Hypervariable 3′ UTR region of plant LTR-retrotransposons as a source of novel satellite repeats

The repetitive sequence PisTR-A has an unusual organization in the pea (Pisum sativum) genome, being present both as short dispersed repeats as well as long arrays of tandemly arranged satellite DNA. Cloning, sequencing and FISH analysis of both PisTR-A variants revealed that the former occurs in the genome embedded within the sequence of Ty3/gypsy-like Ogre elements, whereas the latter forms homogenized arrays of satellite repeats at several genomic loci. The Ogre elements carry the PisTR-A sequences in their 3′ untranslated region (UTR) separating the gag-pol region from the 3′ LTR. This region was found to be highly variable among pea Ogre elements, and includes a number of other tandem repeats along with or instead of PisTR-A. Bioinformatic analysis of LTR-retrotransposons mined from available plant genomic sequence data revealed that the frequent occurrence of variable tandem repeats within 3′ UTRs is a typical feature of the Tat lineage of plant retrotransposons. Comparison of these repeats to known plant satellite sequences uncovered two other instances of satellites with sequence similarity to a Tat-like retrotransposon 3′ UTR regions. These observations suggest that some retrotransposons may significantly contribute to satellite DNA evolution by generating a library of short repeat arrays that can subsequently be dispersed through the genome and eventually further amplified and homogenized into novel satellite repeats.     

Ogre elements--a distinct group of plant Ty3/gypsy-like retrotransposons

Ogre elements are a group of LTR retrotransposons recently discovered in legume plants, where they constitute almost 40% of the genome in some species. They are exceptional in their size (reaching 25 kb) and possess several specific features, including an intron within a polyprotein-coding region, and an extra open reading frame (ORF1) encoding a protein of unknown function located upstream of the gag gene. Although these features make Ogres interesting for further research, identification of additional elements from a broader range of plant taxa has been complicated by the divergence of their sequences, preventing their detection using similarity-based searches. Here we report the results of structure-based computational searches for Ogre elements in available plant genomic sequences, which proved to be more efficient and revealed occurrences of Ogres in three families of dicot plants (Leguminosae, Solanaceae and Salicaceae). In addition, a representative set of 85 elements was retrieved from a model legume species Medicago truncatula. All identified full-length elements were used for comparative analysis, which showed that in spite of only little conservation of their nucleotide sequences, their protein domains were highly conserved, including several regions within ORF1. Further, the elements shared the same functional regions, including a primer binding site complementary to tRNA_arg, a conserved motif within a polypurine tract, and a putative intron between the pro and rt/rh coding domains. These findings, together with analysis of their phylogenetic relationship to other retrotransposons based on similarities of rt domains suggest that Ogre elements from different plant taxa have a common origin and thus constitute a distinct group of Ty3/gypsy retrotransposons.     

DNA, chromosomes, and in situ hybridization.

In situ hybridization is a powerful and unique technique that correlates molecular information of a DNA sequence with its physical location along chromosomes and genomes. It thus provides valuable information about physical map position of sequences and often is the only means to determine abundance and distribution of repetitive sequences making up the majority of most genomes. Repeated DNA sequences, composed of units of a few to a thousand base pairs in size, occur in blocks (tandem or satellite repeats) or are dispersed (including transposable elements) throughout the genome. They are often the most variable components of a genome, often being species and, occasionally, chromosome specific. Their variability arises through amplification, diversification and dispersion, as well as homogenization and loss; there is a remarkable correlation of molecular sequence features with chromosomal organization including the length of repeat units, their higher order structures, chromosomal locations, and dispersion mechanisms. Our understanding of the structure, function, organization, and evolution of genomes and their evolving repetitive components enabled many new cytogenetic applications to both medicine and agriculture, particularly in diagnosis and plant breeding.     

