Molecular analysis of the yeast Ty4 element: homology with Ty1, copia, and plant retrotransposons

Horizontal transfer and recombination fuel Ty4 retrotransposon evolution in Saccharomyces

Horizontal transposon transfer (HTT) plays an important role in the evolution of eukaryotic genomes, however the detailed evolutionary history and impact of most HTT events remain to be elucidated. To better understand the process of HTT in closely-related microbial eukaryotes, we studied Ty4 retrotransposon subfamily content and sequence evolution across the genus Saccharomyces using short- and long-read whole genome sequence data, including new PacBio genome assemblies for two S. mikatae strains. We find evidence for multiple independent HTT events introducing the Tsu4 subfamily into specific lineages of S. paradoxus, S. cerevisiae, S. eubayanus, S. kudriavzevii and the ancestor of the S. mikatae/S. jurei species pair. In both S. mikatae and S. kudriavzevii, we identified novel Ty4 clades that were independently generated through recombination between resident and horizontally-transferred subfamilies. Our results reveal that recurrent HTT and lineage-specific extinction events lead to a complex pattern of Ty4 subfamily content across the genus Saccharomyces. Moreover, our results demonstrate how HTT can lead to coexistence of related retrotransposon subfamilies in the same genome that can fuel evolution of new retrotransposon clades via recombination.

The structure and retrotransposition mechanism of LTR-retrotransposons in the asexual yeast Candida albicans

Retrotransposons constitute a major part of the genome in a number of eukaryotes. Long-terminal repeat (LTR) retrotransposons are one type of the retrotransposons. Candida albicans have 34 distinct LTR-retrotransposon families. They respectively belong to the Ty1/copia and Ty3/gypsy groups which have been extensively studied in the model yeast Saccharomyces cerevisiae. LTR-retrotransposons carry two LTRs flanking a long internal protein-coding domain, open reading frames. LTR-retrotransposons use RNA as intermediate to synthesize double-stranded DNA copies. In this article, we describe the structure feature, retrotransposition mechanism and the influence on organism diversity of LTR retrotransposons in C. albicans. We also discuss the relationship between pathogenicity and LTR retrotransposons in C. albicans.

Genomic evolution of the long terminal repeat retrotransposons in hemiascomycetous yeasts

We identified putative long terminal repeat- (LTR) retrotransposon sequences among the 50,000 random sequence tags (RSTs) obtained by the Génolevures project from genomic libraries of 13 Hemiascomycetes species. In most cases additional sequencing enabled us to assemble the whole sequences of these retrotransposons. These approaches identified 17 distinct families, 10 of which are defined by full-length elements. We also identified five families of solo LTRs that were not associated with retrotransposons. Ty1-like retrotransposons were found in four of five species that are phylogenetically related to Saccharomyces cerevisiae (S. uvarum, S. exiguus, S. servazzii, and S. kluyveri but not Zygosaccharomyces rouxii), and in two of three Kluyveromyces species (K. lactis and K. marxianus but not K. thermotolerans). Only multiply crippled elements could be identified in the K. lactis and S. servazzii strains analyzed, and only solo LTRs could be identified in S. uvarum. Ty4-like elements were only detected in S. uvarum, indicating that these elements appeared recently before speciation of the Saccharomyces sensu stricto species. Ty5-like elements were detected in S. exiguus, Pichia angusta, and Debaryomyces hansenii. A retrotransposon homologous with Tca2 from Candida albicans, an element absent from S. cerevisiae, was detected in the closely related species D. hansenii. A complete Ty3/gypsy element was present in S. exiguus, whereas only partial, often degenerate, sequences resembling this element were found in S. servazzii, Z. rouxii, S. kluyveri, C. tropicalis, and Yarrowica lipolytica. P. farinosa (syn. P. sorbitophila) is currently the only yeast species in which no LTR retrotransposons or remnants have been found. Thorough analysis of protein sequences, structural characteristics of the elements, and phylogenetic relationships deduced from these data allowed us to propose a classification for the Ty1/copia elements of hemiascomycetous yeasts and a model of LTR-retrotransposon evolution in yeasts.

Tca5, a Ty5-like retrotransposon from Candida albicans

This report describes the identification and characterization of a retrotransposon, termed Tca5, from the pathogenic yeast Candida albicans. Tca5 has identical 685 bp LTRs flanking 4218 bp of internal sequence within which lies a single long ORF. Immediately internal to the left LTR is a primer binding site complementary to an internal portion of the initiator methionine tRNA and upstream of the right LTR is a polypurine tract. The ORF predicts a protein containing all the conserved motifs characteristic of Gag, protease, integrase, reverse transcriptase and RNaseH. Genomic Southern blots probed with Tca5 sequences show that it is a low copy number element and is present at different loci in different strains. This, together with the apparently intact structure of Tca5, suggests that it has transposed very recently. Potentially full-length Tca5 transcripts were detected in some strains raising the possibility that some copies of Tca5 may still be active. Phylogenetic analyses and other sequence comparisons suggest that Tca5 is most closely related to the Ty5 element of Saccharomyces cerevisiae and S. paradoxus. The nucleotide sequence of Tca5 has been submitted to GenBank under Accession No. AF093417.

