Mapping and analysis of the LINE and SINE type of repetitive elements in rice

Non-LTR retrotransposons comprise significant portion of the plants genome. Their complete characterization is thus necessary if the sequenced genome is to be annotated correctly. The long and short interspersed nucleotide repetitive elements (LINE and SINE) may be responsible for alteration in the expression mechanism of neighboring genes, the complete identification of these elements in the rice genome is essential in order studying their putative functional interactions with the plant genes and its role in genome composition. The main emphasis of this work is to assemble a comprehensive dataset of nonLTR (LINEs and SINEs) and the map of completely inserted LINEs and SINE type of retroelement by both intact ends (3' and 5' ends). The assembled information and work may help for further research in this direction.     

Short interspersed nuclear elements (SINEs) are abundant in Solanaceae and have a family‐specific impact on gene structure and genome organization

Short interspersed nuclear elements (SINEs) are highly abundant non‐autonomous retrotransposons that are widespread in plants. They are short in size, non‐coding, show high sequence diversity, and are therefore mostly not or not correctly annotated in plant genome sequences. Hence, comparative studies on genomic SINE populations are rare. To explore the structural organization and impact of SINEs, we comparatively investigated the genome sequences of the Solanaceae species potato (Solanum tuberosum), tomato (Solanum lycopersicum), wild tomato (Solanum pennellii), and two pepper cultivars (Capsicum annuum). Based on 8.5 Gbp sequence data, we annotated 82 983 SINE copies belonging to 10 families and subfamilies on a base pair level. Solanaceae SINEs are dispersed over all chromosomes with enrichments in distal regions. Depending on the genome assemblies and gene predictions, 30% of all SINE copies are associated with genes, particularly frequent in introns and untranslated regions (UTRs). The close association with genes is family specific. More than 10% of all genes annotated in the Solanaceae species investigated contain at least one SINE insertion, and we found genes harbouring up to 16 SINE copies. We demonstrate the involvement of SINEs in gene and genome evolution including the donation of splice sites, start and stop codons and exons to genes, enlargement of introns and UTRs, generation of tandem‐like duplications and transduction of adjacent sequence regions.     

A non-LTR retroelement extinction in Spermophilus tridecemlineatus

The typical mammalian genome is dominated by two types of transposable elements (TEs), the autonomous and non-autonomous non-LTR retrotransposons, i.e. LINEs and SINEs, and with few exceptions there is a sole active LINE family (L1). During an ongoing investigation of TEs in rodents we determined that overall transposon activity has been steadily declining in Spermophilus tridecemlineatus. More specifically, the typically ubiquitous L1 activity of mammals has decreased drastically within the last 26MY. Indeed, only three L1 insertions with intact ORF1 sequences were readily identifiable and no intact ORF2 sequences were identified. The last L1 and SINE insertions date to ~5.3MYA and 4MYA, respectively. Based on our inability to computationally identify recently inserted L1 elements we suggest that S. tridecemlineatus is experiencing a quiescence or extinction of non-LTR retrotransposon activity. Such a finding represents only the fourth instance of a loss of non-LTR retrotransposon activity identified in mammals and, as such, represents an important additional data point to guide our understanding of LINE dynamics in eutherians.     

Evolutionary applications of MIRs and SINEs

It is believed that short interspersed elements (SINEs) are irreversibly inserted into genomes. We use this concept to try to deduce the evolution of whales using sequence and hybridization studies. The observation that microsatellites are associated with SINEs lead us to screen sequences surrounding cetacean microsatellites for artiodactyl-derived SINEs. Two sequences that were thought to be cetacean SINEs and the bovine SINE were aligned for comparison to sequences flanking microsatellites from ungulates. The bovine SINE was observed only in ruminants while CetSINE1 and 2 were found in mammals. Hybridization studies using these three SINEs revealed that CetSINE1 was found in all ungulates and cetaceans with the strongest hybridization signal observed in the hippopotamus and beluga; CetSINE2 hybridized to all ungulate suborders, while the bovine SINE was only observed in Ruminantia. It is proposed that these putative SINEs are not 'generic' SINEs but mammalian-wide interspersed repeats (MIRs). Caution is urged: what initially appears to be a SINE may instead be a MIR and have reduced evolutionary resolving power.     