In Depth Characterization of Repetitive DNA in 23 Plant Genomes Reveals Sources of Genome Size Variation in the Legume Tribe Fabeae

The differential accumulation and elimination of repetitive DNA are key drivers of genome size variation in flowering plants, yet there have been few studies which have analysed how different types of repeats in related species contribute to genome size evolution within a phylogenetic context. This question is addressed here by conducting large-scale comparative analysis of repeats in 23 species from four genera of the monophyletic legume tribe Fabeae, representing a 7.6-fold variation in genome size. Phylogenetic analysis and genome size reconstruction revealed that this diversity arose from genome size expansions and contractions in different lineages during the evolution of Fabeae. Employing a combination of low-pass genome sequencing with novel bioinformatic approaches resulted in identification and quantification of repeats making up 55–83% of the investigated genomes. In turn, this enabled an analysis of how each major repeat type contributed to the genome size variation encountered. Differential accumulation of repetitive DNA was found to account for 85% of the genome size differences between the species, and most (57%) of this variation was found to be driven by a single lineage of Ty3/gypsy LTR-retrotransposons, the Ogre elements. Although the amounts of several other lineages of LTR-retrotransposons and the total amount of satellite DNA were also positively correlated with genome size, their contributions to genome size variation were much smaller (up to 6%). Repeat analysis within a phylogenetic framework also revealed profound differences in the extent of sequence conservation between different repeat types across Fabeae. In addition to these findings, the study has provided a proof of concept for the approach combining recent developments in sequencing and bioinformatics to perform comparative analyses of repetitive DNAs in a large number of non-model species without the need to assemble their genomes.     

LTR retrotransposons and flowering plant genome size: emergence of the increase/decrease model

Long Terminal Repeat (LTR) retrotransposons are ubiquitous components of plant genomes. Because of their copy-and-paste mode of transposition, these elements tend to increase their copy number while they are active. In addition, it is now well established that the differences in genome size observed in the plant kingdom are accompanied by variations in LTR retrotransposon content, suggesting that LTR retrotransposons might be important players in the evolution of plant genome size, along with polyploidy. The recent availability of large genomic sequences for many crop species has made it possible to examine in detail how LTR retrotransposons actually drive genomic changes in plants. In the present paper, we provide a review of the recent publications that have contributed to the knowledge of plant LTR retrotransposons, as structural components of the genomes, as well as from an evolutionary genomic perspective. These studies have shown that plant genomes undergo genome size increases through bursts of retrotransposition, while there is a counteracting process that tends to eliminate the transposed copies from the genomes. This process involves recombination mechanisms that occur either between the LTRs of the elements, leading to the formation of solo-LTRs, or between direct repeats anywhere in the sequence of the element, leading to internal deletions. All these studies have led to the emergence of a new model for plant genome evolution that takes into account both genome size increases (through retrotransposition) and decreases (through solo-LTR and deletion formation). In the conclusion, we discuss this new model and present the future prospects in the study of plant genome evolution in relation to the activity of transposable elements.     

植物反转录转座子及其在功能基因组学中的应用

高等植物中的反转录转座子是构成植物基因组的重要成分之一.它分病毒家族和非病毒家族两类,病毒家族包括反转录病毒和类似于反转录病毒的非病毒转座子,病毒家族中的反转录转座子可再细分为Ty3-gypsy类和Ty1-copia类;非病毒家族可细分为LINE类和SINE类.正常情况下大部分反转录转座子不具有活性,某些生物或非生物因素胁迫可激活部分反转录转座子转座.反转录转座子自身编码反转录酶进行转录,以"拷贝-粘贴"的转座模式导致基因组扩增和进化.具有活性的反转录转座子通过插入产生新的突变,可作为一种基因标签技术,应用于功能基因组学研究,并成为研究植物基因功能和表达的重要技术平台.本文综述了近几年来在植物反转录转座子方面的研究进展,主要包括植物反转录转座子的结构、特征、活性及其对基因组的影响和它们在功能基因组学中的应用.     

Origins and recombination of the bacterial-sized multichromosomal mitochondrial genome of cucumber

Members of the flowering plant family Cucurbitaceae harbor the largest known mitochondrial genomes. Here, we report the 1685-kb mitochondrial genome of cucumber (Cucumis sativus). We help solve a 30-year mystery about the origins of its large size by showing that it mainly reflects the proliferation of dispersed repeats, expansions of existing introns, and the acquisition of sequences from diverse sources, including the cucumber nuclear and chloroplast genomes, viruses, and bacteria. The cucumber genome has a novel structure for plant mitochondria, mapping as three entirely or largely autonomous circular chromosomes (lengths 1556, 84, and 45 kb) that vary in relative abundance over a twofold range. These properties suggest that the three chromosomes replicate independently of one another. The two smaller chromosomes are devoid of known functional genes but nonetheless contain diagnostic mitochondrial features. Paired-end sequencing conflicts reveal differences in recombination dynamics among chromosomes, for which an explanatory model is developed, as well as a large pool of low-frequency genome conformations, many of which may result from asymmetric recombination across intermediate-sized and sometimes highly divergent repeats. These findings highlight the promise of genome sequencing for elucidating the recombinational dynamics of plant mitochondrial genomes.     

