Rodent type 2 Alu family, rat identifier sequence, rabbit C family, and bovine or goat 73-bp repeat may have evolved from tRNA genes

Variable patterns of retrotransposition in different HeLa strains provide mechanistic insights into SINE RNA mobilization processes

Alu elements are non-autonomous Short INterspersed Elements (SINEs) derived from the 7SL RNA gene that are present at over one million copies in human genomic DNA. Alu mobilizes by a mechanism known as retrotransposition, which requires the Long INterspersed Element-1 (LINE-1) ORF2-encoded protein (ORF2p). Here, we demonstrate that HeLa strains differ in their capacity to support Alu retrotransposition. Human Alu elements retrotranspose efficiently in HeLa-HA and HeLa-CCL2 (Alu-permissive) strains, but not in HeLa-JVM or HeLa-H1 (Alu-nonpermissive) strains. A similar pattern of retrotransposition was observed for other 7SL RNA-derived SINEs and tRNA-derived SINEs. In contrast, mammalian LINE-1s, a zebrafish LINE, a human SINE-VNTR-Alu (SVA) element, and an L1 ORF1-containing mRNA can retrotranspose in all four HeLa strains. Using an in vitro reverse transcriptase-based assay, we show that Alu RNAs associate with ORF2p and are converted into cDNAs in both Alu-permissive and Alu-nonpermissive HeLa strains, suggesting that 7SL- and tRNA-derived SINEs use strategies to 'hijack' L1 ORF2p that are distinct from those used by SVA elements and ORF1-containing mRNAs. These data further suggest ORF2p associates with the Alu RNA poly(A) tract in both Alu-permissive and Alu-nonpermissive HeLa strains, but that Alu retrotransposition is blocked after this critical step in Alu-nonpermissive HeLa strains.

Variable patterns of retrotransposition in different HeLa strains provide mechanistic insights into SINE RNA mobilization processes

Alu elements are non-autonomous Short INterspersed Elements (SINEs) derived from the 7SL RNA gene that are present at over one million copies in human genomic DNA. Alu mobilizes by a mechanism known as retrotransposition, which requires the Long INterspersed Element-1 (LINE-1 or L1) ORF2 -encoded protein (ORF2p). Here, we demonstrate that HeLa strains differ in their capacity to support Alu retrotransposition. Human Alu elements retrotranspose efficiently in HeLa-HA and HeLa-CCL2 ( Alu -permissive) strains, but not in HeLa-JVM or HeLa-H1 ( Alu -nonpermissive) strains. A similar pattern of retrotransposition was observed for other 7SL RNA -derived SINEs and tRNA -derived SINEs. In contrast, mammalian LINE-1s, a zebrafish LINE, a human SINE-VNTR - Alu ( SVA ) element, and an L1 ORF1 -containing messenger RNA can retrotranspose in all four HeLa strains. Using an in vitro reverse transcriptase-based assay, we show that Alu RNAs associate with ORF2p and are converted into cDNAs in both Alu -permissive and Alu -nonpermissive HeLa strains, suggesting that 7SL - and tRNA -derived SINE RNAs use strategies to 'hijack' L1 ORF2p that are distinct from those used by SVA elements and ORF1 -containing mRNAs. These data further suggest ORF2p associates with the Alu RNA poly(A) tract in both Alu -permissive and Alu -nonpermissive HeLa strains, but that Alu retrotransposition is blocked after this critical step in Alu -nonpermissive HeLa strains.

SINEs as Credible Signs to Prove Common Ancestry in the Tree of Life: A Brief Review of Pioneering Case Studies in Retroposon Systematics

Currently, the insertions of SINEs (and other retrotransposed elements) are regarded as one of the most reliable synapomorphies in molecular systematics. The methodological mainstream of molecular systematics is the calculation of nucleotide (or amino acid) sequence divergences under a suitable substitution model. In contrast, SINE insertion analysis does not require any complex model because SINE insertions are unidirectional and irreversible. This straightforward methodology was named the “SINE method,” which resolved various taxonomic issues that could not be settled by sequence comparison alone. The SINE method has challenged several traditional hypotheses proposed based on the fossil record and anatomy, prompting constructive discussions in the Evo/Devo era. Here, we review our pioneering SINE studies on salmon, cichlids, cetaceans, Afrotherian mammals, and birds. We emphasize the power of the SINE method in detecting incomplete lineage sorting by tracing the genealogy of specific genomic loci with minimal noise. Finally, in the context of the whole-genome era, we discuss how the SINE method can be applied to further our understanding of the tree of life.

B2 SINE Copies Serve as a Transposable Boundary of DNA Methylation and Histone Modifications in the Mouse

More than one million copies of short interspersed elements (SINEs), a class of retrotransposons, are present in the mammalian genomes, particularly within gene-rich genomic regions. Evidence has accumulated that ancient SINE sequences have acquired new binding sites for transcription factors (TFs) through multiple mutations following retrotransposition, and as a result have rewired the host regulatory network during the course of evolution. However, it remains unclear whether currently active SINEs contribute to the expansion of TF binding sites. To study the mobility, expression, and function of SINE copies, we first identified about 2,000 insertional polymorphisms of SINE B1 and B2 families within Mus musculus. Using a novel RNA sequencing method designated as melRNA-seq, we detected the expression of SINEs in male germ cells at both the subfamily and genomic copy levels: the vast majority of B1 RNAs originated from evolutionarily young subfamilies, whereas B2 RNAs originated from both young and old subfamilies. DNA methylation and chromatin immunoprecipitation-sequencing (ChIP-seq) analyses in liver revealed that polymorphic B2 insertions served as a boundary element inhibiting the expansion of DNA hypomethylated and histone hyperacetylated regions, and decreased the expression of neighboring genes. Moreover, genomic B2 copies were enriched at the boundary of various histone modifications, and chromatin insulator protein, CCCTC-binding factor, a well-known chromatin boundary protein, bound to >100 polymorphic and >10,000 non-polymorphic B2 insertions. These results suggest that the currently active B2 copies are mobile boundary elements that can modulate chromatin modifications and gene expression, and are likely involved in epigenomic and phenotypic diversification of the mouse species.

