Characterization of the transmission during cytoductant formation of the 2 micrometers DNA plasmid from Saccharomyces

Phenotype-Independent Isolation of Interspecies Saccharomyces Hybrids by Dual-Dye Fluorescent Staining and Fluorescence-Activated Cell Sorting

Interspecies hybrids of Saccharomyces species are found in a variety of industrial environments and often outperform their parental strains in industrial fermentation processes. Interspecies hybridization is therefore increasingly considered as an approach for improvement and diversification of yeast strains for industrial application. However, current hybridization methods are limited by their reliance on pre-existing or introduced selectable phenotypes. This study presents a high-throughput phenotype-independent method for isolation of interspecies Saccharomyces hybrids based on dual dye-staining and subsequent mating of two strains, followed by enrichment of double-stained hybrid cells from a mating population by fluorescence-activated cell sorting (FACS). Pilot experiments on intra-species mating of heterothallic haploid S. cerevisiae strains showed that 80% of sorted double-stained cells were hybrids. The protocol was further optimized by mating an S. cerevisiae haploid with homothallic S. eubayanus spores with complementary selectable phenotypes. In crosses without selectable phenotype, using S. cerevisiae and S. eubayanus haploids derived from laboratory as well as industrial strains, 10 to 15% of double-stained cells isolated by FACS were hybrids. When applied to rare mating, sorting of double-stained cells consistently resulted in about 600-fold enrichment of hybrid cells. Mating of dual-stained cells and FACS-based selection allows efficient enrichment of interspecies Saccharomyces hybrids within a matter of days and without requiring selectable hybrid phenotypes, both for homothallic and heterothallic strains. This strategy should accelerate the isolation of laboratory-made hybrids, facilitate research into hybrid heterosis and offer new opportunities for non-GM industrial strain improvement and diversification.

Mitochondrial Genome Variation Affects Multiple Respiration and Nonrespiration Phenotypes in Saccharomyces cerevisiae

Mitochondrial genome variation and its effects on phenotypes have been widely analyzed in higher eukaryotes but less so in the model eukaryote Saccharomyces cerevisiae Here, we describe mitochondrial genome variation in 96 diverse S. cerevisiae strains and assess associations between mitochondrial genotype and phenotypes as well as nuclear-mitochondrial epistasis. We associate sensitivity to the ATP synthase inhibitor oligomycin with SNPs in the mitochondrially encoded ATP6 gene. We describe the use of iso-nuclear F1 pairs, the mitochondrial genome equivalent of reciprocal hemizygosity analysis, to identify and analyze mitochondrial genotype-dependent phenotypes. Using iso-nuclear F1 pairs, we analyze the oligomycin phenotype-ATP6 association and find extensive nuclear-mitochondrial epistasis. Similarly, in iso-nuclear F1 pairs, we identify many additional mitochondrial genotype-dependent respiration phenotypes, for which there was no association in the 96 strains, and again find extensive nuclear-mitochondrial epistasis that likely contributes to the lack of association in the 96 strains. Finally, in iso-nuclear F1 pairs, we identify novel mitochondrial genotype-dependent nonrespiration phenotypes: resistance to cycloheximide, ketoconazole, and copper. We discuss potential mechanisms and the implications of mitochondrial genotype and of nuclear-mitochondrial epistasis effects on respiratory and nonrespiratory quantitative traits.

2μ plasmid in Saccharomyces species and in Saccharomyces cerevisiae

We determined that extrachromosomal 2μ plasmid was present in 67 of the Saccharomyces cerevisiae 100-genome strains; in addition to variation in the size and copy number of 2μ, we identified three distinct classes of 2μ. We identified 2μ presence/absence and class associations with populations, clinical origin and nuclear genotypes. We also screened genome sequences of S. paradoxus, S. kudriavzevii, S. uvarum, S. eubayanus, S. mikatae, S. arboricolus and S. bayanus strains for both integrated and extrachromosomal 2μ. Similar to S. cerevisiae, we found no integrated 2μ sequences in any S. paradoxus strains. However, we identified part of 2μ integrated into the genomes of some S. uvarum, S. kudriavzevii, S. mikatae and S. bayanus strains, which were distinct from each other and from all extrachromosomal 2μ. We identified extrachromosomal 2μ in one S. paradoxus, one S. eubayanus, two S. bayanus and 13 S. uvarum strains. The extrachromosomal 2μ in S. paradoxus, S. eubayanus and S. cerevisiae were distinct from each other. In contrast, the extrachromosomal 2μ in S. bayanus and S. uvarum strains were identical with each other and with one of the three classes of S. cerevisiae 2μ, consistent with interspecific transfer.

Cellular dynamics of small RNAs

This review highlights the unexpectedly complicated nuclear egress and nuclear import of small RNAs. Although nucleus/cytoplasm trafficking was thought to be restricted to snRNAs of many, but not all, eukaryotes, recent data indicate that such traffic may be more common than previously appreciated. First, in conflict with numerous previous reports, new information indicates that Saccharomyces cerevisiae snRNAs may cycle between the nucleus and the cytoplasm. Second, recent studies also provide evidence that other small RNAs that function exclusively in the nucleus-the budding yeast telomerase RNA and possibly small nucleolar RNAs-may exit to the cytoplasm, only to return to the nucleus. Third, nucleus/cytoplasm cycling of RNAs also occurs for RNAs that function solely in the cytoplasm, as it has been discovered that cytoplasmic tRNAs of budding yeast travel "retrograde" to the nucleus and, perhaps, back again to the cytoplasm to function in protein synthesis. Fourth, there is at least one example in ciliates of small double-stranded RNAs traveling multiple cycles between the cytoplasm and distinct nuclei to direct genome structure. This report discusses data that support or argue against nucleus/cytoplasm bidirectional movement for each category of small RNA and the possible roles that such movement may serve.

