Isolation and Characterization of Active LINE and SINEs from the Eel

Characterization of an active LINE-1 in the naked mole-rat genome

Naked mole-rats (NMRs, Heterocephalus glaber) are the longest-living rodent species. A reason for their long lifespan is pronounced cancer resistance. Therefore, researchers believe that NMRs have unknown secrets of cancer resistance and seek to find them. Here, to reveal the secrets, we noticed a retrotransposon, long interspersed nuclear element 1 (L1). L1s can amplify themselves and are considered endogenous oncogenic mutagens. Since the NMR genome contains fewer L1-derived sequences than other mammalian genomes, we reasoned that the retrotransposition activity of L1s in the NMR genome is lower than those in other mammalian genomes. In this study, we successfully cloned an intact L1 from the NMR genome and named it NMR-L1. An L1 retrotransposition assay using the NMR-L1 reporter revealed that NMR-L1 was active retrotransposon, but its activity was lower than that of human and mouse L1s. Despite lower retrotrasposition activity, NMR-L1 was still capable of inducing cell senescence, a tumor-protective system. NMR-L1 required the 3′ untranslated region (UTR) for retrotransposition, suggesting that NMR-L1 is a stringent-type of L1. We also confirmed the 5′ UTR promoter activity of NMR-L1. Finally, we identified the G-quadruplex structure of the 3′ UTR, which modulated the retrotransposition activity of NMR-L1. Taken together, the data indicate that NMR-L1 retrotranspose less efficiently, which may contribute to the cancer resistance of NMRs.

SINE Retrotransposon variation drives Ecotypic disparity in natural populations of Coilia nasus

Background

SINEs are a type of nonautonomous retrotransposon that can transpose from one site to be integrated elsewhere in an organism genome. SINE insertion can give rise to genetic variants and regulate gene expression, allowing organisms to acquire new adaptive capacity. Studies on this subject have focused on the impacts of SINEs on genes. However, ecological disparities in fish have not yet been explained by SINEs.

Results

New SINEs were isolated from Coilia nasus, which has two ecotypes—migratory and resident—that differ in their spawning and migration behaviors. The SINEs possess two structures that resemble a tRNA gene and a LINE retrotransposon tail. Comparison of olfactory tissue transcriptomes, intact SINE transcript copies were detected in only the migratory fish at the initial retrotransposition stage. The SINE DNA copy numbers were higher in the resident type than in the migratory type, while the frequency of SINE insertion was higher in the migratory type than in the resident type. Furthermore, SINE insertions can lead to new repeats of short DNA fragments in the genome, along with target site duplications. SINEs in the resident type have undergone excision via a mechanism in which predicted cleavage sites are formed by mutations, resulting in gaps that are then filled by microsatellites via microhomology-induced replication.

Conclusions

Notably, SINEs in the resident type have undergone strong natural selection, causing genomic heteroplasmy and driving ecological diversity of C. nasus. Our results reveal possible evolutionary mechanisms underlying the ecological diversity at the interface between SINE mobilization and organism defense.

Unique structure (construction and configuration) and evolution of the array of small serum protein genes of Protobothrops flavoviridis snake

The nucleotide sequence of Protobothrops flavoviridis (Pf) 30534 bp genome segment which contains genes encoding small serum proteins (SSPs) was deciphered. The genome segment contained five SSP genes (PfSSPs), PfSSP-4, PfSSP-5, PfSSP-1, PfSSP-2, and PfSSP-3 in this order and had characteristic configuration and constructions of the particular nucleotide sequences inserted. Comparison between the configurations of the inserted chicken repeat-1 (CR1) fragments of P. flavoviridis and Ophiophagus hannah (Oh) showed that the nucleotide segment encompassing from PfSSP-1 to PfSSP-2 was inverted. The inactive form of PfSSP-1, named PfSSP-1δ(Ψ), found in the intergenic region (I-Reg) between PfSSP-5 and PfSSP-1 had also been destroyed by insertions of the plural long interspersed nuclear elements (LINEs) and DNA transposons. The L2 LINE inserted into the third intron or the particular repetitive sequences inserted into the second intron structurally divided five PfSSPs into two subgroups, the Long SSP subgroup of PfSSP-1, PfSSP-2 and PfSSP-5 or the Short SSP subgroup of PfSSP-3 and PfSSP-4. The mathematical analysis also showed that PfSSPs of the Long SSP subgroup evolved alternately in an accelerated and neutral manner, whereas those of the Short SSP subgroup evolved in an accelerated manner. Moreover, the ortholog analysis of SSPs of various snakes showed that the evolutionary emerging order of SSPs was as follows: SSP-5, SSP-4, SSP-2, SSP-1, and SSP-3. The unique interpretation about accelerated evolution and the novel idea that the transposable elements such as LINEs and DNA transposons are involved in maintaining the host genome besides its own transposition natures were proposed.