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.

A New Class of SINEs with snRNA Gene-Derived Heads

Eukaryotic genomes are colonized by various transposons including short interspersed elements (SINEs). The 5' region (head) of the majority of SINEs is derived from one of the three types of RNA genes--7SL RNA, transfer RNA (tRNA), or 5S ribosomal RNA (rRNA)--and the internal promoter inside the head promotes the transcription of the entire SINEs. Here I report a new group of SINEs whose heads originate from either the U1 or U2 small nuclear RNA gene. These SINEs, named SINEU, are distributed among crocodilians and classified into three families. The structures of the SINEU-1 subfamilies indicate the recurrent addition of a U1- or U2-derived sequence onto the 5' end of SINEU-1 elements. SINEU-1 and SINEU-3 are ancient and shared among alligators, crocodiles, and gharials, while SINEU-2 is absent in the alligator genome. SINEU-2 is the only SINE family that was active after the split of crocodiles and gharials. All SINEU families, especially SINEU-3, are preferentially inserted into a family of Mariner DNA transposon, Mariner-N4_AMi. A group of Tx1 non-long terminal repeat retrotransposons designated Tx1-Mar also show target preference for Mariner-N4_AMi, indicating that SINEU was mobilized by Tx1-Mar.

Epigenetic regulation of transcription and possible functions of mammalian short interspersed elements, SINEs

Short interspersed elements (SINEs) are a class of retrotransposons, which amplify their copy numbers in their host genomes by retrotransposition. More than a million copies of SINEs are present in a mammalian genome, constituting over 10% of the total genomic sequence. In contrast to the other two classes of retrotransposons, long interspersed elements (LINEs) and long terminal repeat (LTR) elements, SINEs are transcribed by RNA polymerase III. However, like LINEs and LTR elements, the SINE transcription is likely regulated by epigenetic mechanisms such as DNA methylation, at least for human Alu and mouse B1. Whereas SINEs and other transposable elements have long been thought as selfish or junk DNA, recent studies have revealed that they play functional roles at their genomic locations, for example, as distal enhancers, chromatin boundaries and binding sites of many transcription factors. These activities imply that SINE retrotransposition has shaped the regulatory network and chromatin landscape of their hosts. Whereas it is thought that the epigenetic mechanisms were originated as a host defense system against proliferation of parasitic elements, this review discusses a possibility that the same mechanisms are also used to regulate the SINE-derived functions.

Characterization of swine short interspersed repetitive sequences

Swine genomic DNA segments containing repetitive sequences were isolated from a porcine genomic library using genomic DNA as a probe. Three fragments containing the repetitive sequences from two of the primary phage clones were subcloned for sequence analysis, which revealed six new PRE-1 repetitive families other than those reported earlier by Singer et al. (Nucleic Acids Research 15, 2780, 1987). The frequency of the repetitive sequences in the swine genome was estimated at 2 x 10(6) per diploid genome. Sequence analysis revealed similarities between these repetitive sequences and that of arginine-tRNA gene.

Characterization and evolutionary landscape of AmnSINE1 in Amniota genomes

Discovery of a large number of conserved non-coding elements (CNEs) in vertebrate genomes provides a cornerstone to elucidate molecular mechanisms of macroevolution. Extensive comparative genomics has proven that transposons such as short interspersed elements (SINEs) were an important source of CNEs. We recently characterized AmnSINE1, a SINE family in Amniota genomes, some of which are present in CNEs, and demonstrated that two AmnSINE1 loci play an important role in mammalian-specific brain development by functioning as an enhancer (Sasaki et al. Proc. Natl. Acad. Sci. USA 2008). To get more information about AmnSINE1s, we here performed a multi-species search for AmnSINE1, and revealed the distribution and evolutionary history of these SINEs in amniote genomes. The number of AmnSINE1 regions in amniotes ranged from 160 to 1200; the number in the eutherians were under 500 and the largest was that in chicken. Phylogenetic analysis established that each AmnSINE1 locus has evolved uniquely, primarily since the divergence of mammals from reptiles. These results support the notion that AmnSINE1s were amplified as an ancient retroposon in a common ancestor of Amniota and subsequently have survived for 300 Myr because of functions acquired by mutation-coupled exaptation prior mammalian radiation. On the basis of sequence homology and conserved synteny, we detected the orthologs of AmnSINE1 for candidates of further enhancer analysis, which are more conserved than two loci that were shown to have been involved in mammalian brain development. The present work provides a comprehensive data set to test the role of AmnSINE1s, many of which were exapted and contributed to mammalian macroevolution.

New SINE families from rice, OsSN, with poly(A) at the 3' ends

A database search of the sequences flanking a member of rice retrotransposon RIRE7 revealed that a 298-bp sequence in the region downstream of the member is a repetitive sequence interspersed in the genome of Oryza sativa cv. Nipponbare. Most of the repetitive sequences were flanked by a direct repeat of a target-site sequence, about 14 bp in length. The consensus sequence, 293 bp in length, had no regions encoding any proteins but had sequence motifs of an internal promoter of RNA polymerase III. These indicate that the sequence is a retroposon SINE, designated OsSN1 (Oryza sativa SINE1). OsSN1 is a new rice SINE, because it has no homology with any of the three p-SINE families previously identified from rice, and because it has a stretch of A at the 3' end, unlike p-SINE and any other Gramineae SINEs which have a stretch of T at the 3' end. The Nipponbare genome was found to have many members related to OsSN1, forming two additional new SINE families (designated OsSN2 and OsSN3). OsSN2 and OsSN3 are highly homologous to the 3' and 5' regions of OsSN1, respectively. This suggests that OsSN1 has a mosaic structure, which is generated by sequence exchange (or shuffling) between ancestral OsSN2 and OsSN3. Despite the absence of homology in the 3' regions between OsSN1 (or OsSN2) and OsSN3, a sequence, 5'-TTCTC-3', is commonly present in the region preceding the A stretch at the 3' end. This sequence together with the A stretch and a stem-loop structure found in the region near the A stretch are assumed to be important for retroposition. OsSN members were present in strains of Oryza species, as were p-SINE members. Some of the members showed insertion polymorphism at the respective loci among the rice strains. p-SINE had such polymorphic members, which are useful for classification and phylogenetic analysis of various strains of Oryza species. The polymorphic members of OsSN were more frequently found than those of p-SINE, and therefore, such members are likely to be useful for extensive taxonomic and phylogenetic studies on various rice strains.

