Plasmid accumulation reduces life span in Saccharomyces cerevisiae

Aging in the yeast Saccharomyces cerevisiae is under the control of multiple pathways. The production and accumulation of extrachromosomal rDNA circles (ERCs) is one pathway that has been proposed to bring about aging in yeast. To test this proposal, we have developed a plasmid-based model system to study the role of DNA episomes in reduction of yeast life span. Recombinant plasmids containing different replication origins, cis-acting partitioning elements, and selectable marker genes were constructed and analyzed for their effects on yeast replicative life span. Plasmids containing the ARS1 replication origin reduce life span to the greatest extent of the plasmids analyzed. This reduction in life span is partially suppressed by a CEN4 centromeric element on ARS1 plasmids. Plasmids containing a replication origin from the endogenous yeast 2 mu circle also reduce life span, but to a lesser extent than ARS1 plasmids. Consistent with this, ARS1 and 2 mu origin plasmids accumulate in approximately 7-generation-old cells, but ARS1/CEN4 plasmids do not. Importantly, ARS1 plasmids accumulate to higher levels in old cells than 2 mu origin plasmids, suggesting a correlation between plasmid accumulation and life span reduction. Reduction in life span is neither an indirect effect of increased ERC levels nor the result of stochastic cessation of growth. The presence of a fully functional 9.1-kb rDNA repeat on plasmids is not required for, and does not augment, reduction in life span. These findings support the view that accumulation of DNA episomes, including episomes such as ERCs, cause cell senescence in yeast.     

Evidence for the involvement of a single major species of replicative complex in DNA synthesis from two diverse nuclear replicons in yeast

The activity that replicates the 2-micron yeast DNA plasmid in vitro can be isolated as a high-molecular weight (approximately 2 X 10(6)) fraction, which possesses many of the features of a multiprotein replicative complex. This fraction also initiates DNA synthesis at the yeast chromosomal replicator ARS1 raising the question whether the preparations discriminate between origins. It was determined that the binding of replicative complex to plasmids containing either 2-microns or ARS1 origins of replication was indistinguishable. The preparations also showed no preference among them for replication. In addition, the DNAs competed with each other to the same extent for binding of replicative complex. These results suggest that these two origins share one major species of replicative complex.     

Rtg2 protein links metabolism and genome stability in yeast longevity

Mitochondrial dysfunction induces a signaling pathway, which culminates in changes in the expression of many nuclear genes. This retrograde response, as it is called, extends yeast replicative life span. It also results in a marked increase in the cellular content of extrachromosomal ribosomal DNA circles (ERCs), which can cause the demise of the cell. We have resolved the conundrum of how these two molecular mechanisms of yeast longevity operate in tandem. About 50% of the life-span extension elicited by the retrograde response involves processes other than those that counteract the deleterious effects of ERCs. Deletion of RTG2, a gene that plays a central role in relaying the retrograde response signal to the nucleus, enhances the generation of ERCs in cells with (grande) or in cells without (petite) fully functional mitochondria, and it curtails the life span of each. In contrast, overexpression of RTG2 diminishes ERC formation in both grandes and petites. The excess Rtg2p did not augment the retrograde response, indicating that it was not engaged in retrograde signaling. FOB1, which is known to be required for ERC formation, and RTG2 were found to be in converging pathways for ERC production. RTG2 did not affect silencing of ribosomal DNA in either grandes or petites, which were similar to each other in the extent of silencing at this locus. Silencing of ribosomal DNA increased with replicative age in either the presence or the absence of Rtg2p, distinguishing silencing and ERC accumulation. Our results indicate that the suppression of ERC production by Rtg2p requires that it not be in the process of transducing the retrograde signal from the mitochondrion. Thus, RTG2 lies at the nexus of cellular metabolism and genome stability, coordinating two pathways that have opposite effects on yeast longevity.     

A rapid preparation of plasmid DNA fromSaccharomyces cerevisiae

A procedure for extraction of plasmid DNA from Saccharomyces cerevisiae is described. The plasmid DNA of interest is extracted together with 2-micron circular DNA naturally occurring in many yeast strains. Spheroplasts are lyzed at alkaline pH which denatures linear but not covalently closed circular (CCC) DNA. The CCC DNA is recovered by ethanol precipitation and can be detected by gel electrophoresis or used for routine bacterial transformation.     

Copy number and the stability of 2-micron circle-based artificial plasmids of Saccharomyces cerevisiae

The copy number and stability of artificial 2-micron circle-based plasmids have been accurately measured in [Cir+] and [Cir0] strains of Saccharomyces cerevisiae. We conclude that (i) instability and copy number vary greatly from plasmid to plasmid; (ii) instability and copy number are negatively correlated--that is, high copy number is associated with low instability; (iii) it is difficult to reconcile this variability with a strict and direct system of copy number control; (iv) instabilities are much higher than expected from random partition and the observed copy numbers: this may imply partition which is less efficient than random. Even so, (v) the partitioning of 2-micron circle-like plasmids is more efficient than that of ARS-based plasmids, which hints at the existence of a system for the (inefficient) distribution of 2-micron circles.     