Gene CATCHR--gene cloning and tagging for Caenorhabditis elegans using yeast homologous recombination: a novel approach for the analysis of gene expression

Expression patterns of gene products provide important insights into gene function. Reporter constructs are frequently used to analyze gene expression in Caenorhabditis elegans, but the sequence context of a given gene is inevitably altered in such constructs. As a result, these transgenes may lack regulatory elements required for proper gene expression. We developed Gene Catchr, a novel method of generating reporter constructs that exploits yeast homologous recombination (YHR) to subclone and tag worm genes while preserving their local sequence context. YHR facilitates the cloning of large genomic regions, allowing the isolation of regulatory sequences in promoters, introns, untranslated regions and flanking DNA. The endogenous regulatory context of a given gene is thus preserved, producing expression patterns that are as accurate as possible. Gene Catchr is flexible: any tag can be inserted at any position without introducing extra sequence. Each step is simple and can be adapted to process multiple genes in parallel. We show that expression patterns derived from Gene Catchr transgenes are consistent with previous reports and also describe novel expression data. Mutant rescue assays demonstrate that Gene Catchr-generated transgenes are functional. Our results validate the use of Gene Catchr as a valuable tool to study spatiotemporal gene expression.

Retrograde movement of tRNAs from the cytoplasm to the nucleus in Saccharomyces cerevisiae

In eukaryotes, tRNAs transcribed in the nucleus function in cytoplasmic protein synthesis. The Ran-GTP-binding exportin, Los1p/Xpo-t, and additional pathway(s) mediate tRNA transport to the cytoplasm. Although tRNA movement was thought to be unidirectional, recent reports that yeast precursor tRNA splicing occurs in the cytoplasm, whereas fully spliced tRNAs can reside in the nucleus, require that either the precursor tRNA splicing machinery or mature tRNAs move from the cytoplasm to the nucleus. Our data argue against the first possibility and strongly support the second. Combining heterokaryon analysis with fluorescence in situ hybridization, we show that a foreign tRNA encoded by one nucleus can move from the cytoplasm to a second nucleus that does not encode the tRNA. We also discovered nuclear accumulation of endogenous cytoplasmic tRNAs in haploid yeast cells in response to nutritional deprivation. Nuclear accumulation of cytoplasmic tRNA requires Ran and the Mtr10/Kap111 member of the importin-beta family. Retrograde tRNA nuclear import may provide a novel mechanism to regulate gene expression in eukaryotes.

A diverse set of nuclear RNAs transfer between nuclei of yeast heterokaryons

Small nuclear RNAs and small nucleolar RNAs function in the nucleus of eukaryotic cells during pre-mRNA splicing and ribosomal RNA processing, respectively. In metazoan cells, the small nuclear RNAs shuttle between the nucleus and the cytoplasm during ribonucleoprotein particle assembly. Nuclear export of these small RNAs in yeast, however, has not been demonstrated. Therefore, we have attempted to visualize internuclear RNA movements by in situ hybridization in heterokaryon yeast cells. Using the kar1Delta15 mutation to block karyogamy, we mated two strains, each expressing a unique allele of U1 snRNA. In these heterokaryons, we observed a time-dependent transfer of U1 snRNA from one nucleus to the other. This transfer was reduced two-fold by the addition of the Crm1p-inhibitor leptomycin B. Interestingly, however, we observed identical transfer of the U2 and U6 snRNAs and SNR4, SNR8, SNR9 and SNR11 snoRNAs. Remarkably, when the U2, U6 or SNR4 RNAs were observed in the same heterokaryon as the U1 snRNA, both RNAs always transferred simultaneously. These data suggest a global leaking or transport of material between nuclei of yeast heterokaryons. Our results suggest that caution must be taken when testing nuclear envelope shuttling in yeast heterokaryons.

[PSI+]: an epigenetic modulator of translation termination efficiency

The [PSI+] factor of the yeast Saccharomyces cerevisiae is an epigenetic regulator of translation termination. More than three decades ago, genetic analysis of the transmission of [PSI+] revealed a complex and often contradictory series of observations. However, many of these discrepancies may now be reconciled by a revolutionary hypothesis: protein conformation-based inheritance (the prion hypothesis). This model predicts that a single protein can stably exist in at least two distinct physical states, each associated with a different phenotype. Propagation of one of these traits is achieved by a self-perpetuating change in the protein from one form to the other. Mounting genetic and biochemical evidence suggests that the determinant of [PSI+] is the nuclear encoded Sup35p, a component of the translation termination complex. Here we review the series of experiments supporting the yeast prion hypothesis and provide another look at the 30 years of work preceding this theory in light of our current state of knowledge.