Retroposons of salmonoid fishes (Actinopterygii: Salmonoidei) and their evolution

Short and long retroposons, or non-LTR retrotransposons (SINEs and LINEs, respectively) are two groups of interspersed repetitive elements amplifying in the genome via RNA and cDNA-mediated reverse transcription. In this process, SINEs entirely depend on the enzymatic machinery of autonomous LINEs. The impact of retroposons on the host genome is difficult to overestimate: their sequences account for significant portion of the eukaryotic genome, while propagation of their active copies gradually reshapes it. In this way, the retropositional activity plays a role of important evolutionary factor. More than 100 LINE and nearly 100 SINE families have been described to date from the genomes of various eukaryotes, and it is salmonoid fishes (Actinopterygii: Salmonoidei) that are particularly noticeable for the diversity of transposons they host in their genomes, including two LINE and seven SINE families. Moreover, this group of ray-finned fish represents an excellent opportunity to study such a rare evolutionary phenomenon as lateral gene transfer, due to a great variety of transposons and other sequences salmons share with a blood fluke, Schistosoma japonicum (Trematoda: Strigeiformes)--a parasitic helminth infecting various vertebrates. The aim of the present review is to structure all knowledge accumulated about salmonoid retroposons by now, as well as to complement it with the new data pertaining to the distribution of some SINE families.

MyrSINEs: a novel SINE family in the anteater genomes

Recent rapid generation of genomic sequence data has allowed many researchers to perform comparative analyses in various mammalian species. However, characterization of transposable elements, such as short interspersed repetitive elements (SINEs), has not been reported for several mammalian groups. Because SINEs occupy a large portion of the mammalian genome, they are believed to have contributed to the constitution and diversification of the host genomes during evolution. In the present study, we characterized a novel SINE family in the anteater genomes and designated it the MyrSINE family. Typical SINEs consist of a tRNA-related, a tRNA-unrelated and an AT-rich (or poly-A) region. MyrSINEs have only tRNA-related and poly-A regions; they are included in a group called t-SINE. The tRNA-related regions of the MyrSINEs were found to be derived from tRNA(Gly). We demonstrate that the MyrSINE family can be classified into three subfamilies. Two of the MyrSINE subfamilies are distributed in the genomes of both giant anteater and tamandua, while the other is present only in the giant anteater. We discuss the evolutionary history of MyrSINEs and their relationship to the evolution of anteaters. We also speculate that the simple structure of t-SINEs may be a potential evolutionary source for the generation of the typical SINE structure.

Genomic expansion of the Bov-A2 retroposon relating to phylogeny and breed management

Bov-A2 is a retroposon that is widely distributed among the genomes of ruminants (e.g., cow, deer, giraffe, pronghorn, musk deer, and chevrotain). This retroposon is composed of two monomers, called Bov-A units, which are joined by a linker sequence. The structure and origin of Bov-A2 has been well characterized but a genome-level exploration of this retroposon has not been implemented. In this study we performed an extensive search for Bov-A2 using all available genome sequence data on Bos taurus. We found unique Bov-A2-derived sequences that were longer than Bov-A2 due to amplification of three to six Bov-A units arranged in tandem. Detailed analysis of these elongated Bov-A2-derived sequences revealed that they originated through unequal crossing-over of Bov-A2. We found a large number of these elongated Bov-A2-derived sequences in cattle genomes, indicating that unequal crossing-over of Bov-A2 occurred very frequently. We found that this type of elongation is not observed in wild bovine and is therefore specific to the domesticated cattle genome. Furthermore, at specific loci, the number of Bov-A units was also polymorphic between alleles, implying that the elongation of Bov-A units might have occurred very recently. For these reasons, we speculate that genomic instability in bovine genomes can lead to extensive unequal crossing-over of Bov-A2 and levels of polymorphism might be generated in part by repeated outbreeding.

SINEs of progress: Mobile element applications to molecular ecology

Mobile elements represent a unique and under-utilized set of tools for molecular ecologists. They are essentially homoplasy-free characters with the ability to be genotyped in a simple and efficient manner. Interpretation of the data generated using mobile elements can be simple compared to other genetic markers. They exist in a wide variety of taxa and are useful over a wide selection of temporal ranges within those taxa. Furthermore, their mode of evolution instills them with another advantage over other types of multilocus genotype data: the ability to determine loci applicable to a range of time spans in the history of a taxon. In this review, I discuss the application of mobile element markers, especially short interspersed elements (SINEs), to phylogenetic and population data, with an emphasis on potential applications to molecular ecology.

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.