Distinct RNA recognition mechanisms in closely related LINEs from zebrafish

Long interspersed nuclear element (LINE) is known to be transposed by the reverse transcription using its RNA transcript. Recognition of the 3' stem-loop of LINE RNA by its reverse transcriptase (RT) is an important step of the retrotransposition. We focused on the RNA recognition by RT from two related LINEs, ZfL2-1 and ZfL2-2, from zebrafish. Previous study showed that RT from ZfL2-2 recognizes a single residue in the specific position of the RNA loop. In the present study, it was found that RT from ZfL2-1 recognizes the inserted stem-loop of ZfL2-1 RNA. Thus, these related RTs recognize the same region of LINE RNAs but discriminate them by different mechanism.

Retrotransposon methylation and activity in wild fish (A. anguilla): A matter of size

Understanding how organisms cope with global change is a major question in many fields of biology. Mainly, understanding the molecular mechanisms supporting rapid phenotypic changes of organisms in response to stress and linking stress-induced molecular events to adaptive or adverse outcomes at the individual or population levels remain a major challenge in evolutionary biology, ecology or ecotoxicology. In this view, the present study aimed to test (i) whether environmental factors, especially pollutants, can trigger changes in the activity of retrotransposons (RTs) in wild fish and (ii) if changes in RT DNA methylation or transcription levels can be linked to modifications at the individual level. RTs are genetic elements that have the ability to replicate and integrate elsewhere in the genome. Although RTs are mainly quiescent during normal development, they can be experimentally activated under life-threatening conditions, affecting the fitness of their host. Wild eels were collected in four sampling sites presenting differing levels of contamination. The methylation level and the transcriptional activity of two RTs and two genes involved in development and cell differentiation were analyzed in fish liver in addition to the determination of fish contaminants levels and diverse growth and morphometric indices. An up-regulation of RTs associated to lower methylation levels and lower growth indices were observed in highly contaminated fish. Our results suggest that RT activation in fish experiencing stress conditions could have both detrimental and beneficial implications, affecting fish growth but promoting resistance to environmental stressors such as pollutants.

Solution structure of a reverse transcriptase recognition site of a LINE RNA from zebrafish

Long interspersed nuclear element (LINE) is known to be transposed by reverse transcription using its RNA transcript. Recognition of the 3' stem-loop of LINE RNA by its reverse transcriptase (RT) is an important step of the retrotransposition. Our previous study revealed that the second G residue (G8) in the GGAUA loop of a 17mer LINE RNA from eel, UnaL2-17, is recognized by its RT and the U residue (U10) in the same loop is required to maintain the loop structure (Baba S, Kajikawa M, Okada N, Kawai G. Solution structure of an RNA stem-loop derived from the 3' conserved region of eel LINE UnaL2. RNA 2004;10:1380-1387). ZfL2-2, a LINE from zebrafish, has the same 3' stem-loop with UnaL2 and ZfL2-1 has similar but distinct 3' stem-loop with an insertion which can form an additional stem-loop. Here, we determined the solution structure of the 34mer RT recognition site of the LINE RNA (ZfL2-1-34). It was found that ZfL2-1-34 forms a hairpin with an internal loop, the tertiary structure of which is superimposed with that of ZfL2-2. It is noted that A10 and the inserted stem-loop, starting with A12, in ZfL2-1-34 located at the positions corresponding to those of G8 and U10, respectively, in UnaL2-17. These results strongly suggest that the two LINEs share the similar recognition mechanism and the A10 in ZfL2-1-34 is the determinant recognized by its RT.

