scholarly journals Phosphoregulation of the cytokinetic protein Fic1 contributes to fission yeast growth polarity establishment

2020 ◽  
Vol 133 (18) ◽  
pp. jcs244392
Author(s):  
K. Adam Bohnert ◽  
Anthony M. Rossi ◽  
Quan-Wen Jin ◽  
Jun-Song Chen ◽  
Kathleen L. Gould
Keyword(s):  
Cell Cycle ◽  
Fission Yeast ◽  
Cell Behavior ◽  
Polarized Growth ◽  
Yeast Growth ◽  
Multiple Protein ◽  
A Cell ◽  
Growth Polarity ◽  
Polarity Regulation ◽  
Cellular Polarization

ABSTRACTCellular polarization underlies many facets of cell behavior, including cell growth. The rod-shaped fission yeast Schizosaccharomyces pombe is a well-established, genetically tractable system for studying growth polarity regulation. S. pombe cells elongate at their two cell tips in a cell cycle-controlled manner, transitioning from monopolar to bipolar growth in interphase when new ends established by the most recent cell division begin to extend. We previously identified cytokinesis as a critical regulator of new end growth and demonstrated that Fic1, a cytokinetic factor, is required for normal polarized growth at new ends. Here, we report that Fic1 is phosphorylated on two C-terminal residues, which are each targeted by multiple protein kinases. Endogenously expressed Fic1 phosphomutants cannot support proper bipolar growth, and the resultant defects facilitate the switch into an invasive pseudohyphal state. Thus, phosphoregulation of Fic1 links the completion of cytokinesis to the re-establishment of polarized growth in the next cell cycle. These findings broaden the scope of signaling events that contribute to regulating S. pombe growth polarity, underscoring that cytokinetic factors constitute relevant targets of kinases affecting new end growth.This article has an associated First Person interview with Anthony M. Rossi, joint first author of the paper.

Three proteins required for early steps in the protein secretory pathway also affect nuclear envelope structure and cell cycle progression in fission yeast

2002 ◽  
Vol 115 (2) ◽  
pp. 421-431
Author(s):  
Anna Matynia ◽  
Sandra S. Salus ◽  
Shelley Sazer
Keyword(s):  
Cell Cycle ◽  
Nuclear Envelope ◽  
Fission Yeast ◽  
Cell Cycle Progression ◽  
Secretory Pathway ◽  
Yeast Cells ◽  
Ran Gtpase ◽  
A Cell ◽  
Cell Cycle Block ◽  
Er Membrane

The Ran GTPase is an essential protein that has multiple functions in eukaryotic cells. Fission yeast cells in which Ran is misregulated arrest after mitosis with condensed, unreplicated chromosomes and abnormal nuclear envelopes. The fission yeast sns mutants arrest with a similar cell cycle block and interact genetically with the Ran system. sns-A10, sns-B2 and sns-B9 have mutations in the fission yeast homologues of S. cerevisiae Sar1p, Sec31p and Sec53p, respectively, which are required for the early steps of the protein secretory pathway. The three sns mutants accumulate a normally secreted protein in the endoplasmic reticulum (ER), have an increased amount of ER membrane, and the ER/nuclear envelope lumen is dilated. Neither a post-ER block in the secretory pathway, nor ER proliferation caused by overexpression of an integral ER membrane protein, results in a cell cycle-specific defect. Therefore, the arrest seen in sns-A10, sns-B2 and sns-B9 is most likely due to nuclear envelope defects that render the cells unable to re-establish the interphase organization of the nucleus after mitosis. As a consequence, these mutants are unable to decondense their chromosomes or to initiate of the next round of DNA replication.