Bov-tA short interspersed nucleotide element sequences in circulating nucleic acids from sera of cattle with bovine spongiform encephalopathy (BSE) and sera of cattle exposed to BSE

Circulating nucleic acids (CNA) are known to be enriched in repetitive DNA sequences in humans. Here, bovine sera CNA were analyzed to determine if cell stress-related short interspersed nucleotide elements (SINEs) could be detected in sera from cattle associated with bovine spongiform encephalopathy (BSE). Nucleic acids were extracted, amplified, cloned, and sequenced from the sera of protease-resistant prion protein (PrP(res))-positive cattle (n = 2) and sera from BSE-cohort cows (n = 6); 150 out of 163 clones revealed the presence of, on average, an 80-bp sequence from the 3' region of Bov-tA SINE. A PCR protocol was developed that differentially identified SINE-associated CNA in BSE-exposed versus normal cattle. CNA were extracted from a serum vesicular fraction after controlled blood collection and processing procedures. Sera from four confirmed cases of BSE, 137 BSE-exposed cohort animals associated with eight confirmed BSE cases, and 845 healthy, PrP(res)-negative control cows were tested. All four sera from confirmed BSE cases were repeatedly reactive in the assay. BSE-exposed cohorts had a 100-fold higher occurrence of repeatedly reactive individuals per cohort (average = 63%; range = 33% to 91%), compared to healthy controls (average = 0.6%; P < 0.001). This study shows that BSE-confirmed and cohort animals possess a unique profile of SINE-associated serum CNA that can be utilized as a marker that highly correlates to BSE exposure.

Primate phylogeny: molecular evidence from retroposons

In these postgenomic times where aspects of functional genetics and character evolution form a focal point of human-mouse comparative research, primate phylogenetic research gained a widespread interest in evolutionary biology. Nevertheless, it also remains a controversial subject. Despite the surge in available primate sequences and corresponding phylogenetic interpretations, primate origins as well as several branching events in primate divergence are far from settled. The analysis of SINEs - short interspersed elements - as molecular cladistic markers represents a particularly interesting complement to sequence data. The following summarizes and discusses potential applications of this new approach in molecular phylogeny and outlines main results obtained with SINEs in the context of primate evolutionary research. Another molecular cladistic marker linking the tarsier with the anthropoid primates is also presented. This eliminates any possibility of confounding phylogenetic interpretations through lineage sorting phenomena and makes use of a new point of view in settling the phylogenetic relationships of the primate infraorders.

A novel class of mammalian-specific tailless retropseudogenes

In addition to their central function in protein biosynthesis, tRNAs also play a pervasive role in genome evolution and architecture because of their extensive ability to serve as templates for retroposition. Close to half of the human genome consists of discernible transposable elements, a vast majority of which are derived from RNA via reverse transcription and genomic integration. Apart from the presence of direct repeats (DRs) that flank the integrated sequence of retroposons, genomic integrations are usually marked by an oligo(A) tail. Here, we describe a novel class of retroposons that lack A-tails and are therefore termed tailless retropseudogenes. Analysis of approximately 2500 tRNA-related young tailless retropseudogene sequences revealed that they comprise processed and unprocessed (pre-)tRNAs, 3'-truncated in their loop regions, or truncated tRNA-derived SINE RNAs. Surprisingly, their mostly nonrandom integration is dependent on the priming of reverse transcription at sites determined by their 3'-terminal 2-18 nucleotides and completely independent from oligoadenylation of the template RNA. Thus, tailless retropseudogenes point to a novel, variant mechanism for the biogenesis of retrosequences.

A novel family of tRNA-derived SINEs in the colugo and two new retrotransposable markers separating dermopterans from primates

Short interspersed nuclear elements (SINEs) provide a near homoplasy free and copious source of molecular evolutionary markers with precisely defined character polarity. Used as molecular cladistic markers in presence/absence analyses, they represent a powerful complement to phylogenetic reconstructions that are based on sequence comparisons on the level of nucleotide substitutions. Recent sequence comparisons of large data sets incorporating a broad eutherian taxonomic sample have led to considerations of the different primate infraorders to constitute a paraphyletic group. Statistically significant support against the monophyly of primates has been obtained by clustering the flying lemur-also termed colugo-(Cynocephalus, Dermoptera) amidst the primates as the sister group to anthropoid primates (New World monkeys, Old World monkeys, and hominoids). We discovered retrotransposed markers that clearly favor the monophyly of primates, with the markers specific to all extant primates but definitively absent at the orthologous loci in the flying lemur and other non-primates. By screening the colugo genome for phylogenetic informative SINEs, we also recovered a novel family of dermopteran specific SINE elements that we call CYN. This element is probably derived from the isoleucine tRNA and appears in monomeric, dimeric, and trimeric forms. It has no long tRNA unrelated region and no poly(A) linker between the monomeric subunits. The characteristics of the novel CYN-SINE family indicate a relatively recent history. Therefore, this SINE family is not suitable to solve the phylogenetic affiliation between dermopterans and primates. Nevertheless it is a valuable device to reconstruct the evolutionary steps from a functional tRNA to an interspersed SINE element.

Analysis of the 3' Cmu region of the rabbit Ig heavy chain locus

The immunoglobulin D (IgD) antibody class was, for many years, identified only in primates, rodents and teleost fish. The limited distribution of IgD among vertebrates suggested that IgD is a functionally redundant antibody class that has been lost by many vertebrate species during evolution. The recent identification of IgD in artiodactyls, however, suggests that IgD might be more widely expressed among vertebrates than previously thought, possibly serving a unique role in immunity. IgD expression has been searched for but not detected in rabbits. In order to search directly for a rabbit Cdelta locus encoding the constant region of IgD, we determined the nucleotide sequence of 13.5 kb of genomic DNA downstream of the rabbit Cmu locus. We did not find a rabbit Cdelta locus in this region, but found instead that this region is densely populated by repetitive elements, including a long interspersed DNA element repeat, six C repeats, and two processed pseudogenes. We conclude that the rabbit probably does not express IgD because there is no Cdelta locus immediately downstream of the rabbit Cmu locus.

