure of a repetitive extragenic palindrome bound to its associated nuclease

Extragenic sequences in genomes, such as microRNA and CRISPR, are vital players in the cell. Repetitive extragenic palindromic sequences (REPs) are a class of extragenic sequences, which form nucleotide stem-loop structures. REPs are found in many bacterial species at a high copy number and are important in regulation of certain bacterial functions, such as Integration Host Factor recruitment and mRNA turnover. Although a new clade of putative transposases (RAYTs or TnpA_REP) is often associated with an increase in these repeats, it is not clear how these proteins might have directed amplification of REPs. We report here the structure to 2.6 Å of TnpA_REP from Escherichia coli MG1655 bound to a REP. Sequence analysis showed that TnpA_REP is highly related to the IS200/IS605 family, but in contrast to IS200/IS605 transposases, TnpA_REP is a monomer, is auto-inhibited and is active only in manganese. These features suggest that, relative to IS200/IS605 transposases, it has evolved a different mechanism for the movement of discrete segments of DNA and has been severely down-regulated, perhaps to prevent REPs from sweeping through genomes.     

In vivo cleavage of Escherichia coli BIME-2 repeats by DNA gyrase: genetic characterization of the target and identification of the cut site

The Escherichia coli chromosome contains about 300 bacterial interspersed mosaic elements (BIMEs). These elements, located at the 3' end of genes, are composed of three types of alternating repetitive extragenic palindromes (REPs). Based on the type of REP they contain and on their ability to interact with the integration host factor (IHF), BIMEs are subdivided into two families: BIME-1 elements contain an IHF binding site flanked by converging Y and Z1 REPs, whereas BIME-2 elements contain a variable number of alternating Y and Z2 REPs without an IHF site. Although some BIMEs have been implicated in the protection of mRNA against 3' exonucleolytic degradation, the main role of elements belonging to both families remains to be elucidated. In this paper, we used oxolinic acid, a drug that reveals potential sites of DNA gyrase action, to demonstrate that DNA gyrase interacts in vivo with BIME-2 elements. The frequency of cleavage varied from one element to another, and the cleavage pattern observed in elements containing several REPs indicated that DNA gyrase cut DNA every two REPs. A single cleavage site has been identified in the Y REP in six out of seven instances, and the nucleotide sequence of a 44 bp fragment containing the scission point displayed conserved residues at six positions. The lack of one of the conserved residues accounted for the absence of cleavage in most of the Z2 REPs. Our results also showed that cleaved REPs were always associated with another REP, suggesting that a pair of diverging REPs constitutes the target of DNA gyrase. DNA gyrase cleavage at repetitive BIME-2 elements may have consequences for DNA topology and genomic rearrangements.     

Functional organization and insertion specificity of IS607, a chimeric element of Helicobacter pylori

A search by subtractive hybridization for sequences present in only certain strains of Helicobacter pylori led to the discovery of a 2-kb transposable element to be called IS607, which further PCR and hybridization tests indicated was present in about one-fifth of H. pylori strains worldwide. IS607 contained two open reading frames (ORFs) of possibly different phylogenetic origin. One ORF (orfB) exhibited protein-level homology to one of two putative transposase genes found in several other chimeric elements including IS605 (also of H. pylori) and IS1535 (of Mycobacterium tuberculosis). The second IS607 gene (orfA) was unrelated to the second gene of IS605 and might possibly be chimeric itself: it exhibited protein-level homology to merR bacterial regulatory genes in the first approximately 50 codons and homology to the second gene of IS1535 (annotated as "resolvase," apparently due to a weak short recombinase motif) in the remaining three-fourths of its length. IS607 was found to transpose in Escherichia coli, and analyses of sequences of IS607-target DNA junctions in H. pylori and E. coli indicated that it inserted either next to or between adjacent GG nucleotides, and generated either a 2-bp or a 0-bp target sequence duplication, respectively. Mutational tests showed that its transposition in E. coli required orfA but not orfB, suggesting that OrfA protein may represent a new, previously unrecognized, family of bacterial transposases.     

