bilbo, a non-LTR retrotransposon of Drosophila subobscura: a clue to the evolution of LINE-like elements in Drosophila

We used the repetitive character of transposable elements to isolate a non-LTR retrotransposon in Drosophila subobscura. bilbo, as we have called it, has homology to TRIM and LOA elements. Sequence analysis showed a 5' untranslated region (UTR), an open reading frame (ORF) with no RNA-binding domains, a downstream ORF that had structural homology to that of the I factor, and, finally, a 3' UTR which ended in several 5-nt repeats. The results of our phylogenetic and structural analyses shed light on the evolution of Drosophila non-LTR retrotransposons and support the hypothesis that an ancestor of these elements was structurally complex.      

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.     

Coevolution of telomeric repeats and telomeric repeat-specific non-LTR retrotransposons in insects

In the telomeres of the silkworm Bombyx mori, telomeric repeat-specific non-long terminal repeat (LTR) retrotransposon SARTBm1 is accumulated in the TTAGG telomeric repeats. Here, we identify novel telomeric repeat-specific non-LTR retrotransposons, SARTTc family, from the red flour beetle Tribolium castaneum in the unconventional TCAGG telomeric repeats. To compare the sequence specificity of SARTBm1 and SARTTc1, we developed a comparable ex vivo retrotransposition assay. Both SARTBm1 and SARTTc1 preferred the telomeric sequence of their hosts, suggesting that the target specificity of these retrotransposons coevolved with their host's telomeric repeats. Swapping experiment indicated that the endonuclease domain is involved in recognizing the target sequence. Moreover, SARTBm1 proteins could retrotranspose 3'untranslated region (UTR) sequence of SARTTc1 as well as their own 3'UTR, whereas SARTTc1 proteins could only retrotranspose their own 3'UTRs. These results provide insights to the mechanism and divergence of sequence specificity and 3'UTR recognition in non-LTR retrotransposons.     

Hypervariable 3′ UTR region of plant LTR-retrotransposons as a source of novel satellite repeats

The repetitive sequence PisTR-A has an unusual organization in the pea (Pisum sativum) genome, being present both as short dispersed repeats as well as long arrays of tandemly arranged satellite DNA. Cloning, sequencing and FISH analysis of both PisTR-A variants revealed that the former occurs in the genome embedded within the sequence of Ty3/gypsy-like Ogre elements, whereas the latter forms homogenized arrays of satellite repeats at several genomic loci. The Ogre elements carry the PisTR-A sequences in their 3′ untranslated region (UTR) separating the gag-pol region from the 3′ LTR. This region was found to be highly variable among pea Ogre elements, and includes a number of other tandem repeats along with or instead of PisTR-A. Bioinformatic analysis of LTR-retrotransposons mined from available plant genomic sequence data revealed that the frequent occurrence of variable tandem repeats within 3′ UTRs is a typical feature of the Tat lineage of plant retrotransposons. Comparison of these repeats to known plant satellite sequences uncovered two other instances of satellites with sequence similarity to a Tat-like retrotransposon 3′ UTR regions. These observations suggest that some retrotransposons may significantly contribute to satellite DNA evolution by generating a library of short repeat arrays that can subsequently be dispersed through the genome and eventually further amplified and homogenized into novel satellite repeats.     

The Krüppel-like transcriptional factors Zf9 and GKLF coactivate the human keratin 4 promoter and physically interact

A total of 4940 random sequence tags of the dimorphic yeast Yarrowia lipolytica, totalling 4.9 Mb, were analyzed. BLASTX comparisons revealed at least 1229 novel Y. lipolytica genes 1083 genes having homology with Saccharomyces cerevisiae genes and 146 with genes from various other genomes. This confirms the rapid sequence evolution assumed for Y. lipolytica. Functional analysis of newly discovered genes revealed that several enzymatic activities were increased compared to S. cerevisiae, in particular, transport activities, ion homeostasis, and various metabolism pathways. Most of the mitochondrial genes were identified in contigs spanning more than 47 kb. Matches to retrotransposons were observed, including a S. cerevisiae Ty3 and a LINE element. The sequences have been deposited with EMBL under the accession numbers AL409956-AL414895.     

The changing tails of a novel short interspersed element in Aedes aegypti: genomic evidence for slippage retrotransposition and the relationship between 3' tandem repeats and the poly(dA) tail

A novel family of tRNA-related SINEs named gecko was discovered in the yellow fever mosquito, Aedes aegypti. Approximately 7200 copies of gecko were distributed in the A. aegypti genome with a significant bias toward A + T-rich regions. The 3' end of gecko is similar in sequence and identical in secondary structure to the 3' end of MosquI, a non-LTR retrotransposon in A. aegypti. Nine conserved substitutions and a deletion separate gecko into two groups. Group I includes all gecko that end with poly(dA) and a copy that ends with AGAT repeats. Group II comprises gecko elements that end with CCAA or CAAT repeats. Members within each group cannot be differentiated when the 3' repeats are excluded in phylogenetic and sequence analyses, suggesting that the alterations of 3' tails are recent. Imperfect poly(dA) tail was recorded in group I and partial replication of the 3' tandem repeats was frequently observed in group II. Genomic evidence underscores the importance of slippage retrotransposition in the alteration and expansion of the tandem repeat during the evolution of gecko sequences, although we do not rule out postinsertion mechanisms that were previously invoked to explain the evolution of Alu-associated microsatellites. We propose that the 3' tandem repeats and the poly(dA) tail may be generated by similar mechanisms during retrotransposition of both SINEs and non-LTR retrotransposons and thus the distinction between poly(dA) retrotransposons such as L1 and non-poly(dA) retrotransposons such as I factor may not be informative.