MetaSINEs: Broad Distribution of a Novel SINE Superfamily in Animals

SINEs (short interspersed elements) are transposable elements that typically originate independently in each taxonomic clade (order/family). However, some SINE families share a highly similar central sequence and are thus categorized as a SINE superfamily. Although only four SINE superfamilies (CORE-SINEs, V-SINEs, DeuSINEs, and Ceph-SINEs) have been reported so far, it is expected that new SINE superfamilies would be discovered by deep exploration of new SINEs in metazoan genomes. Here we describe 15 SINEs, among which 13 are novel, that have a similar 66-bp central region and therefore constitute a new SINE superfamily, MetaSINEs. MetaSINEs are distributed from fish to cnidarians, suggesting their common evolutionary origin at least 640 Ma. Because the 3′ tails of MetaSINEs are variable, these SINEs most likely survived by changing their partner long interspersed elements for retrotransposition during evolution. Furthermore, we examined the presence of members of other SINE superfamilies in bivalve genomes and characterized eight new SINEs belonging to the CORE-SINEs, V-SINEs, and DeuSINEs, in addition to the MetaSINEs. The broad distribution of bivalve SINEs suggests that at least three SINEs originated in the common ancestor of Bivalvia. Our comparative analysis of the central domains of the SINEs revealed that, in each superfamily, only a restricted region is shared among all of its members. Because the functions of the central domains of the SINE superfamilies remain unknown, such structural information of SINE superfamilies will be useful for future experimental and comparative analyses to reveal why they have been retained in metazoan genomes during evolution.

Mechanism by which a LINE protein recognizes its 3' tail RNA

LINEs mobilize their own copies via retrotransposition. LINEs can be divided into two types. One is a stringent type, which constitutes a majority of LINEs. The other is a relaxed type. To elucidate the molecular mechanism of retrotransposition, we used here two different zebrafish LINEs belonging to the stringent type. By using retrotransposition assays, we demonstrated that proteins (ORF2) encoded by an individual LINE recognize the cognate 3′ tail sequence of the LINE RNA strictly. By conducting in vitro binding assays with a variety of ORF2 proteins, we demonstrated that the region between the endonuclease and reverse transcriptase domains in ORF2 is the site at which the proteins bind the stem-loop structure of the 3′ tail RNA, showing that the strict recognition of the stem-loop structure by the cognate ORF2 protein is an important step in retrotransposition. This recognition can be bipartite, involving the general recognition of the stem by cTBR (conserved tail-binding region) of ORF2 and the specific recognition of the loop by vTBR (variable tail-binding region). This is the first report that clearly characterized the RNA-binding region in ORF2, providing the generality for the recognition mechanism of the RNA tail by the ORF2 protein encoded by LINEs.

RNA-Mediated Gene Duplication and Retroposons: Retrogenes, LINEs, SINEs, and Sequence Specificity

A substantial number of “retrogenes” that are derived from the mRNA of various intron-containing genes have been reported. A class of mammalian retroposons, long interspersed element-1 (LINE1, L1), has been shown to be involved in the reverse transcription of retrogenes (or processed pseudogenes) and non-autonomous short interspersed elements (SINEs). The 3′-end sequences of various SINEs originated from a corresponding LINE. As the 3′-untranslated regions of several LINEs are essential for retroposition, these LINEs presumably require “stringent” recognition of the 3′-end sequence of the RNA template. However, the 3′-ends of mammalian L1s do not exhibit any similarity to SINEs, except for the presence of 3′-poly(A) repeats. Since the 3′-poly(A) repeats of L1 and Alu SINE are critical for their retroposition, L1 probably recognizes the poly(A) repeats, thereby mobilizing not only Alu SINE but also cytosolic mRNA. Many flowering plants only harbor L1-clade LINEs and a significant number of SINEs with poly(A) repeats, but no homology to the LINEs. Moreover, processed pseudogenes have also been found in flowering plants. I propose that the ancestral L1-clade LINE in the common ancestor of green plants may have recognized a specific RNA template, with stringent recognition then becoming relaxed during the course of plant evolution.