Characterization of novel Alu- and tRNA-related SINEs from the tree shrew and evolutionary implications of their origins

We characterized two novel 7SL RNA-derived short interspersed nuclear element (SINE) families (Tu types I and II) and a novel tRNA-derived SINE family (Tu type III) from the tree shrew (Tupaia belangeri). Tu type I contains a monomer unit of a 7SL RNA-derived Alu-like sequence and a tRNA-derived region that includes internal RNA polymerase III promoters. Tu type II has a similar hybrid structure, although the monomer unit of the 7SL RNA-derived sequence is replaced by a dimer. Along with the primate Alu, the galago Alu type II, and the rodent B1, these two families represent the fourth and fifth 7SL RNA-derived SINE families to be identified. Furthermore, comparison of the Alu domains of Tu types I and II with those of other 7SL RNA-derived SINEs reveals that the nucleotides responsible for stabilization of the Alu domain have been conserved during evolution, providing the possibility that these conserved nucleotides play an indispensable role in retropositional activity. Evolutionary relationships among these 7SL RNA-derived SINE families, as well as phylogenetic relationships of their host species, are discussed.

Mosaic structure and retropositional dynamics during evolution of subfamilies of short interspersed elements in African cichlids

The African cichlid (AFC) family of short interspersed elements (SINEs) is found in the genomes of cichlid fish. The alignment of the sequences of 70 members of this family, isolated from such fish in Africa, revealed the presence of correlated changes in specific nucleotides (diagnostic nucleotides) that allowed us to categorize the various members into six subfamilies, which were designated Af1 through Af6. Dividing the SINE consensus sequence into a 5'-head and 3'-tail region, these subfamilies were defined by various combinations of four types of head region (A-D) and three types of tail region [X, Y, and (YX)], with each region of each type including unique diagnostic nucleotides. The observed structures of the subfamilies Af1 through Af6 were AX, AY, CY, A(YX), BY, and DX, respectively. The formation of such structures might have involved the shuffling of head or tail regions among preexisting and existing (or both) subfamilies of the AFC family (and, probably, even another SINE family or a pseudogene for a tRNA in the case of the Af6 subfamily) by recombination at the so-called core region during the course of evolution. By plotting the timing of the retroposition of individual members of each subfamily on a phylogenetic tree of AFCs, we found that the Af3 and Af6 subfamilies became active only recently in the evolutionary history of these fish. The integrity of the 3'-tails of SINEs, which are, apparently, recognized by reverse transcriptase, has been reported to be indispensable for retention of retropositional activity. Therefore, we postulate that recombination might have been involved in the apparent recent activation of the retroposition of the Af3 and Af6 subfamilies via introduction of active tails (types Y and X, respectively) into potential ancestral sequences that might have had inactive tails. If this hypothesis is correct, shuffling of tail regions among subfamilies by recombination at the core region might have played a role in the recycling of dead copies of AFC SINEs.

SINEs and LINEs: the art of biting the hand that feeds you

SINEs and LINEs are short and long interspersed retrotransposable elements, respectively, that invade new genomic sites using RNA intermediates. SINEs and LINEs are found in almost all eukaryotes (although not in Saccharomyces cerevisiae) and together account for at least 34% of the human genome. The noncoding SINEs depend on reverse transcriptase and endonuclease functions encoded by partner LINEs. With the completion of many genome sequences, including our own, the database of SINEs and LINEs has taken a great leap forward. The new data pose new questions that can only be answered by detailed studies of the mechanism of retroposition. Current work ranges from the biochemistry of reverse transcription and integration invitro, target site selection in vivo, nucleocytoplasmic transport of the RNA and ribonucleoprotein intermediates, and mechanisms of genomic turnover. Two particularly exciting new ideas are that SINEs may help cells survive physiological stress, and that the evolution of SINEs and LINEs has been shaped by the forces of RNA interference. Taken together, these studies promise to explain the birth and death of SINEs and LINEs, and the contribution of these repetitive sequence families to the evolution of genomes.

Identification and structural analysis of SINE elements in the Arabidopsis thaliana genome

An insertion sequence was found in a Mu homologue in the genome of Arabidopsis thaliana. The insertion sequence had poly(A) at the 3' end, and promoter motifs (A- and B-boxes) recognized by RNA polymerase III. The sequence was flanked by direct repeats of a 15-bp sequence of the Mu homologue, which appears to be a target-site sequence duplicated upon insertion. These findings indicate that the insertion sequence is a retroposon SINE, and it was therefore named AtSN (A. thaliana SINE). Many members of the AtSN family were identified through a computer-aided homology search of databases and classified into two subfamilies, AtSN1 and AtSN2, having consensus sequences 159 and 149 bp in length, respectively. These had no homology to SINEs in other organisms. About half of AtSN members were truncated through loss of a region at either end of the element. Most of them were truncated at the 5' end, and had a duplication of the target-site sequence. This suggests that the ones with 5' truncation retroposed by the same mechanism as those without truncation. Members of the AtSN1 or AtSN2 subfamilies had many base substitutions when compared with the consensus sequence. All of the members examined were present in three different ecotypes of A. thaliana (Columbia, Landsberg erecta, and Wassilewskija). These findings suggest that AtSN members had proliferatedbefore the A. thaliana ecotype strains diverged.

Transposable B2 SINE elements can provide mobile RNA polymerase II promoters

Short interspersed elements (SINEs) are highly abundant components of mammalian genomes that are propagated by retrotransposition. SINEs are recognized as a causal agent of human disease and must also have had a profound influence in shaping eukaryotic genomes. The B2 SINE family constitutes approximately 0.7% of total mouse genomic DNA (ref. 2) and is also found at low abundance in humans. It resembles the Alu family in several respects, such as its mechanism of propagation. B2 SINEs are derived from tRNA and are transcribed by RNA polymerase (pol) III to generate short transcripts that are not translated. We find here, however, that one B2 SINE also carries an active pol II promoter located outside the tRNA region. Indeed, a B2 element is responsible for the production of a mouse Lama3 transcript. The B2 pol II promoters can be bound and stimulated by the transcription factor USF (for upstream stimulatory factor), as shown by transient transfection experiments. Moreover, this pol II activity does not preclude the pol III transcription necessary for retrotransposition. Dispersal of B2 SINEs by retrotransposition may therefore have provided numerous opportunities for creating regulated pol II transcription at novel genomic sites. This mechanism may have allowed the evolution of new transcription units and new genes.