Cyclin Dependent Kinases and Regulation of the Fission Yeast Cell Cycle

1999 ◽  
Vol 380 (7-8) ◽  
pp. 729-733 ◽  
Author(s):  
P. Nurse
Keyword(s):  
Cell Cycle ◽  
Yeast Cell ◽  
Fission Yeast ◽  
S Phase ◽  
Yeast Cell Cycle ◽  
Cyclin Dependent Kinases ◽  
Fission Yeast Cell ◽  
Nutritional Deprivation ◽  
Orderly Fashion ◽  
A Cell

AbstractThe cyclin dependent kinases (CDKs), formed by complexes between Cdc2p and the B-cyclins Cig2p and Cdc13p, have a central role in regulating the fission yeast cell cycle and maintaining genomic stability. The CDK Cig2p/Cdc2p controls the onset of S-phase and the CDK Cdc13p/Cdc2p controls the onset of mitosis and ensures that there is only one S-phase in each cell. Cdc13p/Cdc2p can replace Cig2p/Cdc2p for the onset of S-phase, suggesting that the increasing activity of a single CDK during the cell cycle is sufficient to drive a cell in an orderly fashion into S-phase and into mitosis. If S-phase is incomplete, then inhibition of Cdc13p/Cdc2p prevents cells with unreplicated DNA from undergoing a catastrophic entry into mitosis. Control of CDK activity is also important to allow cells to exit the cell cycle and accumulate in G1 in response to nutritional deprivation and the presence of pheromone.

scholarly journals Fission Yeast Cells Grow Approximately Exponentially

2018 ◽  
Author(s):  
Mary Pickering ◽  
Lauren Nicole Hollis ◽  
Edridge D’Souza ◽  
Nicholas Rhind
Keyword(s):  
Cell Cycle ◽  
Cell Growth ◽  
Fission Yeast ◽  
Cell Size ◽  
Exponential Growth ◽  
Cell Biology ◽  
Growth Models ◽  
Growth Period ◽  
Yeast Cells ◽  
Yeast Growth

ABSTRACTHow the rate of cell growth is influenced by cell size is a fundamental question of cell biology. The simple model that cell growth is proportional to cell size, based on the proposition that larger cells have proportionally greater synthetic capacity than smaller cells, leads to the predication that the rate of cell growth increases exponentially with cell size. However, other modes of cell growth, including bilinear growth, have been reported. The distinction between exponential and bilinear growth has been explored in particular detail in the fission yeast Schizosaccharomyces pombe. We have revisited the mode of fission yeast cell growth using high-resolution time-lapse microscopy and find, as previously reported, that these two growth models are difficult to distinguish both because of the similarity in shapes between exponential and bilinear curves over the two-fold change in length of a normal cell cycle and because of the substantial biological and experimental noise inherent to these experiments. Therefore, we contrived to have cells grow more than two fold, by holding them in G2 for up to eight hours. Over this extended growth period, in which cells grow up to 5.5-fold, the two growth models diverge to the point that we can confidently exclude bilinear growth as a general model for fission yeast growth. Although the growth we observe is clearly more complicated than predicted by simple exponential growth, we find that exponential growth is a robust approximation of fission yeast growth, both during an unperturbed cell cycle and during extended periods of growth.

scholarly journals Characterizing non-exponential growth and bimodal cell size distributions in Schizosaccharomyces pombe: an analytical approach

2021 ◽  
Author(s):  
Chen Jia ◽  
Abhyudai Singh ◽  
Ramon Grima
Keyword(s):  
Cell Cycle ◽  
Fission Yeast ◽  
Cell Size ◽  
Control Strategy ◽  
Size Control ◽  
Birth Size ◽  
Size Distributions ◽  
Cell Size Distribution ◽  
A Cell ◽  
Cell Size Control

Unlike many single-celled organisms, the growth of fission yeast cells within a cell cycle is not exponential. It is rather characterized by three distinct phases (elongation, septation and fission), each with a different growth rate. Experiments also show that the distribution of cell size in a lineage is often bimodal, unlike the unimodal distributions measured for the bacterium Escherichia coli. Here we construct a detailed stochastic model of cell size dynamics in fission yeast. The theory leads to analytic expressions for the cell size and the birth size distributions, and explains the origin of bimodality seen in experiments. In particular our theory shows that the left peak in the bimodal distribution is associated with cells in the elongation phase while the right peak is due to cells in the septation and fission phases. We show that the size control strategy, the variability in the added size during a cell cycle and the fraction of time spent in each of the three cell growth phases have a strong bearing on the shape of the cell size distribution. Furthermore we infer all the parameters of our model by matching the theoretical cell size and birth size distributions to those from experimental single cell time-course data for seven different growth conditions. Our method provides a much more accurate means of determining the cell size control strategy (timer, adder or sizer) than the standard method based on the slope of the best linear fit between the birth and division sizes. We also show that the variability in added size and the strength of cell size control of fission yeast depend weakly on the temperature but strongly on the culture medium.