Low dependency of retrotransposition on the ORF1 protein of the zebrafish LINE, ZfL2-1

The zebrafish long interspersed element (LINE), ZfL2-1, which belongs to the L2 clade, contains two open reading frames, ORF1 and ORF2. ORF1 encodes a protein containing a coiled-coil motif and an esterase domain, whereas ORF2 encodes a protein containing an endonuclease and a reverse transcriptase domain. To elucidate the functional significance of ORF1 in retrotransposition, we constructed many variants of ZfL2-1 and examined their retrotransposition ability. We concluded: 1) the ORF1 protein is not essential for ZfL2-1 retrotransposition in cultured cells; 2) the translation of ORF1 is required for the translation of ORF2; and 3) ORF2 translation probably occurs via suppression of the ORF1 stop codon, the efficiency of which is influenced by the context of the sequence juxtaposed to the 3' side of the stop codon. These results offer a new perspective on the evolution of the L2 clade LINEs.

BmSE, a SINE family with 3' ends of (ATTT) repeats in domesticated silkworm (Bombyx mori)

Short interspersed elements (SINEs), which are mainly composed of Bm1, are abundant in the domesticated silkworm. A 294 bp novel SINE family, designated as BmSE, was identified by mining the database of the complete Bombyx mori genome. A representational BmSE element is flanked by an 11 bp target site duplication sequence posterior poly (A) at the 3' end and has the sequence motifs of an internal promoter of RNA polymerase III, which are similar to that of Bm1. The repetitive elements of BmSE are widely distributed in all 28 chromosomes of the genome and share the common (ATTT) repeats at the ends. GC-content distribution shows that BmSE tends to accumulate preferably in the region of higher AT content than that of Bm1. A high proportion of the BmSEs are mapped to the coding sequence introns, whereas several elements are also present in the UTR of some transcripts, indicating that BmSEs are indeed exonized with UTRs. Of the 615 identified structural variants (SVs) of BmSE among the 40 domesticated and wild silkworms, only 230 SVs were found in the domesticated silkworms, indicating that many recent SV events of BmSE occurred after domestication, which was probably due to its mobilization. Our analysis might assist in developing BmSE as a potential marker and in understanding the evolutionary roles of SINEs in the domesticated silkworm.

Polypteridae (Actinopterygii: Cladistia) and DANA-SINEs insertions

SINE sequences are interspersed throughout virtually all eukaryotic genomes and greatly outnumber the other repetitive elements. These sequences are of increasing interest for phylogenetic studies because of their diagnostic power for establishing common ancestry among taxa, once properly characterized. We identified and characterized a peculiar family of composite tRNA-derived short interspersed SINEs, DANA-SINEs, associated with mutational activities in Danio rerio, in a group of species belonging to one of the most basal bony fish families, the Polypteridae, in order to investigate their own inner specific phylogenetic relationships. DANA sequences were identified, sequenced and then localized, by means of fluorescent in situ hybridization (FISH), in six Polypteridae species (Polypterus delhezi, P. ornatipinnis, P. palmas, P. buettikoferi P. senegalus and Erpetoichthys calabaricus) After cloning, the sequences obtained were aligned for phylogenetic analysis, comparing them with three Dipnoan lungfish species (Protopterus annectens, P. aethiopicus, Lepidosiren paradoxa), and Lethenteron reissneri (Petromyzontidae)was used as outgroup. The obtained overlapping MP, ML and NJ tree clustered together the species belonging to the two taxonomically different Osteichthyans groups: the Polypteridae, by one side, and the Protopteridae by the other, with the monotypic genus Erpetoichthys more distantly related to the Polypterus genus comprising three distinct groups: P. palmas and P. buettikoferi, P. delhezi and P. ornatipinnis and P. senegalus. In situ hybridization with DANA probes marked along the whole chromosome arms in the metaphases of all the Polypteridae species examined.

Unique structural characteristics and evolution of a cluster of venom phospholipase A2 isozyme genes of Protobothrops flavoviridis snake