SINE insertions: powerful tools for molecular systematics

Short interspersed repetitive elements, or SINEs, are tRNA-derived retroposons that are dispersed throughout eukaryotic genomes and can be present in well over 10(4) total copies. The enormous volume of SINE amplifications per organism makes them important evolutionary agents for shaping the diversity of genomes, and the irreversible, independent nature of their insertion allows them to be used for diagnosing common ancestry among host taxa with extreme confidence. As such, they represent a powerful new tool for systematic biology that can be strategically integrated with other conventional phylogenetic characters, most notably morphology and DNA sequences. This review covers the basic aspects of SINE evolution that are especially relevant to their use as systematic characters and describes the practical methods of characterizing SINEs for cladogram construction. It also discusses the limits of their systematic utility, clarifies some recently published misunderstandings, and illustrates the effective application of SINEs for vertebrate phylogenetics with results from selected case studies. BioEssays 22:148-160, 2000.

Wide distribution of short interspersed elements among eukaryotic genomes

Most short interspersed elements (SINEs) in eukaryotic genomes originate from tRNA and have internal promoters for RNA polymerase III. The promoter contains two boxes (A and B) spaced by approximately 33 bp. We used oligonucleotide primers specific to these boxes to detect SINEs in the genomic DNA by polymerase chain reaction (PCR). Appropriate DNA fragments were revealed by PCR in 30 out of 35 eukaryotic species suggesting the wide distribution of SINEs. The PCR products were used for hybridization screening of genomic libraries which resulted in identification of four novel SINE families. The application of this approach is illustrated by discovery of a SINE family in the genome of the bat Myotis daubentoni. Members of this SINE family termed VES have an additional B-like box, a putative polyadenylation signal and RNA polymerase III terminator.

Local hypomethylation in atherosclerosis found in rabbit ec-sod gene

Extracellular superoxide dismutase (EC-SOD) protects arteries against deleterious effects of superoxide anions and the development of atherosclerosis. In this study, we cloned and characterized rabbit ec-sod gene. We identified 6 rabbit C-elements and 5 CpG clusters in the cloned sequence. One of the CpG clusters is located on the coding sequence. Because CpG clusters are potential sites for methylation and may explain the occurrence of mutations, methylation status of each of the CpG dimers located in the coding sequence CpG cluster was characterized using direct genomic sequencing. Unexpectedly, a marked reduction in the amount of methylated CpG dinucleotides in ec-sod gene was detected in atherosclerotic aortas as compared with normal aortic intima-media. Although alterations in DNA methylation are well characterized in malignant tumors, the presence of methylation changes in atherosclerosis has not been studied even though both diseases are characterized by excess cellular proliferation and alterations in gene expression. Further analysis of the whole genomic methylation by high-pressure liquid chromatography in normal and atherosclerotic aortas revealed a tendency for a decreased 5-methylcytosine (5-mC) content in atherosclerotic aortas as compared with normal arteries. Hypomethylation in atherosclerotic aortas occurred at the same level as has been reported from malignant tumors. Although a causal relationship between the methylation level and expression of EC-SOD cannot be proven, our results show that ec-sod hypomethylation is associated with the development of atherosclerosis and suggest that it may affect structure and function of ec-sod and other genes possibly involved in the development of atherosclerotic lesions.

Pseudouridine and ribothymidine formation in the tRNA-like domain of turnip yellow mosaic virus RNA

The last 82 nucleotides of the 6.3 kb genomic RNA of plant turnip yellow mosaic virus (TYMV), the so-called 'tRNA-like' domain, presents functional, structural and primary sequence homologies with canonical tRNAs. In particular, one of the stem-loops resembles the TPsi(pseudouridine)-branch of tRNA, except for the presence of a guanosine at position 37 (numbering is from the 3'-end) instead of the classical uridine-55 in tRNA (numbering is from the 5'-end). Both the wild-type TYMV-RNA fragment and a variant, TYMV-mut G37U in which G-37 has been replaced by U-37, have been tested as potential substrates for the yeast tRNA modification enzymes. Results indicate that two modified nucleotides were formed upon incubation of the wild-type TYMV-fragment in a yeast extract: one Psi which formed quantitatively at position 65, and one ribothymidine (T) which formed at low level at position U-38. In the TYMV-mutant G37U, besides the quantitative formation of both Psi-65 and T-38, an additional Psi was detected at position 37. Modified nucleotides Psi-65, T-38 and Psi-37 in TYMV RNA are equivalent to Psi-27, T-54 and Psi-55 in tRNA, respectively. Purified yeast recombinant tRNA:Psisynthases (Pus1 and Pus4), which catalyze respectively the formation of Psi-27 and Psi-55 in yeast tRNAs, are shown to catalyze the quantitative formation of Psi-65 and Psi-37, respectively, in the tRNA-like 3'-domain of mutant TYMV RNA in vitro . These results are discussed in relation to structural elements that are needed by the corresponding enzymes in order to catalyze these post-transcriptional modification reactions.

SINEs and LINEs share common 3' sequences: a review

There are now five reported examples in which the 3' ends of tRNA-derived SINEs are derived from the 3' ends of LINEs. These examples include representative sequences from turtles, fish, mammals and plants (Ohshima et al., 1996, Mol. Cell. Biol., 16, 3756 3764; Okada and Hamada, 1997, J. Mol. Evol. 44, Suppl 1:S52-S56). In this review, we discuss the generality of this architecture of SINEs, adding new examples of pairs of SINEs and LINEs, which include one complete and two probable examples from this laboratory and one complete example from the laboratory of Arian Smit. This organization of SINEs and LINEs provides the basis for a simple general scheme by which SINEs might acquire retropositional activity.

