Copy number and partition of the Saccharomyces cerevisiae 2 micron plasmid controlled by transcription regulators

A natural variant of the essential host gene MMS21 restricts the parasitic 2-micron plasmid in Saccharomyces cerevisiae

Antagonistic coevolution with selfish genetic elements (SGEs) can drive evolution of host resistance. Here, we investigated host suppression of 2-micron (2μ) plasmids, multicopy nuclear parasites that have co-evolved with budding yeasts. We developed SCAMPR (Single-Cell Assay for Measuring Plasmid Retention) to measure copy number heterogeneity and 2μ plasmid loss in live cells. We identified three S. cerevisiae strains that lack endogenous 2μ plasmids and reproducibly inhibit mitotic plasmid stability. Focusing on the Y9 ragi strain, we determined that plasmid restriction is heritable and dominant. Using bulk segregant analysis, we identified a high-confidence Quantitative Trait Locus (QTL) with a single variant of MMS21 associated with increased 2μ instability. MMS21 encodes a SUMO E3 ligase and an essential component of the Smc5/6 complex, involved in sister chromatid cohesion, chromosome segregation, and DNA repair. Our analyses leverage natural variation to uncover a novel means by which budding yeasts can overcome highly successful genetic parasites.

DNA sequence elements required for partitioning competence of the Saccharomyces cerevisiae 2-micron plasmid STB locus

Equal partitioning of the multi-copy yeast 2-micron plasmid requires association of plasmid proteins Rep1 and Rep2 with tandem repeats at the plasmid STB locus. To identify sequence elements required for these associations we generated synthetic versions of a 63-bp section of STB, encompassing one repeat. A single copy of this sequence was sufficient for Rep protein association in vivo, while two directly arrayed copies provided partitioning function to a plasmid lacking all other 2-micron sequences. Partitioning efficiency increased with increasing repeat number, reaching that conferred by the native STB repeat array. By altering sequences in synthetic repeats, we identified the TGCA component of a TGCATTTTT motif as critical for Rep protein recognition, with a second TGCA sequence in each repeat also contributing to association. Mutation of TGCATTTTT to TGTATTTT, as found in variant 2-micron STB repeats, also allowed Rep protein association, while mutation to TGCATTAAT impaired inheritance without abolishing Rep protein recognition, suggesting an alternate role for the T-tract. Our identification of sequence motifs required for Rep protein recognition provides the basis for understanding higher-order Rep protein arrangements at STB that enable the yeast 2-micron plasmid to be efficiently partitioned during host cell division.

Deficient sumoylation of yeast 2-micron plasmid proteins Rep1 and Rep2 associated with their loss from the plasmid-partitioning locus and impaired plasmid inheritance

The 2-micron plasmid of the budding yeast Saccharomyces cerevisiae encodes copy-number amplification and partitioning systems that enable the plasmid to persist despite conferring no advantage to its host. Plasmid partitioning requires interaction of the plasmid Rep1 and Rep2 proteins with each other and with the plasmid-partitioning locus STB. Here we demonstrate that Rep1 stability is reduced in the absence of Rep2, and that both Rep proteins are sumoylated. Lysine-to-arginine substitutions in Rep1 and Rep2 that inhibited their sumoylation perturbed plasmid inheritance without affecting Rep protein stability or two-hybrid interaction between Rep1 and Rep2. One-hybrid and chromatin immunoprecipitation assays revealed that Rep1 was required for efficient retention of Rep2 at STB and that sumoylation-deficient mutants of Rep1 and Rep2 were impaired for association with STB. The normal co-localization of both Rep proteins with the punctate nuclear plasmid foci was also lost when Rep1 was sumoylation-deficient. The correlation of Rep protein sumoylation status with plasmid-partitioning locus association suggests a theme common to eukaryotic chromosome segregation proteins, sumoylated forms of which are found enriched at centromeres, and between the yeast 2-micron plasmid and viral episomes that depend on sumoylation of their maintenance proteins for persistence in their hosts.

