The proteomics of quiescent and nonquiescent cell differentiation in yeast stationary-phase cultures

As yeast cultures enter stationary phase in rich, glucose-based medium, differentiation of two major subpopulations of cells, termed quiescent and nonquiescent, is observed. Differences in mRNA abundance between exponentially growing and stationary-phase cultures and quiescent and nonquiescent cells are known, but little was known about protein abundance in these cells. To measure protein abundance in exponential and stationary-phase cultures, the yeast GFP-fusion library (4159 strains) was examined during exponential and stationary phases, using high-throughput flow cytometry (HyperCyt). Approximately 5% of proteins in the library showed twofold or greater changes in median fluorescence intensity (abundance) between the two conditions. We examined 38 strains exhibiting two distinct fluorescence-intensity peaks in stationary phase and determined that the two fluorescence peaks distinguished quiescent and nonquiescent cells, the two major subpopulations of cells in stationary-phase cultures. GFP-fusion proteins in this group were more abundant in quiescent cells, and half were involved in mitochondrial function, consistent with the sixfold increase in respiration observed in quiescent cells and the relative absence of Cit1p:GFP in nonquiescent cells. Finally, examination of quiescent cell-specific GFP-fusion proteins revealed symmetry in protein accumulation in dividing quiescent and nonquiescent cells after glucose exhaustion, leading to a new model for the differentiation of these cells.     

System-level analysis of genes and functions affecting survival during nutrient starvation in Saccharomyces cerevisiae

An essential property of all cells is the ability to exit from active cell division and persist in a quiescent state. For single-celled microbes this primarily occurs in response to nutrient deprivation. We studied the genetic requirements for survival of Saccharomyces cerevisiae when starved for either of two nutrients: phosphate or leucine. We measured the survival of nearly all nonessential haploid null yeast mutants in mixed populations using a quantitative sequencing method that estimates the abundance of each mutant on the basis of frequency of unique molecular barcodes. Starvation for phosphate results in a population half-life of 337 hr whereas starvation for leucine results in a half-life of 27.7 hr. To measure survival of individual mutants in each population we developed a statistical framework that accounts for the multiple sources of experimental variation. From the identities of the genes in which mutations strongly affect survival, we identify genetic evidence for several cellular processes affecting survival during nutrient starvation, including autophagy, chromatin remodeling, mRNA processing, and cytoskeleton function. In addition, we found evidence that mitochondrial and peroxisome function is required for survival. Our experimental and analytical methods represent an efficient and quantitative approach to characterizing genetic functions and networks with unprecedented resolution and identified genotype-by-environment interactions that have important implications for interpretation of studies of aging and quiescence in yeast.     

Regulation of proliferation by the budding yeast Saccharomyces cerevisiae

Mutations in the budding yeast Saccharomyces cerevisiae define regulatory activities both for the mitotic cell cycle and for resumption of proliferation from the quiescent stationary-phase state. In each case, the regulation of proliferation occurs in the prereplicative interval that precedes the initiation of DNA replication. This regulation is particularly responsive to the nutrient environment and the biosynthetic capacity of the cell. Mutations in components of the cAMP-mediated effector pathway and in components of the biosynthetic machinery itself affect regulation of proliferation within the mitotic cell cycle. In the extreme case of nutrient starvation, cells cease proliferation and enter stationary phase. Mutations in newly defined genes prevent stationary-phase cells from reentering the mitotic cell cycle, but have no effect on proliferating cells. Thus stationary phase represents a unique developmental state, with requirements to resume proliferation that differ from those for the maintenance of proliferation in the mitotic cell cycle.     

Cell cycle checkpoints: Arresting progress in mitosis

Cell cycle arrest in M phase can be induced by the failure of a single chromosome to attach properly to the mitotic spindle. The same cell cycle checkpoint mediates M phase arrest when cells are treated with drugs that either disrupt or hyperstabilize spindle microtubules. Study of yeast mutants that fail to arrest in the presence of microtubule disruptors identified a set of genes important in this checkpoint pathway. Two recent papers report the cloning of human and Xenopus homologues of one of these yeast genes, called MAD2 (for mitotic arrest deficient-2)^(1,2). Introduction of antibodies to the MAD2 protein into living mammalian cells or Xenopus egg extracts abrogates the M phase arrest induced by microtubule inhibitors. This and other recent developments suggest a model for the M phase checkpoint in which unattached kinetochores inhibit the ubiquitination of proteins whose proteolysis is necessary for chromatid separation and exit from mitosis.     

