LTR_FINDER: an efficient tool for the prediction of full-length LTR retrotransposons

Xu, Zhonghui; Wang, Hao

doi:10.1093/nar/gkm286

Cited by 1,889 publications

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References 21 publications

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“…The repetitive sequences of the B. juncea genome were identified with a combination of de novo and homolog strategies. Four de novo programs including RepeatScout 44 , LTR-FINDER 45 , MITE 46 and PILER 47 were used to generate the initial repeat library. The initial repeat database was classified into classes, subclasses, superfamilies and families by the PASTEClassifier with REPET 48 .…”

Section: Competing Financial Interestsmentioning

confidence: 99%

The genome sequence of allopolyploid Brassica juncea and analysis of differential homoeolog gene expression influencing selection

et al. 2016

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2 2 5The Brassica genus contains a diverse range of oilseed and vegetable crops important for human nutrition 1 . Crops of particular agricultural importance include three diploid species, Brassica rapa (AA), Brassica nigra (BB) and Brassica oleracea (CC), and three allopolyploid species, B. napus (AACC), B. juncea (AABB) and Brassica carinata (BBCC). The evolutionary relationships among these Brassica species are described by what is called the 'triangle of U' model 2 , which proposes how the genomes of the three ancestral Brassica species, B. rapa, B. nigra and Brassica oleracae, combined to give rise to the allopolyploid species of this genus. B. juncea formed by hybridization between the diploid ancestors of B. rapa and B. nigra, followed by spontaneous chromosome doubling. Subsequent diversifying selection then gave rise to the vegetable-and oil-use subvarieties of B. juncea. These subvarieties include vegetable and oilseed mustard in China, oilseed crops in India, canola crops in Canada and Australia, and condiment crops in Europe and other regions 3 . Cultivation of B. juncea began in China about 6,000 to 7,000 years ago 4 , and flourished in India from 2,300 BC onward 5 .The genomes of B. rapa, B. oleracea and their allopolyploid offspring B. napus have been published recently [6][7][8] , and are often used to explain genome evolution in angiosperms [6][7][8] . The genomes of all Brassica species underwent a lineage-specific whole-genome triplication 6,7,9 , followed by diploidization that involved substantial genome reshuffling and gene losses 6,10-13 . In general, plant genomes are typically repetitive, polyploid and heterozygous, which complicates genome assembly 14 . The short read lengths of next-generation sequencing hinder assembly through complex regions, and fragmented draft and reference genomes usually lack skewed (G+C)-content sequences and repetitive intergenic sequences. Furthermore, in allopolyploid species, homoeolog expression dominance or bias, and specifically differential homoelog gene expression, has often been detected, for instance in Gossypium [15][16][17] Triticum 18,19 and Arabidopsis 20,21 , but the role of this phenomenon in selection for phenotypic traits remains mechanistically mysterious 22 .We reported here the draft genomes of an allopolyploid, B. juncea var. tumida, constructed by de novo assembly using shotgun reads, single-molecule long reads (PacBio sequencing), genomic (optical) mapping (BioNano sequencing) and genetic mapping, serving to resolve complicated allopolyploid genomes. The multiuse allopolyploid B. juncea genome offers a distinctive model to study the underlying genomic basis for selection in breeding improvement. These findings place this work into the broader context of plant breeding, highlighting The Brassica genus encompasses three diploid and three allopolyploid genomes, but a clear understanding of the evolution of agriculturally important traits via polyploidy is lacking. We assembled an allopolyploid Brassica juncea genome by shotgun and single-m...

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Section: Competing Financial Interestsmentioning

confidence: 99%

The genome sequence of allopolyploid Brassica juncea and analysis of differential homoeolog gene expression influencing selection

et al. 2016

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“…RepeatMasker and LTR_FINDER version 1.1.0.5 (ref. 79) were then used to identify and classify repeat elements in the genome ( Supplementary Fig. 32 and Supplementary Table 9).…”

Section: Methodsmentioning

confidence: 99%

A high-quality carrot genome assembly provides new insights into carotenoid accumulation and asterid genome evolution