Air proteins control differential TRAMP substrate specificity for nuclear RNA surveillance

RNA surveillance systems function at critical steps during the formation and function of RNA molecules in all organisms. The RNA exosome plays a central role in RNA surveillance by processing and degrading RNA molecules in the nucleus and cytoplasm of eukaryotic cells. The exosome functions as a complex of proteins composed of a nine-member core and two ribonucleases. The identity of the molecular determinants of exosome RNA substrate specificity remains an important unsolved aspect of RNA surveillance. In the nucleus of Saccharomyces cerevisiae, TRAMP complexes recognize and polyadenylate RNAs, which enhances RNA degradation by the exosome and may contribute to its specificity. TRAMPs contain either of two putative RNA-binding factors called Air proteins. Previous studies suggested that these proteins function interchangeably in targeting the poly(A)-polymerase activity of TRAMPs to RNAs. Experiments reported here show that the Air proteins govern separable functions. Phenotypic analysis and RNA deep-sequencing results from air mutants reveal specific requirements for each Air protein in the regulation of the levels of noncoding and coding RNAs. Loss of these regulatory functions results in specific metabolic and plasmid inheritance defects. These findings reveal differential functions for Air proteins in RNA metabolism and indicate that they control the substrate specificity of the RNA exosome.

Partitioning of the 2-microm circle plasmid of Saccharomyces cerevisiae. Functional coordination with chromosome segregation and plasmid-encoded rep protein distribution

The efficient partitioning of the 2-microm plasmid of Saccharomyces cerevisiae at cell division is dependent on two plasmid-encoded proteins (Rep1p and Rep2p), together with the cis-acting locus REP3 (STB). In addition, host encoded factors are likely to contribute to plasmid segregation. Direct observation of a 2-microm-derived plasmid in live yeast cells indicates that the multiple plasmid copies are located in the nucleus, predominantly in clusters with characteristic shapes. Comparison to a single-tagged chromosome or to a yeast centromeric plasmid shows that the segregation kinetics of the 2-microm plasmid and the chromosome are quite similar during the yeast cell cycle. Immunofluorescence analysis reveals that the plasmid is colocalized with the Rep1 and Rep2 proteins within the yeast nucleus. Furthermore, the Rep proteins (and therefore the plasmid) tend to concentrate near the poles of the yeast mitotic spindle. Depolymerization of the spindle results in partial dispersion of the Rep proteins in the nucleus concomitant with a loosening in the association between plasmid molecules. In an ipl1-2 yeast strain, shifted to the nonpermissive temperature, the chromosomes and plasmid almost always missegregate in tandem. Our results suggest that, after DNA replication, plasmid distribution to the daughter cells occurs in the form of specific DNA-protein aggregates. They further indicate that the plasmid partitioning mechanism may exploit at least some of the components of the cellular machinery required for chromosomal segregation.

The plasmid replicon of EBV consists of multiple cis-acting elements that facilitate DNA synthesis by the cell and a viral maintenance element

Plasmids containing oriP, the plasmid origin of Epstein-Barr virus (EBV), are replicated stably in human cells that express a single viral trans-acting factor, EBNA-1. Unlike plasmids of other viruses, but akin to human chromosomes, oriP plasmids are synthesized once per cell cycle, and are partitioned faithfully to daughter cells during mitosis. Although EBNA-1 binds multiple sites within oriP, its role in DNA synthesis and partitioning has been obscure. EBNA-1 lacks enzymatic activities that are present in the origin-binding proteins of other mammalian viruses, and does not interact with human cellular proteins that provide equivalent enzymatic functions. We demonstrate that plasmids with oriP or its constituent elements are synthesized efficiently in human cells in the absence of EBNA-1. Further, we show that human cells rapidly eliminate or destroy newly synthesized plasmids, and that both EBNA-1 and the family of repeats of oriP are required for oriP plasmids to escape this catastrophic loss. These findings indicate that EBV's plasmid replicon consists of genetic elements with distinct functions, multiple cis-acting elements that facilitate DNA synthesis and viral cis/trans elements that permit retention of replicated DNA in daughter cells. They also explain historical failures to identify mammalian origins of DNA synthesis as autonomously replicating sequences.

Localisation and interaction of the protein components of the yeast 2 mu circle plasmid partitioning system suggest a mechanism for plasmid inheritance