啤酒酵母复制衰老的分子机制

 复制衰老是啤酒酵母衰老形式之一,表现出芽痕累积、细胞体积变大、不对称分裂丧失、不育、核仁脆裂和代谢变化等特征.染色体外rDNA环累积是啤酒酵母复制衰老的重要原因,而组蛋白去乙酰化酶家族成员Sir2蛋白在调节染色体外rDNA环累积、啤酒酵母衰老和寿命方面起到核心作用.作为去乙酰化反应底物的NAD+正性调节Sir2组蛋白去乙酰化酶活性,NAD+代谢产物尼克酰胺对Sir2有负性调节作用,而有尼克酰胺参与的NAD+补救合成途径对于Sir2活性十分重要.目前,已经在人等动物细胞中发现参与这些调节过程的相关蛋白的同源基因,在功能上也表现出一定的相似性.啤酒酵母的衰老机制研究将为人体衰老的认识提供重要线索.     

Asymmetrical Inheritance of Plasmids Depends on Dynamic Cellular Geometry and Volume Exclusion Effects

The asymmetrical inheritance of plasmid DNA, as well as other cellular components, has been shown to be involved in replicative aging. In Saccharomyces cerevisiae, there is an ongoing debate regarding the mechanisms underlying this important asymmetry. Currently proposed models suggest it is established via diffusion, but differ on whether a diffusion barrier is necessary or not. However, no study so far incorporated key aspects to segregation, such as dynamic morphology changes throughout anaphase or plasmids size. Here, we determine the distinct effects and contributions of individual cellular variability, plasmid volume and moving boundaries in the asymmetric segregation of plasmids. We do this by measuring cellular nuclear geometries and plasmid diffusion rates with confocal microscopy, subsequently incorporating this data into a growing domain stochastic spatial simulator. Our modelling and simulations confirms that plasmid asymmetrical inheritance does not require an active barrier to diffusion, and provides a full analysis on plasmid size effects.     

Effects of mutations in DNA repair genes on formation of ribosomal DNA circles and life span in Saccharomyces cerevisiae

A cause of aging in Saccharomyces cerevisiae is the accumulation of extrachromosomal ribosomal DNA circles (ERCs). Introduction of an ERC into young mother cells shortens life span and accelerates the onset of age-associated sterility. It is important to understand the process by which ERCs are generated. Here, we demonstrate that homologous recombination is necessary for ERC formation. rad52 mutant cells, defective in DNA repair through homologous recombination, do not accumulate ERCs with age, and mutations in other genes of the RAD52 class have varying effects on ERC formation. rad52 mutation leads to a progressive delocalization of Sir3p from telomeres to other nuclear sites with age and, surprisingly, shortens life span. We speculate that spontaneous DNA damage, perhaps double-strand breaks, causes lethality in mutants of the RAD52 class and may be an initial step of aging in wild-type cells.     

A mathematical model of ageing in yeast

Budding yeast, Saccharomyces cerevisiae, is commonly used as a system to study cellular ageing. Yeast mother cells are capable of only a limited number of divisions before they undergo senescence, whereas newly formed daughters usually have their replicative age "reset" to zero. Accumulation of extrachromosomal ribosomal DNA circles (ERCs) appears to be an important contributor to ageing in yeast, and we describe a mathematical model that we developed to examine this process. We show that an age-related accumulation of ERCs readily explains the observed features of yeast ageing but that in order to match the experimental survival curves quantitatively, it is necessary that the probability of ERC formation increases with the age of the cell. This implies that some other mechanism(s), in addition to ERC accumulation, must underlie yeast ageing. We also demonstrate that the model can be used to gain insight into how an extra copy of the Sir2 gene might extend lifespan and we show how the model makes novel, testable predictions about patterns of age-specific mortality in yeast populations.     