Protobothrops flavoviridis (Crotalinae) venom gland phospholipase A(2) (PLA(2)) isozyme genes have evolved in an accelerated manner to acquire diverse physiological activities in their products. For elucidation of the multiplication mechanism of PLA(2) genes, a 25,026 bp genome segment harboring five PLA(2) isozyme genes was obtained from Amami-Oshima P. flavoviridis liver and sequenced. The gene PfPLA 2 encoded [Lys(49)]PLA(2) called BPII, the gene PfPLA 4 neurotoxic [Asp(49)]PLA(2) called PLA-N, the gene PfPLA 5 basic [Asp(49)]PLA(2) called PLA-B, and PfPLA 1(psi) and PfPLA 3(psi) were the inactivated genes. The 5' truncated reverse transcriptase (RT) elements, whose intact forms constitute long interspersed nuclear elements (LINEs), were found in close proximity to the 3' end of PLA(2) genes and named PLA(2) gene-coupled RT fragments (PcRTFs). The facts that PcRTFs have the stem-loop and repetitive sequence in the 3' untranslated region (UTR) which is characteristic of CR1 LINEs suggest that PcRTFs are the debris of P. flavoviridis ancestral CR1 LINEs, denoted as PfCR1s. Since the associated pairs of PLA(2) genes and PcRTFs are arranged in tandem in the 25,026 bp segment, it is thought that an ancestral PLA(2) gene-PfCR1 unit (PfPLA-PfCR1) which was produced by retrotransposition of PfCR1 by itself to the 3' end of PLA(2) gene duplicated several times to form a multimer of PfPLA-PfCR1, a cluster of PLA(2) genes, in the period after Crotalinae and Viperinae snakes branched off. Recombinational hot spot of a 37bp segment, named Scomb, was found in the region 548 bp upstream from the TATA box of PLA(2) genes. Thus, it could be assumed that multiplication of PfPLA-PfCR1 occurred by unequal crossing over of the segment, -Scomb-PfPLA-PfCR1-Scomb-. The PfCR1 moieties were afterward disrupted in the 5' portion to PcRTFs. The detection of two types of PcRTFs different in length which were produced by elimination of two definitive sequences in PfCR1 moiety possibly by gene conversion clearly supports such process but not multiplication of the PLA(2) gene-PcRTF unit.

Unique functions of repetitive transcriptomes

Repetitive sequences occupy a huge fraction of essentially every eukaryotic genome. Repetitive sequences cover more than 50% of mammalian genomic DNAs, whereas gene exons and protein-coding sequences occupy only ~3% and 1%, respectively. Numerous genomic repeats include genes themselves. They generally encode "selfish" proteins necessary for the proliferation of transposable elements (TEs) in the host genome. The major part of evolutionary "older" TEs accumulated mutations over time and fails to encode functional proteins. However, repeats have important functions also on the RNA level. Repetitive transcripts may serve as multifunctional RNAs by participating in the antisense regulation of gene activity and by competing with the host-encoded transcripts for cellular factors. In addition, genomic repeats include regulatory sequences like promoters, enhancers, splice sites, polyadenylation signals, and insulators, which actively reshape cellular transcriptomes. TE expression is tightly controlled by the host cells, and some mechanisms of this regulation were recently decoded. Finally, capacity of TEs to proliferate in the host genome led to the development of multiple biotechnological applications.

Bead-probe complex capture a couple of SINE and LINE family from genomes of two closely related species of East Asian cyprinid directly using magnetic separation

Background

Short and long interspersed elements (SINEs and LINEs, respectively), two types of retroposons, are active in shaping the architecture of genomes and powerful tools for studies of phylogeny and population biology. Here we developed special protocol to apply biotin-streptavidin bead system into isolation of interspersed repeated sequences rapidly and efficiently, in which SINEs and LINEs were captured directly from digested genomic DNA by hybridization to bead-probe complex in solution instead of traditional strategy including genomic library construction and screening.

Results

A new couple of SINEs and LINEs that shared an almost identical 3'tail was isolated and characterized in silver carp and bighead carp of two closely related species. These SINEs (34 members), designated HAmo SINE family, were little divergent in sequence and flanked by obvious TSD indicated that HAmo SINE was very young family. The copy numbers of this family was estimated to 2 × 10⁵ and 1.7 × 10⁵ per haploid genome by Real-Time qPCR, respectively. The LINEs, identified as the homologs of LINE2 in other fishes, had a conserved primary sequence and secondary structures of the 3'tail region that was almost identical to that of HAmo SINE. These evidences suggest that HAmo SINEs are active and amplified recently utilizing the enzymatic machinery for retroposition of HAmoL2 through the recognition of higher-order structures of the conserved 42-tail region. We analyzed the possible structures of HAmo SINE that lead to successful amplification in genome and then deduced that HAmo SINE, SmaI SINE and FokI SINE that were similar in sequence each other, were probably generated independently and created by LINE family within the same lineage of a LINE phylogeny in the genomes of different hosts.