A novel IS element,IS621, of the IS110/IS492 family transposes to a specific site in repetitive extragenic palindromic sequences in Escherichia coli

An Escherichia coli strain, ECOR28, was found to have insertions of an identical sequence (1,279 bp in length) at 10 loci in its genome. This insertion sequence (named IS621) has one large open reading frame encoding a putative protein that is 326 amino acids in length. A computer-aided homology search using the DNA sequence as the query revealed that IS621 was homologous to the piv genes, encoding pilin gene invertase (PIV). A homology search using the amino acid sequence of the putative protein encoded by IS621 as the query revealed that the protein also has partial homology to transposases encoded by the IS110/IS492 family elements, which were known to have partial homology to PIV. This indicates that IS621 belongs to the IS110/IS492 family but is most closely related to the piv genes. In fact, a phylogenetic tree constructed on the basis of amino acid sequences of PIV proteins and transposases revealed that IS621 belongs to the piv gene group, which is distinct from the IS110/IS492 family elements, which form several groups. PIV proteins and transposases encoded by the IS110/IS492 family elements, including IS621, have four acidic amino acid residues, which are conserved at positions in their N-terminal regions. These residues may constitute a tetrad D-E(or D)-D-D motif as the catalytic center. Interestingly, IS621 was inserted at specific sites within repetitive extragenic palindromic (REP) sequences at 10 loci in the ECOR28 genome. IS621 may not recognize the entire REP sequence in transposition, but it recognizes a 15-bp sequence conserved in the REP sequences around the target site. There are several elements belonging to the IS110/IS492 family that also transpose to specific sites in the repeated sequences, as does IS621. IS621 does not have terminal inverted repeats like most of the IS110/IS492 family elements. The terminal sequences of IS621 have homology with the 26-bp inverted repeat sequences of pilin gene inversion sites that are recognized and used for inversion of pilin genes by PIV. This suggests that IS621 initiates transposition through recognition of their terminal regions and cleavage at the ends by a mechanism similar to that used for PIV to promote inversion at the pilin gene inversion sites.     

TnpAREP and REP sequences dissemination in bacterial genomes: REP recognition determinants

REP, diverse palindromic DNA sequences found at high copy number in many bacterial genomes, have been attributed important roles in cell physiology but their dissemination mechanisms are poorly understood. They might represent non-autonomous transposable elements mobilizable by TnpA_REP, the first prokaryotic domesticated transposase associated with REP. TnpA_REP, fundamentally different from classical transposases, are members of the HuH superfamily and closely related to the transposases of the IS200/IS605 family. We previously showed that Escherichia coli TnpA_REP processes cognate single stranded REP in vitro and that this activity requires the integrity of the REP structure, in particular imperfect palindromes interrupted by a bulge and preceded by a conserved DNA motif. A second group of REPs rather carry perfect palindromes, raising questions about how the latter are recognized by their cognate TnpA_REP. To get insight into the importance of REP structural and sequence determinants in these two groups, we developed an in vitro activity assay coupled to a mutational analysis for three different TnpA_REP/REP duos via a SELEX approach. We also tackled the question of how the cleavage site is selected. This study revealed that two TnpA_REP groups have co-evolved with their cognate REPs and use different strategies to recognize their REP substrates.     

Conserved amino acid motifs from the novel Piv/MooV family of transposases and site-specific recombinases are required for catalysis of DNA inversion by Piv

Piv, a site-specific invertase from Moraxella lacunata, exhibits amino acid homology with the transposases of the IS110/IS492 family of insertion elements. The functions of conserved amino acid motifs that define this novel family of both transposases and site-specific recombinases (Piv/MooV family) were examined by mutagenesis of fully conserved amino acids within each motif in Piv. All Piv mutants altered in conserved residues were defective for in vivo inversion of the M. lacunata invertible DNA segment, but competent for in vivo binding to Piv DNA recognition sequences. Although the primary amino acid sequences of the Piv/MooV recombinases do not contain a conserved DDE motif, which defines the retroviral integrase/transposase (IN/Tnps) family, the predicted secondary structural elements of Piv align well with those of the IN/Tnps for which crystal structures have been determined. Molecular modelling of Piv based on these alignments predicts that E59, conserved as either E or D in the Piv/MooV family, forms a catalytic pocket with the conserved D9 and D101 residues. Analysis of Piv E59G confirms a role for E59 in catalysis of inversion. These results suggest that Piv and the related IS110/IS492 transposases mediate DNA recombination by a common mechanism involving a catalytic DED or DDD motif.     

