Expression strategies of the yeast retrotransposon Ty: a short sequence directs ribosomal frameshifting

The Ty element of yeast is a member of a class of eukaryotic transposons which bear a striking resemblance to retroviral proviruses in their structure and expression strategies (1,2). A direct comparison can be drawn between the production of a fusion protein encoded by Ty, resulting from a frameshift event which fuses two out-of-phase open reading frames TYA and TYB, and the production of Pr180gag-pol in a retrovirus such as Rous Sarcoma Virus (RSV) (3,4). We present data which shows, definitively, that RNA splicing is not responsible for the frameshift in Ty. By in vitro mutation of a class I element, Ty1-15, we demonstrate that 31 nucleotides contained within the region where the TYA and TYB open reading frames overlap direct the frameshift. Within this short sequence there is a region of homology with a class II element which we show is also able to frameshift.     

Heterogeneous Functional Ty1 Elements Are Abundant in the Saccharomyces Cerevisiae Genome

Despite the abundance of Ty1 RNA in Saccharomyces cerevisiae, Ty1 retrotransposition is a rare event. To determine whether transpositional dormancy is the result of defective Ty1 elements, functional and defective alleles of the retrotransposon in the yeast genome were quantitated. Genomic Ty1 elements were isolated by gap repair-mediated recombination of pGTy1-H3(Δ475-3944)HIS3, a multicopy plasmid containing a GAL1/Ty1-H3 fusion element lacking most of the gag domain (TYA) and the protease (PR) and integrase (IN) domains. Of 39 independent gap repaired pGTyHIS3 elements isolated, 29 (74%) transposed at high levels following galactose induction. The presence of restriction site polymorphisms within the gap repaired region of the 29 functional pGTyHIS3 elements indicated that they were derived from at least eight different genomic Ty1 elements and one Ty2 element. Of the 10 defective pGTyHIS3 elements, one was a partial gap repair event while the other nine were derived from at least six different genomic Ty1 elements. These results suggest that most genomic Ty1 elements encode functional TYA, PR and IN proteins. To understand how functional Ty1 elements are regulated, we tested the hypothesis that a TYB protein associates preferentially in cis with the RNA template that encodes it, thereby promoting transposition of its own element. A genomic Ty1 mhis3AI element containing either an in-frame insertion in PR or a deletion in TYB transposed at the same rate as a wild-type Ty1mhis3AI allele, indicating that TYB proteins act efficiently in trans. This result suggests in principle that defective genomic Ty1 elements could encode trans-acting repressors of transposition; however, expression of only one of the nine defective pGTy1 isolates had a negative effect on genomic Ty1 mhis3AI element transposition in trans, and this effect was modest. Therefore, the few defective Ty1 elements in the genome are not responsible for transpositional dormancy.     

The production of hybrid Ty:IFN virus-like particles in yeast.

The yeast retrotransposon Ty encodes proteins that assemble into virus-like particles (Ty-VLPs) which can be readily purified. We have recently shown that expression of the pl protein encoded by the TYA gene of Ty is sufficient for particle formation. In this paper we show that when a heterologous coding sequence, human interferon-alpha 2 (IFN), is fused in frame to the TYA gene, the resulting p1-IFN fusion protein is still assembled into VLPs. These Ty:IFN-VLPs can be easily purified to near homogeneity and furthermore, they induce an antibody response to interferon when they are injected into rabbits. Therefore, these data show that hybrid Ty-VLPs can be used as a convenient system for the efficient purification of fusion proteins in yeast.     

A ''hot-spot'' for Ty transposition on the left arm of yeast chromosome III.

The small ring derivative of Saccharomyces cerevisiae chromosome III, which was formed by a cross-over between HML on the left arm and HMR on the right arm, contains three Ty elements. The class II element Ty 1-17 lies immediately centromere-distal to LEU2 on the left arm while two class I elements are tandemly arranged distal to PGK on the right arm. We have sequenced the regions of chromosome III surrounding Ty 1-17 and have defined a region where a number of transposition events have occurred. This region is flanked by the 5' ends of two tRNA genes, tRNA3Glu on the centromere distal side and tRNA3Leu immediately in front of LEU2. Close to the tRNA3Glu gene there is a region containing degenerate delta sequences organised in opposite orientations. Immediately distal to Ty 1-17 there are two complete solo delta elements, one inserted into the other. The sequence indicates that these two delta sequences were inserted into chromosome II by separate transposition events. A model is presented to explain how this structure arose and the role of solo delta elements in transposon propagation and maintenance is discussed.     

Nucleotide sequence characterization of Ty 1-17, a class II transposon from yeast

We have determined the nucleotide sequence of a class II yeast transposon (Ty 1-17) which is found just centromere-distal to the LEU2 structural gene on chromosome III of Saccharomyces cerevisiae. The complete element is 5961 bp long and is bounded by two identical, directly repeated, delta sequences of 332 bp each. The sequence organization indicates that Ty 1-17 is a retrotransposon, like the class I elements characterized previously. It contains two long open reading-frames, TyA (439 amino acids) and TyB (1349 amino acids). In this paper, the sequences of the two classes of yeast transposon are compared with one another and with analogous elements, such as retroviral proviruses, cauliflower mosaic virus and copia sequences. Features of the Ty 1-17 sequence which may be important to its mechanism of transposition and its genetic action are discussed.     

