Mobilization of the Active MITE Transposons mPing and Pong in Rice by Introgression from Wild Rice (Zizania latifolia Griseb.)

Shan, Xiuming; Liu, Zhenlan; Dong, Zhenying; Wang, Yongming; Chen, Yu; Lin, Xiuyun; Long, Likun; Han, Fangpu; Dong, Yingshan; B, Liu

doi:10.1093/molbev/msi082

Cited by 153 publications

(171 citation statements)

References 76 publications

(128 reference statements)

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“…Another example of transposable element (TE) mobilization comes from intergeneric hybridization between rice (cultivar Matsumae) and wild rice (Zizania latifolia). Shan et al (2005) used a repeated pollination procedure to generate a series of morphologically distinct inbred lines of rice with introgressed genomic DNA from wild rice, and showed that mPing miniature inverted-repeat transposable element (MITE) and its transposase-encoding partner, Pong, were mobilized in these lines. In contrast, these two MITEs remained immobile in control lines sharing the same parentage to the experimental lines but possessing no introgressed DNA.…”

Section: Transposable Element Derepression During Hybridizationmentioning

confidence: 99%

“…Dobzhansky-Muller's model of genetic incompatibilities has long provided a useful theoretical framework for speciation genetics, but it is becoming increasingly clear that the model is too general to generate more specific predictions regarding the genetic mechanisms involved. Accumulating evidence indicates that the merging of two distinct genomes typically sets in motion extensive modifications of the genome and transcriptome, creating cascades of novel gene expression patterns (Michalak and Noor, 2003;Wu et al, 2003;Ranz et al, 2004;Auger et al, 2005;Hegarty et al, 2006), regulatory interactions and new phenotypic variation (Riddle and Birchler, 2003;Adams and Wendel, 2005a, b), chromosomal rearrangements (Rieseberg et al, 2003;Metcalfe et al, 2007), transposable element mobilization (Liu and Wendel, 2000;Shan et al, 2005;Ungerer et al, 2006), miRNA deficiency (Michalak and Malone, 2008) and DNA methylation changes (Waugh O'Neill et al, 1998;Vrana et al, 2000;Salmon et al 2005;Josefsson et al, 2006).…”

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confidence: 99%

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Epigenetic, transposon and small RNA determinants of hybrid dysfunctions

2008

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Accumulating evidence suggests that hybrid genetic dysfunctions accrue not only because of sequence divergence of incompatible alleles but also result from a broad variety of mechanisms related to the maintenance of chromatin integrity. For example, it has been observed that hybridization in plants and mammals disrupts patterns of DNA methylation and imprinting. These epigenetic changes can be associated with transcriptional activation and mobilization of transposable elements in hybrids. It raises a question of how these alterations are matched by small regulatory RNAs, such as piwi-interacting RNAs, which play a potent role in both suppressing transposable elements and epigenetic control. The review offers a handful of glimpses into these complex dynamics.

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Section: Transposable Element Derepression During Hybridizationmentioning

confidence: 99%

mentioning

confidence: 99%

Epigenetic, transposon and small RNA determinants of hybrid dysfunctions

2008

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“…The recent studies on a rice MITE (Jiang et al 2003;Kikuchi et al 2003) confirmed the cut-and-paste mechanism and indicated that amplification could be influenced by specific (environmental or genomic) conditions ( Jiang et al 2003;Shan et al 2005). However, although putative autonomous partners have been proposed for several MITE families, a clear demonstration that they are indeed necessary for MITE transposition is still lacking.…”

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confidence: 99%

Transposition of a Fungal Miniature Inverted-Repeat Transposable Element Through the Action of a Tc1-Like Transposase

et al. 2007

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The mimp1 element previously identified in the ascomycete fungus Fusarium oxysporum has hallmarks of miniature inverted-repeat transposable elements (MITEs): short size, terminal inverted repeats (TIRs), structural homogeneity, and a stable secondary structure. Since mimp1 has no coding capacity, its mobilization requires a transposase-encoding element. On the basis of the similarity of TIRs and target-site preference with the autonomous Tc1-like element impala, together with a correlated distribution of both elements among the Fusarium genus, we investigated the ability of mimp1 to jump upon expression of the impala transposase provided in trans. Under these conditions, we present evidence that mimp1 transposes by a cut-and-paste mechanism into TA dinucleotides, which are duplicated upon insertion. Our results also show that mimp1 reinserts very frequently in genic regions for at least one-third of the cases. We also show that the mimp1/impala double-component system is fully functional in the heterologous species F. graminearum, allowing the development of a highly efficient tool for gene tagging in filamentous fungi. M INIATURE inverted-repeat transposable elements (MITEs) are a particular group of transposable elements (TEs), first described in plants (Bureau and

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“…In general terms, MITE-like elements have been widely described in plants ( Moreno-Vazquez et al, 2005 ;Lin et al, 2006 ;Guermonprez et al, 2008) and specifically in grapevine (Benjak et al, 2009), maize (Bureau & Wessler, 1992;Zerjal et al, 2009), cereal grasses (Bureau & Wessler, 1994), Arabidopsis (Feschotte & Mouches, 2000), rice (Feschotte et al, 2003 ;Jiang et al, 2003 ;Nakazaki et al, 2003 ;Shan et al, 2005), Medicago (Grzebelus et al, 2007(Grzebelus et al, , 2009, apple (Han & Korban, 2007), beet (Menzel et al, 2006), barley (Lyons et al, 2008;Petersen & Seberg, 2009), grasses (Park et al, 2003), pearl millet (Remigereau et al, 2006) and pome fruit trees (Wakasa et al, 2003). Descriptions in other organisms, such as bacteria (Chen et al, 2008), cyanobacteria , fungi (Xu et al, 2010), silkworms (Han et al, 2010), fish (de Boer et al, 2007) and amphibians (Hikosaka et al, 2011) are also found in the literature, but few occurrences have been reported in the Drosophila genus (Tudor et al, 1992 ;Miller et al, 2000 ;Ortiz et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

msechBari, a new MITE-like element inDrosophila sechelliarelated to theBaritransposon

Dias

Carareto

2011

Genet. Res.

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SummaryA few occurrences of miniature inverted-repeat transposable elements (MITEs) have been reported in species of the genus Drosophila. Here, we describe msechBari, a MITE-like element in Drosophila sechellia. The element is short, approximately 90 bp in length, AT-rich and occurs in association with, or close to, genes, characteristics that are typical for MITEs. The identification was performed in silico using the sequenced genome of D. sechellia and confirmed in a laboratory strain. This short element is related to the Bari_DM transposon of Drosophila melanogaster, having terminal inverted repeats (TIRs) of a similar length and a high identity with the full-length Bari_DM element. The estimated recent origin of the element and the homogeneity observed between copies found in the genome suggests that msechBari could be active in D. sechellia.

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Mobilization of the Active MITE Transposons mPing and Pong in Rice by Introgression from Wild Rice (Zizania latifolia Griseb.)

Cited by 153 publications

References 76 publications

Epigenetic, transposon and small RNA determinants of hybrid dysfunctions

Epigenetic, transposon and small RNA determinants of hybrid dysfunctions

Transposition of a Fungal Miniature Inverted-Repeat Transposable Element Through the Action of a Tc1-Like Transposase

msechBari, a new MITE-like element inDrosophila sechelliarelated to theBaritransposon

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