The maize genome as a model for efficient sequence analysis of large plant genomes

The genomes of flowering plants vary in size from about 0.1 to over 100 gigabase pairs (Gbp), mostly because of polyploidy and variation in the abundance of repetitive elements in intergenic regions. High-quality sequences of the relatively small genomes of Arabidopsis (0.14 Gbp) and rice (0.4 Gbp) have now been largely completed. The sequencing of plant genomes that have a more representative size (the mean for flowering plant genomes is 5.6 Gbp) has been seen as a daunting task, partly because of their size and partly because of the numerous highly conserved repeats. Nevertheless, creative strategies and powerful new tools have been generated recently in the plant genetics community, so that sequencing large plant genomes is now a realistic possibility. Maize (2.4-2.7 Gbp) will be the first gigabase-size plant genome to be sequenced using these novel approaches. Pilot studies on maize indicate that the new gene-enrichment, gene-finishing and gene-orientation technologies are efficient, robust and comprehensive. These strategies will succeed in sequencing the gene-space of large genome plants, and in locating all of these genes and adjacent sequences on the genetic and physical maps.     

A new middle repetitive sequence of Nicotiana plumbaginifolia genome

A middle repetitive sequence NPR18 was isolated from Nicotiana plumbaginifolia nuclear genome [8]. Sequences homologous to the repeat are dispersed through genomes of several Nicotiana species. compute-assisted data analysis of NPR18 primary sequence reveals several features attributed to mobile genetic elements: an AT content higher than average for nuclear DNA of genus Nicotiana plants; a number of direct and inverted repeats. Some of the repeats displayed homology to the terminal and subterminal repeats of Ac/Ds-like plant elements.     

A family of Tc1-like transposons from the genomes of fishes and frogs: evidence for horizontal transmission.

Tc1-like transposons are very widely distributed within the genomes of animal species. They consist of an inverted repeat sequence flanking a transposase gene with homology to the mobile DNA element, Tc1 of the nematode Caenorhabditis elegans. These elements seem particularly to infest the genomes of fish and amphibian species where they can account for 1% of the total genome. However, all vertebrate Tc1-like elements isolated so far are non-functional in that they contain multiple frameshifts within their transposase coding regions. Here I describe a Tc1-like transposon (PPTN) from the genome of a marine flatfish species (Pleuronectes platessa) which bears conserved inverted repeats flanking an apparently intact transposase gene. Closely related, although degenerate, Tc1-like transposons were also isolated from the genomes of Atlantic salmon (SSTN, Salmo salar) and frog (RTTN, Rana temporaria). Consensual nucleic acid sequences were derived by comparing several individual isolates from each species and conceptual amino acid sequences were thence derived for their transposases. Phylogenetic analysis of these sequences with previously isolated Tc1-like transposases shows that the elements from plaice, salmon and frog comprise a new subfamily of Tc1-like transposons. Each member is distinct in that it is not found in the genomes of the other species tested. Plaice genomes contain about 300 copies of PPTN, salmon 1200 copies of SSTN and frog genomes about 500 copies of RTTN. The presence of these closely related elements in the genomes of fish and frog species, representing evolutionary lines, which diverged more than 400 million years ago, is not consistent with a vertical transmission model for their distributions.     

