Author response: Cell size sensing in animal cells coordinates anabolic growth rates and cell cycle progression to maintain cell size uniformity

Ginzberg, Miriam Bracha; Chang, Nancy; D'Souza, Heather; Patel, Nish; Kafri, Ran; Kirschner, Marc W.

doi:10.7554/elife.26957.040

2018

DOI: 10.7554/elife.26957.040

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Author response: Cell size sensing in animal cells coordinates anabolic growth rates and cell cycle progression to maintain cell size uniformity

Miriam Bracha Ginzberg

Nancy Chang

Heather D'Souza

et al.

Abstract: Cell size uniformity in healthy tissues suggests that control mechanisms might coordinate cell growth and division. We derived a method to assay whether cellular growth rates depend on cell size, by monitoring how variance in size changes as cells grow. Our data revealed that, twice during the cell cycle, growth rates are selectively increased in small cells and reduced in large cells, ensuring cell size uniformity. This regulation was also observed directly by monitoring nuclear growth in live cells. We also … Show more

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Cited by 3 publications

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Simultaneous suppression of ribosome biogenesis and Tor activation by TRIM-NHL proteins promotes terminal differentiation

Gui

2021

Preprint

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Proper stem cell differentiation relies on a balance between cellular growth and terminal differentiation, but the mechanisms coordinating these processes remain elusive. Recent studies indicate that ribosome biogenesis (RiBi) and protein synthesis, two of the most energy-consuming cellular processes supporting growth, are tightly regulated and yet can be uncoupled during stem cell fate transitions. Here, using the Drosophila adult female germline stem cell (GSC) and larval neuroblast (NB) systems, we show that Mei-P26 and Brat, two Drosophila TRIM-NHL paralogues of the mammalian TRIM32 protein family, are responsible for uncoupling RiBi and protein synthesis during GSC and NB differentiation, respectively. This is achieved by TRIM-NHL-mediated activation of the Target of rapamycin (Tor) kinase and concomitant repression of RiBi specifically during stem cell differentiation. In consequence, the anabolic reprogramming established by TRIM-NHL activity creates the conditions for terminal differentiation. In agreement with this, depletion of mei-P26 or brat, which results in excessive cellular growth and defective terminal differentiation, can be counterbalanced by ectopic activation of Tor together with suppression of RiBi, allowing completion of differentiation. Our work indicates that TRIM-NHL proteins uncouple RiBi and translation activities to coordinate growth and differentiation, and proposes that the control of cellular resources provides a meter for terminal differentiation.

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Simultaneous suppression of ribosome biogenesis and Tor activation by TRIM-NHL proteins promotes terminal differentiation

Gui

2021

Preprint

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Beyond G1/S regulation: How cell size homeostasis is tightly controlled throughout the cell cycle?

Liu

Yan

Kirschner

2022

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Proliferating cells require control mechanisms to counteract stochastic noise and stabilize the cell mass distribution in a population. It is widely believed that size-dependent timing of the G1/S transition is the predominant control process in mammalian cells. However, a model based only on such a checkpoint cannot explain why cell lines with deficient G1/S control are still able to maintain a stable cell mass distribution or how cell mass is maintained throughout the subsequent phases of the cell cycle. To answer such questions, we used a recently developed form of Quantitative Phase Microscopy (ceQPM), which provides much-improved accuracy of individual cell mass measurement, to investigate the factors contributing to cell mass homeostasis. We find that cell mass homeostasis is robustly maintained, despite disruptions of the normal G1/S transition or cell growth rate. The coefficient of variation in mass, nevertheless declines well after the G1/S transition and throughout the cell cycle in both transformed and non-transformed cells. Furthermore, the cell growth rate responds to cell mass in different ways in different cell types. Growth rate modulation is conveyed by mTORC1-dependent and mTORC1-independent processes, which are independently regulated. Slightly reduced mass accumulation, below exponential growth can effectively reduce cell mass variation in a population. Both size-dependent cell cycle regulation and size-dependent growth rate modulation contribute to cell mass homeostasis. Together they form a compensatory network that strictly controls the coefficient of variation of cell mass in a population. These findings opens new avenues for the discovery of underlying molecular mechanisms. Furthermore, understanding feedback directly on cell growth may provide insights into fundamental principles of cell size control in normal proliferating and terminally differentiated cells, as well as cells in pathological circumstances.

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Computationally Enhanced Quantitative Phase Microscopy Reveals Autonomous Oscillations in Mammalian Cell Growth

Liu

Peshkin

et al. 2019

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The regulation of growth is fundamental to cell size control. Lack of sufficient accuracy in the measurement of the growth rate of adherent cells through the cell cycle has thwarted the understanding of how such cell populations maintain a stable size distribution. The accuracy of Quantitative Phase Microscopy (QPM) is just shy of the accuracy needed to resolve the principle features of mammalian cell growth and perhaps to reveal new ones. Based on our analysis of the source of errors in QPM we both improved image processing algorithms and automated cell tracking software, making it suitable for longitudinal and large scale applications. Using these tools we revealed a remarkable a series of episodes of the convergence of cell growth rate, which may play a large role in the control of cell size variability.Main text

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Author response: Cell size sensing in animal cells coordinates anabolic growth rates and cell cycle progression to maintain cell size uniformity

Cited by 3 publications

References 0 publications

Simultaneous suppression of ribosome biogenesis and Tor activation by TRIM-NHL proteins promotes terminal differentiation

Simultaneous suppression of ribosome biogenesis and Tor activation by TRIM-NHL proteins promotes terminal differentiation

Beyond G1/S regulation: How cell size homeostasis is tightly controlled throughout the cell cycle?

Computationally Enhanced Quantitative Phase Microscopy Reveals Autonomous Oscillations in Mammalian Cell Growth

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