Characterization of the Pseudomonas putida mobile genetic element ISPpu10: an occupant of repetitive extragenic palindromic sequences

We have characterized the Pseudomonas putida KT2440 insertion element ISPpu10. This insertion sequence encodes a transposase which exhibits homology to the transposases and specific recombinases of the Piv/Moov family, and no inverted repeats are present at the borders of its left and right ends, thus constituting a new member of the atypical IS110/IS492 family. ISPpu10 was found in at least seven identical loci in the KT2440 genome, and variants were identified having an extra insertion at distinct loci. ISPpu10 always appeared within the core of specific repetitive extragenic palindromic (REP) sequences TCGCGGGTAAACCCGCTCCTAC, exhibiting high target stringency. One intragenic target was found associated with the truncation of a GGDEF/EAL domain protein. After active in vitro transposition to a plasmid-borne target, a duplication of the CT (underlined above) at the junction as a consequence of the ISPpu10 insertion was experimentally demonstrated for the first time in the IS110/IS492 family. The same duplication was observed after transposition of ISPpu10 from a plasmid to the chromosome of P. putida DOT-T1E, an ISPpu10-free strain with REPs similar to those of strain KT2440. Plasmid ISPpu10-mediated rearrangements were observed in vivo under laboratory conditions and in the plant rhizosphere.     

Les BIMEs: un exemple de séquences répétées chez les entérobactéries

Bacterial interspersed mosaic elements (or BIMEs) are repeated sequences identified in several enterobacterial genomes. BIMEs are a mosaic combination of small sequence motifs. It has been estimated that 500 BIMEs are scattered over the bacterial genome. BIMEs have been identified in several enterobacteria: Escherichia coli, Salmonella typhimurium, Klebsiella sp. and relatives of these bacteria. BIME function is not known, but their interactions with specific proteins (DNA polymerase I, gyrase and integration host factor) suggest that they could be involved in functional organization of bacterial chromosomes. Four other families of interspersed repetitive sequences have been shown to exist in a variety of bacterial genomes. Like BIMEs, these sequences are rather small, contain a region of dyad symmetry, and are found in extragenic locations. Unlike BIMEs, IRU (or ERIC), box C sequences and RSA sequences occur in enterobacteria but also in other Gram-negative bacteria.     

Reconstitution of a functional IS608 single-strand transpososome: role of non-canonical base pairing

Single-stranded (ss) transposition, a recently identified mechanism adopted by members of the widespread IS200/IS605 family of insertion sequences (IS), is catalysed by the transposase, TnpA. The transposase of IS608, recognizes subterminal imperfect palindromes (IP) at both IS ends and cleaves at sites located at some distance. The cleavage sites, C, are not recognized directly by the protein but by short sequences 5' to the foot of each IP, guide (G) sequences, using a network of canonical ('Watson-Crick') base interactions. In addition a set of non-canonical base interactions similar to those found in RNA structures are also involved. We have reconstituted a biologically relevant complex, the transpososome, including both left and right ends and TnpA, which catalyses excision of a ss DNA circle intermediate. We provide a detailed picture of the way in which the IS608 transpososome is assembled and demonstrate that both C and G sequences are essential for forming a robust transpososome detectable by EMSA. We also address several questions central to the organization and function of the ss transpososome and demonstrate the essential role of non-canonical base interactions in the IS608 ends for its stability by using point mutations which destroy individual non-canonical base interactions.     