Cdc42 reactivation at growth sites is regulated by local cell-cycle-dependent loss of its GAP Rga4

2021 ◽  
Author(s):  
Julie Rich-Robinson ◽  
Afton Russell ◽  
Eleanor Mancini ◽  
Maitreyi Das
Keyword(s):  
Cell Cycle ◽  
Cell Separation ◽  
Fixed Time ◽  
Negative Regulator ◽  
Dependent Manner ◽  
Polarized Growth ◽  
A Cell ◽  
Local Cell ◽  
Cycle Dependent ◽  
Anaphase B

In fission yeast, polarized cell growth stops during division and resumes after cytokinesis completes and cells separate. It is unclear how growth reactivation is timed to occur immediately after cell separation. We uncoupled these sequential events by delaying cytokinesis with a temporary Latrunculin A treatment. Mitotic cells recovering from treatment initiate end growth during septation, displaying a polar elongation simultaneous with septation (PrESS) phenotype. PrESS cell ends reactivate Cdc42, a major regulator of polarized growth, during septation, but at a fixed time after anaphase B. A candidate screen implicates Rga4, a negative regulator of Cdc42, in this process. We show that Rga4 appears punctate at the cell sides during G2, but is diffuse during mitosis, extending to the ends. While the Morphogenesis Orb6 (MOR) pathway is known to promote cell separation and growth by activating protein synthesis, we find that for polarized growth, removal of Rga4 from the ends is also necessary. Therefore, we propose that growth resumes after division once the MOR pathway is activated and the ends lose Rga4 in a cell-cycle-dependent manner.

The Effect of Cell Mass on the Cell Cycle Timing and Duration of S-Phase in Fission Yeast

1979 ◽  
Vol 39 (1) ◽  
pp. 215-233
Author(s):  
KIM NASMYTH ◽  
PAUL NURSE ◽  
R. S. S. FRASER
Keyword(s):  
Cell Cycle ◽  
Dna Replication ◽  
Fission Yeast ◽  
Critical Level ◽  
Single Cells ◽  
Cell Mass ◽  
S Phase ◽  
Pulse Labelling ◽  
Random Transition ◽  
A Cell

Request for reprints to Paul Nurse. Two isotopic methods for measuring DNA replication in the fission yeast Schizosaccharomyces pombe are described. The first is a method for measuring the total quantity of [3H]uracil incorporated into DNA after pulse labelling. The second is a means of detecting DNA replication in single cells by autoradiography. Both of these techniques have been used to investigate the timing and duration of S-phase in a series of mutant strains whose cell mass at division varies over a 3-fold range. The results support the hypothesis that in S. pombe there are 2 different controls over the timing of S-phase: an attainment of a critical cell mass and a dependency upon the completion of the previous mitosis coupled with a short minimum time in G1. Strains whose cell mass at birth is above this critical level initiate DNA replication almost immediately after septation, that is, very soon after the previous mitosis. Strains whose cell mass at birth is below the critical level do not initiate replication until the critical cell mass is attained. The duration of S-phase has been estimated from the proportion of cells whose nuclei are labelled after a pulse of given duration. S-phase is short in S. pombe, lasting only about 0.1 of a cell cycle in wild type. Cell mass at S-phase does not have any consistent effect on this length. We have also investigated the degree of synchrony of S-phase initiation in daughter cells, and have found that, in a cell cycle 240 min long, their S-phases are initiated within 1–2 min of each other. This result indicates that between sisters variability in the duration of the G1 phase is small compared with variability in the total cell cycle time, and argues against the hypothesis that the rate of cell cycle traverse is determined by a random transition in G1.