Transcriptional activity and chromatin structure of enhancer-deleted rRNA genes in Saccharomyces cerevisiae

We used the psoralen gel retardation assay and Northern blot analysis in an in vivo yeast system to analyze effects of rDNA enhancer deletions on the chromatin structure and the transcription of tagged rDNA units. We found that upon deletion of a single enhancer element, transcription of the upstream and downstream rRNA gene was reduced by about 50%. Although removing both flanking enhancers of an rRNA gene led to a further reduction in transcription levels, a significant amount of transcriptional activity remained, either resulting from the influence of more distantly located enhancer elements or reflecting the basal activity of the polymerase I promoter within the nucleolus. Despite the reduction of transcriptional activity upon enhancer deletion, the activation frequency (proportion of nonnucleosomal to nucleosomal gene copies in a given cell culture) of the tagged rRNA genes was not significantly altered, as determined by the psoralen gel retardation assay. This is a strong indication that, within the nucleolus, the yeast rDNA enhancer functions by increasing transcription rates of active rRNA genes and not by activating silent transcription units.

The 2 micrometer plasmid stability system: analyses of the interactions among plasmid- and host-encoded components

The stable inheritance of the 2 micrometer plasmid in a growing population of Saccharomyces cerevisiae is dependent on two plasmid-encoded proteins (Rep1p and Rep2p), together with the cis-acting locus REP3 (STB). In this study we demonstrate that short carboxy-terminal deletions of Rep1p and Rep2p severely diminish their normal capacity to localize to the yeast nucleus. The nuclear targeting, as well as their functional role in plasmid partitioning, can be restored by the addition of a nuclear localization sequence to the amino or the carboxy terminus of the shortened Rep proteins. Analyses of deletion derivatives of the Rep proteins by using the in vivo dihybrid genetic test in yeast, as well as by glutathione S-transferase fusion trapping assays in vitro demonstrate that the amino-terminal portion of Rep1p (ca. 150 amino acids long) is responsible for its interactions with Rep2p. In a monohybrid in vivo assay, we have identified Rep1p, Rep2p, and a host-encoded protein, Shf1p, as being capable of interacting with the STB locus. The Shf1 protein expressed in Escherichia coli can bind with high specificity to the STB sequence in vitro. In a yeast strain deleted for the SHF1 locus, a 2 micrometer circle-derived plasmid shows relatively poor stability.

The 2microm-plasmid-encoded Rep1 and Rep2 proteins interact with each other and colocalize to the Saccharomyces cerevisiae nucleus

The efficient partitioning of the 2microm plasmid of Saccharomyces cerevisiae at cell division requires two plasmid-encoded proteins (Rep1p and Rep2p) and a cis-acting locus, REP3 (STB). By using protein hybrids containing fusions of the Rep proteins to green fluorescent protein (GFP), we show here that fluorescence from GFP-Rep1p or GFP-Rep2p is almost exclusively localized in the nucleus in a cir+ strain. Nuclear localization of GFP-Rep1p and GFP-Rep2p, though discernible, is less efficient in a cir(0) host. GFP-Rep2p or GFP-Rep1p is able to promote the stability of a 2microm circle-derived plasmid harboring REP1 or REP2, respectively, in a cir(0) background. Under these conditions, fluorescence from GFP-Rep2p or GFP-Rep1p is concentrated within the nucleus, as is the case in cir+ cells. This characteristic nuclear accumulation is not dependent on the expression of the FLP or RAF1 gene of the 2microm circle. Nuclear colocalization of Rep1p and Rep2p is consistent with the hypothesis that the two proteins directly or indirectly interact to form a functional bipartite or high-order protein complex. Immunoprecipitation experiments as well as baiting assays using GST-Rep hybrid proteins suggest a direct interaction between Rep1p and Rep2p which, in principle, may be modulated by other yeast proteins. Furthermore, these assays provide evidence for Rep1p-Rep1p and Rep2p-Rep2p associations as well. The sum of these interactions may be important in controlling the effective cellular concentration of the Rep1p-Rep2p complex.

Transcription in the yeast rRNA gene locus: distribution of the active gene copies and chromatin structure of their flanking regulatory sequences

In growing yeast cells, about half of the 150 tandemly repeated rRNA genes are transcriptionally active and devoid of nucleosomes. By using the intercalating drug psoralen as a tool to mark accessible sites along chromatin DNA in vivo, we found that the active rRNA gene copies are rather randomly distributed along the ribosomal rRNA gene locus. Moreover, results from the analysis of a single, tagged transcription unit in the tandem array are not consistent with the presence of a specific subset of active genes that is stably maintained throughout cell divisions. In the rRNA intergenic spacers of yeast cells, an enhancer is located at the 3' end of each transcription unit, 2 kb upstream of the next promoter. Analysis of the chromatin structure along the tandem array revealed a structural link between transcription units and adjacent, 3' flanking enhancer sequences: each transcriptionally active gene is flanked by a nonnucleosomal enhancer, whereas inactive, nucleosome-packed gene copies are followed by enhancers regularly packaged in nucleosomes. From the fact that nucleosome-free enhancers were also detected in an RNA polymerase I mutant strain, we interpret these open chromatin structures as being the result of specific protein-DNA interactions that can occur before the onset of transcription. In contrast, in this mutant strain, all of the rRNA coding sequences are packaged in nucleosomal arrays. This finding indicates that the establishment of the open chromatin conformation on the activated gene copies requires elongating RNA polymerase I molecules advancing through the template.