Single-stranded DNA intermediates in IS91 rolling-circle transposition

IS91 displays a number of characteristics unique among insertion sequence (IS) elements, suggesting that it transposes by a novel mechanism called rolling-circle (RC) transposition. We reported previously that IS91 transposase (TnpA) amino acid sequence shares a series of five conserved signatures with A proteins of RC replicating phages, including a pair of invariant tyrosines that catalyse two successive transesterification reactions during replication initiation and termination. To analyse their role in IS91 transposition, we constructed a series of TnpA derivatives in which the invariant Tyr-249 and/or Tyr-253 were mutated to either phenylalanine or serine. Mutation of either tyrosine resulted in complete loss of transposition activity in vivo. This result was taken as a first new line of evidence that TnpA is a functional analogue of phiX174 phage A protein. Secondly, RC replication plasmids and phages accumulate single-stranded DNA (ssDNA) intermediates as a result of uncoupled leading and lagging DNA strand synthesis. Using a plasmid carrying an IS91-derived IRLkan-IRR transposable cassette, in which the left (IRL)- and right (IRR)-terminal sequences of IS91 flank a kanamycin resistance gene (kan), we demonstrated the in vivo formation of two new DNA species after induction of transposase expression. The first was a circular ssDNA that contained the transposable cassette covalently joined at its exact termini, whereas the second was a double-stranded circle of the same element. When this experiment was repeated using the mutant transposases described above, the ssDNA and dsDNA intermediates could not be observed, indicating that the integrity of both Y249 and Y253 was essential for their appearance. The presence of ssDNA intermediate products is the first biochemical evidence for a RC mechanism of IS91 transposition.     

Bacterial interspersed mosaic elements (BIMEs) are present in the genome of Klebsiella

Bacterial interspersed mosaic elements (BIMEs) constitute a family of highly repetitive sequences containing palindromic units (PUs), also called repetitive extragenic palindromes (REPs). BIMEs were originally described in Escherichia coli and Salmonella typhimurium. We show here, by determining the nucleotide sequence of two intergenic regions of Klebsiella pneumoniae, by computer searches, and by hybridization, that sequences with similar characteristics are found in the genome of several Klebsiella species. This reinforces the idea that BIMEs play general and important roles in enterobacteria such as in the organization of the bacterial chromosome.     

Mechanism of IS200/IS605 family DNA transposases: activation and transposon-directed target site selection

The smallest known DNA transposases are those from the IS200/IS605 family. Here we show how the interplay of protein and DNA activates TnpA, the Helicobacter pylori IS608 transposase, for catalysis. First, transposon end binding causes a conformational change that aligns catalytically important protein residues within the active site. Subsequent precise cleavage at the left and right ends, the steps that liberate the transposon from its donor site, does not involve a site-specific DNA-binding domain. Rather, cleavage site recognition occurs by complementary base pairing with a TnpA-bound subterminal transposon DNA segment. Thus, the enzyme active site is constructed from elements of both protein and DNA, reminiscent of the interdependence of protein and RNA in the ribosome. Our structural results explain why the transposon ends are asymmetric and how the transposon selects a target site for integration, and they allow us to propose a molecular model for the entire transposition reaction.     

Within-genome evolution of REPINs: a new family of miniature mobile DNA in bacteria

Repetitive sequences are a conserved feature of many bacterial genomes. While first reported almost thirty years ago, and frequently exploited for genotyping purposes, little is known about their origin, maintenance, or processes affecting the dynamics of within-genome evolution. Here, beginning with analysis of the diversity and abundance of short oligonucleotide sequences in the genome of Pseudomonas fluorescens SBW25, we show that over-represented short sequences define three distinct groups (GI, GII, and GIII) of repetitive extragenic palindromic (REP) sequences. Patterns of REP distribution suggest that closely linked REP sequences form a functional replicative unit: REP doublets are over-represented, randomly distributed in extragenic space, and more highly conserved than singlets. In addition, doublets are organized as inverted repeats, which together with intervening spacer sequences are predicted to form hairpin structures in ssDNA or mRNA. We refer to these newly defined entities as REPINs (REP doublets forming hairpins) and identify short reads from population sequencing that reveal putative transposition intermediates. The proximal relationship between GI, GII, and GIII REPINs and specific REP-associated tyrosine transposases (RAYTs), combined with features of the putative transposition intermediate, suggests a mechanism for within-genome dissemination. Analysis of the distribution of REPs in a range of RAYT-containing bacterial genomes, including Escherichia coli K-12 and Nostoc punctiforme, show that REPINs are a widely distributed, but hitherto unrecognized, family of miniature non-autonomous mobile DNA.     

