A novel class of SINE elements derived from 5S rRNA

Eukaryotic genomes are colonized by different retroposons, including short interspersed repetitive elements (SINEs). All currently known SINEs are derived from tRNA and 7SL RNA genes and exploit their type 2 internal pol III promoters. We report here a novel class of SINE elements, called SINE3, derived from 5S rRNA. SINE3s are transcribed from the type 1 internal pol III promoter. Approximately 10,000 copies of SINE3 elements are present in the zebrafish genome, they constitute approximately 0.4% of the genomic DNA. Some elements are as little as 1% diverged from each other, indicating that the retrotransposition of SINE3 in zebrafish is an ongoing process. The 3'-tail of SINE3 is significantly similar to that of CR1-like non-LTR retrotransposons, represented by numerous subfamilies in the zebrafish genome. Analogously to CR1-like elements, SINE3 copies are not flanked by target site duplications, and their 3' termini are composed of (ACATT)n and (ATT)n microsatellites, specific for different subfamilies of SINE3. Given the common structural features, it is highly likely that the enzymatic machinery encoded by CR1-like elements powers proliferation of SINE3.     

PCR detection of DNAs of animal origin in feed by primers based on sequences of short and long interspersed repetitive elements

PCR primers for the detection of materials derived from ruminants, pigs, and chickens were newly designed on the basis of sequences of the Art2 short interspersed repetitive element (SINE), PRE-1 SINE, and CR1 long interspersed repetitive element (LINE), respectively. These primers amplified the SINE or LINE from total DNA extracted from the target animals and from test feed containing commercial meat and bone meal (MBM). With the primers, detection of Art2, PRE-1, or CR1 in test feed at concentrations of 0.01% MBM or less was possible. This method was suitable for the detection of microcontamination of feed by animal materials.     

Sjalpha elements, short interspersed element-like retroposons bearing a hammerhead ribozyme motif from the genome of the oriental blood fluke Schistosoma japonicum

Smalpha is a short interspersed element (SINE)-like retroposon that occurs in high copy number of the genome of the human blood fluke Schistosoma mansoni. The sequence of the consensus Smalpha element includes the hallmark features of SINE-like elements including a promoter region for RNA polymerase III, an AT-rich stretch at its 3'-terminus, a short length of 500 bp or less, and short direct repeat sequences flanking the insertion site. Interestingly, the sequence of Smalpha also encodes an active ribozyme bearing a hammerhead domain. Contrary to the recent findings of Ferbeyre et al. (Mol. Cell. Biol. 18 (1998) 3880-8) that indicated that Smalpha-like elements were absent from the genome of the Oriental blood fluke Schistosoma japonicum, we report here that the genome of S. japonicum does contain a family of Smalpha-like retroposons, elements that we have named the Sjalpha family. Like Smalpha, Sjalpha elements are SINE-like in structure and sequence, are present at high copy number interspersed throughout the S. japonicum genome, and contain an ostensibly functional, hammerhead ribozyme motif. The presence of these elements in all species of Schistosoma so far examined suggests that the hammerhead domain was acquired by vertical transmission from a common schistosome ancestor.     

Identification of a short interspersed repetitive element insertion polymorphism in the porcine MX1 promoter associated with resistance to porcine reproductive and respiratory syndrome virus infection

The myxovirus resistance (Mx) proteins belong to the dynamin superfamily and are important for innate host defence against RNA viruses. In this study, we demonstrate that positive elements are present in the two promoter regions of ?2713 to ?2565 and ?688 to ?431 in the porcine MX1 gene. Sequencing and alignment of the amplified porcine MX1 gene promoter region identified a short interspersed repetitive element (SINE) insertion of 275 bp at site ?547. At this site, allele B (an insertion of 275 bp) is dominant in Chinese indigenous pig breeds but has a workable minor allele frequency in western lean‐type pig breeds. Luciferase activity was compared between promoters with and without the insertion of the 275‐bp fragment in transiently transfected MARC‐145 cells. The insertion of the 275‐bp fragment increased the luciferase activity significantly (P < 0.05) both prior to and post‐porcine reproductive and respiratory syndrome (PRRS) virus inoculation. These results suggest that the SINE insertion polymorphism at site ?547 of the MX1 gene promoter region is a potential DNA marker for PRRS resistance in pigs.     

CetSINEs and AREs are not SINEs but are parts of cetartiodactyl L1

Short interspersed repetitive elements (SINEs) are widely distributed among the genomes of eukaryotes. We proposed previously that a SINE should be defined by the presence of a region homologous to a tRNA or to 7SL RNA, together with A-box and B-box promoter sequences, in order to distinguish SINEs from other short repetitive sequences, such as short segments of LINEs (long interspersed repetitive elements; Okada et al. Gene 205, 229–243, 1997). Numerous SINE sequences have been deposited to date in DNA databases. In some cases, however, designation of a particular sequence is problematic when the short repetitive sequence has been defined as a SINE without reference to the presence or absence of promoter elements specific for RNA polymerase III. We demonstrate here that four different sequences, namely, ARE1p, ARE2p, CetSINE1, and CetSINE2, each of which has been reported as a SINE, are, in fact, only partial sequences of members of a new subfamily of L1. We also demonstrate that members of this subfamily are distributed specifically among the genomes of cetartiodactyls. Received: 3 May 2000 / Accepted: 22 August 2000     