Transcripts containing the sea urchin retroposon family 1 (SURF1) in embryos of the sea urchin Anthocidaris crassispina

We isolated two cDNAs, termed D7 and C2 in the present study, from a cDNA library of the 16-cell embryo of the sea urchin Anthocidaris crassispina. The nucleotide sequence was determined completely for D7, and partially for C2. D7 does not have any significant open reading frames. Both D7 and C2 contain a common sequence that is 62% homologous to the sea urchin retroposon family 1 (SURF1). The SURF1 is a short interspersed repetitive element identified from the sea urchin Strongylocentrotus purpuratus, and is reported to be transcribed by RNA polymerase III. The structural feature of D7 and C2, however, suggests that they may be transcribed by RNA polymerase II. RT-PCR analyses revealed that (1) both D7 and C2 transcripts exist as a maternal RNA in the egg, (2) they appear evenly distributed in the 16-cell embryo, and (3) C2 transcripts are present throughout the development up to the gastrula, while D7 transcripts decrease in amount after the early cleavage stage.

Polyploid-specific repetitive DNA sequences from triploid ginbuna (Japanese silver crucian carp, Carassius auratus langsdorfi)

Repetitive DNA sequences (Cal3nDr) in the genome of a triploid ginbuna (Carassius auratus langsdorfi) were isolated from the DraI digests of the genomic DNA. This AT-rich (61%) Cal3nDr monomer was 137 bp in length. The nucleotide similarity among the monomers from the same individual was considerably high (above 97%). Hybridization analyses revealed that the Cal3nDr sequences were organized into tandem arrays. These DNA sequences were present only in triploid and tetraploid ginbunas and were absent from diploid ginbuna, gengorobuna, goldfish, and other cyprinid fishes, and therefore appeared to be specific to polyploid ginbunas. In situ hybridization data showed their localization on one to four out of a total of 150 to 156 chromosomes, depending on the individuals or clonal lines, of the triploid ginbuna. The origin of the Cal3nDr sequences is also discussed on the basis of observation of the artificial triploid ginbuna produced by crossing a diploid female with a tetraploid male.

The 3' ends of tRNA-derived SINEs originated from the 3' ends of LINEs: a new example from the bovine genome

Our group demonstrated recently that the 3' ends of several families of tRNA-derived SINEs (short interspersed repetitive elements) originated from the 3' ends of LINEs (long interspersed repetitive elements) [Ohshima et al. (1996) Mol. Cell. Biol. 16:3756-3764]. Two fully characterized examples of such organization were provided by the tortoise Pol III/SINE and the salmonid HpaI family of SINEs, and two probable examples were provided by the tobacco TS family of SINEs and the salmon SmaI family of SINEs. This organization of SINEs can explain their potential to retropose in the genome since it appears reasonable that the sites for recognition of LINEs by reverse transcriptase should be located within the 3'-end sequences of LINEs. We now add another example to this category of SINEs. In the bovine genome, there are Bov-tA SINEs, which belong to the superfamily of tRNA-derived families of SINEs, and Bov-B LINEs, which were recently demonstrated to belong to a LINE family. Moreover, Bov-tA and Bov-B share the same 3'-end tail. We propose a possible scenario whereby the composite structure of the bovine Bov-tA family of SINEs might have been generated from the Bov-B family of LINEs during evolution.

A swine SINE (PRE-1 sequence) distribution in swine-related animal species and its phylogenetic analysis in swine genome

The distribution of PRE-1 sequence (a swine SINE) among the animal species related to Sus scrofa, i.e. Phacochoerus aethiopicus and Tayassu tajacu, was examined by dot-blot analysis using PRE-1 sequences as a probe. This revealed that Phacochoerus aethiopicus and Tayassu tajacu contained PRE-1 sequences, amounts of which in their genomes are almost the same as that in the swine genome, indicating that these species separated after PRE-1 sequences proliferated to diversify in the genome. In order to estimate the time when the PRE-1 started to diversify in the swine genome, PRE-1 sequences were extracted from GenBank DNA database by homology analysis using the PRE-1 consensus sequence as a probe. The 22 PRE-1 sequences obtained were aligned and their phylogenetic relation was calculated by the neighbour-joining method. The result of the calculation combined with the mutation rate of the pseudogenes (r = 4.6 x 10(-9)) indicated that the PRE-1 sequence diversified at least 43.2 million years ago. Taken together, the period of time since the separation of the three species, Sus scrofa, Phacochoerus aethiopicus and Tayassu tajacu, is currently estimated to be less than 43.2 million years.

MIRs are classic, tRNA-derived SINEs that amplified before the mammalian radiation

Short Interspersed Nucleotide Elements (SINEs) are highly abundant in mammalian genomes. The term SINE has come to be restricted to short retroposons with internal RNA polymerase III promoter sites in a region derived from a structural RNA (usually a tRNA). Here we describe a novel, 260 bp tRNA-derived SINE, some fragments of which have been noted before to be repetitive in mammalian DNA. Unlike previously reported SINEs, which are restricted to closely related species, copies of this element can be found in all mammalian genomes, including marsupials. It is therefore called MIR for mammalian-wide interspersed repeat. Their high divergence and their presence at orthologous sites in different mammals indicate that MIRs, at least in part, amplified before the mammalian radiation. Next to Alu, MIRs are the most common interspersed repeat in primates with an estimated 300,000 copies still discernible, which account for 1 to 2% of our DNA. Interestingly, a small, central region of MIR appears to be much better conserved in the genomic copies than the rest of the sequence.

