Retrotransposons Represent the Most Labile Fraction for Genomic Rearrangements in Polyploid Plant Species

Bento, Miguel; Tomás, Diana; Viegas, Wanda; Silva, M.

doi:10.1159/000353308

Cited by 14 publications

(10 citation statements)

References 56 publications

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“…IRAP PCR was performed in a 20 µL reaction mixture as previously described [38], using primers targeting the LTR of retrotransposons Nikita (5 1 -CGCTCCAGCGGTACTGCC) [39], Tat-1 (5 1 -TCCTCGTAAAACAACCACAAG), and Athila4-6 (5 1 -AAATGGATGCTCAAAACATGC) [19]. PCR products were separated by 1.7% agarose gel electrophoresis and detected by Ethidium Bromide staining.…”

Section: Irapmentioning

confidence: 99%

“…IRAP methodology was used to target three distinct retrotransposable elements: Nikita (identified in barley [39]), Tat-1 [44] and Athila4-6 [45] (the last two from A. thaliana). These retrotransposons have been previously used to study genome diversity in other species besides the ones where they were identified [19,33,34,46]. They were selected to produce consistent banding profiles with easily distinguishable bands allowing the assessment of faba bean genotypes.…”

Section: Irap Analysis Of Genomic Diversitymentioning

confidence: 99%

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Genetic Diversity Assessment of Portuguese Cultivated Vicia faba L. through IRAP Markers

et al. 2016

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Faba bean have been grown in Portugal for a long time and locally adapted populations are still maintained on farm. The genetic diversity of four Portuguese faba bean populations that are still cultivated in some regions of the country was evaluated using the Inter Retrotransposons Amplified Polymorphism (IRAP) technique. It was shown that molecular markers based on retrotransposons previously identified in other species can be efficiently used in the genetic variability assessment of Vicia faba. The IRAP experiment targeting Athila yielded the most informative banding patterns. Cluster analysis using the neighbor-joining algorithm generated a dendrogram that clearly shows the distribution pattern of V. faba samples. The four equina accessions are separated from each other and form two distinct clades while the two major faba bean accessions are not unequivocally separated by the IRAP. Fluorescent In Situ Hybridization (FISH) analysis of sequences amplified by IRAP Athila revealed a wide distribution throughout V. faba chromosomes, confirming the whole-genome coverage of this molecular marker. Morphological characteristics were also assessed through cluster analysis of seed characters using the unweighted pair group method arithmetic average (UPGMA) and principal component analysis (PCA), showing a clear discrimination between faba bean major and equina groups. It was also found that the seed character most relevant to distinguish accessions was 100 seed weight. Seed morphological traits and IRAP evaluation give similar results supporting the potential of IRAP analysis for genetic diversity studies.

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Section: Irapmentioning

confidence: 99%

Section: Irap Analysis Of Genomic Diversitymentioning

confidence: 99%

Genetic Diversity Assessment of Portuguese Cultivated Vicia faba L. through IRAP Markers

et al. 2016

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“…When first discovered, TEs were considered as selfish or junk DNA, but they are now recognized as key components of genome evolution and diversification, as well as gene regulation (Feschotte and Pritham, 2007;Volff, 2006). TEs constitute a considerable fraction of the eukaryotic genome, and LTR retrotransposons are particularly abundant in higher-plant genomes (Bento et al, 2013;Tenaillon et al, 2010). Wide variations of genome size exist among plant species, and a difference of over 2000-fold has been reported between Genlisea margaretae Hutch.…”

Section: Discussionmentioning

confidence: 99%

“…Wide variations of genome size exist among plant species, and a difference of over 2000-fold has been reported between Genlisea margaretae Hutch. (63.4 Mbp) and Paris japonica (149,000 Mbp) (Pellicer et al, 2010); these differences are thought to have been driven by factors such as polyploidization and TE amplification (Bento et al, 2013;Tenaillon et al, 2010). In fact, plant genome size and TE (especially retrotransposon) content are well correlated (Tenaillon et al, 2010): plant species with huge genomes, such as maize and barley, tend to have higher proportions of TEs (> 85%), whereas plant species with smaller genomes, such as Arabidopsis thaliana and Brachypodium distachyon, show lower levels (20%-30%).…”

