Transposon Tagging Using Ty Elements in Yeast

We have used the ability to induce high levels of Ty transposition to develop a method for transposon mutagenesis in Saccharomyces cerevisiae. To facilitate genetic and molecular analysis, we have constructed GAL1-promoted TyH3 or Ty917 elements that contain unique cloning sites, and marked these elements with selectable genes. These genes include the yeast HIS3 gene, and the plasmid PiAN7 containing the Tn903 NEO gene. The marked Ty elements retain their ability to transpose, to mutate the LYS2, LYS5, or STE2 genes, and to activate the promoterless his3 delta 4 target gene. Ty elements containing selectable genes are also useful in strain construction, in chromosomal mapping, and in gene cloning strategies.     

Chromatin structure in a region of a yeast transposable element regulating adjacent gene expression.

The chromatin structure of a portion of yeast transposable elements known to be responsible for regulation of the expression of the adjacent HIS4 gene has been investigated, using the nuclease probe micrococcal nuclease. Yeast strains containing Ty917 or derivatives of this element that possess either a His-, weak His+, or strong His+ phenotype were examined. The chromatin at the Ty/HIS4 junction region was accessible to micrococcal nuclease. A partial nucleosome ladder was observed upon digestion with micrococcal nuclease indicating the presence of three phased nucleosomes located in Ty sequences upstream of the HIS4 gene. Phased nucleosomes could not be detected upstream of the HIS4 gene in wild-type cells. These data suggest that nucleosomal structure is not a major contributor to Ty917-regulated adjacent gene expression at HIS4.     

New selectable marker/auxotrophic host strain combinations for molecular genetic manipulation of Pichia pastoris

We describe the isolation and characterization of three new biosynthetic genes-ARG4, ADE1, and URA3-from the methylotrophic yeast Pichia pastoris. The predicted products of the genes share significant sequence similarity to their Saccharomyces cerevisiae counterparts, namely argininosuccinate lyase, PR-aminoimidazolesuccinocarboxamide synthase, and orotidine-5'-phosphate decarboxylase, respectively. Along with the previously described HIS4 gene, each gene was incorporated as the yeast selectable marker into a set of shuttle vectors designed to express foreign genes in P. pastoris. In addition, we have constructed a series of host strains containing all possible combinations of ade1, arg4, his4, and ura3 auxotrophies to be used with these new vectors.     

Intrachromosomal movement of genetically marked Saccharomyces cerevisiae transposons by gene conversion.

In this paper, we describe the movement of a genetically marked Saccharomyces cerevisiae transposon. Ty912(URA3), to new sites in the S. cerevisiae genome. Ty912 is an element present at the HIS4 locus in the his4-912 mutant. To detect movement of Ty912, this element has been genetically marked with the S. cerevisiae URA3 gene. Movement of Ty912(URA3) occurs by recombination between the marked element and homologous Ty elements elsewhere in the S. cerevisiae genome. Ty912(URA3) recombines most often with elements near the HIS4 locus on chromosome III, less often with Ty elements elsewhere on chromosome III, and least often with Ty elements on other chromosomes. These recombination events result in changes in the number of Ty elements present in the cell and in duplications and deletions of unique sequence DNA.     

Physical analysis of the CYC1-sup4 interval in Saccharomyces cerevisiae.

CYC1 and sup4 are part of a tightly linked cluster of genes on chromosome X in the yeast Saccharomyces cerevisiae. Using as probes previously cloned fragments containing the CYC1 and sup4 genes, we have identified and cloned the deoxyribonucleic acid (DNA) present between these genes in one strain of yeast. We find that the CYC1 and sup4 genes are approximately 21 kilobases apart. In the same strain, the meiotic map distance is approximately 3.7 centimorgans, for a ratio of 5.6 kilobases per centimorgan in this interval. The physical mapping has allowed unambiguous determination of the orientation of CYC1 and sup4 relative to each other, the centromere, and a nearby transfer ribonucleic acid (tRNA(2Ser)) gene. The spontaneous mutation cyc1-1 inactivates the CYC1 gene as well as the neighboring loci OSM1 and RAD7. We have determined that a cyc1-1-bearing strain lacks approximately 13 kilobases of single-copy DNA from the CYC1-sup4 region, including all of the CYC1 coding information. There is a sequence homologous to the middle-repetitive element Ty1 at or near the breakpoint of the cyc1-1 deletion. We discuss the possibility that Ty elements play a role in the formation of such large, spontaneous deletions, which occur frequently in this region of chromosome X in certain yeast strains.     