Artificial tethering to nuclear pores promotes partitioning of extrachromosomal DNA during yeast asymmetric cell division

SUMMARY: Asymmetric cell division in unicellular organisms enables sequestration of senescence factors to specific subpopulations. Accumulation of autonomously replicating sequence (ARS) plasmids, which frequently emerge from recombination within the highly repetitive ribosomal DNA locus, is linked to limited replicative life span of Saccharomyces cerevisiae cells [1]. During budding yeast cell division, ARS plasmids are retained in the ageing mother cell, such that only 1 out of 10 plasmids enters the rejuvenated bud [2]. Binding of ARS plasmids to nuclear structures retained in the mother cell was speculated to explain asymmetric plasmid segregation [2]. Association with nuclear pore complexes (NPCs) was proposed to underlie retention of ARS plasmids in the mother cell [3]. However, the role of NPCs in segregation of ARS plasmids is unclear, as NPCs are partitioned between mother and bud nuclei during mitosis [4,5]. Here we analyzed how segregation of ARS plasmids is influenced by their interaction with NPCs. We found that artificial tethering to NPCs promotes transport of ARS plasmids into the bud. Moreover, our experiments provide support for the notion that interaction with ARS plasmids does not affect movement of NPCs into the bud. We conclude that binding to NPCs cannot by itself contribute to asymmetric segregation of ARS plasmids.     

Slow growth phenotype - A possible approach to improved plasmid maintenance in Saccharomyces cerevisiae

Summary Transformation-induced slow growth phenotype (SGP) in yeast is repressed in the presence of 2m plasmids. A full 2m-sequence-based recombinant plasmid (pJB502) was found to be more stable in a 2m-free- [cir] strain of Saccharomyces cerevisiae than in a cir⁺ strain. This could not be attributed to differences in growth rate calculated from kinetic analysis of plasmid loss, but transformed [cir] isolates, which had lost the recombinant plasmid, exhibited varying degrees of SGP in batch culture. One of these isolates was outcompeted in chemostat culture by the recombinant-plasmid-containing strain, suggesting that improved plasmid maintenance can result from SGP in cir hosts.     

Apparent Involvement of a Plasmid in Phaseotoxin Production by Pseudomonas phaseolicola

Three naturally occurring toxigenic strains (HB-36, G-50, and HB-33), one nontoxigenic strain (HB-20), and one ultraviolet light-induced toxinless mutant (G-50 Tox⁻) of Pseudomonas phaseolicola were examined by dye-buoyant density equilibrium centrifugation for the presence of plasmid deoxyribonucleic acid. All strains contained plasmid deoxyribonucleic acid. Comparison of the plasmid deoxyribonucleic acid of different strains by agarose gel electrophoresis showed that strain G-50 harbored three plasmids, whereas the rest of the strains contained two plasmids each. Irrespective of their toxigenicity, all strains shared the large-sized first plasmid band, but differed with respect to other plasmids. Restriction endonuclease analyses of the plasmids indicated that a 22.50-megadalton plasmid was common to two of the toxigenic strains (HB-36 and G-50). However, strain HB-33, which is also toxigenic, contained a much smaller plasmid (4.23 megadaltons). It is hypothesized that this small plasmid may have arisen by a recombination event from a larger plasmid.     

The shortened replicative life span of prohibitin mutants of yeast appears to be due to defective mitochondrial segregation in old mother cells

Prohibitin proteins have been implicated in cell proliferation, aging, respiratory chain assembly and the maintenance of mitochondrial integrity. The prohibitins of Saccharomyces cerevisiae, Phb1 and Phb2, have strong sequence similarity with their human counterparts prohibitin and BAP37, making yeast a good model organism in which to study prohibitin function. Both yeast and mammalian prohibitins form high-molecular-weight complexes (Phb1/2 or prohibitin/BAP37, respectively) in the inner mitochondrial membrane. Expression of prohibitins declines with senescence, both in mammalian fibroblasts and in yeast. With a total loss of prohibitins, the replicative (budding) life span of yeast is reduced, whilst the chronological life span (the survival of stationary cells over time) is relatively unaffected. This effect of prohibitin loss on the replicative life span is still apparent in the absence of an assembled respiratory chain. It also does not reflect the production of extrachromosomal ribosomal DNA circles (ERCs), a genetic instability thought to be a major cause of replicative senescence in yeast. Examination of cells containing a mitochondrially targeted green fluorescent protein indicates this shortened life span is a reflection of defective mitochondrial segregation from the mother to the daughter in the old mother cells of phb mutant strains. Old mother phb mutant cells display highly aberrant mitochondrial morphology and, frequently, a delayed segregation of mitochondria to the daughter. They often arrest growth with their last bud strongly attached and with the mitochondria adjacent to the septum between the mother and the daughter cell.     

High frequency of yeast transformation by plasmids carrying part or entire 2-micron yeast plasmid.