Conclusion

The presented results show the advantage of the novel method for retroposons isolation and a pair of young SINE family and its partner LINE family in two carp fishes, which strengthened the hypotheses containing the slippage model for initiation of reverse transcription, retropositional parasitism of SINEs on LINEs, the formation of the stem loop structure in 3'tail region of some SINEs and LINEs and the mechanism of template switching in generating new SINE family.

Target site analysis of RTE1_LA and its AfroSINE partner in the elephant genome

SINEs retrotranspose using their partner LINE's enzymatic machinery. It has recently been proposed that AfroSINEs ending with GGTTT 3' tandem repeats were mobilized by RTE elements ending with CAA 3' tandem repeats in the Afrotherian genome. Using sequences from the elephant genome, we show that AfroSINEs derive from RTE ending with GGTTT-like 3' tandem repeats, a subgroup of RTE1_LA that only reached low copy number, and confirm that they were most likely mobilized by RTE ending with CAA(n) tandem repeats (RTE1_LA-CAA(n)). This partnership is supported by sequence similarity between two regions of the elements, overlap in the timing of their activity, common features of their target site consensus that are not shared by other members of the RTE family, and their high copy number. Detailed analyses of pre-insertion loci reveal that like many other apurinic/apyrimidinic endonuclease encoding elements, RTE1_LA-CAA(n) shows loose target site specificity. In addition, the RTE1_LA-CAA(n) target site consensus shares several structural and primary sequence features with that of LINE1, suggesting that these two elements share close functional similarity in the target primed reverse transcription (TPRT) reaction. Interestingly, although globally similar, the target site consensus of AfroSINE(Anc) and RTE1_LA-CAA(n) differ in several aspects. These differences, not observed among all SINE/LINE pairs so far examined, are most likely due to the fact that AfroSINEs and RTE1_LA-CAA(n) are terminated by a different tandem repeat motif. We propose that these differences reflect constraints imposed by base pairing interactions between the mRNA 3' terminal tandem repeats and the target DNA at the onset of TPRT. So in addition to the endonuclease nicking preference, the mRNA of these elements appears to play an important role in integration site choice through a passive, post-nicking, selective process.

Novel SINE families from salmons validate Parahucho (Salmonidae) as a distinct genus and give evidence that SINEs can incorporate LINE-related 3'-tails of other SINEs

Short interspersed elements (SINEs) constitute a group of retroposons propagating in the genome via a mechanism of reverse transcription, in which they depend on the enzymatic machinery of long retroposons (LINEs). Over 70 SINE families have been described to date from the genomes of various eukaryotes. Here, we characterize two novel SINEs from salmons (Actinopterygii: Salmonoidei). The first family, termed SlmI, was shown to be widespread among all genera of the suborder. These SINEs have a tRNA(Leu)-related promoter region at their 5'-end, a unique central conserved domain with a subfamily-specific region, and an end with RSg-1-LINE-derived 3'-terminus preceding the A/T-rich tail. The same LINE-related segment is also shared by two other salmonid SINEs: HpaI and OS-SINE1. The structural peculiarities and overall sequence identity of the SlmI 3'-terminus suggest that it has been acquired from HpaI SINEs but not directly from the partner LINE. This region plays a crucial role in the process of retrotransposition of short interspersed elements, and the case of its SINE-to-SINE transmission is the first recorded to date. Possible scenarios and potential evolutionary implications of the observed interaction between short retroposons are discussed. Apart from the above, we found a copy of the SlmI SINE in the GenBank entry for the blood fluke, Schistosoma japonicum (Trematoda: Strigeiformes) -- a trematode causing one of the most important human helminth infections, with its genome known to host other groups of salmonoid retroposons. In the present article, we suggest our views with regard to possible ways in which such an intensive horizontal transfer of salmonoid retroposons to the schistosomal genome occurs. The second novel SINE family, termed SlmII, originates from one of the SlmI subfamilies, with which it shares the same tRNA-related region, central domain, and a part of RSg-1-derived segment, but has a different 3'-tail of unidentified origin. Its distribution among salmonids validates Parahucho (Japanese huchen) as a distinct monotypic genus.

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.

