ODE Constrained Mixture Modelling: A Method for Unraveling Subpopulation Structures and Dynamics

Hasenauer, Jan; Hasenauer, Christine; Hucho, Tim; Theis, Fabian J.

doi:10.1371/journal.pcbi.1003686

Cited by 50 publications

(81 citation statements)

References 86 publications

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“…Such models assume that the different observations arise from different realizations of the same stochastic process and, therefore, are still based on the notion of a virtual mean-although noisy-cell. In comparison, and despite recent methodological developments [27,28], few attempts have been made to infer extrinsic noise models from data, see [4,10,23,29,30] and our previous work [31]. We refer the reader to Karlsson et al [24] for a detailed discussion of these works.…”

Section: Discussionmentioning

confidence: 99%

What Population Reveals About Individual Cell Identity: Single-Cell Parameter Estimation of Models of Gene Expression in Yeast

Batt¹

2016

Electron. Proc. Theor. Comput. Sci.

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Significant cell-to-cell heterogeneity is ubiquitously observed in isogenic cell populations. Consequently, parameters of models of intracellular processes, usually fitted to populationaveraged data, should rather be fitted to individual cells to obtain a population of models of similar but non-identical individuals. Here, we propose a quantitative modeling framework that attributes specific parameter values to single cells for a standard model of gene expression. We combine high quality single-cell measurements of the response of yeast cells to repeated hyperosmotic shocks and state-of-the-art statistical inference approaches for mixed-effects models to infer multidimensional parameter distributions describing the population, and then derive specific parameters for individual cells. The analysis of single-cell parameters shows that single-cell identity (e.g. gene expression dynamics, cell size, growth rate, mother-daughter relationships) is, at least partially, captured by the parameter values of gene expression models (e.g. rates of transcription, translation and degradation). Our approach shows how to use the rich information contained into longitudinal single-cell data to infer parameters that can faithfully represent single-cell identity. Author SummaryBecause of non-genetic variability, cells in an isogenic population respond differently to a same stimulation. Therefore, the mean behavior of a cell population does not generally correspond to the behavior of the mean cell, and more generally, neglecting cell-to-cell differences biases our quantitative representation and understanding of the functioning of cellular systems. Here we introduce a statistical inference approach allowing for the calibration of (a population of) single cell models, differing by their parameter values. It enables to view time-lapse microscopy data as many experiments performed on one cell rather than one experiment performed on many cells. By harnessing existing cell-to-cell differences, one can then learn how environmental cues affect (non-observed) intracellular processes. Our approach is generic and enables to exploit in unprecedented manner the high informative content of single-cell longitudinal data.

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Section: Discussionmentioning

confidence: 99%

What Population Reveals About Individual Cell Identity: Single-Cell Parameter Estimation of Models of Gene Expression in Yeast

Batt¹

2016

Electron. Proc. Theor. Comput. Sci.

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“…A combination of ODEs and mixture models is treated in [56]. This allows flexible modeling, and has the advantage of incorporating not only the RRE, but also moment approximations and LNA models, as computing these also reduces to the solution of ODEs.…”

Section: Inference For Single-cell Distribution Datamentioning

confidence: 99%

Bayesian inference of reaction kinetics from single-cell recordings across a heterogeneous cell population

Bronstein

Zechner

Koeppl

2015

Methods

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“…For example, gene transcriptional processes have been shown to occur in stochastic (random) bursts [4][5][6]. Many modeling frameworks have been used to capture cellular heterogeneity-for example, by using ensemble models (EM) of ordinary differential equations (ODEs) [7][8][9], population balance models (PBMs) [10], stochastic ordinary differential equations (SDEs) [11,12], and chemical master equations (CMEs) [13][14][15]. In these models, the cell-to-cell variability is described by a probability density or distribution function of cell state variables.…”

Section: Introductionmentioning

confidence: 99%

Elucidating Cellular Population Dynamics by Molecular Density Function Perturbations

Perumal

2018

Processes

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Studies performed at single-cell resolution have demonstrated the physiological significance of cell-to-cell variability. Various types of mathematical models and systems analyses of biological networks have further been used to gain a better understanding of the sources and regulatory mechanisms of such variability. In this work, we present a novel sensitivity analysis method, called molecular density function perturbation (MDFP), for the dynamical analysis of cellular heterogeneity. The proposed analysis is based on introducing perturbations to the density or distribution function of the cellular state variables at specific time points, and quantifying how such perturbations affect the state distribution at later time points. We applied the MDFP analysis to a model of a signal transduction pathway involving TRAIL (tumor necrosis factor-related apoptosis-inducing ligand)-induced apoptosis in HeLa cells. The MDFP analysis shows that caspase-8 activation regulates the timing of the switch-like increase of cPARP (cleaved poly(ADP-ribose) polymerase), an indicator of apoptosis. Meanwhile, the cell-to-cell variability in the commitment to apoptosis depends on mitochondrial outer membrane permeabilization (MOMP) and events following MOMP, including the release of Smac (second mitochondria-derived activator of caspases) and cytochrome c from mitochondria, the inhibition of XIAP (X-linked inhibitor of apoptosis) by Smac, and the formation of the apoptosome.

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ODE Constrained Mixture Modelling: A Method for Unraveling Subpopulation Structures and Dynamics

Cited by 50 publications

References 86 publications

What Population Reveals About Individual Cell Identity: Single-Cell Parameter Estimation of Models of Gene Expression in Yeast

What Population Reveals About Individual Cell Identity: Single-Cell Parameter Estimation of Models of Gene Expression in Yeast

Bayesian inference of reaction kinetics from single-cell recordings across a heterogeneous cell population

Elucidating Cellular Population Dynamics by Molecular Density Function Perturbations

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