Fabio Echegaray Iturra scite author profile

SummaryDistinct protein phosphorylation levels in interphase and M phase require tight regulation of Cdk1 activity [1, 2]. A bistable switch, based on positive feedback in the Cdk1 activation loop, has been proposed to generate different thresholds for transitions between these cell-cycle states [3, 4, 5]. Recently, the activity of the major Cdk1-counteracting phosphatase, PP2A:B55, has also been found to be bistable due to Greatwall kinase-dependent regulation [6]. However, the interplay of the regulation of Cdk1 and PP2A:B55 in vivo remains unexplored. Here, we combine quantitative cell biology assays with mathematical modeling to explore the interplay of mitotic kinase activation and phosphatase inactivation in human cells. By measuring mitotic entry and exit thresholds using ATP-analog-sensitive Cdk1 mutants, we find evidence that the mitotic switch displays hysteresis and bistability, responding differentially to Cdk1 inhibition in the mitotic and interphase states. Cdk1 activation by Wee1/Cdc25 feedback loops and PP2A:B55 inactivation by Greatwall independently contributes to this hysteretic switch system. However, elimination of both Cdk1 and PP2A:B55 inactivation fully abrogates bistability, suggesting that hysteresis is an emergent property of mutual inhibition between the Cdk1 and PP2A:B55 feedback loops. Our model of the two interlinked feedback systems predicts an intermediate but hidden steady state between interphase and M phase. This could be verified experimentally by Cdk1 inhibition during mitotic entry, supporting the predictive value of our model. Furthermore, we demonstrate that dual inhibition of Wee1 and Gwl kinases causes loss of cell-cycle memory and synthetic lethality, which could be further exploited therapeutically.

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Cyclin A triggers Mitosis either via the Greatwall kinase pathway or Cyclin B

Hégarat

Crncec

Rodriguez

et al. 2020

The EMBO Journal

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Two mitotic cyclin types, cyclin A and B, exist in higher eukaryotes, but their specialised functions in mitosis are incompletely understood. Using degron tags for rapid inducible protein removal, we analyse how acute depletion of these proteins affects mitosis. Loss of cyclin A in G2-phase prevents mitotic entry. Cells lacking cyclin B can enter mitosis and phosphorylate most mitotic proteins, because of parallel PP2A:B55 phosphatase inactivation by Greatwall kinase. The final barrier to mitotic establishment corresponds to nuclear envelope breakdown, which requires a decisive shift in the balance of cyclin-dependent kinase Cdk1 and PP2A:B55 activity. Beyond this point, cyclin B/Cdk1 is essential for phosphorylation of a distinct subset of mitotic Cdk1 substrates that are essential to complete cell division. Our results identify how cyclin A, cyclin B and Greatwall kinase coordinate mitotic progression by increasing levels of Cdk1-dependent substrate phosphorylation.

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Prophase-Specific Perinuclear Actin Coordinates Centrosome Separation and Positioning to Ensure Accurate Chromosome Segregation

et al. 2020

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Autonomous clocks that regulate organelle biogenesis, cytoskeletal organization, and intracellular dynamics

Mofatteh

Iturra

Alamban

et al. 2021

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How do cells perceive time? Do cells use temporal information to regulate the production/degradation of their enzymes, membranes, and organelles? Does controlling biological time influence cytoskeletal organization and cellular architecture in ways that confer evolutionary and physiological advantages? Potential answers to these fundamental questions of cell biology have historically revolved around the discussion of ‘master’ temporal programs, such as the principal cyclin-dependent kinase/cyclin cell division oscillator and the circadian clock. In this review, we provide an overview of the recent evidence supporting an emerging concept of ‘autonomous clocks,’ which under normal conditions can be entrained by the cell cycle and/or the circadian clock to run at their pace, but can also run independently to serve their functions if/when these major temporal programs are halted/abrupted. We begin the discussion by introducing recent developments in the study of such clocks and their roles at different scales and complexities. We then use current advances to elucidate the logic and molecular architecture of temporal networks that comprise autonomous clocks, providing important clues as to how these clocks may have evolved to run independently and, sometimes at the cost of redundancy, have strongly coupled to run under the full command of the cell cycle and/or the circadian clock. Next, we review a list of important recent findings that have shed new light onto potential hallmarks of autonomous clocks, suggestive of prospective theoretical and experimental approaches to further accelerate their discovery. Finally, we discuss their roles in health and disease, as well as possible therapeutic opportunities that targeting the autonomous clocks may offer.

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Cytoplasmic divisions without nuclei

Bakshi

Iturra

Alamban

et al. 2022

Preprint

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Cytoplasmic divisions have been commonly considered a sequel to nuclear divisions, even in the absence of DNA replication. Here we found in fruit fly embryos that the cytoplasm can compartmentalize and divide without nuclei. Our targeted screen for potential necessary and sufficient conditions revealed that, although the cytoplasmic compartments are tightly associated with centrosomes, they can form without astral microtubules and divide without centrioles. Although a focal pool of microtubules is necessary for maintaining cytoplasmic compartments, this is not sufficient for their initial formation. Actin filaments are similarly an essential component of cytoplasmic compartments; however, their myosin II-based contractility is unexpectedly dispensable for divisions. We show that the myosin II-based contractility is instead involved in regulating the pace of these divisions. Importantly, our results revealed that the cytoplasmic divisions without nuclei can occur in a periodic manner autonomously of the Cdk-Cyclin oscillator that normally drives the cell cycle. We demonstrate that such autonomy of cytoplasmic divisions is preserved even in normal development, where it is leveraged to extrude mitotically delayed nuclei from the blastoderm, protecting the synchrony of rapid nuclear divisions against local delays in mitotic entry. We propose that an active coordination between otherwise autonomous cycles of cytoplasmic and nuclear divisions acts as a quality control mechanism for genome integrity and partitioning in development.

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