A NIMA homologue promotes chromatin condensation in fission yeast

1998 ◽  
Vol 111 (7) ◽  
pp. 967-976 ◽  
Author(s):  
M.J. Krien ◽  
S.J. Bugg ◽  
M. Palatsides ◽  
G. Asouline ◽  
M. Morimyo ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Fission Yeast ◽  
Chromatin Condensation ◽  
Cell Types ◽  
Cell Cycle Delay ◽  
Downstream Target ◽  
A Cell ◽  
Chromatin Organisation ◽  
Bona Fide ◽  
P34 Cdc2

Entry into mitosis requires p34(cdc2), which activates downstream mitotic events through phosphorylation of key target proteins. In Aspergillus nidulans, the NIMA protein kinase has been identified as a potential downstream target and plays a role in regulating chromatin condensation at mitosis. nimA- mutants arrest in a state that physically resembles interphase even though p34(cdc2) is fully active. Despite evidence for the existence of NIMA-like activities in a variety of cell types, the only bona fide NIMA homologue that has been identified is the nim-1 gene of Neurospora crassa. We report here the isolation of a fission yeast NIMA homologue, and have designated this gene fin1 and the 83 kDa predicted protein p83(fin1). Overexpression of fin1 promotes premature chromatin condensation from any point in the cell cycle independently of p34(cdc2) function. Like NIMA, p83(fin1) levels fluctuate through the cell cycle, peaking in mitosis and levels are greatly elevated by removal of C-terminal PEST sequences. Deletion of fin1 results in viable but elongated cells, indicative of a cell cycle delay. Genetic analysis has placed this delay in G2 but, unlike in nimA mutants of Aspergillus, p34(cdc2) activation appears to be delayed. Interaction of fin1 mutants with other strains defective in chromatin organisation also support the hypothesis of p83(fin1) playing a role in this process at the onset of mitosis. These data indicate that NIMA-related kinases may be a general feature of the cell cycle and chromatin organisation at mitosis.

Fission yeast Nda1 and Nda4, MCM homologs required for DNA replication, are constitutive nuclear proteins

1996 ◽  
Vol 109 (2) ◽  
pp. 319-326 ◽  
Author(s):  
N. Okishio ◽  
Y. Adachi ◽  
M. Yanagida
Keyword(s):  
Cell Cycle ◽  
Dna Replication ◽  
Fission Yeast ◽  
Budding Yeast ◽  
Affinity Column ◽  
Wild Type ◽  
M Phase ◽  
A Cell ◽  
Mcm Proteins ◽  
Cycle Dependent

The nda1+ and nda4+ genes of the fission yeast Schizosaccharomyces pombe encode proteins similar to budding yeast MCM2 and MCM5/CDC46, respectively, which are required for the early stages of DNA replication. The budding yeast Mcm proteins display cell-cycle dependent localization. They are present in the nucleus specifically from late M phase until the beginning of S phase, so that they were suggested to be components of a replication licensing factor, a positive factor for the onset of replication, which is thought to be inactivated after use, thus restricting replication to only once in a cell cycle. In the present study, we raised antibodies against Nda1 or Nda4 and identified 115 kDa and 80 kDa proteins, respectively. Their immunolocalization was examined in wild-type cells and in various cell-cycle mutants. Both Nda1 and Nda4 proteins remained primarily in the nucleus throughout the cell cycle. In mutants arrested in G1, S, and G2 phases, these proteins were also enriched in the nucleus. These results indicate that the dramatic change in subcellular localization as seen in budding yeast is not essential in fission yeast for the functions of Nda1 and Nda4 proteins to be executed. The histidine-tagged nda1+ gene was constructed and integrated into the chromosome to replace the wild-type nda1+ gene. The resulting His-tagged Nda1 protein was adsorbed to the Ni-affinity column, and co-eluted with the untagged Nda4 protein, suggesting that they formed a complex.

The Wellcome Lecture, 1992. Cell cycle control

1993 ◽  
Vol 341 (1298) ◽  
pp. 449-454 ◽  
Keyword(s):  
Cell Cycle ◽  
Fission Yeast ◽  
Gene Network ◽  
Cell Cycle Control ◽  
Regulatory Gene ◽  
Eukaryotic Cell ◽  
S Phase ◽  
M Phase ◽  
A Cell ◽  
Future Work

Genetic analysis using the fission yeast has provided a powerful methodology to investigate the eukaryotic cell cycle and its control. The onset of M -phase in fission yeast is controlled by a regulatory gene network which activates the p34 cdc2 protein kinase encoded by the cdc 2 + gene. The coupling of M -phase to the completion of S-phase also works through p34 cdc2 . A similar network is operative in vertebrate cells. Future work will focus on the controls regulating onset of S-phase and on the mechanisms by which a cell duplicates itself in space during division.

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