Isolation of quiescent and nonquiescent cells from yeast stationary-phase cultures

Quiescence is the most common and, arguably, most poorly understood cell cycle state. This is in part because pure populations of quiescent cells are typically difficult to isolate. We report the isolation and characterization of quiescent and nonquiescent cells from stationary-phase (SP) yeast cultures by density-gradient centrifugation. Quiescent cells are dense, unbudded daughter cells formed after glucose exhaustion. They synchronously reenter the mitotic cell cycle, suggesting that they are in a G(0) state. Nonquiescent cells are less dense, heterogeneous, and composed of replicatively older, asynchronous cells that rapidly lose the ability to reproduce. Microscopic and flow cytometric analysis revealed that nonquiescent cells accumulate more reactive oxygen species than quiescent cells, and over 21 d, about half exhibit signs of apoptosis and necrosis. The ability to isolate both quiescent and nonquiescent yeast cells from SP cultures provides a novel, tractable experimental system for studies of quiescence, chronological and replicative aging, apoptosis, and the cell cycle.     

Tumor necrosis factor and interleukin-1 cause a rapid and transient stimulation of c-fos and c-myc mRNA levels in human fibroblasts

Tumor necrosis factor (TNF) and interleukin-1 (IL-1) were shown previously to be mitogenic for human fibroblasts. Here we show that recombinant human TNF and recombinant human IL-1 alpha increase steady state levels of c-fos and c-myc proto-oncogene mRNAs in quiescent human FS-4 fibroblasts. Proto-oncogene mRNA levels were enhanced within 20 min of TNF or IL-1 addition, peaked at 30 min, and declined to undetectable levels (c-fos) or basal levels (c-myc) by 60 or 90 min. A similar rapid increase in c-fos and c-myc mRNA was seen in quiescent FS-4 cells exposed to cycloheximide. However, in the presence of cycloheximide, both proto-oncogene mRNA levels continued to rise for at least 90 min. The transient nature of the increase in c-myc mRNA levels appears to be a response characteristic for TNF and IL-1 because in quiescent FS-4 cells exposed to 10% fetal bovine serum, steady state levels of c-myc mRNA remained elevated for at least 4 h.     

Molecular cloning of cDNA corresponding to mRNA species whose steady state levels in the thyroid are enhanced by thyrotropin. Homology of one of these sequences with ferritin H

A lambda gt11 cDNA library was constructed using poly(A)+ mRNA from thyrotropin (TSH)-stimulated Fisher rat thyroid (FRTL5) cells. The library was screened for nonthyroglobulin cDNA sequences by differential plaque filter hybridization using single-stranded cDNA probes synthesized from mRNA prepared from quiescent and TSH-stimulated FRTL5 cells. Thyroglobulin cDNA-containing recombinants in the library were avoided by prehybridizing the TSH probe to excess thyroglobulin cDNA. Of 48,000 clones screened, 60 were chosen as representing mRNA species whose abundance was increased in TSH-stimulated versus quiescent cultures. Southern blot analysis of 9 clones confirmed that the TSH-cDNA probe hybridized to a greater extent to the cDNA inserts than did the control probe. cDNA insert sizes varied between 0.3 kilobase (kb) and 1.0 kb. Northern slot blot analysis using as probes the cDNA of four of these clones (FC4, FC26, FC29, and FC43) demonstrated that TSH stimulation of FRTL5 cells increased the steady state levels of the respective mRNA species by 4-12-fold. For all 4 clones, increases in mRNA levels were apparent within approximately 1 h and were maximal after 14-18 h of TSH stimulation. Determination of the partial nucleotide sequence of these 4 clones confirmed that none was thyroglobulin, thyroid peroxidase, or any other gene previously reported to be stimulated by TSH. Three of the clones bore no homology to any known nucleotide sequence, but FC26 was 85% homologous with human ferritin H. Northern blot analysis using the FC26 cDNA insert as a probe confirmed hybridization to an mRNA species of 1 kb, the known size of ferritin H mRNA. In summary, using the technique of differential plaque filter hybridization, we have identified 4 new genes whose mRNA levels are increased by TSH stimulation of thyroid cells. One of these genes is homologous to human ferritin H.