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.     

Long interspersed repeated DNA (LINE) causes polymorphism at the rat insulin 1 locus.

The insulin 1, but not the insulin 2, locus is polymorphic (i.e., exhibits allelic variation) in rats. Restriction enzyme analysis and hybridization studies showed that the polymorphic region is 2.2 kilobases upstream of the insulin 1 coding region and is due to the presence or absence of an approximately 2.7-kilobase repeated DNA element. DNA sequence determination showed that this DNA element is a member of a long interspersed repeated DNA family (LINE) that is highly repeated (greater than 50,000 copies) and highly transcribed in the rat. Although the presence or absence of LINE sequences at the insulin 1 locus occurs in both the homozygous and heterozygous states, LINE-containing insulin 1 alleles are more prevalent in the rat population than are alleles without LINEs. Restriction enzyme analysis of the LINE-containing alleles indicated that at least two versions of the LINE sequence may be present at the insulin 1 locus in different rats. Either repeated transposition of LINE sequences or gene conversion between the resident insulin 1 LINE and other sequences in the genome are possible explanations for this.     

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.     

Two LINE 1 repeats in rat

One LINE 1 repeat has been located 661 bp downstream from the last albumin exon and another approx. 10 kbp downstream from the last alpha-fetoprotein exon in the rat genomic DNA. The LINE 1 repeat following the albumin gene is truncated at its 5' end and is 1204 nucleotides long. The 5' end of the longer repeat downstream from the alpha-fetoprotein gene has not been determined. The two repeats have 95% homology with each other, with the exception of a short diverse 3' end sequence just preceding the putative polyadenylation signal.     

SINEs and LINEs: symbionts of eukaryotic genomes with a common tail

Many SINEs and LINEs have been characterized to date, and examples of the SINE and LINE pair that have the same 3' end sequence have also increased. We report the phylogenetic relationships of nearly all known LINEs from which SINEs are derived, including a new example of a SINE/LINE pair identified in the salmon genome. We also use several biological examples to discuss the impact and significance of SINEs and LINEs in the evolution of vertebrate genomes.     

Utilization of the IR hybrid dysgenesis system in Drosophila to test in vivo mobilization of synthetic SINEs sharing 3' homology with the I factor

The current model of short interspersed nuclear element (SINE) mobility suggests that these non-coding retroposons are able to recruit for their own benefits the enzymatic machinery encoded by autonomous long interspersed nuclear elements (LINEs). The recent characterization of potential SINE-LINE partner pairs that share common 3' end sequences concurs with this model and has led to a potent picture of tRNA-derived SINEs consisting of a tripartite functional structure (Mol. Cell. Biol. 16 (1996) 3756; Mol. Biol. Evol. 16 (1999) 1238; Proc. Natl. Acad. Sci. USA 96 (1999) 2869). This structure consist of a 5' polIII tRNA-related promoter region, a central conserved domain and a variable 3' region with homology to the 3' end of LINEs, believed to be essential to direct recognition by the LINE proteins. To test this model in vivo, we have designed synthetic SINEs possessing this 'canonical' structure, including 3' homology to the 3' UTR of the LINE I factor from Drosophila. These synthetic elements were introduced in a Drosophila reactive strain, and SINE retroposition was assessed following dysgenic crosses that are known to induce high levels of I factor germinal transposition. In the progeny from the dysgenic crosses 3400-4000 flies were analyzed but no retroposed copy of the chimeric SINEs was detected, indicating that what is assumed to be a typical SINE structure is not sufficient per se to allow efficient trans-mobilization of our synthetic SINEs by an actively amplifying partner LINE. Alternatively, the apparent absence of natural fly SINEs may underline intrinsic properties of fly biology that are incompatible with the genesis and/or propagation of SINE-like elements.     

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.     

Functional splice sites in a zebrafish LINE and their influence on zebrafish gene expression

Long interspersed elements (LINEs) are transposable elements that exist in many kinds of eukaryotic genomes, where they have a large effect on genome evolution. There are several thousands to hundreds of thousands of LINE copies in each eukaryotic genome. LINE elements are amplified by a mechanism called retrotransposition, in which a LINE-encoded protein reverse transcribes (copies) its own RNA. We previously isolated two retrotransposition-competent LINEs, ZfL2-1 and ZfL2-2, from zebrafish. Although it has generally been thought that LINEs do not have ‘introns’ (because the LINE RNA is used as the template during retrotransposition), we now show that these two LINEs contain multiple putative functional splice sites. We further show that at least one pair of these splice sites is actually functional in zebrafish cells. Moreover, some of these splice sites are coupled with the splicing signal of a host endogenous gene, thereby generating a new chimeric spliced mRNA variant for this gene. Our results suggest the possible role of these LINE splice sites in modulating retrotransposition and host gene expression.