The Saccharomyces cerevisiae genome contains functional and nonfunctional copies of transposon Ty1.

Saccharomyces cerevisiae Ty elements are transposons closely related to retroviruses. The DNA sequence of a functional Ty element (TyH3) is presented. The long terminal repeat sequences are different, suggesting that TyH3 is a recombinant Ty element. A chromosomal Ty element near the LYS2 gene, Ty173, was found to be nonfunctional, even though it has no detectable insertions or deletions. The defect in Ty173 transposition is caused by a missense mutation giving rise to a Leu-to-Ile substitution in the TYB (pol) open reading frame. Several chromosomal Ty elements carry this lesion in their DNA, indicating that nonfunctional Ty elements are common in the yeast genome.     

Doubling Ty1 Element Copy Number in Saccharomyces Cerevisiae: Host Genome Stability and Phenotypic Effects

Haploid yeast strains bearing approximately double the normal number of Ty1 elements have been constructed using marked GAL/Ty1 fusion plasmids. The strains maintain their high transposon copy number and overall genome structure in the absence of selection. The strains bearing extra Ty1 copies are surprisingly similar phenotypically to the parental strain. The results suggest that the limit to transposon copy number, if any, has not been reached. When these strains are crossed by wild-type strains (i.e., bearing the normal complement of Ty1 elements) or by strains of opposite mating type also bearing excess Ty1 elements, normal to very slightly reduced spore viability is observed, indicating that increasing the extent of transposon homology scattered around the genome does not result in significant increases in frequency of ectopic reciprocal recombination. The results suggest that yeast cells have evolved mechanisms for coping with excess transposon copies in the genome.     

Evidence for transposition of dispersed repetitive DNA families in yeast.

Dispersed repetitive DNA sequences from yeast (Saccharomyces cerevisiae) nuclear DNA have been isolated as molecular hybrids in lambdagt. Related S. cerevisiae strains show marked alterations in the size of the restriction fragments containing these repetitive DNAs. "Ty1" is one such family of repeated sequences in yeast and consists of a 5.6 kilobase (kb) sequence including a noninverted 0.25 kb sequence of another repetitious family, "delta", on each end. There are about 35 copies of Ty1 and at least 100 copies of delta (not always associated with Ty1) in the haploid genome. A few Ty1 elements are tandem and/or circular, but most are disperse and show (along with delta) some sequence divergence between repeat units. Sequence alterations involving Ty1 elements have been found during the continual propagation of a single yeast clone over the course of a month. One region with a large number of delta sequences (SUP4) also shows a high frequency of sequence alterations when different strains are compared. One of the differences between two such strains involves the presence or absence of a Ty1 element. The novel joint is at one inverted pair of delta sequences.     

Site-specific integration of heterologous genes in yeast via Ty3 retrotransposition

The Ty3 retrotransposon of Saccharomyces cerevisiae was employed for the site-specific integration of heterologous genes into the yeast genome. A GAL-regulated promoter allowed induction of the retrotransposition process, and a bacterial neo(r) gene inserted in the Ty3 element was used as a selectable model heterologous gene. The frequency of transposition of this neo(r)-marked element was found to be comparable to that of an unmarked element. Three amplification systems were constructed; the systems varied with respect to the location and number of the GAL-regulated helper and neo(r)-marked Ty3 elements. For all three systems, neo(r) integrations were readily selected with a maximum of two insertions obtained per round of amplification. A sequential amplification strategy was effective for further increasing the number of integrated cloned genes, and families of strains varying by only one neo(r) insertion were easily obtained. Resistance to the antibiotic G418 correlated well with the number of integrated neo(r) genes, and Northern blots verified the relationship between cloned gene number (up to four) and neo(r) expression. Structural stability of the integrated genes was also demonstrated. By controlling the number of rounds of amplification and the level of G418 selection, precise numbers of integrated heterologous genes could be obtained. Because the amplification process can be repeated using different cloned genes inserted in the Ty3 element, these results demonstrate the potential of retrotransposition for the regulated integration of a series of different genes at nondeleterious chromosomal locations.