Landscape and flux reveal a new global view and physical quantification of mammalian cell cycle

Li, Chunhe; Wang, Jin

doi:10.1073/pnas.1408628111

Cited by 133 publications

(216 citation statements)

References 35 publications

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“…30,50 We have shown that the mRNA number is distinctly larger in the case of random division than in the case of constant division, implying that the efficiency is higher in the former case than in the latter case. 30,50 We have shown that the MFPT is shorter in the case of random division than in the case of constant division, and that the MFPT in the case of slow switching is nearly as large as that in the case of fast switching (Fig. 4 Another constraint is in the ability that a gene responds quickly to external stimuli.…”

Section: Conclusion and Discussionmentioning

confidence: 83%

“…5,6 While quantitative time-lapse fluorescence microscopy allows for tracing the real-time expression of genes in individual cells, [7][8][9] there is considerable interest in theoretically understanding how different molecular mechanisms of gene expression affect variations in mRNA and protein abundances across a population of genetically identical cells. When cellular energy and growth factors are enough, cell growth and division are all periodic events [27][28][29][30] (traditionally, cell division means that a cell begins to divide when its volume reaches twice the original volume, so this kind of division is actually a volume-based division. [17][18][19][20][21][22][23][24][25][26] Cell growth and division are ubiquitous in natural systems.…”

Section: Introductionmentioning

confidence: 99%

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Division time-based amplifiers for stochastic gene expression

2015

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While cell-to-cell variability is a phenotypic consequence of gene expression noise, sources of this noise may be complex - apart from intrinsic sources such as the random birth/death of mRNA and stochastic switching between promoter states, there are also extrinsic sources of noise such as cell division where division times are either constant or random. However, how this time-based division affects gene expression as well as how it contributes to cell-to-cell variability remains unexplored. Using a computational model combined with experimental data, we show that the cell-cycle length defined as the difference between two sequential division times can significantly impact the expression dynamics. Specifically, we find that both divisions (constant or random) always increase the mean level of mRNA and lengthen the mean first passage time. In contrast to constant division, random division always amplifies expression noise but tends to stabilize its temporal level, and unimodalizes the mRNA distribution, but makes its tail longer. These qualitative results reveal that cell division based on time is an effective mechanism for both increasing expression levels and enhancing cell-to-cell variability.

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Section: Conclusion and Discussionmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Division time-based amplifiers for stochastic gene expression

2015

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“…., X n represent the concentration or number of molecules of species), we expect to have n-coupled differential equations, which are hard to solve analytically. Applying a self-consistent mean field approach (14,(32)(33)(34)(35), we split the probability into the products of individual ones: P X 1 ; X 2 ; . .…”

Section: Self-consistent Mean Field Approximationmentioning

confidence: 99%

Quantifying the Landscape for Development and Cancer from a Core Cancer Stem Cell Circuit

Wang

2015

Cancer Research

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101

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Cancer presents a serious threat to human health. The understanding of the cell fate determination during development and tumor-genesis remains challenging in current cancer biology. It was suggested that cancer stem cell (CSC) may arise from normal stem cells or be transformed from normal differentiated cells. This gives hints on the connection between cancer and development. However, the molecular mechanisms of these cell-type transitions and the CSC formation remain elusive. We quantified landscape, dominant paths, and switching rates between cell types from a core gene regulatory network for cancer and development. Stem cell, CSC, cancer, and normal cell types emerge as basins of attraction on associated landscape. The dominant paths quantify the transition processes among CSC, stem cell, normal cell, and cancer cell attractors. Transition actions of the dominant paths are shown to be closely related to switching rates between cell types, but not always to the barriers in between, because of the presence of the curl flux. During the process of P53 gene activation, landscape topography changes gradually from a CSC attractor to a normal cell attractor. This confirms the roles of P53 of preventing the formation of CSC through suppressing self-renewal and inducing differentiation. By global sensitivity analysis according to landscape topography and action, we identified key regulations determining cell-type switchings and suggested testable predictions. From landscape view, the emergence of the CSCs and the associated switching to other cell types are the results of underlying interactions among cancer and developmental marker genes. This indicates that the cancer and development are intimately connected. This landscape and flux theoretical framework provides a quantitative way to understand the underlying mechanisms of CSC formation and interplay between cancer and development. Cancer Res; 75(13); 2607-18. Ó2015 AACR.

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“…Therefore, it is not only continuous nonlinear dynamics that is relevant, but it is also stochasticity induced by the paucity of some key molecular regulator(s) in the system. Thus, the notion of stochastic potential is of paramount importance (see Wang et al [13][14][15][16][17][18][19][20][21][22][23]). The role of energy in the establishment and maintenance of living systems at steady-states far from equilibrium is related, but is not addressed here (see Qian et al [24][25][26][27][28][29]).…”

Section: Biochemical Noise Contributes In Subtle Waysmentioning

confidence: 99%

Parameter asymmetry and time‐scale separation in core genetic commitment circuits

Xi¹,

Turcotte²

2015

Quant. Biol.

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Theory allows studying why Evolution might select core genetic commitment circuit topologies over alternatives. The nonlinear dynamics of the underlying gene regulation together with the unescapable subtle interplay of intrinsic biochemical noise impact the range of possible evolutionary choices. The question of why certain genetic regulation circuits might present robustness to phenotype-delivery breaking over others, is therefore of high interest. Here, the behavior of systematically more complex commitment circuits is studied, in the presence of intrinsic noise, with a focus on two aspects relevant to biology: parameter asymmetry and time-scale separation. We show that phenotype delivery is broken in simple two-and three-gene circuits. In the two-gene circuit, we show how stochastic potential wells of different depths break commitment. In the three-gene circuit, we show that the onset of oscillations breaks the commitment phenotype in a systematic way. Finally, we also show that higher dimensional circuits (four-gene and five-gene circuits) may be intrinsically more robust.

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Landscape and flux reveal a new global view and physical quantification of mammalian cell cycle

Cited by 133 publications

References 35 publications

Division time-based amplifiers for stochastic gene expression

Division time-based amplifiers for stochastic gene expression

Quantifying the Landscape for Development and Cancer from a Core Cancer Stem Cell Circuit

Parameter asymmetry and time‐scale separation in core genetic commitment circuits

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