et al. 2016

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5 7Carrot (Daucus carota subsp. carota L.; 2n = 2x = 18) is a globally important root crop whose production has quadrupled between 1976 and 2013 (FAO Statistics; see URLs), outpacing the overall rate of increase in vegetable production and world population growth (FAO Statistics; see URLs) through development of high-value products for fresh consumption, juices, and natural pigments and cultivars adapted to warmer production regions 1 .The first documented colors for domesticated carrot root were yellow and purple in Central Asia approximately 1,100 years ago 2,3 , with orange carrots not reliably reported until the sixteenth century in Europe 4,5 . The popularity of orange carrots is fortuitous for modern consumers because the orange pigmentation results from high quantities of alpha-and beta-carotene, making carrots the richest source of provitamin A in the US diet 6 . Carrot breeding has substantially increased nutritional value, with a 50% average increase in carotene content in the United States as compared to 40 years ago 6 . Lycopene and lutein in red and yellow carrots, respectively, are also nutritionally important carotenoids, making carrot a model system to study storage root development and carotenoid accumulation.Carrot is the most important crop in the Apiaceae family, which includes numerous other vegetables, herbs, spices, and medicinal plants that enhance the epicurean experience 7 , including celery, parsnip, arracacha, parsley, fennel, coriander, and cumin. The Apiaceae family belongs to the euasterid II clade, which includes important crops such as lettuce and sunflower 8 . Genome sequences of euasterid I species have been reported, but only two genomes 9,10 have been published among the other euasterid II species.Here we report a high-quality genome assembly of a doubledhaploid orange carrot, characterization of the mechanism controlling carotenoid accumulation in storage roots, and the resequencing of 35 accessions spanning the genetic diversity of the Daucus genus. Our comprehensive genomic analyses provide insights into the evolution of the asterids and several gene families. These results will facilitate biological discovery and crop improvement in carrot and other crops.A high-quality carrot genome assembly provides new insights into carotenoid accumulation and asterid genome evolution We report a high-quality chromosome-scale assembly and analysis of the carrot (Daucus carota) genome, the first sequenced genome to include a comparative evolutionary analysis among members of the euasterid II clade. We characterized two new polyploidization events, both occurring after the divergence of carrot from members of the Asterales order, clarifying the evolutionary scenario before and after radiation of the two main asterid clades. Large- and small-scale lineage-specific duplications have contributed to the expansion of gene families, including those with roles in flowering time, defense response, flavor, and pigment accumulation. We identified a candidate gene, DCAR_032551, that conditions caro...

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“…The moso bamboo transposable element library was composed of a total of 1,403 generated consensus sequences and their classification information, and the library was used to run RepeatMasker on the whole-genome assemblies. Full-length LTR retrotransposons were predicted using LTRharvest 58 and LTR_FINDER 59 .…”

Section: Methodsmentioning

confidence: 99%

The draft genome of the fast-growing non-timber forest species moso bamboo (Phyllostachys heterocycla)

et al. 2013

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l e t t e r sBamboo represents the only major lineage of grasses that is native to forests and is one of the most important nontimber forest products in the world. However, no species in the Bambusoideae subfamily has been sequenced. Here, we report a high-quality draft genome sequence of moso bamboo (P. heterocycla var. pubescens). The 2.05-Gb assembly covers 95% of the genomic region. Gene prediction modeling identified 31,987 genes, most of which are supported by cDNA and deep RNA sequencing data. Analyses of clustered gene families and gene collinearity show that bamboo underwent whole-genome duplication 7-12 million years ago. Identification of gene families that are key in cell wall biosynthesis suggests that the whole-genome duplication event generated more gene duplicates involved in bamboo shoot development. RNA sequencing analysis of bamboo flowering tissues suggests a potential connection between droughtresponsive and flowering genes.Bamboo is one of the most important non-timber forest products in the world. About 2.5 billion people depend economically on bamboo, and international trade in bamboo amounts to over 2.5 billion US dollars per year 1 . Bamboo has a rather striking life history, characterized by a prolonged vegetative phase lasting decades before flowering, thereby inhibiting genetic improvement. Recent genomic studies in bamboo have included genome-wide full-length cDNA sequencing 2 , chloroplast genome sequencing 3 , identification of syntenic genes between bamboo and other grasses 4 and phylogenetic analysis of Bambusoideae subspecies 5 . Fifty-nine simple sequence repeat markers from rice and sugarcane were used in the genetic diversity analyses of 23 bamboo species 6 , and 2 species-specific sequence-characterized amplified region markers were developed in the identification of different bamboo species 7 .Here, we report the draft genome of moso bamboo, a large woody bamboo that has ecological, economic and cultural value in Asia and accounts for ~70% of the total bamboo growth area. Comparative genome-wide analyses of bamboo to other grass species, including rice, maize and sorghum, yielded new genetic insights into the rapid and marked phenotypic and ecological divergence of bamboo and closely related grasses.The moso bamboo genome contains 24 pairs of chromosomes 8 (2n = 48) and is characteristic of a diploid (Supplementary Fig. 1a). We conducted a flow cytometry analysis and estimated that it had a genome size of 2.075 Gb (2C = 4.24 pg; Supplementary Fig. 1b), which was very close to that estimated in a previous report 9 .Because it is difficult to generate an inbred line of moso bamboo, owing to its infrequent sexual reproduction and the long periods of time between flowering intervals, we selected five plants from a single individual rhizome of the moso bamboo ecotype (P. heterocycla var. pubescens) and performed whole-genome shotgun sequencing. We generated 295 Gb of raw sequence data (approximately 147-fold coverage), including Illumina short reads and 10,327 pairs of BAC end ...

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LTR_FINDER: an efficient tool for the prediction of full-length LTR retrotransposons

Cited by 1,889 publications

References 21 publications

The genome sequence of allopolyploid Brassica juncea and analysis of differential homoeolog gene expression influencing selection

The genome sequence of allopolyploid Brassica juncea and analysis of differential homoeolog gene expression influencing selection

A high-quality carrot genome assembly provides new insights into carotenoid accumulation and asterid genome evolution

The draft genome of the fast-growing non-timber forest species moso bamboo (Phyllostachys heterocycla)

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