A new system for analyzing LINE retrotransposition in the chicken DT40 cell line widely used for reverse genetics

Long interspersed elements (LINEs) are autonomous transposable elements that proliferate via retrotransposition, which involves reverse transcription of LINE RNAs. It is anticipated that LINE retrotransposition requires both LINE-encoded proteins and host-encoded proteins. However, identification of the host factors, their roles, and the steps at which they act on retrotransposition are poorly understood because of the lack of an appropriate genetic system to study LINE retrotransposition in a series of mutant hosts. To construct such a genetic system, we applied the retrotransposition-indicative cassette method to DT40 cells, a chicken cell line for which a variety of isogenic mutants have been established by gene targeting. Because DT40 cells are non-adherent, we utilized a selective soft agarose medium to allow the formation of colonies of cells that had undergone LINE retrotransposition. Colony formation was completely dependent on the activities of the LINE-encoded proteins and on the presence of the essential 3' region of the LINE RNA. Moreover, the selected colonies indeed carried retrotransposed LINE copies in their chromosomes, with integration features similar to those of genomic (native) LINE copies. This method thus allows the authentic selection of LINE-retrotransposed cells and the approximate recapitulation of retrotransposition events that occur in nature. Therefore, the DT40 cell system established here provides a powerful tool for the elucidation of LINE retrotransposition pathways, the host factors involved, and their roles.

Solution structure and functional importance of a conserved RNA hairpin of eel LINE UnaL2

The eel long interspersed element (LINE) UnaL2 and its partner short interspersed element (SINE) share a conserved 3′ tail that is critical for their retrotransposition. The predicted secondary structure of the conserved 3′ tail of UnaL2 RNA contains a stem region with a putative internal loop. Deletion of the putative internal loop region abolishes UnaL2 mobilization, indicating that this putative internal loop is required for UnaL2 retrotransposition; the exact role of the putative internal loop in retrotransposition, however, has not been elucidated. To establish a structure-based foundation on which to address the issue of the putative internal loop function in retrotransposition, we used NMR to determine the solution structure of a 36 nt RNA derived from the 3′ conserved tail of UnaL2. The region forms a compact structure containing a single bulged cytidine and a U–U mismatch. The bulge and mismatch region have conformational flexibility and molecular dynamics simulation indicate that the entire stem of the 3′ conserved tail RNA can anisotropically fluctuate at the bulge and mismatch region. Our structural and mutational analyses suggest that stem flexibility contributes to UnaL2 function and that the bulged cytidine and the U–U mismatch are required for efficient retrotransposition.

Functional noncoding sequences derived from SINEs in the mammalian genome

Recent comparative analyses of mammalian sequences have revealed that a large number of nonprotein-coding genomic regions are under strong selective constraint. Here, we report that some of these loci have been derived from a newly defined family of ancient SINEs (short interspersed repetitive elements). This is a surprising result, as SINEs and other transposable elements are commonly thought to be genomic parasites. We named the ancient SINE family AmnSINE1, for Amniota SINE1, because we found it to be present in mammals as well as in birds, and some copies predate the mammalian-bird split 310 million years ago (Mya). AmnSINE1 has a chimeric structure of a 5S rRNA and a tRNA-derived SINE, and is related to five tRNA-derived SINE families that we characterized here in the coelacanth, dogfish shark, hagfish, and amphioxus genomes. All of the newly described SINE families have a common central domain that is also shared by zebrafish SINE3, and we collectively name them the DeuSINE (Deuterostomia SINE) superfamily. Notably, of the approximately 1000 still identifiable copies of AmnSINE1 in the human genome, 105 correspond to loci phylogenetically highly conserved among mammalian orthologs. The conservation is strongest over the central domain. Thus, AmnSINE1 appears to be the best example of a transposable element of which a significant fraction of the copies have acquired genomic functionality.