A novel structural form of the 2 micron plasmid of the yeast Saccharomyces cerevisiae

DNA was isolated from cells of Saccharomyces cerevisiae incubated under conditions that enriched for DNA replication intermediates. A novel form of the 2 microns plasmid was detected, in which two monomeric or dimeric circles were joined by a linear double-stranded segment of variable length. We suggest that this molecule is a consequence of site-specific recombination within a dimeric DNA molecule during DNA replication. The existence of this molecule provides supporting physical evidence for a variant of the model of 2 mu plasmid amplification first proposed by Futcher (1986).

The REV2 gene of Saccharomyces cerevisiae: cloning and DNA sequence

The REV2 gene of Saccharomyces cerevisiae was cloned and sequenced; it contains an open reading frame of 1986 bp with a coding potential of 662 amino acids. Interruption of the chromosomal REV2 gene by integrating the URA3 gene coupled with partial deletion of the 3' terminal region produced viable haploid rev2 delta mutants. This indicates that the REV2 gene is non-essential for growth. The rev2 delta mutant is slightly more UV-sensitive than strains carrying various rev2 alleles (rev2-1, rev2x, rad5-1, rad5-8). The putative Rev2 protein is probably a globular protein containing a highly conserved nucleotide-binding site and two zinc-finger domains.

A transcriptionally active tRNA gene interferes with nucleosome positioning in vivo

Incorporation into a positioned nucleosome of a cis-acting element essential for replication in Saccharomyces cerevisiae disrupts the function of the element in vivo [R. T. Simpson, Nature (London) 343:387-389, 1990]. Furthermore, nucleosome positioning has been implicated in repression of transcription by RNA polymerase II in yeast cells. We have now asked whether the function of cis-acting elements essential for transcription of a gene transcribed by RNA polymerase III can be similarly affected. A tRNA gene was fused to either of two nucleosome positioning signals such that the predicted nucleosome would incorporate near its center the tRNA start site and essential A-box element. These constructs were then introduced into yeast cells on stably maintained, multicopy plasmids. Competent tRNA genes were transcribed in vivo and were not incorporated into positioned nucleosomes. Mutated, inactive tRNA genes were incorporated into nucleosomes whose positions were as predicted. This finding demonstrates that the transcriptional competence of the tRNA gene determined its ability to override a nucleosome positioning signal in vivo and establishes that a hierarchy exists between cis-acting elements and nucleosome positioning signals.

A transcriptionally active tRNA gene interferes with nucleosome positioning in vivo

Incorporation into a positioned nucleosome of a cis-acting element essential for replication in Saccharomyces cerevisiae disrupts the function of the element in vivo [R. T. Simpson, Nature (London) 343:387-389, 1990]. Furthermore, nucleosome positioning has been implicated in repression of transcription by RNA polymerase II in yeast cells. We have now asked whether the function of cis-acting elements essential for transcription of a gene transcribed by RNA polymerase III can be similarly affected. A tRNA gene was fused to either of two nucleosome positioning signals such that the predicted nucleosome would incorporate near its center the tRNA start site and essential A-box element. These constructs were then introduced into yeast cells on stably maintained, multicopy plasmids. Competent tRNA genes were transcribed in vivo and were not incorporated into positioned nucleosomes. Mutated, inactive tRNA genes were incorporated into nucleosomes whose positions were as predicted. This finding demonstrates that the transcriptional competence of the tRNA gene determined its ability to override a nucleosome positioning signal in vivo and establishes that a hierarchy exists between cis-acting elements and nucleosome positioning signals.

Direct simulation of yeast 2-microns circle plasmid amplification

The 2-microns circle is a plasmid found in most strains of the yeast Saccharomyces cerevisiae at approximately 60-100 copies per cell. The plasmid possesses the novel capacity for replicative amplification induced by site-specific recombination. To address the question of whether the recombination model is adequate to account for observed rates of 2-microns circle amplification, we developed a direct computational simulation of the amplification system. Results of this simulation show that theoretically at least six copies per plasmid can be produced in each generation, and that previously unanticipated replication intermediates contribute largely to this degree of amplification.

Strategies for the genetic manipulation of Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae is now widely used as a model organism in the study of gene structure, function, and regulation in addition to its more traditional use as a workhorse of the brewing and baking industries. In this article the plethora of methods available for manipulating the genome of S. cerevisiae are reviewed. This will include a discussion of methods for manipulating individual genes and whole chromosomes, and will address both classic genetic and recombinant DNA-based methods. Furthermore, a critical evaluation of the various genetic strategies for genetically manipulating this simple eukaryote will be included, highlighting the requirements of both the new and the more traditional biotechnology industries.

Physiological aspects of growth and recombinant DNA stability in Saccharomyces cerevisiae

Despite the fact that plasmid stability in the yeast Saccharomyces cerevisiae is influenced by both genetical and physiological parameters most attention has been focused on the former. Physiological factors affecting the stability of plasmids have been poorly characterized despite the need for such information in order to optimize the use of S. cerevisiae as a host for recombinant protein production processes. The physiology of wild type S. cerevisiae differs considerably when grown using different cultivation techniques. A limited amount of phenomenological data has been reported concerning plasmid instability effects under these different conditions and in this article these have been collected together with the intention of providing an overview to instability effects and to try and propose reasons as to how the physiological response to different growth conditions can be manifested as stability/instability effects.