IS200/IS605 family single-strand transposition: mechanism of IS608 strand transfer

Transposase, TnpA, of the IS200/IS605 family member IS608, catalyses single-strand DNA transposition and is dimeric with hybrid catalytic sites composed of an HUH motif from one monomer and a catalytic Y127 present in an α-helix (αD) from the other (trans configuration). αD is attached to the main body by a flexible loop. Although the reactions leading to excision of a transposition intermediate are well characterized, little is known about the dynamic behaviour of the transpososome that drives this process. We provide evidence strongly supporting a strand transfer model involving rotation of both αD helices from the trans to the cis configuration (HUH and Y residues from the same monomer). Studies with TnpA heterodimers suggest that TnpA cleaves DNA in the trans configuration, and that the catalytic tyrosines linked to the 5′-phosphates exchange positions to allow rejoining of the cleaved strands (strand transfer) in the cis configuration. They further imply that, after excision of the transposon junction, TnpA should be reset to a trans configuration before the cleavage required for integration. Analysis also suggests that this mechanism is conserved among members of the IS200/IS605 family.     

IS1397 is active for transposition into the chromosome of Escherichia coli K-12 and inserts specifically into palindromic units of bacterial interspersed mosaic elements

We demonstrate that IS1397, a putative mobile genetic element discovered in natural isolates of Escherichia coli, is active for transposition into the chromosome of E. coli K-12 and inserts specifically into palindromic units, also called repetitive extragenic palindromes, the basic element of bacterial interspersed mosaic elements (BIMEs), which are found in intergenic regions of enterobacteria closely related to E. coli and Salmonella. We could not detect transposition onto a plasmid carrying BIMEs. This unprecedented specificity of insertion into a well-characterized chromosomal intergenic repeated element and its evolutionary implications are discussed.     

Structural and functional diversity among bacterial interspersed mosaic elements (BIMEs)

Palindromic units (PU or REP) were defined as 40-nucleotide DNA sequences which are highly repeated in the genome of several members of the Enterobacteriaceae. They were shown to be a constituent of the bacterial interspersed mosaic element (BIME), in which they are associated with other repetitive sequences. We report here that Escherichia coli PU sequences contain three motifs (Y, Z¹ and Z²), leading to the definition of two BIME families. The BIME-1 family, highly conserved over 145 nucleotides, contains two PUs (motifs Y and Z¹). The BIME-2 family contains a variable number of PUs (motifs Y and Z²). We present evidence, using band shift experiments, that each PU motif binds DNA gyrase with a different affinity. This suggests that the two families are functionally distinct.     

Physical mapping of repetitive extragenic palindromic sequences in Escherichia coli and phylogenetic distribution among Escherichia coli strains and other enteric bacteria.

Repetitive extragenic palindromic (REP) sequences are highly conserved inverted repeat sequences originally discovered in Escherichia coli and Salmonella typhimurium. We have physically mapped these sequences in the E. coli genome by using Southern hybridization of an ordered phage bank of E. coli (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987) with generic REP probes derived from the REP consensus sequence. The set of REP probe-hybridizing clones was correlated with a set of clones expected to contain REP sequences on the basis of computer searches. We also show that a generic REP probe can be used in Southern hybridization to analyze genomic DNA digested with restriction enzymes to determine genetic relatedness among natural isolates of E. coli. A search for these sequences in other members of the family Enterobacteriaceae shows a consistent correlation between both the number of occurrences and the hybridization strength and genealogical relationship.