Retropositional parasitism of SINEs on LINEs: identification of SINEs and LINEs in elasmobranchs.

Some previously unidentified short interspersed repetitive elements (SINEs) and long interspersed repetitive element (LINEs) were isolated from various higher elasmobranchs (sharks, skates, and rays) and characterized. These SINEs, members of the HE1 SINE family, were tRNA-derived and were widespread in higher elasmobranches. The 3'-tail region of this SINE family was strongly conserved among elasmobranchs. The LINEs, members of the HER1 LINE family, encoded an amino acid sequence similar to that encoded by the chicken CR1 LINE family, and they contained a strongly conserved 3'-tail region in the 3' untranslated region. This tail region of the HER1 LINE family was almost identical to that of the HE1 SINE family. Thus, the HE1 SINE family and the HER1 LINE family provide a clear example of a pair of SINEs and LINEs that share the same tail region. Conservation of the secondary structures of the tail regions, as well as of the nucleotide sequences, between the HE1 SINE family and HER1 LINE family during evolution suggests that SINEs utilize the enzymatic machinery for retroposition of LINEs through the recognition of higher-order structures of the conserved 3'-tail region. A discussion is presented of the parasitism of SINEs on LINEs during the evolution of these retroposons.     

Cold-induced retrotransposition of fish LINEs

Classes of retrotransposons constitute a large portion of metazoan genome. There have been cases reported that genomic abundance of retrotransposons is correlated with the severity of low environmental temperatures. However, the molecular mechanisms underlying such correlation are unknown. We show here by cell transfection assays that retrotransposition(RTP) of a long interspersed nuclear element(LINE) from an Antarctic notothenioid fish Dissostichus mawsoni(dmLl) could be activated by low temperature exposure, causing increased dmL1 copies in the host cell genome. The cold-induced dmL1 propagation was demonstrated to be mediated by the mitogen-activated protein kinases(MAPK)/p38 signaling pathway, which is activated by accumulation of reactive oxygen species(ROS) in cold-stressed conditions. Surprisingly, dmL1 transfected cells showed an increase in the number of viable cells after prolonged cold exposures than non-transfected cells. Features of cold inducibility of dmL1 were recapitulated in LINEs of zebrafish origin both in cultured cell lines and tissues, suggesting existence of a common cold-induced LINE amplification in fishes. The findings reveal an important function of LINES in temperature adaptation and provid insights into the MAPK/p38 stress responsive pathway that shapes LINE composition in fishes facing cold stresses.     

Molecular evolution of Bov-B LINEs in vertebrates

Since their discovery in family Bovidae (bovids), Bov-B LINEs, believed to be order-specific SINEs, have been found in all ruminants and recently also in Viperidae snakes. The distribution and the evolutionary relationships of Bov-B LINEs provide an indication of their origin and evolutionary dynamics in different species. The evolutionary origin of Bov-B LINE elements has been shown unequivocally to be in Squamata (squamates). The horizontal transfer of Bov-B LINE elements in vertebrates has been confirmed by their discontinuous phylogenetic distribution in Squamata (Serpentes and two lizard infra-orders) as well as in Ruminantia, by the high level of nucleotide identity, and by their phylogenetic relationships. The direction of horizontal transfer from Squamata to the ancestor of Ruminantia is evident from the genetic distances and discontinuous phylogenetic distribution of Bov-B LINE elements. The ancestor of Colubroidea snakes has been recognized as a possible donor of Bov-B LINE elements to Ruminantia. The timing of horizontal transfer has been estimated from the distribution of Bov-B LINE elements in Ruminantia and the fossil data of Ruminantia to be 40-50 My ago. The phylogenetic relationships of Bov-B LINE elements from the various Squamata species agrees with that of the species phylogeny, suggesting that Bov-B LINE elements have been stably maintained by vertical transmission since the origin of Squamata in the Mesozoic era.     

Straightening out the LINEs: LINE-1 orthologous loci

The L1Hs preTa subfamily of long interspersed elements (LINEs) originated after the divergence of human and chimpanzee and is therefore found only in the human genome. Thirty-three of the 254 L1Hs preTa elements are polymorphic for the absence/presence of the insertion, making them useful markers for studying human population genetics. The problem of homoplasy, however, can diminish the value of LINEs as phylogenetic and population genetic markers. We examined anomalous orthologous sites in a range of nonhuman primates. Only two cases of other mobile elements inserting near the preintegration sites of L1Hs preTa elements were observed: an AluY insertion in Chlorocebus and an L1PA8 insertion in Aotus. Sequence analysis showed that both elements were clearly distinguishable from their human counterparts. We conclude that L1 elements can continue to be regarded as essentially homoplasy-free genetic characters.     

植物基因组中的非LTR反转录转座子SINEs和LINEs

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

A new class of LINEs (ATLN-L) from Arabidopsis thaliana with extraordinary structural features.