Introduction of nonselectible 2 mu plasmid into [cir(o)] cells of the yeast S. cerevisiae by DNA transformation and in vivo site-specific resolution

The 2 mu DNA plasmid of the yeast Saccharomyces cerevisiae does not confer any known selectable phenotype to the host cell carrying it. Selection of cells transformed with purified 2 mu DNA therefore cannot be achieved, and the intracellular presence of 2 mu can only be assessed by molecular analysis of the DNA complement. In addition, 2 mu alone does not replicate in bacterial hosts, thus rendering its amplification by conventional methods impossible. We have isolated a shuttle plasmid, pBH-2L, generated by in vivo site-specific recombination between the endogenous 2 mu DNA plasmid and pRL, a pBR322 derivative containing the yeast LEU2 gene and one 2 mu repeat sequence associated with the origin of replication. This new shuttle plasmid has the property, when transformed into yeast, of undergoing site-specific recombinational resolution between its two direct repeat sequences. This releases 2 mu plasmid and pRL as individual molecules. The latter can undergo progressive mitotic loss during growth in nonselective medium, ultimately leaving leucine auxotrophic transformants that contain only 2 mu DNA plasmid. This system can be utilized to introduce 2 mu DNA alone into cells lacking it, thereby providing a novel means to study the biology and the molecular genetics of the plasmid and its potential practical applications as a vector.

A mathematical model of recombinational amplification of the 2 mu plasmid in the yeast Saccharomyces cerevisiae

A mathematical model of 2 mu plasmid recombinational amplification in Saccharomyces cerevisiae has been developed, based on mechanisms of 2 mu recombination and replication presented in the literature. A probabilistic description reveals the limits inherent in the recombinational mode of plasmid amplification. These limits correspond well with values calculated from reported results. In the model, copy number control is effected by the constitutive expression of a repressor of recombinase expression. Estimation of the model parameters is accomplished via a set of heuristic rules which restrict the feasible parameter space considerably. It is demonstrated that many parameter sets arbitrarily chosen from the feasible parameter space reproduce the observed characteristics of 2 mu plasmid amplification: rapid correction of downward copy number deviations, with a lack of strict control of steady-state copy number.

Roles of the 2 microns gene products in stable maintenance of the 2 microns plasmid of Saccharomyces cerevisiae

We have examined the replication and segregation of the Saccharomyces cerevisiae 2 microns circle. The amplification of the plasmid at low copy numbers requires site-specific recombination between the 2 microns inverted repeat sequences catalyzed by the plasmid-encoded FLP gene. No other 2 microns gene products are required. The overexpression of FLP in a strain carrying endogenous 2 microns leads to uncontrolled plasmid replication, longer cell cycles, and cell death. Two different assays show that the level of Flp activity decreases with increasing 2 microns copy number. This regulation requires the products of the REP1 and REP2 genes. These gene products also act together to ensure that 2 microns molecules are randomly segregated between mother and daughter cells at cell division.

Amplification of plasmid copy number by thymidine kinase expression in Saccharomyces cerevisiae

A 2 micron circle-based chimaeric plasmid containing the yeast LEU2 and the Herpes Simplex Virus type 1 thymidine kinase (HSV-1 TK) genes was constructed. Transformants grown under selective conditions for the LEU2 gene harboured the plasmid at about 15 copies per cell whilst selection for the HSV-1 TK gene led to an increase to about 100 copies per cell. Furthermore, the plasmid copy number could be controlled by the stringency of selection for the TK gene, and the increase in TK gene dosage was reflected in an increase in intracellular thymidine kinase activity. The mitotic stability of the plasmid in "high-copy" and "low-copy" number cells was determined. "High-copy" number cells showed a greater mitotic stability. The relationship of TK expression to plasmid copy number may be useful for the isolation of plasmid copy number mutants in yeast and the control of heterologous gene expression.

Yeast nucleosomes allow thermal untwisting of DNA

Thermal untwisting of DNA is suppressed in vitro in nucleosomes formed with chicken or monkey histones. In contrast, results obtained for the 2 micron plasmid in Saccharomyces cerevisiae are consistent with only 30% of the DNA being constrained from thermal untwisting in vivo. In this paper, we examine thermal untwisting of several plasmids in yeast cells, nuclei, and nuclear extracts. All show the same quantitative degree of thermal untwisting, indicating that this phenomenon is independent of DNA sequence. Highly purified yeast plasmid chromatin also shows a large degree of thermal untwisting, whereas circular chromatin reconstituted using chicken histones is restrained from thermal untwisting in yeast nuclear extracts. Thus, the difference in thermal untwisting between yeast chromatin and that assembled with chicken histones is most likely due to differences in the constituent histone proteins.

Changes in the DNase I sensitivity of DNA sequences within the yeast 2 micron plasmid nucleoprotein complex effected by plasmid-encoded products

We examined the effect of plasmid-encoded gene products on two DNase-I-sensitive regions of DNA in the yeast 2 micron plasmid nucleoprotein complex. For these studies, each sensitive region was cloned into an appropriate vector, and the chimeric plasmids were transformed into yeast. Nucleoprotein complexes of the chimeric plasmids were partially purified and tested for sensitivity to DNase I digestion. One sensitive region is between the 3' end of the 2 micron plasmid coding region D and the plasmid REP3 locus. This region was more sensitive and exhibited a different cleavage pattern when purified from a yeast strain containing endogenous 2 micron plasmid copies than when purified from a yeast strain lacking plasmid copies. Examination of the effect of individual gene products and combinations of the various gene products revealed that the plasmid's REP1, REP2 and D loci were all necessary to restore the pattern to that found in the preparation containing endogenous 2 micron plasmid copies. The other sensitive region studied brackets the binding site of the plasmid-encoded FLP protein, which catalyzes site-specific recombination between the 2 micron plasmid's inverted repeated sequences. In contrast to the first sensitive region examined, the sensitive region in the inverted repeat was less sensitive in chimeric plasmids isolated from a yeast strain containing endogenous 2 micron plasmid copies than from one lacking endogenous copies. Presumably, this protection results from the binding of the FLP protein.

