The domain structure and retrotransposition mechanism of R2 elements are conserved throughout arthropods

Burke, William D.; Malik, Harmit S.; Jones, Jeffrey P.; Eickbush, Thomas H.

doi:10.1093/oxfordjournals.molbev.a026132

Cited by 98 publications

(150 citation statements)

References 32 publications

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“…Analogous to our results, multiple successive jumps of R2 RT can occur (Bibillo and Eickbush 2002b). RT template jumping was proposed to facilitate attachment of the 5Ј end of R2 to the host DNA during integration (George et al 1996;Burke et al 1999;Eickbush et al 2000;Bibillo and Eickbush 2002b), and our data suggest that template jumping may also be a feature of L1 retrotransposition. A similar mechanism was postulated to create chimeric L1 insertions (e.g., U6-L1) (Hayward et al 1997;Buzdin et al 2002Buzdin et al , 2003Gilbert et al 2005).…”

Section: L1 Rt Template Jumping Creates Extra 5ј Nucleotides and 5ј-esupporting

confidence: 89%

L1 integration in a transgenic mouse model

et al. 2005

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To study integration of the human LINE-1 retrotransposon (L1) in vivo, we developed a transgenic mouse model of L1 retrotransposition that displays de novo somatic L1 insertions at a high frequency, occasionally several insertions per mouse. We mapped 3Ј integration sites of 51 insertions by Thermal Asymmetric Interlaced PCR (TAIL-PCR). Analysis of integration locations revealed a broad genomic distribution with a modest preference for intergenic regions. We characterized the complete structures of 33 de novo retrotransposition events. Our results highlight the large number of highly truncated L1s, as over 52% (27/51) of total integrants were <1/3 the length of a full-length element. New integrants carry all structural characteristics typical of genomic L1s, including a number with inversions, deletions, and 5Ј-end microhomologies to the target DNA sequence. Notably, at least 13% (7/51) of all insertions contain a short stretch of extra nucleotides at their 5Ј end, which we postulate result from template-jumping by the L1-encoded reverse transcriptase. We propose a unified model of L1 integration that explains all of the characteristic features of L1 retrotransposition, such as 5Ј truncations, inversions, extra nucleotide additions, and 5Ј boundary and inversion point microhomologies.[Supplemental material is available online at www.genome.org.]The long interspersed nucleotide element-1 (L1) retrotransposon enjoyed tremendous evolutionary success in colonizing eukaryotic genomes (Kazazian Jr. 2004); its roughly 500,000 copies comprise ∼17% of human DNA (Lander et al. 2001). The full-length 6-kb L1 encodes a 5Ј UTR containing an internal promoter, two proteins-ORF1, a nucleic acid-binding protein with chaperone activity (Hohjoh andSinger 1996, 1997;Martin and Bushman 2001), and ORF2, a protein with endonuclease (EN) and reverse transcriptase (RT) activities (Mathias et al. 1991;Feng et al. 1996), and a 3Ј UTR ending with a poly(A) tail (Fig. 1A). Both ORF1 and ORF2 proteins are required for retrotransposition . Once transcribed and translated, L1 RNA is copied into the genome by target-primed reverse transcription (TPRT) (Luan et al. 1993;Cost et al. 2002). During TPRT, one strand of host DNA is cleaved by the EN to expose a free 3Ј-hydroxyl, which is then used by the RT as a primer in reverse transcription, copying the L1 RNA template directly into the host genome. To complete integration, the second strand of host DNA must be cleaved, RNA removed, the newly synthesized strand copied, and breaks resolved. The mechanism by which these later steps are accomplished is only beginning to be understood, with recent biochemical data from a related non-LTR retrotransposon R2 of the silkmoth, Bombyx mori, suggesting that a second R2 protein is involved in cleavage, RNA displacement, and synthesis of the second strand (Bibillo and Eickbush 2002a; Christensen and Eickbush 2005).Following essentially random integration, endogenous L1s are thought to be lost over time due to strong negative selection leading to their uneven ...

