Sensitivity to the Yeast Plasmid 2mu DNA is conferred by the nuclear allele nibl

A Flp-SUMO hybrid recombinase reveals multi-layered copy number control of a selfish DNA element through post-translational modification

Mechanisms for highly efficient chromosome-associated equal segregation, and for maintenance of steady state copy number, are at the heart of the evolutionary success of the 2-micron plasmid as a stable multi-copy extra-chromosomal selfish DNA element present in the yeast nucleus. The Flp site-specific recombination system housed by the plasmid, which is central to plasmid copy number maintenance, is regulated at multiple levels. Transcription of the FLP gene is fine-tuned by the repressor function of the plasmid-coded partitioning proteins Rep1 and Rep2 and their antagonist Raf1, which is also plasmid-coded. In addition, the Flp protein is regulated by the host's post-translational modification machinery. Utilizing a Flp-SUMO fusion protein, which functionally mimics naturally sumoylated Flp, we demonstrate that the modification signals ubiquitination of Flp, followed by its proteasome-mediated degradation. Furthermore, reduced binding affinity and cooperativity of the modified Flp decrease its association with the plasmid FRT (Flp recombination target) sites, and/or increase its dissociation from them. The resulting attenuation of strand cleavage and recombination events safeguards against runaway increase in plasmid copy number, which is deleterious to the host-and indirectly-to the plasmid. These results have broader relevance to potential mechanisms by which selfish genomes minimize fitness conflicts with host genomes by holding in check the extra genetic load they pose.

The partitioning and copy number control systems of the selfish yeast plasmid: an optimized molecular design for stable persistence in host cells

The multi-copy 2 micron plasmid of Saccharomyces cerevisiae, a resident of the nucleus, is remarkable for its high chromosome-like stability. The plasmid does not appear to contribute to the fitness of the host, nor does it impose a significant metabolic burden on the host at its steady state copy number. The plasmid may be viewed as a highly optimized selfish DNA element whose genome design is devoted entirely towards efficient replication, equal segregation and copy number maintenance. A partitioning system comprised of two plasmid coded proteins, Rep1 and Rep2, and a partitioning locus STB is responsible for equal or nearly equal segregation of plasmid molecules to mother and daughter cells. Current evidence supports a model in which the Rep-STB system promotes the physical association of the plasmid with chromosomes and thus plasmid segregation by a hitchhiking mechanism. The Flp site-specific recombination system housed by the plasmid plays a critical role in maintaining steady state plasmid copy number. A decrease in plasmid population due to rare missegregation events is rectified by plasmid amplification via a recombination induced rolling circle replication mechanism. Appropriate plasmid amplification, without runaway increase in copy number, is ensured by positive and negative regulation of FLP gene expression by plasmid coded proteins and by the control of Flp level/activity through host mediated post-translational modification(s) of Flp. The Flp system has been successfully utilized to understand mechanisms of site-specific recombination, to bring about directed genetic alterations for addressing fundamental problems in biology, and as a tool in biotechnological applications.

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.

Stimulation of in vitro sumoylation by Slx5-Slx8: evidence for a functional interaction with the SUMO pathway

The yeast genes SLX5 and SLX8 were identified based on their requirement for viability in the absence of the Sgs1 DNA helicase. Loss of these genes results in genome instability, nibbled colonies, and other phenotypes associated with defects in sumoylation. The Slx5 and Slx8 proteins form a stable complex and each subunit contains a single RING-finger domain at its C-terminus. To determine the physiological function of the Slx5-8 complex, we explored its interaction with the SUMO pathway. Curing 2micro circle from the mutants, suppressed their nibbled colony phenotype and partially improved their growth rate, but did not affect their sensitivity to hydroxyurea. The increase in sumoylation observed in slx5Delta and slx8Delta mutants was found to be dependent on the Siz1 SUMO ligase. Physical interactions between the Slx5-8 complex and both Ubc9 and Smt3 were identified and characterized. Using in vitro reactions, we show that Slx5, Slx8, or the Slx5-8 complex stimulates the formation of SUMO chains and the sumoylation of a test substrate. Interestingly, a functional RING-finger domain is not required for this stimulation in vitro. These biochemical data demonstrate for the first time that the Slx5 and Slx8 complex is capable of interacting directly with the SUMO pathway.

Purification of the yeast Slx5-Slx8 protein complex and characterization of its DNA-binding activity

SLX5 and SLX8 encode RING-finger proteins that were previously identified based on their requirement for viability in yeast cells lacking Sgs1 DNA helicase. Slx5 and Slx8 proteins are known to be required for genome stability and to physically interact in yeast extracts; however, their biochemical functions are unknown. To address this question we purified and characterized recombinant Slx5 and Slx8 proteins. Here we show that Slx5 and Slx8 form a heterodimeric complex with double-stranded DNA (dsDNA)-binding activity. Individually, only the Slx8 subunit displays this activity. Structure–function studies indicate that the DNA-binding activity requires only the N-terminal 160 amino acids of Slx8, but not its C-terminal RING-finger domain. Alleles of SLX8 that express the RING-finger domain alone show almost complete complementation in yeast indicating that this DNA-binding domain is not essential for this in vivo function. Consistent with these findings we show that Slx5 immunolocalizes to the nucleus and that a portion of the Slx8 protein co-fractionates with chromatin. These results suggest that Slx5–Slx8 may act directly on DNA to promote genome stability.