Roles of the 2 microns gene products in stable maintenance of the 2 microns plasmid of Saccharomyces cerevisiae

We have examined the replication and segregation of the Saccharomyces cerevisiae 2 microns circle. The amplification of the plasmid at low copy numbers requires site-specific recombination between the 2 microns inverted repeat sequences catalyzed by the plasmid-encoded FLP gene. No other 2 microns gene products are required. The overexpression of FLP in a strain carrying endogenous 2 microns leads to uncontrolled plasmid replication, longer cell cycles, and cell death. Two different assays show that the level of Flp activity decreases with increasing 2 microns copy number. This regulation requires the products of the REP1 and REP2 genes. These gene products also act together to ensure that 2 microns molecules are randomly segregated between mother and daughter cells at cell division.

Bending the rules: the 2-mu plasmid of yeast

The replication of eukaryotic DNA is normally initiated at each origin only once per cell cycle. Yet, in spite of this restriction, the 2-mu plasmid of yeast has evolved an elegant mechanism which can allow it to rapidly amplify its copy number without initiating multiple rounds of replication. It achieves this by exploiting a plasmid-encoded site-specific recombination system in a way that is apparently unique to this plasmid. The 2-mu plasmid has also evolved a mechanism that allows effective partition of itself between mother and daughter cells. Together these processes ensure the persistence of the 2-mu plasmid within a population, even though retention of the plasmid is of no advantage to the host cell and causes a slightly slower growth rate. The success of this survival strategy is illustrated by the near ubiquity of the 2-mu plasmid in both wild-type and laboratory strains of yeast.

Mating type-like conversion promoted by the 2 micrograms circle site-specific recombinase: implications for the double-strand-gap repair model

Double-strand breaks in DNA are known to promote recombination in Saccharomyces cerevisiae. Yeast mating type switching, which is a highly efficient gene conversion event, is apparently initiated by a site-specific double-strand break. The 2 micrograms circle site-specific recombinase, FLP, has been shown to make double-strand breaks in its substrate DNA. By using a hybrid 2 micrograms circle::Tn5 plasmid, a portion of which resembles, in its DNA organization, the active (MAT) and the silent (HML) yeast mating type loci, it is shown that FLP mediates a conversion event analogous to mating type switching. Whereas the FLP site-specific recombination is not dependent on the RAD52 gene product, the FLP-induced conversion is abolished in a rad52 background. The FLP-promoted conversion in vivo can be faithfully reproduced by making a double-stranded gap in vitro in the vicinity of the FLP site and allowing the gap to be repaired in vivo.

A nuclear gene of Saccharomyces cerevisiae needed for stable maintenance of plasmids

We have isolated host mutants of Saccharomyces cerevisiae in which the 2 microns plasmid is poorly maintained. All the mutants tested constituted one complementation group, which was designated map1 (maintenance of plasmid). Minichromosomes carrying a chromosomal replication origin and a centromere were affected in the mutants. Two types of hybrid plasmids generated in vivo and in vitro appeared to compensate for the mutations and had DNA regions containing multiple ARS (autonomously replicating sequence) or a set of 2 microns inverted repeat sequences. These results suggested that poor maintenance of plasmids was due to low levels of replication, probably at the initiation of replication.

The yeast 2 micron plasmid: strategies for the survival of a selfish DNA

The designation of the yeast 2 mu circle as a "selfish" DNA molecule has been confirmed by demonstrating that the plasmid is lost with exponential kinetics from haploid yeast populations grown in continuous culture. We show that plasmid-free yeast cells have a growth rate advantage of some 1.5%-3% over their plasmid-containing counterparts. This finding makes the ubiquity of this selfish DNA in yeast strains puzzling. Two other factors probably account for its survival. First, the rate of plasmid loss was reduced by allowing haploid populations to enter stationary phase periodically. Second, it was not possible to isolate a plasmid-free segregant from a diploid yeast strain. Competition experiments demonstrated that stability in a diploid is conferred at the level of segregation and that plasmid-free diploid cells are at a selective advantage compared with their plasmid-containing counterparts. Yeast cells in nature are usually homothallic and must frequently pass through both diploid and stationary phases. The 2 mu plasmid appears to have evolved a survival strategy which exploits these two features of its host's life cycle.

DNA repair genes of Saccharomyces cerevisiae: complementing rad4 and rev2 mutations by plasmids which cannot be propagated in Escherichia coli

The RAD4 gene of yeast required for the incision step of DNA excision repair and the REV2 (= RAD5) gene involved in mutagenic DNA repair could not be isolated from genomic libraries propagated in E. coli regardless of copy number of the shuttle vector in yeast. Transformants with plasmids conferring UV resistance to a rad4-4 or a rev2-1 mutant were only recovered if yeast was transformed directly without previous amplification of the gene bank in E. coli. DNA preparations from these yeast clones yielded no transformants in E. coli but retransformation of yeast was possible. This lead to the isolation of a defective derivative of the rad4 complementing plasmid. The modified plasmid was now capable of transforming E. coli but still interfered significantly with its growth.