Dispersed repeats and structural reorganization in subclover chloroplast DNA

The plastid genome from subclover, Trifolium subterraneum, is unusual in a variety of respects, compared with other land-plant chloroplast DNAs. Gene mapping of subclover chloroplast DNA reveals major structural reorganization of the genome. Ten clusters of genes are rearranged in both order and orientation. Eight large inversions are sufficient to explain this reorganization; however, the actual evolutionary changes may have been more complex. For example, a fine-scale analysis of a set of ribosomal protein genes reveals the occurrence of insertions, deletions, and transpositions. Associated with this unusually unstable genome are two structural features potentially involved in the rearrangements. A dispersed family of repeats, with each element about 1 kb in length, is present in at least six copies. A survey of a wide taxonomic range of species indicates that these elements are unique to the chloroplast DNAs of subclover and two closely related species. Several of the repeated elements are associated with genomic rearrangements, and one repeat is inserted within a normally highly conserved series of genes. This set of dispersed repeats may be the first family of transposable elements found in any organelle genome. In addition, the subclover genome is much larger than those in other closely related legumes, even when one takes into account the presence of the repeated elements. Some of the extra DNA has no sequence similarity to other chloroplast genomes and may represent insertion of DNA from another genome. These unusual features are not found in the structurally stable chloroplast genomes of other vascular plants and may, therefore, be implicated in the rapid and major reorganization of the chloroplast DNA in subclover.     

Illumina TruSeq Synthetic Long-Reads Empower De Novo Assembly and Resolve Complex,Highly-Repetitive Transposable Elements

High-throughput DNA sequencing technologies have revolutionized genomic analysis, including the de novo assembly of whole genomes. Nevertheless, assembly of complex genomes remains challenging, in part due to the presence of dispersed repeats which introduce ambiguity during genome reconstruction. Transposable elements (TEs) can be particularly problematic, especially for TE families exhibiting high sequence identity, high copy number, or complex genomic arrangements. While TEs strongly affect genome function and evolution, most current de novo assembly approaches cannot resolve long, identical, and abundant families of TEs. Here, we applied a novel Illumina technology called TruSeq synthetic long-reads, which are generated through highly-parallel library preparation and local assembly of short read data and which achieve lengths of 1.5–18.5 Kbp with an extremely low error rate (0.03% per base). To test the utility of this technology, we sequenced and assembled the genome of the model organism Drosophila melanogaster (reference genome strain y; cn, bw, sp) achieving an N50 contig size of 69.7 Kbp and covering 96.9% of the euchromatic chromosome arms of the current reference genome. TruSeq synthetic long-read technology enables placement of individual TE copies in their proper genomic locations as well as accurate reconstruction of TE sequences. We entirely recovered and accurately placed 4,229 (77.8%) of the 5,434 annotated transposable elements with perfect identity to the current reference genome. As TEs are ubiquitous features of genomes of many species, TruSeq synthetic long-reads, and likely other methods that generate long-reads, offer a powerful approach to improve de novo assemblies of whole genomes.     

Karyotype analysis of four Vicia species using in situ hybridization with repetitive sequences

Mitotic chromosomes of four Vicia species (V. sativa, V. grandiflora, V. pannonica and V. narbonensis) were subjected to in situ hybridization with probes derived from conserved plant repetitive DNA sequences (18S-25S and 5S rDNA, telomeres) and genus-specific satellite repeats (VicTR-A and VicTR-B). Numbers and positions of hybridization signals provided cytogenetic landmarks suitable for unambiguous identification of all chromosomes, and establishment of the karyotypes. The VicTR-A and -B sequences, in particular, produced highly informative banding patterns that alone were sufficient for discrimination of all chromosomes. However, these patterns were not conserved among species and thus could not be employed for identification of homologous chromosomes. This fact, together with observed variations in positions and numbers of rDNA loci, suggests considerable divergence between karyotypes of the species studied.     

Retrotransposon populations of <Emphasis Type="Italic">Vicia</Emphasis> species with varying genome size

The (non-LTR) LINE and Ty3-gypsy-type LTR retrotransposon populations of three Vicia species that differ in genome size (Vicia faba, Vicia melanops and Vicia sativa) have been characterised. In each species the LINE retrotransposons comprise a complex, very heterogeneous set of sequences, while the Ty3-gypsy elements are much more homogeneous. Copy numbers of all three retrotransposon groups (Ty1-copia, Ty3-gypsy and LINE) in these species have been estimated by random genomic sequencing and Southern hybridisation analysis. The Ty3-gypsy elements are extremely numerous in all species, accounting for 18–35% of their genomes. The Ty1-copia group elements are somewhat less abundant and LINE elements are present in still lower amounts. Collectively, 20–45% of the genomes of these three Vicia species are comprised of retrotransposons. These data show that the three retrotransposon groups have proliferated to different extents in members of the Vicia genus and high proliferation has been associated with homogenisation of the retrotransposon population.Electronic Supplementary Material Supplementary material is available for this article at .