The conserved 3′ Angio‐domain defines a superfamily of short interspersed nuclear elements (SINEs) in higher plants

Repetitive sequences are ubiquitous components of eukaryotic genomes affecting genome size and evolution as well as gene regulation. Among them, short interspersed nuclear elements (SINEs) are non‐coding retrotransposons usually shorter than 1000 bp. They contain only few short conserved structural motifs, in particular an internal promoter derived from cellular RNAs and a mostly AT‐rich 3′ tail, whereas the remaining regions are highly variable. SINEs emerge and vanish during evolution, and often diversify into numerous families and subfamilies that are usually specific for only a limited number of species. In contrast, at the 3′ end of multiple plant SINEs we detected the highly conserved ‘Angio‐domain’. This 37 bp segment defines the Angio‐SINE superfamily, which encompasses 24 plant SINE families widely distributed across 13 orders within the plant kingdom. We retrieved 28 433 full‐length Angio‐SINE copies from genome assemblies of 46 plant species, frequently located in genes. Compensatory mutations in and adjacent to the Angio‐domain imply selective restraints maintaining its RNA structure. Angio‐SINE families share segmental sequence similarities, indicating a modular evolution with strong Angio‐domain preservation. We suggest that the conserved domain contributes to the evolutionary success of Angio‐SINEs through either structural interactions between SINE RNA and proteins increasing their transpositional efficiency, or by enhancing their accumulation in genes.     

SINEs: Short interspersed repeated elements of the eukaryotic genome

Much of the eukaryotic genome is composed of a variety of repetitive sequences. Amongst these, there are two kinds of retroposons (sequence elements derived from nonviral cellular RNA): SINEs (short interspersed elements) and LINEs (long interspersed elements). Amplification of SINEs occurs in a single germ cell, and the members of SINEs spread and become fixed in populations through genetic drift. SINEs can be regarded as phylogenetic landmarks: they are specific to one species, a few species, a genus or in some cases a family, indicating a specific time of amplification during evolution. Recent studies concerning the structure and origin of many SINEs revealed that retroposons are more widespread in animal genomes than was previously thought.     

Isolation and characterization of active LINE and SINEs from the eel

Long interspersed elements (LINEs) and short interspersed elements (SINEs) are retrotransposons. These elements can mobilize by the "copy-and-paste" mechanism, in which their own RNA is reverse-transcribed into complementary DNA (cDNA). LINEs and SINEs not only are components of eukaryotic genomes but also drivers of genomic evolution. Thus, studies of the amplification mechanism of LINEs and SINEs are important for understanding eukaryotic genome evolution. Here we report the characterization of one LINE family (UnaL2) and two SINE families (UnaSINE1 and UnaSINE2) from the eel (Anguilla japonica) genome. UnaL2 is approximately 3.6 kilobases (kb) and encodes only one open reading frame (ORF). UnaL2 belongs to the stringent type--thought to be a major group of LINEs--and can mobilize in HeLa cells. We also show that UnaL2 and the two UnaSINEs have similar 3' tails, and that both UnaSINE1 and UnaSINE2 can be mobilized by UnaL2 in HeLa cells. These elements are thus useful for delineating the amplification mechanism of stringent type LINEs as well as that of SINEs.     

Analysis of major repetitive DNA sequences in the dog (Canis familiaris) genome

A systematic screening and analysis of repeated DNA sequences from a dog genomic library composed of small DNA inserts enabled us to characterize abundant canine repetitive DNA families. Four main families were identified: i) a group of highly repeated tRNA-derived short interspersed repetitive DNA elements (tRNA-SINEs); ii) another type of SINE-like element that was mainly found inserted into long interspersed repetitive elements (LINEs); iii) LINEs of the L1 type; and iv) satellite or satellite-like DNA. Surprisingly, no SINEs derived from 7SL RNA were found in the dog genome. These data should help in the analysis of canine DNA sequences and in the design of canine genome mapping reagents. Received: 4 November 1998 / Accepted: 2 February 1999     

