Piv Site-Specific Invertase Requires a DEDD Motif Analogous to the Catalytic Center of the RuvC Holliday Junction Resolvases

Buchner, John M.; Robertson, A.E.; Poynter, David J.; Denniston, Shelby S.; Karls, Anna C.

doi:10.1128/jb.187.10.3431-3437.2005

Cited by 20 publications

(23 citation statements)

References 35 publications

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“…A similar type of Tpase, known as a DEDD Tpase, is related to the Holliday junction resolvase, RuvC (39,40). These possess a similar predicted structural topology in their catalytic site and presumably have similar chemistry to the DDE enzymes.…”

Section: Dedd Transposasesmentioning

confidence: 99%

“…At present, only a single IS family, IS110, is known to encode this type of DEDD enzyme, related to the RuvC Holliday junction resolvase (40). There are over 250 examples from nearly 130 bacterial and archaeal species.…”

Section: Is With Dedd Transposases Is110 (I) Generalmentioning

confidence: 99%

“…However, the organization of IS110 family members and the inversion systems are different. In the inversion systems, the recombinase is located outside the invertible segment, whereas it is located within the IS element (40).…”

Section: Is With Dedd Transposases Is110 (I) Generalmentioning

confidence: 99%

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Everyman's Guide to Bacterial Insertion Sequences

et al. 2015

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The number and diversity of known prokaryotic insertion sequences (IS) have increased enormously since their discovery in the late 1960s. At present the sequences of more than 4000 different IS have been deposited in the specialized ISfinder database. Over time it has become increasingly apparent that they are important actors in the evolution of their host genomes and are involved in sequestering, transmitting, mutating and activating genes, and in the rearrangement of both plasmids and chromosomes. This review presents an overview of our current understanding of these transposable elements (TE), their organization and their transposition mechanism as well as their distribution and genomic impact. In spite of their diversity, they share only a very limited number of transposition mechanisms which we outline here. Prokaryotic IS are but one example of a variety of diverse TE which are being revealed due to the advent of extensive genome sequencing projects. A major conclusion from sequence comparisons of various TE is that frontiers between the different types are becoming less clear. We detail these receding frontiers between different IS-related TE. Several, more specialized chapters in this volume include additional detailed information concerning a number of these.In a second section of the review, we provide a detailed description of the expanding variety of IS, which we have divided into families for convenience. Our perception of these families continues to evolve and families emerge regularly as more IS are identified. This section is designed as an aid and a source of information for consultation by interested specialist readers.

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Section: Dedd Transposasesmentioning

confidence: 99%

Section: Is With Dedd Transposases Is110 (I) Generalmentioning

confidence: 99%

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Everyman's Guide to Bacterial Insertion Sequences

et al. 2015

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“…After aligning transposases encoded by IS110/IS492 members and proteins encoded by piv genes, Choi and coworkers (8) identified the motif DEDD, relating it to the one found in the catalytic center of the RuvC Holliday junction resolvase. In fact, a model for Piv-mediated inversion that includes resolution of a Holliday junction has been proposed (6).…”

Section: Resultsmentioning

confidence: 99%

Characterization of thePseudomonas putidaMobile Genetic Element ISPpu10: an Occupant of Repetitive Extragenic Palindromic Sequences

et al. 2006

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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 GGD EF/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.Chromosomal rearrangements are a source of genetic variability on which selection can act and, although preponderantly deleterious, may produce beneficial mutations that are necessary for adaptive evolution, thus increasing bacterial fitness (19). Transposable elements (TEs) can mediate various genomic rearrangements more efficiently and often more specifically than other processes through two mechanisms that require repetitive sequences: homologous recombination and alternative transposition (see reference 20 for a review). TEs are classified by their sequence structure and transposition mechanisms. Class II TE transpose by a DNA intermediate catalyzed by a transposase. This group comprises insertion sequences (IS). IS elements contain a transposase and left and right ends, generally bounded by terminal inverted repeats, in addition to sequences that differentiate the two ends and are necessary for transposition. Although IS elements may sometimes function as genomic parasites, microbial evolution experiments demonstrate that IS elements can also promote adaptation by generating beneficial mutations (33).In a genetic screen for functions involved in the colonization of corn seeds by Pseudomonas putida KT2440, Mus-9, a putative transposase/site-specific recombinase was identified (15). In this work, we demonstrate the transposase activity of this protein and present the characterization of the mobile genetic element of which it is part, ISPpu10, a new member of the atypical family of insertion elements IS110/IS492. Nelson and coworkers (28) observed that ISPpu10 was inserted in the repetitive extragenic palindromic (REP) sequence of P. putida KT2440. REPs were first detected in Escherichia coli and in other Enterobacteria...