NeSL-1, an ancient lineage of site-specific non-LTR retrotransposons from Caenorhabditis elegans

Phylogenetic analyses of non-LTR retrotransposons suggest that all elements can be divided into 11 lineages. The 3 oldest lineages show target site specificity for unique locations in the genome and encode an endonuclease with an active site similar to certain restriction enzymes. The more "modern" non-LTR lineages possess an apurinic endonuclease-like domain and generally lack site specificity. The genome sequence of Caenorhabditis elegans reveals the presence of a non-LTR retrotransposon that resembles the older elements, in that it contains a single open reading frame with a carboxyl-terminal restriction-like endonuclease domain. Located near the N-terminal end of the ORF is a cysteine protease domain not found in any other non-LTR element. The N2 strain of C. elegans appears to contain only one full-length and several 5' truncated copies of this element. The elements specifically insert in the Spliced leader-1 genes; hence the element has been named NeSL-1 (Nematode Spliced Leader-1). Phylogenetic analysis confirms that NeSL-1 branches very early in the non-LTR lineage and that it represents a 12th lineage of non-LTR elements. The target specificity of NeSL-1 for the spliced leader exons and the similarity of its structure to that of R2 elements leads to a simple model for its expression and retrotransposition.     

Characterization of the IS895 family of insertion sequences from the cyanobacterium Anabaena sp. strain PCC 7120.

A family of repetitive elements from the cyanobacterium Anabaena sp. strain PCC 7120 was identified through the proximity of one element to the psbAI gene. Four members of this seven-member family were isolated and shown to have structures characteristic of bacterial insertion sequences. Each element is approximately 1,200 bp in length, is delimited by a 30-bp inverted repeat, and contains two open reading frames in tandem on the same DNA strand. The four copies differ from each other by small insertions or deletions, some of which alter the open reading frames. By using a system designed to trap insertion elements, one of the elements, denoted IS895, was shown to be mobile. The target site was not duplicated upon insertion of the element. Two other filamentous cyanobacterial strains were also found to contain sequences homologous to IS895.     

SINE retroposons can be used in vivo as nucleation centers for de novo methylation

SINEs (short interspersed elements) are an abundant class of transposable elements found in a wide variety of eukaryotes. Using the genomic sequencing technique, we observed that plant S1 SINE retroposons mainly integrate in hypomethylated DNA regions and are targeted by methylases. Methylation can then spread from the SINE into flanking genomic sequences, creating distal epigenetic modifications. This methylation spreading is vectorially directed upstream or downstream of the S1 element, suggesting that it could be facilitated when a potentially good methylatable sequence is single stranded during DNA replication, particularly when located on the lagging strand. Replication of a short methylated DNA region could thus lead to the de novo methylation of upstream or downstream adjacent sequences.     

Competition between R1 and R2 transposable elements in the 28S rRNA genes of insects

R1 and R2 are non-LTR retrotransposons that insert in the 28S rRNA genes of arthropods. R1 elements insert into a site that is 74 bp downstream of the R2 insertion site, thus the presence of an R2 in the same 28S gene may inhibit the expression of R1. Consistent with such a suggestion, the R1 elements of Drosophila melanogaster have a strong bias against inserting into 28S genes already containing an R2 element. R2 elements, on the other hand, are only 2-3 fold inhibited from inserting into a 28S gene already containing an R1. D. melanogaster R1 elements are unusual in that they generate a 23-bp deletion of the target site upstream of the insertion. Using in vitro assays developed to study R2 integration, we show that the presence of R1 sequences 51 bp downstream of the R2 insertion site changes the nucleosomal structure that can be formed by the R2 target site. The R2 endonuclease is inhibited from cleaving these altered nucleosomes. We suggest that R1 elements have been selected to make this large deletion of the 28S gene to block the insertion of an upstream R2 element. These findings are consistent with the model that R1 and R2 are in competition for the limited number of insertion sites available within their host's genome.     

Comparative studies of the endonucleases from two related Xenopus laevis retrotransposons, Tx1L and Tx2L: target site specificity and evolutionary implications

In the genome of the South African frog, Xenopus laevis, there are two complex families of transposable elements, Tx1 and Tx2, that have identical overall structures, but distinct sequences. In each family there are approximately 1500 copies of an apparent DNA-based element (Tx1D and Tx2D). Roughly 10% of these elements in each family are interrupted by a non-LTR retrotransposon (Tx1L and Tx2L). Each retrotransposon is flanked by a 23-bp target duplication of a specific D element sequence. In earlier work, we showed that the endonuclease domain (Tx1L EN) located in the second open reading frame (ORF2) of Tx1L encodes a protein that makes a single-strand cut precisely at the expected site within its target sequence, supporting the idea that Tx1L is a site-specific retrotransposon. In this study, we express the endonuclease domain of Tx2L (Tx2L EN) and compare the target preferences of the two enzymes. Each endonuclease shows some preference for its cognate target, on the order of 5-fold over the non- cognate target. The observed discrimination is not sufficient, however, to explain the observation that no cross-occupancy is observed – that is, L elements of one family have never been found within D elements of the other family. Possible sources of additional specificity are discussed. We also compare two hypotheses regarding the genome duplication event that led to the contemporary pseudotetraploid character of Xenopus laevis in light of the Tx1L and Tx2L data. This revised version was published online in July 2006 with corrections to the Cover Date.