植物基因组中的非LTR反转录转座子SINEs和LINEs

反转录转座子是基因组进化的推动者之一。分为LTR和非LTR两种类型。前者是真核基因组的主要组分,结构和转座方式与逆转录病毒类似。后者是最初发现于动物基因组新近发现在植物基因组中也广泛存在的新型重复序列,包括LINEs(long interspersed nuclear elements)和SINEs(short interspersed nuclear elements)两个亚型。它们大多因自身或受宿主基因组的调控而失去转座活性。其转座机理目前还不十分清楚,推测LINEs可以自主转座,SINEs依赖其他转座子被动转座。种系分析认为LINEs可能是最古老的反转录转座子,SINEs的起源未知。文章对以上内容进行了归纳和讨论。     

Common evolutionary trends for SINE RNA structures

Short interspersed elements (SINEs) and long interspersed elements (LINEs) are transposable elements in eukaryotic genomes that mobilize through an RNA intermediate. Understanding their evolution is important because of their impact on the host genome. Most eukaryotic SINEs are ancestrally related to tRNA genes, although the typical tRNA cloverleaf structure is not apparent for most SINE consensus RNAs. Using a cladistic method where RNA structural components were coded as polarized and ordered multistate characters, we showed that related structural motifs are present in most SINE RNAs from mammals, fishes and plants, suggesting common selective constraints imposed at the SINE RNA structural level. Based on these results, we propose a general multistep model for the evolution of tRNA-related SINEs in eukaryotes.     

Exceptional LINE Density at V1R Loci: The Lyon Repeat Hypothesis Revisited on Autosomes

The mammalian olfactory system utilizes three large receptor families: the olfactory receptors (ORs) of the main nose and the vomeronasal type-1 and type-2 receptor genes (V1Rs and V2Rs) of the vomeronasal organ. We find that these loci are among the most long interspersed nuclear element (LINE)-dense regions of mammalian genomes. We investigate two evolutionary models to account for this cohabitation. First, we investigate an adaptive selection model, in which LINEs have contributed to expansions of mouse V1R repertoires. We find that even evolutionarily stable V1R loci are exceptionally LINE-rich compared to other genome loci, including loci containing other large gene clusters. Also, a more detailed analysis of specific V1R duplications does not reveal LINE patterns predicted by common LINE-mediated duplication mechanisms. Next, we investigate neutral models, in which LINEs were tolerated by, but not advantageous for, surrounding V1R genes. We find that V1R loci are exceptionally LINE-rich compared to other regions of similar AT base composition, and that duplicated V1R gene blocks are generally depleted of LINE elements, suggesting that these loci did not become densely populated with LINEs simply as a consequence of targeted integration or passive multiplication along with the genes. Finally, we show that individual LINE repeats of a given age at V1R, V2R, and OR loci exhibit a significantly longer average length than at other autosomal loci, suggesting a reduced tendency for these LINEs to be disrupted. We speculate that LINEs at V1R, V2R, and OR loci might be selectively retained because they contribute to allelic regulation of these three gene families. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

RetroPred: A tool for prediction, classification and extraction of non-LTR retrotransposons (LINEs & SINEs) from the genome by integrating PALS, PILER, MEME and ANN

The problem of predicting non-long terminal repeats (LTR) like long interspersed nuclear elements (LINEs) and short interspersed nuclear elements (SINEs) from the DNA sequence is still an open problem in bioinformatics. To elevate the quality of annotations of LINES and SINEs an automated tool "RetroPred" was developed. The pipeline allowed rapid and thorough annotation of non-LTR retrotransposons. The non-LTR retrotransposable elements were initially predicted by Pairwise Aligner for Long Sequences (PALS) and Parsimonious Inference of a Library of Elementary Repeats (PILER). Predicted non-LTR elements were automatically classified into LINEs and SINEs using ANN based on the position specific probability matrix (PSPM) generated by Multiple EM for Motif Elicitation (MEME). The ANN model revealed a superior model (accuracy = 78.79 +/- 6.86 %, Q(pred) = 74.734 +/- 17.08 %, sensitivity = 84.48 +/- 6.73 %, specificity = 77.13 +/- 13.39 %) using four-fold cross validation. As proof of principle, we have thoroughly annotated the location of LINEs and SINEs in rice and Arabidopsis genome using the tool and is proved to be very useful with good accuracy. Our tool is accessible at http://www.juit.ac.in/RepeatPred/home.html.