Inducible expression of REP1 causes inducible expression of the 2 micron circle stability system

The yeast plasmid, 2 micron circle, encodes a stability system consisting of the plasmid replication origin, a cis-active locus designated REP3 and two trans-active functions--the products of the REP1 and REP2 genes. We have constructed 2 micron circle derivatives in which the expression of the REP1 gene is placed under the control of the yeast GAL10 promoter. We show that in such plasmids the stability-system is inducible, being turned off by glucose and turned on by galactose. Further, our results unequivocally demonstrate that, of the two potential in-frame ATG codons at which REP1 translation might initiate (as inferred from the 2 micron circle DNA sequence and from the cap site of the major REP1 transcript), the upstream ATG is dispensable without affecting REP1 function. We also illustrate here a simple and general method for constructing in vivo in yeast 2 micron circle analogs which contain desired alterations within specific regions of the 2 micron circle genome.

A nuclear gene of Saccharomyces cerevisiae needed for stable maintenance of plasmids

We have isolated host mutants of Saccharomyces cerevisiae in which the 2 microns plasmid is poorly maintained. All the mutants tested constituted one complementation group, which was designated map1 (maintenance of plasmid). Minichromosomes carrying a chromosomal replication origin and a centromere were affected in the mutants. Two types of hybrid plasmids generated in vivo and in vitro appeared to compensate for the mutations and had DNA regions containing multiple ARS (autonomously replicating sequence) or a set of 2 microns inverted repeat sequences. These results suggested that poor maintenance of plasmids was due to low levels of replication, probably at the initiation of replication.

Mating type-like conversion promoted by the 2 micrograms circle site-specific recombinase: implications for the double-strand-gap repair model

Double-strand breaks in DNA are known to promote recombination in Saccharomyces cerevisiae. Yeast mating type switching, which is a highly efficient gene conversion event, is apparently initiated by a site-specific double-strand break. The 2 micrograms circle site-specific recombinase, FLP, has been shown to make double-strand breaks in its substrate DNA. By using a hybrid 2 micrograms circle::Tn5 plasmid, a portion of which resembles, in its DNA organization, the active (MAT) and the silent (HML) yeast mating type loci, it is shown that FLP mediates a conversion event analogous to mating type switching. Whereas the FLP site-specific recombination is not dependent on the RAD52 gene product, the FLP-induced conversion is abolished in a rad52 background. The FLP-promoted conversion in vivo can be faithfully reproduced by making a double-stranded gap in vitro in the vicinity of the FLP site and allowing the gap to be repaired in vivo.

Isolation of an episomal yeast gene and replication origin as chromatin

A multicopy yeast plasmid containing the TRP1 gene (coding for N-5'-phosphoribosylanthranilate isomerase) and ARS1 (autonomously replicating sequence 1) has been purified as chromatin. Electrophoretic analysis of nucleic acid and proteins and electron microscopy show that the plasmid chromatin is largely free of contaminants. Electron-microscopic and linking-number analyses indicate that the plasmid chromatin contains seven nucleosomes, as predicted by the indirect end-label analyses of Thoma, Bergman, and Simpson [J. Mol. Biol. (1984) 177, 715-733]. Indirect end label mapping of micrococcal nuclease cuts demonstrates that nucleosome positions and nuclease-sensitive regions are not altered by the purification. The plasmid chromatin behaves homogeneously with respect to its elution from nuclei, template activity, and intrinsic buoyant density. Taken together, these observations suggest that different copies of the TRP1ARS1 plasmid do not differ from each other grossly in chromatin structure. We discuss the potential for understanding eukaryotic gene regulation offered by the ability to isolate unique genes as chromatin.

Properties of REP3: a cis-acting locus required for stable propagation of the Saccharomyces cerevisiae plasmid 2 microns circle

Stable propagation of the yeast plasmid 2 microns requires an origin of replication, a cis-active locus designated REP3, and two plasmid-encoded proteins which are the products of the REP1 and REP2 genes. The three REP loci appear to constitute a partitioning system, ensuring equal distribution of plasmid molecules to mother and daughter cells after mitosis. We have localized the REP3 site completely within a segment of five-and-one-half direct tandem repeats of a 62-base-pair unit, bordered by HpaI and AvaI restriction sites within the large unique region of the 2 microns genome. In addition, we find that the repeated elements are functionally distinct. Only a subset of the repeats is necessary to promote full partitioning activity. The other repeats appear to promote plasmid transcription. These results are discussed in the context of a model of plasmid copy control involving titration of a plasmid-specific protein by the repeated elements within REP3.

Chromatin organization of the Saccharomyces cerevisiae 2 microns plasmid depends on plasmid-encoded products

We have used gene disruptions and nuclease probes to assess the roles of yeast 2 micron plasmid genes in plasmid chromatin organization. The chromatin structure at the replication origin is not dependent on any of the four major open reading frames, A, B, C, or D. While stable plasmid maintenance is known to depend on a cis-acting locus STB and genes B and C, we find that only gene B influences STB chromatin. Other interactions between plasmid gene products and sequences may reflect gene regulation: the chromatin organization at the 5' end of gene A, which codes for a site-specific recombinase, depends on both gene B and gene C. Since disruption of gene C results in an increase in plasmid copy number that is dependent on gene A, we propose that gene C (and probably gene B) control copy number by regulating the level of the gene A recombinase.