Characterization of a transpositionally active Ty3 element and identification of the Ty3 integrase protein.

Ty3 is a Saccharomyces cerevisiae retrotransposon associated with tRNA genes. Two Ty3 elements have been cloned and characterized. The complete nucleotide sequence for one element, Ty3-2, was reported previously (L. J. Hansen, D. L. Chalker, and S. B. Sandmeyer, Mol. Cell. Biol. 9:5245-5256, 1988). However, this element is incapable of autonomous transposition. The complete DNA sequence of a transpositionally competent Ty3 element, Ty3-1, is presented here. Its sequence translates into two overlapping open reading frames, TYA3-1 and TYB3-1, which encode proteins with homology to the proteins specified by the retroviral gag and pol genes, respectively. Comparison of the Ty3-1 nucleotide sequence to Ty3-2 suggests that the TYB3-2 open reading frame of Ty3-2 is truncated by the deletion of a single nucleotide, which causes a frameshift mutation. Restoration of the reading frame with insertion of a single adenine by site-directed mutagenesis converted Ty3-2 into a transpositionally active element, Ty3-2(+ A). Western blot analysis with antibodies made against synthetic peptides identified integrase (IN) proteins in viruslike particle preparations from cells expressing Ty3 elements. Cells expressing Ty3-1 and Ty3-2 (+A) produce antibody-reactive proteins with approximate molecular masses of 61 and 58 kilodaltons (kDa), while cells expressing Ty3-2 produce reactive proteins of approximately 52 and 49 kDa. Together, these data show that the 61- or 58-kDa protein, or both, provides the integrase function of Ty3.     

Genetic mapping of Ty elements in Saccharomyces cerevisiae.

We used transformation to insert a selectable marker at various sites in the Saccharomyces cerevisiae genome occupied by the transposable element Ty. The vector CV9 contains the LEU2+ gene and a portion of the repeated element Ty1-17. Transformation with this plasmid resulted in integration of the vector via a reciprocal exchange using homology at the LEU2 locus or at the various Ty elements that are dispersed throughout the S. cerevisiae genome. These transformants were used to map genetically sites of several Ty elements. The 24 transformants recovered at Ty sites define 19 distinct loci. Seven of these were placed on the genetic map. Two classes of Ty elements were identified in these experiments: a Ty1-17 class and Ty elements different from Ty1-17. Statistical analysis of the number of transformants at each class of Ty elements shows that there is preferential integration of the CV9 plasmid into the Ty1-17 class.     

Phylogenetic classification of prokaryotic and eukaryotic Sir2-like proteins

Sirtuins (Sir2-like proteins) are present in prokaryotes and eukaryotes. Here, two new human sirtuins (SIRT6 and SIRT7) are found to be similar to a particular subset of insect, nematode, plant, and protozoan sirtuins. Molecular phylogenetic analysis of 60 sirtuin conserved core domain sequences from a diverse array of organisms (including archaeans, bacteria, yeasts, plants, protozoans, and metazoans) shows that eukaryotic Sir2-like proteins group into four main branches designated here as classes I-IV. Prokaryotic sirtuins include members of classes II and III. A fifth class of sirtuin is present in gram positive bacteria and Thermotoga maritima. Saccharomyces cerevisiae has five class I sirtuins. Caenorhabditis elegans and Drosophila melanogaster have sirtuin genes from classes I, II, and IV. The seven human sirtuin genes include all four classes: SIRT1, SIRT2, and SIRT3 are class I, SIRT4 is class II, SIRT5 is class III, and SIRT6 and SIRT7 are class IV.     

Sequences flanking the hexameric G-box core CACGTG affect the specificity of protein binding.

The CACGTG G-box motif is a highly conserved DNA sequence that has been identified in the 5' upstream region of plant genes exhibiting regulation by a variety of environmental signals and physiological cues. Gel mobility shift assays using a panel of G-box oligonucleotides differing in their flanking sequences identified two types of binding activity (A and B) in a cauliflower nuclear extract. Competition gel retardation assays demonstrated that the two types of binding activity were distinct. Type A binding activity interacted with oligonucleotides designated as class I elements, whereas type B binding activity interacted strongly with class II elements and weakly with class I elements. A third class of elements, null elements, did not exhibit any detectable binding under our assay conditions. Gel retardation analysis of nonpalindromic hybrid G-box oligonucleotides indicated that hybrid elements of the same class exhibited binding affinity commensurate with the affinity of the weaker element, hybrid class I/II elements exhibited only type B binding, and hybrid class I/null and class II/null elements did not show any detectable binding activity. These binding activities can be explained by the affinity of bZip G-box binding homo- or heterodimer subunits for G-box half sites. These experiments led to a set of classification rules that can predict the binding activity of all reported plant G-box motifs containing the consensus hexameric core. Tissue- and/or development-specific expression of genes containing G-box motifs may be regulated by the affinity of G-box proteins for the different classes of G-box elements.