Dividing the spoils of growth and the cell cycle: The fission yeast as a model for the study of cytokinesis

Cytokinesis is the final stage of the cell cycle, and ensures completion of both genome segregation and organelle distribution to the daughter cells. Cytokinesis requires the cell to solve a spatial problem (to divide in the correct place, orthogonally to the plane of chromosome segregation) and a temporal problem (to coordinate cytokinesis with mitosis). Defects in the spatiotemporal control of cytokinesis may cause cell death, or increase the risk of tumor formation [Fujiwara et al., 2005 (Fujiwara T, Bandi M, Nitta M, Ivanova EV, Bronson RT, Pellman D. 2005. Cytokinesis failure generating tetraploids promotes tumorigenesis in p53-null cells. Nature 437:1043–1047); reviewed by Ganem et al., 2007 (Ganem NJ, Storchova Z, Pellman D. 2007. Tetraploidy, aneuploidy and cancer. Curr Opin Genet Dev 17:157–162.)]. Asymmetric cytokinesis, which permits the generation of two daughter cells that differ in their shape, size and properties, is important both during development, and for cellular homeostasis in multicellular organisms [reviewed by Li, 2007 (Li R. 2007. Cytokinesis in development and disease: variations on a common theme. Cell Mol Life Sci 64:3044–3058)]. The principal focus of this review will be the mechanisms of cytokinesis in the mitotic cycle of the yeast Schizosaccharomyces pombe. This simple model has contributed significantly to our understanding of how the cell cycle is regulated, and serves as an excellent model for studying aspects of cytokinesis. Here we will discuss the state of our knowledge of how the contractile ring is assembled and disassembled, how it contracts, and what we know of the regulatory mechanisms that control these events and assure their coordination with chromosome segregation.

The role of OCT4 and SOX2 in regulating chromatin accessibility and cell fate across the cell cycle in embryonic stem cells

Torgil Elias Friman

Precise spatiotemporal regulation of gene expression is essential for development and homeostasis of complex organisms. This is achieved in large part by sequence-specific transcription factors (TF) that bind to genomic regulatory elements to activate or repress transcription. DNA in eukaryotic nuclei is wrapped around histones into nucleosomes, which are inaccessible to most proteins. However, certain TFs can access their binding sites in the presence of histones and promote nucleosome eviction to increase chromatin accessibility, allowing for binding of other protein. These TFs, called pioneer factors, include OCT4 and SOX2, which are master regulators of embryonic stem (ES) cells. Dividing cells, including stem cells, must achieve proper gene regulation despite the progression of the cell cycle, which imposes several constraints. During S phase, the replication fork passes through the genome to make a copy of each chromosome, which leads to a loss of chromatin accessibility. Furthermore, the substantial chromatin compaction that occurs during mitosis to prepare for chromosome segregation is associated with eviction of most DNA-binding proteins and reduced accessibility at distal cis-regulatory elements including enhancers. How pioneer factors operate in the context of cell cycle progression is unclear. In this thesis, I will present work studying different features of OCT4 and SOX2, including how they interplay to regulate chromatin accessibility in ES cells, the impact of small endogenous fluctuations of their protein levels on cell fate and chromatin accessibility, and how their roles in regulating cell fate and chromatin accessibility is related to different stages of the cell cycle. Using live-cell imaging of fluorescently labeled proteins, we discovered that OCT4 and SOX2 were associated to mitotic chromatin. Using cell-cycle specific degradation strategies, we could show that the presence of SOX2 and OCT4 at the mitosis-G1 (M-G1) transition contributes to maintain the pluripotency of ES cells. We further showed that ES cells with high levels of OCT4 in G1, but not in S phase, are more prone to differentiate towards neuroectoderm and mesendoderm cell fates. Cells with high levels of OCT4 displayed increased chromatin accessibility at enhancers of differentiation genes, suggesting accessibility fluctuates with OCT4 levels and can prime cells for differentiation. To explore potential cell cycle-dependent regulation of chromatin accessibility, we degraded OCT4 at the M-G1 transition, which led to a reduction in accessibility at many OCT4-bound regions. When OCT4 returned later in the cell cycle, chromatin accessibility was recovered, although at many loci this recovery was incomplete, suggesting that OCT4 is required at the M-G1 transition to maintain these regions open. We then rapidly degraded OCT4 at other phases of the cell cycle. Surprisingly, loss of chromatin accessibility was highly similar at all cell cycle phases, showing that OCT4 is constantly required to maintain regulatory elements accessible. To explore the dynamic regulation of accessibility by OCT4, we performed time-course measurements of accessibility upon its degradation. This revealed that loss of accessibility was temporally correlated to the degradation of OCT4. These results suggest that chromatin accessibility is highly dynamic and continuously dependent on the presence of OCT4 across the cell cycle in ES cells.

EPFL2019

The S-pombe cytokinesis NDR kinase Sid2 activates Fin1 NIMA kinase to control mitotic commitment through Pom1/Wee1

Viesturs Simanis

Mitotic exit integrates the reversal of the phosphorylation events initiated by mitotic kinases with a controlled cytokinesis event that cleaves the cell in two. The mitotic exit network (MEN) of budding yeast regulates both processes, whereas the fission yeast equivalent, the septum initiation network (SIN), controls only the execution of cytokinesis. The components and architecture of the SIN and MEN are highly conserved(1). At present, it is assumed that the functions of the core SIN-MEN components are restricted to their characterized roles at the end of mitosis. We now show that the NDR (nuclear Dbf2-related) kinase component of the fission yeast SIN, Sid2-Mob1, acts independently of the other known SIN components in G2 phase of the cell cycle to control the timing of mitotic commitment. Sid2-Mob1 promotes mitotic commitment by directly activating the NIMA (Never In Mitosis)-related kinase Fin1. Fin1's activation promotes its own destruction, thereby making Fin1 activation a transient feature of G2 phase. This spike of Fin1 activation modulates the activity of the Pom1/Cdr1/Cdr2 geometry network towards Wee1.

Nature Publishing Group2012

The role of OCT4 and SOX2 in regulating chromatin accessibility and cell fate across the cell cycle in embryonic stem cells

Torgil Elias Friman

EPFL2019