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“…Transposable elements drive the evolution of genomes through DNA rearrangements resulting from the process of transposition or by homologous recombination between repeated copies of the element in the genome (for a review, see reference 34). Sitespecific recombination systems, which require very short, shared sequences between the recombining DNA segments, often regulate gene expression or generate antigenic diversity (for a review, see reference 16).Specialized DNA recombinases of the DEDD motif family (also called the Piv/MooV family) mediate reactions that have features of both transposition and site-specific recombination (8,18,23,28,29,37). The transposases of the IS110/IS492 family of insertion sequences and the Piv (pilin inversion) sitespecific DNA invertases of Moraxella lacunata and Moraxella bovis are members of the DEDD family of recombinases, (8,23,29,37).…”

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confidence: 99%

Site-Specific Insertion of IS 492 in Pseudoalteromonas atlantica

et al. 2009

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Reversible insertion of IS492 at a site within epsG on the Pseudoalteromonas atlantica chromosome controls peripheral extracellular polysaccharide production and biofilm formation by P. atlantica. High-frequency precise excision of IS492 from epsG requires 5 and 7 bp of flanking DNA, suggesting that IS492 transposition involves a site-specific recombination mechanism. The site specificity of IS492 insertion was examined in P. atlantica and shown to be specific for a 7-bp target, 5-CTTGTTA-3. Characterization of numerous insertion events at the target site in epsG indicated that insertion is also orientation specific. The frequency of IS492 insertion at the epsG target site (2.7 ؋ 10 ؊7 /cell/generation), determined by quantitative PCR, is 4 to 5 orders of magnitude lower than the frequency of IS492 precise excision from the same site. Comparison of insertion sites for IS492 and the highly related ISPtu2 from Pseudoalteromonas tunicata suggests DNA sequence and/or structural features that may contribute to site recognition and recombination by the transposase of IS492.A variety of specialized DNA recombination systems create genetic diversity and regulate gene expression in prokaryotes and eukaryotes. These specialized recombination systems fall into two categories, transposition and site-specific recombination. Transposition involves movement or copying of a mobile genetic element from a donor DNA site to a target DNA site with no requirement for DNA homology. Transposable elements drive the evolution of genomes through DNA rearrangements resulting from the process of transposition or by homologous recombination between repeated copies of the element in the genome (for a review, see reference 34). Sitespecific recombination systems, which require very short, shared sequences between the recombining DNA segments, often regulate gene expression or generate antigenic diversity (for a review, see reference 16).Specialized DNA recombinases of the DEDD motif family (also called the Piv/MooV family) mediate reactions that have features of both transposition and site-specific recombination (8,18,23,28,29,37). The transposases of the IS110/IS492 family of insertion sequences and the Piv (pilin inversion) sitespecific DNA invertases of Moraxella lacunata and Moraxella bovis are members of the DEDD family of recombinases, (8,23,29,37). The recombinases of this family do not share the conserved amino acid motifs of the characterized site-specific tyrosine (Y) or serine (S) recombinase families or the classical (DDE), rolling circle, or Y or S transposase (Tnp) families (11). However, like the DDE Tnps, molecular modeling indicates that the conserved acidic residues are assembled into the catalytic pocket of an RNase H-like fold. The DEDD motif residues are located at the same linear spacing and predicted tertiary location as the DEDD catalytic amino acids of the RuvC-like Holliday junction resolvases (8, 37), which are part of the polynucleotidyl transferase superfamily (33), and all four acidic residues have been shown to ...

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Piv Site-Specific Invertase Requires a DEDD Motif Analogous to the Catalytic Center of the RuvC Holliday Junction Resolvases

Cited by 20 publications

References 35 publications

Everyman's Guide to Bacterial Insertion Sequences

Everyman's Guide to Bacterial Insertion Sequences

Characterization of thePseudomonas putidaMobile Genetic Element ISPpu10: an Occupant of Repetitive Extragenic Palindromic Sequences

Site-Specific Insertion of IS 492 in Pseudoalteromonas atlantica

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