Signals for transcription initiation and termination in the Saccharomyces cerevisiae plasmid 2 micron circle

By S1 nuclease protection experiments and primer extension analysis, we determined precisely the cap and polyadenylation sites of transcripts from the four genes of the yeast 2 micron circle plasmid, as well as those of other plasmid transcripts of unknown function. In addition, we used deletion analysis to identify sequences necessary for polyadenylation in plasmid transcripts. Our results indicate that plasmid genes constitute independent transcription units and that plasmid mRNAs are not derived by extensive processing of precursor transcripts. In addition, we found that the D coding region of 2 micron circle is precisely encompassed by a polyadenylated transcript, suggesting that this coding region constitutes a functional plasmid gene. Our identification of the position of plasmid polyadenylation sites and of sequences necessary for polyadenylation provides support for a tripartite signal for polyadenylation as proposed by Zaret and Sherman (K.S. Zaret and F. Sherman, Cell 28:563-573, 1982). Finally, these data highlight salient features of the transcriptional regulatory circuitry that underlies the control of plasmid maintenance in the cell.

Site-specific recombination promotes plasmid amplification in yeast

All stable, naturally occurring circular yeast DNA plasmids contain a pair of long, nontandem inverted repeats that undergo frequent reciprocal recombination. This yields two plasmid inversion isomers that exist in the cell in equal numbers. In the 2 mu circle plasmid of S. cerevisiae such inversion is catalyzed by a plasmid-encoded site-specific recombinase, FLP. We show that the site-specific recombination system of 2 mu circle enables the plasmid to increase its mean intracellular copy number in yeast cells growing under nonselective conditions. This apparently occurs by a FLP-induced transient shift in the mode of replication from theta to double rolling circle as initially proposed by Futcher. This capability may ensure stable maintenance of the plasmid by enabling it to correct downward deviations in copy number that result from imprecision of the plasmid-encoded partitioning system.

Copy number amplification of the 2 micron circle plasmid of Saccharomyces cerevisiae

The 2 micron circle is a small double stranded DNA plasmid that occurs at about 60 copies per cell in the nuclei of virtually all strains of Saccharomyces cerevisiae. The plasmid has no apparent phenotypic effect on host cells, and is the basis of many useful vectors for the transformation of yeast. Under certain circumstances, the plasmid is apparently able to replicate more than once per cell cycle; this over-replication allows the maintenance of the plasmid at high copy number. The plasmid has two inverted repeat sequences, and encodes a product that catalyses intra-molecular recombination between these two repeats. Models are proposed whereby recombination leads to copy number amplification. In particular, it is proposed that intra-molecular recombination during replication flips the orientation of one replication fork with respect to the other, so that both forks travel in the same direction around a circular monomer template, generating a large multimer from a monomer and a single initiation of replication.

Survival strategies of the yeast plasmid two-micron circle

The multicopy yeast plasmid 2-micron circle uses a number of strategies to insure its persistence in its host. The plasmid confers no selective phenotype to the cell in which it is resident. Nonetheless, the plasmid is lost at less than 1 per 10(5) cell divisions during continuous exponential growth. We have determined that the plasmid persists at least in part due to the ability of the plasmid to amplify its mean copy number when its cellular copy level is low and to distribute plasmid molecules equally between mother and daughter cells at mitosis. We have found that amplification of plasmid copy number occurs by a novel mechanism in which site-specific recombination induces a transient shift in the mode of replication from theta to rolling circle. Equitable partitioning of plasmid molecules requires plasmid-encoded proteins and a centromere-like segment on the plasmid. We have accumulated evidence consistent with a model of partitioning in which the partitioning proteins form a transnuclear structure that is responsible for distributing plasmid molecules throughout the nucleus prior to cell division. In this chapter we describe evidence supporting the existence and mode of action of these two plasmid strategies and discuss the extent to which these strategies may be a pervasive facet of the biology of eukaryotic extrachromosomal elements.

Signals for transcription initiation and termination in the Saccharomyces cerevisiae plasmid 2 micron circle

By S1 nuclease protection experiments and primer extension analysis, we determined precisely the cap and polyadenylation sites of transcripts from the four genes of the yeast 2 micron circle plasmid, as well as those of other plasmid transcripts of unknown function. In addition, we used deletion analysis to identify sequences necessary for polyadenylation in plasmid transcripts. Our results indicate that plasmid genes constitute independent transcription units and that plasmid mRNAs are not derived by extensive processing of precursor transcripts. In addition, we found that the D coding region of 2 micron circle is precisely encompassed by a polyadenylated transcript, suggesting that this coding region constitutes a functional plasmid gene. Our identification of the position of plasmid polyadenylation sites and of sequences necessary for polyadenylation provides support for a tripartite signal for polyadenylation as proposed by Zaret and Sherman (K.S. Zaret and F. Sherman, Cell 28:563-573, 1982). Finally, these data highlight salient features of the transcriptional regulatory circuitry that underlies the control of plasmid maintenance in the cell.