Chromosomes, karyotype analysis, chromosome rearrangements in fungi

In this review the organization of fungal chromosomes and the methods used for karyotype analysis are briefly summarized. The role of chromosome rearrangement, supernumerary chromosomes and repeated DNA sequences in the genetic change of fungi is evaluated.

Tempo and mode of Ty element evolution in Saccharomyces cerevisiae

The Saccharomyces cerevisiae genome contains five families of long terminal repeat (LTR) retrotransposons, Ty1-Ty5. The sequencing of the S. cerevisiae genome provides an unprecedented opportunity to examine the patterns of molecular variation existing among the entire genomic complement of Ty retrotransposons. We report the results of an analysis of the nucleotide and amino acid sequence variation within and between the five Ty element families of the S. cerevisiae genome. Our results indicate that individual Ty element families tend to be highly homogenous in both sequence and size variation. Comparisons of within-element 5' and 3' LTR sequences indicate that the vast majority of Ty elements have recently transposed. Furthermore, intrafamily Ty sequence comparisons reveal the action of negative selection on Ty element coding sequences. These results taken together suggest that there is a high level of genomic turnover of S. cerevisiae Ty elements, which is presumably in response to selective pressure to escape host-mediated repression and elimination mechanisms.

Yeast retrotransposon Ty4: the majority of the rare transcripts lack a U3-R sequence

The retrotransposon Ty4 is found in different yeast strains at only one to three copies per haploid genome. In the present study, we aimed at relating the apparent low transpositional activity of Ty4 to transcriptional features of this element. RT-PCR revealed that Ty4 is transcribed at a very low level, being comparable with that of GAL4. Contrary to other Ty elements, the transcriptional rate of Ty4 is not affected in a sin4 background nor by treatment of cells with alpha factor. From experiments measuring the expression levels in 1acZ fusion constructs, we conclude that Ty4 transcription is repressed by a negative regulating element residing within the LTR, whereas positive cis-acting elements, like those that have been found to mediate expression of Ty1/2 and Ty3, are absent from Ty4. Analysing Ty4 transcript termini by the RACE-PCR method, we found several distinct transcriptional initiation sites. But surprisingly, the majority of the polyadenylated Ty4 transcripts terminate shortly upstream from the 3' LTR boundary, so that these transcripts do not contain a U3-R sequence, which is normally required for obligate strand transfer during DNA synthesis. Thus, the extremely low transcription rate of Ty4 and imperfect Ty4 transcripts are the reason for the low transpositional activity of this element.

Easel, a gypsy LTR-retrotransposon in the Salmonidae

Despite the close similarities between retroviruses and the gypsy/Ty3 group of LTR-retrotransposons their host ranges are largely distinct: the retroviruses are found only in vertebrates, whereas the gypsy LTR-retrotransposons are almost exclusively restricted to invertebrates, plants and fungi. Here we report the amplification by PCR, and characterisation, of one of the first LTR-retrotransposons to be discovered in vertebrates--in several members of the piscine family Salmonidae. Phylogenetic analysis of this retroelement, termed easel, indicates that it is probably a phylogeneticaly basal member of the gypsy group of LTR-retrotransposons and occurs in some of the same species from which retroviruses have previously been isolated. Thus some members of the Salmonidae are the first organisms known to harbour both retroviral branch elements and the gypsy LTR-retrotransposon branch elements. This creates an overlap in the host ranges of the two retroelement families.

Yeast Ty1 retrotransposon: the minus-strand primer binding site and a cis-acting domain of the Ty1 RNA are both important for packaging of primer tRNA inside virus-like particles

Reverse transcription of the yeast retrotransposon Ty1 is primed by the cytoplasmic initiator methionine tRNA (tRNA(iMet)). The primer tRNA(iMet) is packaged inside virus-like particles (VLPs) and binds to a 10 nucleotides minus-strand primer binding site, the (-)PBS, complementary to its 3' acceptor stem. We have found that three short sequences of the Ty1 RNA (box 1, box 2.1 and box 2.2) located 3' to the (-)PBS are complementary to other regions of the primer tRNA(iMet) (T psi C and DHU stems and loops). Reconstitution of reverse transcription in vitro with T7 transcribed Ty1 RNA species and tRNA(iMet) purified from yeast cells shows that the boxes do not affect the efficiency of reverse transcription. Thus the role of the boxes on packaging of the primer tRNA(iMet) into the VLPs was investigated by analysing the level of tRNA(iMet) packaged into mutant VLPs. Specific nucleotide changes in the (-)PBS or in the boxes that do not change the protein coding sequence but disrupt the complementarity with the primer tRNA(iMet) within the VLPs. We propose that base pairing between the primer tRNA(iMet) and the Ty1 RNA is of major importance for tRNA(iMet) packaging into the VLPs. Moreover the intactness of the boxes is essential for retrotransposition as shown by the transposition defect of a Ty1 element harboring an intact (-)PBS and mutated boxes.