The efficient partitioning of the 2-μm 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-μm–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-μm 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 yeast 2 micron plasmid achieves high fidelity segregation by coupling its partitioning pathway to that of the chromosomes. Mutations affecting distinct steps of chromosome segregation cause the plasmid to missegregate in tandem with the chromosomes. In the absence of the plasmid stability system, consisting of the Rep1 and Rep2 proteins and the STB DNA, plasmid and chromosome segregations are uncoupled. The Rep proteins, acting in concert, recruit the yeast cohesin complex to the STB locus. The periodicity of cohesin association and dissociation is nearly identical for the plasmid and the chromosomes. The timely disassembly of cohesin is a prerequisite for plasmid segregation. Cohesin-mediated pairing and unpairing likely provides a counting mechanism for evenly partitioning plasmids either in association with or independently of the chromosomes.
The 2m circle is a highly persistent "selfish" DNA element resident in the Saccharomyces cerevisiae nucleus whose stability approaches that of the chromosomes. The plasmid partitioning system, consisting of two plasmid-encoded proteins, Rep1p and Rep2p, and a cis-acting locus, STB, apparently feeds into the chromosome segregation pathway. The Rep proteins assist the recruitment of the yeast cohesin complex to STB during the S phase, presumably to apportion the replicated plasmid molecules equally to daughter cells. The DNAprotein and protein-protein interactions of the partitioning system, as well as the chromatin organization at STB, are important for cohesin recruitment. Rep1p variants that are incompetent in binding to Rep2p, STB, or both fail to assist the assembly of the cohesin complex at STB and are nonfunctional in plasmid maintenance. Preventing the cohesin-STB association without impeding Rep1p-Rep2p-STB interactions also causes plasmid missegregation. During the yeast cell cycle, the Rep1p and Rep2p proteins are expelled from STB during a short interval between the late G 1 and early S phases. This dissociation and reassociation event ensures that cohesin loading at STB is replication dependent and is coordinated with chromosomal cohesin recruitment. In an rsc2⌬ yeast strain lacking a specific chromatin remodeling complex and exhibiting a high degree of plasmid loss, neither Rep1p nor the cohesin complex can be recruited to STB. The phenotypes of the Rep1p mutations and of the rsc2⌬ mutant are consistent with the role of cohesin in plasmid partitioning being analogous to that in chromosome partitioning.The 2m circle of Saccharomyces cerevisiae is a high-copynumber selfish extrachromosomal DNA element that resides in the nucleus and propagates itself stably in the cell population (2, 29). The plasmid does not seem to confer any selective advantage to its host under normal laboratory growth conditions, nor does it pose any noticeable disadvantage as long as the copy number does not rise significantly above the steadystate value of approximately 60 per cell. The stability of the plasmid approaches that of the yeast chromosomes, with the loss rate being as low as 10 Ϫ4 to 10 Ϫ5 per cell per generation. The structural organization of the plasmid and its genetic potential are devoted to two goals: (i) efficient plasmid segregation during cell division and (ii) the maintenance of the plasmid copy number with only modest deviations from the mean.The presence of a typical yeast replication origin in its sequence permits each plasmid molecule to be replicated once per cell cycle (35). A stability system consisting of two plasmidencoded proteins (Rep1p and Rep2p) and a cis-acting partitioning locus (STB) mediates equal or nearly equal distribution of the replicated molecules into daughter cells. The direct observation of reporter plasmids tagged with fluorescence indicates that the plasmid molecules are organized into a tightknit cluster in the nucleus and segregate as a cluster. Hence, the copy number relevant ...
The 2m circle plasmid in Saccharomyces cerevisiae is a model for a stable, high-copy-number, extrachromosomal "selfish" DNA element. By combining a partitioning system and an amplification system, the plasmid ensures its stable propagation and copy number maintenance, even though it does not provide any selective advantage to its host. Recent evidence suggests that the partitioning system couples plasmid segregation to chromosome segregation. We now demonstrate an unexpected and unconventional role for the mitotic spindle in the plasmid-partitioning pathway. The spindle specifies the nuclear address of the 2m circle and promotes recruitment of the cohesin complex to the plasmid-partitioning locus STB. Only the nuclear microtubules, and not the cytoplasmic ones, are required for loading cohesin at STB. In cells recovering from nocodazole-induced spindle depolymerization and G 2 /M arrest, cohesin-STB association can be established coincident with spindle restoration. This postreplication recruitment of cohesin is not functional in equipartitioning. However, normally acquired cohesin can be inactivated after replication without causing plasmid missegregation. In the mtw1-1 mutant yeast strain, the plasmid cosegregates with the spindle and the spindle-associated chromosomes; by contrast, a substantial number of the chromosomes are not associated with the spindle. These results are consistent with a model in which the spindle promotes plasmid segregation in a chromosome-linked fashion.The 2m plasmid is an extrachromosomal selfish DNA element in the Saccharomyces cerevisiae nucleus that harbors a partitioning system and a copy number control system for its stable high-copy-number propagation (2,11,21). Despite a copy number of approximately 60 per cell, the plasmid molecules exist as a close-knit cluster and segregate as one unit (18,22). This effective reduction in copy number provides the rationale for the existence of an active segregation mechanism. The partitioning system has a beguiling simplicity. It consists of just two plasmid-encoded proteins, Rep1p and Rep2p, and a cis-acting locus, STB, which includes roughly six copies of a tandem array of a 65-bp consensus sequence. Yet the plasmid manifests a degree of stability comparable to that of the yeast chromosomes, the loss rate being as low as 10 Ϫ4 to 10 Ϫ5 per generation.The remarkable efficiency of the partitioning system appears to stem from its ability to feed into the segregation mechanism established for the host chromosomes (14,20,22). The kinetics of chromosome segregation and 2m circle segregation closely parallel each other during the yeast cell cycle (22). In several mutant yeast strains that missegregate chromosomes at the nonpermissive temperature (ipl1-2 and ndc10-2, for example), the plasmid shows a strong tendency to missegregate in tandem with the bulk of the chromosomes (14). The yeast cohesin complex, critical for the segregation of each pair of sister chromatids to opposite cell compartments, is recruited to the STB locus (8, 14) in a Rep1...