Section: Discussionmentioning

confidence: 99%

“…In addition, over 75% of the maize genome consists of retrotransposons, whereas DNA transposons occupy only 8.6% of the genome (Schnable et al, 2009). This situation is likely due to the "copy and paste" transposition mechanism of retrotransposons, which increases their copy numbers dramatically and contributes to the expansion of plant genomes (Bento et al, 2013;Kumar and Bennetzen, 1999). Thus, multiple and diverse retrotransposon families with high copy numbers exist in present genomes.…”

Section: Introductionmentioning

confidence: 99%

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Plant Transposable Elements and Their Application to Genetic Analysis via High-throughput Sequencing Platform

Monden

Tahara

2015

Hortic J

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Transposable elements (TEs) are mobile genetic elements in the eukaryotic genome. They are divided into two classes (class I: retrotransposons and class II: DNA transposons) based on their structure and manner of transposition. TEs are major components of the eukaryotic genome and retrotransposons are especially abundant in higher-plant genomes. As retrotransposon insertions with high copy numbers are dispersed throughout the genome and are inherited genetically, insertion polymorphisms among crop cultivars have been used as molecular markers. Recently, we developed an efficient method for screening the long terminal repeats (LTRs) of retrotransposon families that exhibit high levels of insertion polymorphisms among crop cultivars using a next-generation sequencing (NGS) platform. This method focuses on the primer binding site (PBS) that is adjacent to the 5' LTR and has a conserved DNA sequence among different LTR retrotransposon families. Construction of a sequencing library through PCR amplification using the PBS conserved sequence allowed us to acquire a large number of LTR sequences and their insertion sites throughout the genome. From our data analysis, we screened the LTR sequences that showed high levels of insertion polymorphism among closely related cultivars. In addition, we identified the insertion sites of these identified LTR retrotransposon families at the genome-wide scale in a number of cultivars with an NGS platform, which enabled us to reveal the genetic relationships among the cultivars and acquire a number of molecular markers for cultivar screening. Our results indicated that the target sequencing of these retrotransposon insertion sites was highly effective for DNA genotyping and marker development without requiring any whole-genome sequence information. This review describes the genomic structure and evolutionary aspects of TEs and discusses the development of molecular markers based on retrotransposon insertion polymorphisms.

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Unravelling genome dynamics in Arabidopsis synthetic auto and allopolyploid species

Bento¹,

Tomás²,

Viegas³

et al. 2015

Biologia plant.

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Polyploidization is a major genome modification that results in plant species with multiple chromosome sets. Parental genome adjustment to cohabit a new nuclear environment results in additional innovation outcomes. We intended to assess genomic changes in polyploid model species with small genomes using inter retrotransposons amplified polymorphism (IRAP) and retrotransposon microsatellite amplified polymorphism (REMAP). Comparative analysis among diploid and autotetraploid A. thaliana and A. suecica lines with their parental lines revealed a marginal fraction of novel bands in both polyploids, and a vast loss of parental bands in allopolyploids. Sequence analysis of some remodelled bands shows that A. suecica parental band losses resulted mainly from sequence changes restricted to primer domains. Moreover, in A. suecica, both parental genomes presented rearrangement frequencies proportional to their sizes. Overall rates of genomic remodelling events detected in A. suecica were similar to those observed in species with a large genome supporting the role of retrotransposons and microsatellite sequences in the evolution of most allopolyploids.

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Retrotransposons Represent the Most Labile Fraction for Genomic Rearrangements in Polyploid Plant Species

Cited by 14 publications

References 56 publications

Genetic Diversity Assessment of Portuguese Cultivated Vicia faba L. through IRAP Markers

Genetic Diversity Assessment of Portuguese Cultivated Vicia faba L. through IRAP Markers

Plant Transposable Elements and Their Application to Genetic Analysis via High-throughput Sequencing Platform

Unravelling genome dynamics in Arabidopsis synthetic auto and allopolyploid species

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