The Arabidopsis thaliana genome has about 250 copies of LINEs (here called ATLNs). Of these, some, called ATLN-Ls, have an extra sequence of about 2 kb in the region downstream of two consecutive open reading frames, orf1 and orf2. Interestingly, the extra sequences in these ATLN-L members have another open reading frame, designated as orf3. Each member is flanked by direct repeats of a target site sequence, showing that ATLN-L members with the three open reading frames have retrotransposed as a unit. The ATLN-L members are also distinct from other ATLN members: orf1 terminates with TAA (or TAG) and is located in the same frame as orf2, and the ATG initiation codon of orf2 is not present in the proximal region. A sequence that may form a pseudoknot structure in ATLN-L mRNA was present in the proximal region of orf2, therefore the TAA (or TAG) termination codon of orf1 is assumed to be suppressed to produce an Orf1-Orf2 transframe protein during the translation of the ATLN-L mRNA. The region between orf2 and orf3 is several hundred bp long, suggesting that orf3 expression is independent of orfl-orf2. The amino acid sequences of the proteins Orf1 and Orf3 are highly homologous in their N-terminal half regions that have a retroviral zinc-finger motif for RNA binding. Orf3, however, has a leucine-zipper motif in addition to the zinc-finger motif. The C-terminal regions of the Orf1 and Orf3 proteins have poor homology, but seem to have nuclear localization signals, suggesting that these proteins are involved in the transfer of ATLN-L mRNA to nuclei. A phylogenetic tree shows that Orf3 proteins form a branch distinct from the branches of the Orf1 proteins encoded by ATLN-L members. This indicates that an ancestor element of ATLN-Ls has incorporated the orf1 frame carried by another ATLN member into its distal region to orf1-orf2 during evolution.     

Non-LTR retrotransposons (LINEs) as ubiquitous components of plant genomes

During the course of work aimed at isolating a rice gene from Oryza australiensis by PCR, the oligonucleotide primers used were found to generate a fragment that showed sequence homology to the endonuclease (EN) region of the maize non-LTR retrotransposon (LINE) Cin4. We carried out further PCRs using oligonucleotide primers that hybridized to these sequences, and found that they amplified several fragments, each with homology to the EN regions, from Oryza sativa cv. Nipponbare as well as O. australiensis. We mapped the approximate locations of two rice LINE homologues by screening clones in a YAC library made from a rice (O. sativa) genome, and found that each homologue was present in a low copy number apparently at nonspecific regions on rice chromosomes. We then carried out PCR using degenerate oligonucleotide primers which hybridized to the rice LINE homologues and Cin4 to ascertain whether LINE homologues are present in a variety of members of the plant kingdom, including angiosperms, gymnosperms, bracken, horsetail and liverwort. Cloning and nucleotide sequencing revealed that 53 clones obtained from 27 out of 33 plant species contained LINE homologues. In addition to these homologues, we identified four homologues with EN regions in the Arabidopsis thaliana genome by a computer search of databases. The nucleotide sequences of almost all the LINE homologues were greatly diverged, but the derived amino acid sequences were well conserved, and all contained glutamic acid and tyrosine residues at almost the same relative positions as in the the active site regions of AP (apurinic/apyrimidinic)-endonucleases. The EN regions in the LINE homologues from closely related plant species show a closer phylogenetic relationship, indicating that sequence divergence during vertical transmission has been a major influence upon the evolution of plant LINEs. Received: 13 July 1998 / Accepted: 13 October 1998     

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.     

SINEs and LINEs cluster in distinct DNA fragments of Giemsa band size

By in situ hybridization, short interspersed repeated DNA elements (SINEs), exemplified by Alu repeats, are located principally in Giemsa-light human metaphase chromosome bands. In contrast, the L1 family of long interspersed repeats (LINEs) preferentially cluster in Giemsa-dark bands. These SINE/LINE patterns also generally correspond to early and later replication band patterns. In order to provide a molecular link between structurally visible chromosome bands and a framework of interspersed repeats, we investigated patterns of SINE and LINE hybridization using pulse-field gel electrophoresis (PFGE). Interspersed SINEs and LINEs hybridize with high intensity to specific size fragments of 0.2–3 megabase pairs (Mb). Using appropriate restriction enzymes and pulse-field conditions, a number of fragments were delineated that were either SINE or LINE rich, and were mutually exclusive. Control studies with a human endogenous retroviral repeat that is related in sequence to the major LINE family, delineated a subset of fragments of 0.07–0.4 Mb with unequal intensity. Thus these less numerous repeats also appear to cluster selectively in DNA domains that are larger than a chromosome loop (60–120 kb). In summary, PFGE studies independently confirm the clustering of interspersed repeats on contiguous DNA loops. Selective clustering of repeat motifs may contribute to special structural or functional properties of large chromosome domains, such as chromatin extension/condensation or replication characteristics. In some cases the DNA fragments defined by these repeats approach the size of tandem satellite arrays.