The 2μm Plasmid Stability System: Analyses of the Interactions among Plasmid- and Host-Encoded Components
The stable inheritance of the 2m 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 2m circle-derived plasmid shows relatively poor stability.The 2m circle, a relatively small circular plasmid (6,318 bp) present in most common strains of Saccharomyces cerevisiae, has optimized a partitioning system and an amplification system that allow it to be propagated stably in a cell population at a copy number of approximately 60 to 100 per cell (reviewed in reference 2). Genetic analyses suggest that two plasmid-coded proteins, Rep1p and Rep2p, in conjunction with a cis-acting locus STB (also called REP3) contribute to the stability function (16,17,19,23). One plausible mechanism for plasmid stability is that the interaction of Rep1p and Rep2p with the STB element serves to overcome the normal bias in plasmid segregation that tends to favor the mother cell over the daughter cell (22). The evidence for this suspected DNA-protein interaction is quite preliminary and rests almost entirely on the observation that urea-solubilized yeast extracts expressing Rep1p and Rep2p or [cir 0 ] extracts supplemented exogenously with Rep1p and Rep2p can bind STB (14).The need for plasmid amplification arises only if and when there is a decrease in copy number below the steady-state value. Normally, each plasmid molecule is replicated once, and only once, per cell cycle (35), and the daughter molecules are partitioned efficiently at cytokinesis (27). When there is a drop in copy number, the amplification system overrides the cell cycle restriction of a single round of plasmid replication during one S phase. Plasmid amplification is absolutely dependent on the 2m circle Flp site-specific recombination system (33). A currently favored model for amplification proposes the recombinational inversion of a bidirectional replication fork and the resultant double-rolling-circle replication mode as the means for obtaining multiple replicas of the plasmid fro...
Localization of Repressor Activator Protein 1 (RAP1) to the telomere is essential for its telomeric functions. RAP1 homologs either directly bind the duplex telomere DNA or interact with telomere-binding proteins. We find that Trypanosoma brucei RAP1 relies on a unique double-stranded DNA (dsDNA) binding activity to achieve this goal. T. brucei causes human sleeping sickness and regularly switches its major surface antigen, variant surface glycoprotein (VSG), to evade the host immune response. VSGs are monoallelically expressed from subtelomeres, and TbRAP1 is essential for VSG regulation. We identify dsDNA and single-stranded DNA binding activities in TbRAP1, which require positively charged 737RKRRR741 residues that overlap with TbRAP1’s nuclear localization signal in the MybLike domain. Both DNA binding activities are electrostatics-based and sequence nonspecific. The dsDNA binding activity can be substantially diminished by phosphorylation of two 737RKRRR741-adjacent S residues and is essential for TbRAP1’s telomere localization, VSG silencing, telomere integrity, and cell proliferation.
Trypanosoma brucei is a protozoan parasite that causes human African trypanosomiasis. Its major surface antigen VSG is expressed from subtelomeric loci in a strictly monoallelic manner. We previously showed that the telomere protein TbRAP1 binds dsDNA through its 737RKRRR741 patch to silence VSGs globally. How TbRAP1 permits expression of the single active VSG is unknown. Through NMR structural analysis, we unexpectedly identify an RNA Recognition Motif (RRM) in TbRAP1, which is unprecedented for RAP1 homologs. Assisted by the 737RKRRR741 patch, TbRAP1 RRM recognizes consensus sequences of VSG 3’UTRs in vitro and binds the active VSG RNA in vivo. Mutating conserved RRM residues abolishes the RNA binding activity, significantly decreases the active VSG RNA level, and derepresses silent VSGs. The competition between TbRAP1’s RNA and dsDNA binding activities suggests a VSG monoallelic expression mechanism in which the active VSG’s abundant RNA antagonizes TbRAP1’s silencing effect, thereby sustaining its full-level expression.
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