Sauria SINEs: Novel short interspersed retroposable elements that are widespread in reptile genomes

SINEs are short interspersed retrotransposable elements that invade new genomic sites. Their retrotransposition depends on reverse transcriptase and endonuclease activities encoded by partner LINEs (long interspersed elements). Recent genomic research has demonstrated that retroposons account for at least 40% of the human genome. Hitherto, more than 30 families of SINEs have been characterized in mammalian genomes, comprising approximately 4600 extant species; the distribution and extent of SINEs in reptilian genomes, however, are poorly documented. With more than 7400 species of lizards and snakes, Squamata constitutes the largest and most diverse group of living reptiles. We have discovered and characterized a novel SINE family, Sauria SINEs, whose members are widely distributed among genomes of lizards, snakes, and tuataras. Sauria SINEs comprise a 5' tRNA-related region, a tRNA-unrelated region, and a 3' tail region (containing short tandem repeats) derived from LINEs. We distinguished eight Sauria SINE subfamilies in genomes of four major squamate lineages and investigated their evolutionary relationships. Our data illustrate the overall efficacy of Sauria SINEs as novel retrotransposable markers for elucidation of squamate evolutionary history. We show that all Sauria SINEs share an identical 3' sequence with Bov-B LINEs and propose that they utilize the enzymatic machinery of Bov-B LINEs for their own retrotransposition. This finding, along with the ubiquity of Bov-B LINEs previously demonstrated in squamate genomes, suggests that these LINEs have been an active partner of Sauria SINEs since this SINE family was generated more than 200 million years ago.

Two families of non-LTR retrotransposons, Syrinx and Daphne, from the Darwinulid ostracod, Darwinula stevensoni

Two novel families of non-LTR retrotransposons, named Syrinx and Daphne, were cloned and characterized in a putative ancient asexual ostracod Darwinula stevensoni. Phylogenetic analysis reveals that Daphne is the founding member of a novel clade of non-LTR retroelements, which also contains retrotransposon families from the sea urchin and the silkworm and forms a sister clade to L2-like elements. The Syrinx family of non-LTR retrotransposons exhibits evidence of relatively recent activity, manifested in high levels of sequence similarity between individual copies and a three- to ten-fold excess of synonymous substitutions, which is indicative of purifying selection. The Daphne family may have very few copies with intact open reading frames, and exhibits neutral within-family ratio of non-synonymous to synonymous substitutions. It can additionally be characterized by formation of inverted truncated head-to-head structures. All of these features make recent activity less likely than in the Syrinx family. Our results are discussed in light of the evolutionary consequences of long-term asexuality in general and in D. stevensoni in particular.

Probing the secondary structure of salmon SmaI SINE RNA

SmaI is a short interspersed element (SINE) of the salmon genome, and is derived from tRNA(Lys). We probed the secondary structure of SmaI SINE RNA by enzymatic cleavage and found that the RNA structure comprises three separate domains. The 5'-terminal region (the 5' domain) forms a tRNA-like cloverleaf structure, whereas the 3'-terminal region (the 3' domain) forms an extended stem-loop. The loop region is thought to be recognized by the reverse transcriptase (RT) encoded by the long interspersed element (LINE). The two structural domains are linked by a single-stranded region (the linker domain). Our melting profile analyses indicated the presence of two structural domains having different thermal stabilities, thus supporting the domain composition described above. Based on these results, we discuss the structural generality and evolutionary advantage of the domain composition of SINE RNA.

Isolation and characterization of retrotransposition-competent LINEs from zebrafish

Long interspersed elements (LINEs) are a type of retroposon and are widely distributed in most eukaryotic genomes. LINEs are classified into two groups, the stringent type and relaxed type, based on the recognition of the 3' tail of their own RNA by reverse transcriptase (RT) during retrotransposition. Although most LINEs are thought to belong to the stringent type, retrotransposition studies of the stringent type LINEs are relatively limited compared with those of the relaxed type. We have now isolated two retrotransposition-competent LINEs (ZfL2-1 and ZfL2-2) from the zebrafish genome. Both ZfL2-1 and ZfL2-2 are members of the L2 clade; ZfL2-1 encodes two open reading frames (ORFs) and ZfL2-2 encodes one ORF, and each of the ORFs is required for retrotransposition. Using a retrotransposition assay in HeLa cells, we established that both ZfL2-1 and Zfl2-2 belong to the stringent type. We also demonstrated that an esterase (ES) domain encoded by ZfL2-1 ORF1 strongly enhances its own retrotransposition. The ES domain is encoded only in ORF1 of LINEs classified in the CR1 and L2 clades, although its function or significance in retrotransposition has not been elucidated. Thus, this is the first experimental evidence that the ES domain has an enhancing function during retrotransposition. These zebrafish LINEs will be useful for determining the function of ORF1 and the retrotransposition mechanism of stringent-type LINEs.

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.