By using two chimeric plasmids containing yeast ura3 gene and 2-micron yeast DNA linked to the bacterial plasmid pCR1, yeast transformation of a high frequency has been achieved. The first plasmid is such that the 2-micron DNA part, in which the ura3 gene is incorporated, can be removed in one step and thus the 2-micron-ura3 sequence can be considered as a "transposable" block. In contrast, the second one bears the entire 2-micron plasmid and the ura3 gene is inserted in the bacterial plasmid part. As shown through hybridization experiments and genetic studies, the ura3 gene was maintained as a cytoplasmic element. Plasmids recovered from the yeast transformants were used to transform Escherichia coli. Their analysis by EcoRI showed that in many cases the vector had recombined with the endogenous 2-micron DNA of the recipient strain. The specific activity of orotidine 5'-monophosphate decarboxylase (coded by ura3) in yeast transformants was 10- to 30-fold higher than in the wild type.     

Measuring Replicative Life Span in the Budding Yeast

Aging is a degenerative process characterized by a progressive deterioration of cellular components and organelles resulting in mortality. The budding yeast Saccharomyces cerevisiae has been used extensively to study the biology of aging, and several determinants of yeast longevity have been shown to be conserved in multicellular eukaryotes, including worms, flies, and mice ¹. Due to the lack of easily quantified age-associated phenotypes, aging in yeast has been assayed almost exclusively by measuring the life span of cells in different contexts, with two different life span paradigms in common usage ². Chronological life span refers to the length of time that a mother cell can survive in a non-dividing, quiescence-like state, and is proposed to serve as a model for aging of post-mitotic cells in multicellular eukaryotes. Replicative life span, in contrast, refers the number of daughter cells produced by a mother cell prior to senescence, and is thought to provide a model of aging in mitotically active cells. Here we present a generalized protocol for measuring the replicative life span of budding yeast mother cells. The goal of the replicative life span assay is to determine how many times each mother cell buds. The mother and daughter cells can be easily differentiated by an experienced researcher using a standard light microscope (total magnification 160X), such as the Zeiss Axioscope 40 or another comparable model. Physical separation of daughter cells from mother cells is achieved using a manual micromanipulator equipped with a fiber-optic needle. Typical laboratory yeast strains produce 20-30 daughter cells per mother and one life span experiment requires 2-3 weeks.Open in a separate windowClick here to view.^{(75M, flv)}     

Trans-kingdom T-DNA transfer from Agrobacterium tumefaciens to Saccharomyces cerevisiae.

Agrobacterium tumefaciens transfers part of its tumour-inducing (Ti) plasmid, the transferred or T-DNA, to plants during tumourigenesis. This represents the only example of naturally occurring trans-kingdom transfer of genetic material. Here we report that A.tumefaciens can transfer its T-DNA not only to plant cells, but also to another eukaryote, namely the yeast Saccharomyces cerevisiae. The Ti plasmid virulence (vir) genes that mediate T-DNA transfer to plants were found to be essential for transfer to yeast as well. Transgenic S.cerevisiae strains were analysed for their T-DNA content. Results showed that T-DNA circles were formed in yeast with precise fusions between the left and right borders. Such T-DNA circles were stably maintained by the yeast if the replicator from the yeast 2 mu plasmid was present in the T-DNA. Integration of T-DNA in the S.cerevisiae genome was found to occur via homologous recombination. This contrasts with integration in the plant genome, where T-DNA integrates preferentially via illegitimate recombination. Our results thus suggest that the process of T-DNA integration is predominantly determined by host factors.     

Bacterial plasmid stability

Bacterial plasmids are ubiquitous ‘minichromosomes’ that have major importance in clinical microbiology, as agents of pathogenicity and as carriers of antibiotic resistance, and in molecular genetics, through their role as vectors in gene manipulation. Plasmids carry a wide range of dispensable, transiently useful and often bizarre functions.¹ Naturally occurring plasmids, in addition to modifying the host cell phenotype, carry genes involved in the control of their own vegetative replication, plasmid copy number² and stable inheritance. They may also carry determinants for the conjugal transfer of DNA between bacteria.³ Whereas low-copy-number plasmids must be partitioned by some active process during cell division, the evidence suggests that multicopy plasmids are distributed randomly between daughter cells. Two independent determinants are necessary for the stable inheritance of multicopy plasmids, and both of these appear to act by maximizing the number of independent plasmid molecules.     

hpr1Δ Affects Ribosomal DNA Recombination and Cell Life Span in Saccharomyces cerevisiae

Multiple genetic pathways have been shown to regulate life span and aging in the yeast Saccharomyces cerevisiae. Here we show that loss of a component of the RNA polymerase II complex, Hpr1p, results in a decreased life span. Although hpr1Delta mutants have an increased rate of recombination within the ribosomal DNA (rDNA) array, this is not accompanied by an increase in extrachromosomal rDNA circles (ERCs). Analyses of mutants that affect replication of the rDNA array and suppressors that reverse the phenotypes of the hpr1Delta mutant show that the reduced life span is associated with increased genomic instability but not with increased ERC formation. The hpr1Delta mutant acts in a pathway distinct from previously described mutants that reduce life span.