A master sequence related to a free left Alu monomer (FLAM) at the origin of the B1 family in rodent genomes

The question of the origin of the B1 family of rodents is addressed. The modern B1 elements are similar to the left Alu monomer, but with a 9 bp deletion and a 29 bp duplication. Search of databases for B1 elements that do not exhibit those modern features revealed sequence fragments that are very similar to the free left Alu monomers (FLAMs) described in the primate genomes. In addition, the analysis reveals elements that have 10 bp or 7 bp deletion in place of the 9 bp deletion but without the 29 bp tandem duplication. The elements described define families of proto B1 elements (referred as PB1, PB1D10 and PB1D7) that appeared before the first modern B1 element. A phylogenetic reconstruction suggest that the origin of Alu and B1 families took place before the divergence between the primate and the rodent lineages and that each family has followed different evolutionary routes since this radiation.

A model for the mechanism of initial generation of short interspersed elements (SINEs)

Most animal genomes contain a large number of short interspersed elements (SINEs) that have a composite structure and contain a region that is homologous to a tRNA. The majority of SINEs have been found to be derived from a tRNA(Lys), being categorized as members of a superfamily of tRNA(Lys)-related SINEs. The consensus sequences of five SINEs that belong to this superfamily were aligned. It was found that, in the tRNA-unrelated region, there are two sequence motifs that are almost identical among these five SINEs and are at a distance of 10-11 nucleotides from each other. This observation suggests a common evolutionary origin of these SINEs and/or some function(s) for these motifs. Similar sequences were unexpectedly found to be present in the sequences complementary to the U5 regions of several mammalian retroviruses whose primer is a tRNA(Lys). On the basis of these findings, we propose a possible model for the generation of SINEs whereby they are derived from a "strong stop DNA" with a primer tRNA that is an intermediate in the process of reverse transcription of certain retroviruses.

Determination of the phylogenetic relationships among Pacific salmonids by using short interspersed elements (SINEs) as temporal landmarks of evolution

Several subfamilies of the salmonid Hpa I short interspersed element (SINE) family were isolated from salmonid genomes and were sequenced. For each genomic locus that represented the subfamily, amplification by PCR of the orthologous loci in the 12 fish allowed us to determine the order of branching of the Pacific salmonid species. The deduced phylogeny suggests three evolutionary lines, namely, a line of chum salmon, pink salmon, and kokanee; a line of coho salmon and chinook salmon; and a line of steelhead trout. Our data also support a change in the phylogenetic assignment of steelhead trout from Salmo to Oncorhynchus. We present here an extensive phylogenetic tree constructed from an analysis of differential insertion of SINEs, and we propose that SINE insertion analysis is one of the best available methods for clarifying the order of divergence of closely related species.

Molecular characterization of a short interspersed repetitive element from tobacco that exhibits sequence homology to specific tRNAs

We have characterized a family of tRNA-derived short interspersed repetitive elements (SINEs) in the tobacco genome. Members of this family of SINEs, designated TS, have a composite structure and include a region structurally similar to a rabbit tRNA(Lys), a tRNA-unrelated region, and a TTG repeat of variable length at the 3' end. Southern blot hybridization, together with a search of the GenBank data base, showed that various plants belonging to the families Solanaceae and Convolvulaceae contain sequences homologous to the TS family in the introns and flanking regions of many genes, whereas Arabidopsis in the family Cruciferae and several species of monocoytledonous plants do not. The TS family is widely involved in structural and genetic variations in the genomes of many plants that belong to the order Tubiflorae. All of nine sequences identified in a data base search are truncated at their 5' regions and lack the tRNA-related region of the TS family. We characterized the entire sequence of the members of the TS family and found that this family can be categorized as a member of a group of SINEs with a tRNA(Lys)-like structure, as can several animal SINEs. The TS family can be divided into two major subfamilies by analysis of diagnostic positions, and one of the subfamilies is clearly younger than the other. Amplification of many copies of the full sequence of the younger subfamily occurred during the recent evolution of the tobacco lineage. We also discuss mechanisms that could be involved in the generation of SINEs in animals and also in plants.

Several short interspersed repetitive elements (SINEs) in distant species may have originated from a common ancestral retrovirus: characterization of a squid SINE and a possible mechanism for generation of tRNA-derived retroposons

Using labeled transcripts generated in vitro from squid total genomic DNA as a probe, we isolated and characterized a SINE that is present in the squid genome. The squid SINE appears to be derived from a tRNA(Lys). When the consensus sequences of five different SINEs with a tRNA(Lys)-like structure from distantly related species, including squid, were aligned, we found in the tRNA-unrelated region two sequence motifs that were almost identical among these five SINEs. This observation suggests a common evolutionary origin for these SINEs and/or some function(s) for these motifs. Similar sequences were unexpectedly found to be present in sequences complementary to the U5 regions of several mammalian retroviruses whose primer is a tRNA(Lys). On the basis of these findings, we present a model for the generation of SINEs. We propose that they are derived from a "strong-stop DNA" with a primer tRNA(Lys) that is an intermediate in the reverse transcription of certain retroviruses. Our model suggests that a certain group of SINEs may have been generated by horizontal transmission, although it is not clear whether information was transmitted via a similar retrovirus or via an RNA or DNA of a SINE.

Short interspersed nuclear element (SINE) sequences of the Bovidae

DNA sequences from Bovidae (cattle, goats and sheep) in the EMBL nucleotide database contain several short interspersed repeated sequences (SINEs). Three different SINEs have been found: Bov-A2, containing two 115-bp A elements; Bov-tA, a tRNA pseudogene coupled to an A element; and Bov-B of 560 bp or less and partially homologous to the A element. Bov-A2, Bov-tA and Bov-B occupy about 1.8%, 1.6% and 0.5%, respectively, of the bovine genome as represented in the nucleotide database. Apart from a tRNA-like sequence in both Bov-tA and the porcine SINEs, there was no similarity with the porcine SINEs. Apparently, the artiodactyle SINEs were established after the divergence leading to the Suidae and Bovidae but before the radiation within these families. Oligonucleotides were designed for a specific amplification of DNA from Bovidae.