Replicating plasmids are highly unstable in yeast, because they are retained in mother cells. The 2 mu circle plasmid overcomes this maternal inheritance bias by using a partitioning system that involves the plasmid encoded proteins Rep1p and Rep2p, and the cis-acting locus STB. It is thus widely exploited as a cloning vehicle in yeast. However, little is known about the cellular or molecular mechanisms by which effective partitioning is achieved, and models of both free diffusion and plasmid localisation have been proposed. Here we show that Rep1p and Rep2p proteins interact to form homo- and hetero-complexes in vitro. In vivo, Rep1p and Rep2p are shown to be nuclear proteins, exhibiting sub-nuclear concentration in distinct foci. The number of foci appears constant regardless of plasmid copy number and cell ploidy level. Before cell division, the number of foci increases, and we observe approximately equal allocation of foci to mother and daughter cell nuclei. We show that whereas Rep2p expressed alone is found exclusively in the nucleus, Rep1p requires the presence of Rep2p for effective nuclear localisation. High levels of 2 mu plasmid induce a multiple-budded elongated cell phenotype, which we show can be phenocopied by overexpression of both REP1 and REP2 together but not alone. Taken together, these results suggest that Rep1p and Rep2p interact in vivo, and occupy defined nuclear sites that are allocated to both mother and daughter nuclei during division. We propose a model for 2 mum plasmid partitioning based on these results, involving the association of plasmid DNA with specific, segregated subnuclear sites.

The maintenance of self-replicating plasmids in Saccharomyces cerevisiae: mathematical modelling, computer simulations and experimental tests

A distributive model has been constructed to describe the maintenance of the native 2 microns and 2 micron-based plasmids in the yeast Saccharomyces cerevisiae. This model includes elements which represent the influence of selection, segregation, replication and amplification on plasmid stability. A computer program has been written in TURBO PASCAL to implement the model and a number of simulation experiments have been carried out. These simulations permitted the choice of a form of the model which is compatible with the available experimental evidence. The form chosen involves an amplification system in which the RAF gene product binds to the Rep1/Rep2 dimer to prevent the latter acting to repress the activity of the FLP gene. At the same time an upper limit (or 'ceiling') was imposed on the number of plasmid molecules able to replicate. Maternal bias was accommodated by 'tagging' a small proportion of molecules for inheritance by the mother nucleus and these tags being removed (or 'cleared') by the Rep1/Rep2 dimers. This final form of the model makes specific predictions about the stability of 2 microns and YEp plasmids in yeast populations and about the distribution of plasmid copy number between cells in such populations. The predictions on stability have been subjected to experimental test and results provide good support for the model.

DNA insertions in the 'silent' regions of the 2 microns plasmid of Saccharomyces cerevisiae influence plasmid stability

The 2 microns plasmid of the yeast Saccharomyces cerevisiae is in principle a suitable vector for expression of foreign genes, due to its high copy number and extreme stability. However, the cloning of genes into 2 microns often results in a reduced copy number and/or reduced stability. One reason for this observed instability could be that the inserts in general were made in one of the several open reading frames (ORFs) of the plasmid. Therefore we studied the effect on stability of insertions in the silent regions of 2 microns without interrupting any known essential regions or ORFs. Using the SnaBI site, a yeast-integrating plasmid (Yip5) was introduced into the region between the ARS and STB locus in two possible orientations. The resulting plasmids could be stably maintained in the cells without the need for complementation by the wild-type 2 microns plasmid. However, the stability of these plasmids in a cir. host was still one to two orders of magnitude lower (0.2% and 0.8% respectively) as reported for the wild-type 2 microns (0.01%). Removal of 2 kb of the bacterial sequences from Yip5 did not increase stability. The stability was dependent on the orientation of the insert. We found that in the less stable orientation, transcription originating from the insert was running into the STB region. DNA inserted in the XmaIII site located outside the ORFs in the REP2/FLP intergenic region influenced both stability and copy number of the plasmid. These effects are strongly dependent on the size of the insert. Insertion of a 2 kb DNA fragment increased the copy number, probably through an effect on FLP expression.

Evidence for cis- and trans-acting element coevolution of the 2-microns circle genome in Saccharomyces cerevisiae

We compared the DNA sequence of the yeast 2-microns plasmid cis-acting STB and transacting REP1 partition loci of laboratory haploid and industrial amphiploid strains. Several industrial strains had a unique STB sequence (type 1) sharing only 70% homology with laboratory STB (type 2). Type 1 plasmids had a REP1 protein with 6-10% amino acid substitutions when compared to REP1 of type 2 plasmids. All 2-microns variants that shared a similar STB consensus sequence exhibited a high degree of REP1 nucleotide and amino acid sequence conservation. These observations suggest molecular coevolution of trans-acting elements with cognate target DNA structure. Based on DNA sequencing and Southern hybridization analyses, we classified 2-microns variants into two main evolutionary lineages that differ at STB as well as REP1 loci. The role of molecular coevolution in yeast intra- and interspecies plasmid evolution was discussed.