2-micron circle plasmids do not reduce yeast life span

Extrachromosomal rDNA circles (ERCs) and recombinant origin-containing plasmids (ARS-plasmids) are thought to reduce replicative life span in the budding yeast Saccharomyces cerevisiae due to their accumulation in yeast cells by an asymmetric inheritance process known as mother cell bias. Most commonly used laboratory yeast strains contain the naturally occurring, high copy number 2-micron circle plasmid. 2-micron plasmids are known to exhibit stable mitotic inheritance, unlike ARS-plasmids and ERCs, but the fidelity of inheritance during replicative aging and cell senescence has not been studied. This raises the question: do 2-micron circles reduce replicative life span? To address this question we have used a convenient method to cure laboratory yeast strains of the 2-micron plasmid. We find no difference in the replicative life spans of otherwise isogenic cir+ and cir0 strains, with and without the 2-micron plasmid. Consistent with this, we find that 2-micron circles do not accumulate in old yeast cells. These findings indicate that naturally occurring levels of 2-micron plasmids do not adversely affect life span, and that accumulation due to asymmetric inheritance is required for reduction of replicative life span by DNA episomes.

The DLP1 mutant of the yeast Saccharomyces cerevisiae with an increased copy number of the 2micron plasmid shows a shortened lifespan

We isolated and characterized a recessive mutant, named dlp1, which shows the Dlp phenotype (delayed loss of proliferation activity) during the autophagic death of cdc28. The dip1 mutant was found to consist of two subtypes of cells based on colony morphology. One subtype with the Dlp phenotype, named dlp1-1, became large, red, and nibbled during the incubation, suggesting that the cells on the surface of the colonies were dying. The other without the Dlp phenotype, named dlp1-s, retained small, white colonies even after a prolonged incubation and was found to be a petite mutant. The change from dlp1-1 to dlp1-s (petite) occurred much more frequently (about 15%) than that from the wild-type to petite mutant (less than 1%). The lifespan of both subtypes of cells was severely shortened. The copy number of the endogenous 2micron plasmid of dlp1-1 was 68-fold that of the original cdc28, and decreased by half after the conversion to dlp1-s (petite). A 4.0-kbp fragment of the 2micron plasmid containing REP2 decreased the copy number of the endogenous 2micron plasmid to 8-fold that of the original cdc28 cells and partially rescued the shortened lifespan, in addition to resulting in the complete complementation of the Dlp and nibbled-colony phenotypes. These results suggest that DLP1 is a chromosomal gene that regulates the copy number of the 2micron plasmid, and that the shortening of the lifespan and other effects of the dlp1 mutation are likely caused by the increased copy number of the endogenous 2micron plasmid.

A new system for amplifying 2 microns plasmid copy number in Saccharomyces cerevisiae

The yeast 2 microns plasmid is found in the nucleus of almost all Saccharomyces cerevisiae strains. Its replication is very similar to that of chromosomal DNA. Although the plasmid does not encode essential genes it is stably maintained in the yeast population and exhibits only a small, though detectable, loss rate. This stability is achieved by a plasmid-encoded copy-number control system which ensures constant plasmid levels. For the investigation of 2 microns replication, a yeast strain that is absolutely dependent on this plasmid was constructed. This was achieved by disruption of the chromosomal CDC9 gene, coding for DNA ligase and providing this essential gene on a 2 microns-derived plasmid. This plasmid is absolutely stable under all growth conditions tested. Using the temperature-sensitive mutant allele cdc9-1 we have developed an artificial control system which allows one to change the copy number of 2 microns-derived plasmids solely by changing the incubation temperature.

Extrachromosomal elements cause a reduced division potential in nib 1 strains of Saccharomyces cerevisiae

The nib 1 allele of yeast confers a sensitivity to an endogenous plasmid, 2 mu DNA, in that nib 1 strains bearing 2 mu DNA (cir+) exhibit a reduction in division potential. In the present study, the reduction in division potential characteristic of nib 1 cir+ strains is shown to be dependent on the simultaneous presence of both the A and the D open reading frames of 2 mu DNA as well as on the presence of an unidentified extrachromosomal element other than 2 mu DNA. Furthermore, in nib 1 strains, an uncharacterized extrachromosomal element can cause a less severe reduction of division potential in the absence of intact 2 mu DNA. Thus, the nib 1 allele may confer a generalized sensitivity to extrachromosomal elements.