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Section: L1 Rt Template Jumping Creates Extra 5ј Nucleotides and 5ј-esupporting

confidence: 89%

L1 integration in a transgenic mouse model

et al. 2005

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“…The 3Ј UTR sequences of R2 elements from another 28 arthropod species are now available (Lathe and Eickbush 1997;Burke et al 1999). Here, we demonstrate that the R2 protein from B. mori can use in the TPRT reaction R2 RNA from even the most evolutionarily divergent arthropod.…”

Section: Introductionmentioning

confidence: 69%

“…1B, lane 6). The 3Ј UTRs of these other R2 elements are shorter than that of R2Bm, and the R2Dmer and R2Fa elements end in a poly(A) tail (Lathe and Eickbush 1997;Burke et al 1999). The three distant R2 RNAs supported TPRT from the cleavage site (bands at ∼310 nt), TPRT from the 3Ј end of the upper strand (bands at ∼360 nt), and template jumping to a second RNA (bands at ∼590 nt).…”

Section: Utr Rnas With No Primary Sequence Similarity Are Recognized mentioning

confidence: 99%

Secondary structure models of the 3′ untranslated regions of diverse R2 RNAs

Ruschak

Mathews²,

Bibiłło³

et al. 2004

RNA

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The RNA structure of the 3 untranslated region (UTR) of the R2 retrotransposable element is recognized by the R2-encoded reverse transcriptase in a reaction called target primed reverse transcription (TPRT). To provide insight into structure-function relationships important for TPRT, we have created alignments that reveal the secondary structure for 22 Drosophila and five silkmoth 3 UTR R2 sequences. In addition, free energy minimization has been used to predict the secondary structure for the 3 UTR R2 RNA of Forficula auricularia. The predicted structures for Bombyx mori and F. auricularia are consistent with chemical modification data obtained with ␤-ethoxy-␣-ketobutyraldehyde (kethoxal), dimethyl sulfate, and 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluene sulfonate. The structures appear to have common helices that are likely important for function.

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“…The R2 element in T. cancriformis To construct the complete sequence, six clones containing the whole insertion site at the 5 0 terminus (5 0 -TTAAkGG TAGC-3 0 ; Burke et al, 1999;Kojima and Fujiwara, 2005) Figure 1 Graphic representation of the regions sequenced for the 28S analyses, with corresponding primer pairs (listed in Table 2). The primer RIN5 was specifically used for individuals M6 and M9, which lack the complete element (see text).…”

Section: Resultsmentioning

confidence: 99%

“…In T. cancriformis, a four base deletion (TTAA) was found in R2-inserted 28S, whereas in the Drosophila genus 28S deletions are larger. On the other hand, the 3 0 end of R2Tc is congruent with that of Drosophila spp., with the typical poly-A tail and the deletion of the two Gs at the insertion site (George et al, 1995;Burke et al, 1999;Pérez-Gonzalez and Eickbush, 2001). These features are determined by the target primed reversed transcription mechanism, in the phase of DNA cleavage and cDNA synthesis (Christensen et al, 2006).…”

Section: Discussionmentioning

confidence: 99%

R2 dynamics in Triops cancriformis (Bosc, 1801) (Crustacea, Branchiopoda, Notostraca): turnover rate and 28S concerted evolution

2010

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The R2 retrotransposon is here characterized in bisexual populations of the European crustacean Triops cancriformis. The isolated element matches well with the general aspects of the R2 family and it is highly differentiated from that of the congeneric North American Triops longicaudatus. The analysis of 5 0 truncations indicates that R2 dynamics in T. cancriformis populations show a high turnover rate as observed in Drosophila simulans. For the first time in the literature, though, individuals harboring truncation variants, but lacking the complete element, are found. Present results suggest that transposition-mediated deletion mechanisms, possibly involving genomic turnover processes acting on rDNAs, can dramatically decrease the copy number or even delete R2 from the ribosomal locus. The presence of R2 does not seem to impact on the nucleotide variation of inserted 28S rDNA with respect to the uninserted genes. On the other hand, a low level of polymorphism characterizes rDNA units because new 28S variants continuously spread across the ribosomal array. Again, the interplay between transposition-mediated deletion and molecular drive may explain this pattern.

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The domain structure and retrotransposition mechanism of R2 elements are conserved throughout arthropods

Cited by 98 publications

References 32 publications

L1 integration in a transgenic mouse model

L1 integration in a transgenic mouse model

Secondary structure models of the 3′ untranslated regions of diverse R2 RNAs

R2 dynamics in Triops cancriformis (Bosc, 1801) (Crustacea, Branchiopoda, Notostraca): turnover rate and 28S concerted evolution

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