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886 results on '"Tyson, John J."'

13. Comparison of Domain Nucleation Mechanisms in a Minimal Model of Shoot Apical Meristem

Author

Battogtokh, Dorjsuren and Tyson, John J.

Subjects
Quantitative Biology - Molecular Networks
Abstract

Existing mathematical models of the shoot apical meristem (SAM) explain nucleation and confinement of a stem cell domain by Turing's mechanism, assuming that the diffusion coefficients of the activator (WUSCHEL) and inhibitor (CLAVATA) are significantly different. As there is no evidence for this assumption of differential diffusivity, we recently proposed a new mechanism based on a bistable switch model of the SAM. Here we study the bistable-switch mechanism in detail, demonstrating that it can be understood as localized switches of WUSHEL activity in individual cells driven by a non-uniform field of a peptide hormone. By comparing domain formation by Turing and bistable-switch mechanisms on a cell network, we show that the latter does not require the assumptions needed by the former, which are not supported by biological evidences., Comment: 9 pages 16 figures

Published
2016

15. Network Topologies and Dynamics Leading to Endotoxin Tolerance and Priming in Innate Immune Cells

Author

Fu, Yan, Glaros, Trevor, Zhu, Meng, Wang, Ping, Wu, Zhanghan, Tyson, John J, Li, Liwu, and Xing, Jianhua

Subjects
Quantitative Biology - Molecular Networks, Quantitative Biology - Quantitative Methods
Abstract

The innate immune system, acting as the first line of host defense, senses and adapts to foreign challenges through complex intracellular and intercellular signaling networks. Endotoxin tolerance and priming elicited by macrophages are classic examples of the complex adaptation of innate immune cells. Upon repetitive exposures to different doses of bacterial endotoxin (lipopolysaccharide) or other stimulants, macrophages show either suppressed or augmented inflammatory responses compared to a single exposure to the stimulant. Endotoxin tolerance and priming are critically involved in both immune homeostasis and the pathogenesis of diverse inflammatory diseases. However, the underlying molecular mechanisms are not well understood. By means of a computational search through the parameter space of a coarse-grained three-node network with a two-stage Metropolis sampling approach, we enumerated all the network topologies that can generate priming or tolerance. We discovered three major mechanisms for priming (pathway synergy, suppressor deactivation, activator induction) and one for tolerance (inhibitor persistence). These results not only explain existing experimental observations, but also reveal intriguing test scenarios for future experimental studies to clarify mechanisms of endotoxin priming and tolerance., Comment: 15 pages, 8 figures, submitted

Published
2012
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16. The oscillation of mitotic kinase governs cell cycle latches in mammalian cells.

Author

Dragoi, Calin-Mihai, Kaur, Ekjot, Barr, Alexis R., Tyson, John J., and Novák, Béla

Subjects
MAMMALIAN cell cycle, CELL cycle proteins, OSCILLATIONS, CYCLINS
Abstract

The mammalian cell cycle alternates between two phases - S-G2-M with high levels of A- and B-type cyclins (CycA and CycB, respectively) bound to cyclin-dependent kinases (CDKs), and G1 with persistent degradation of CycA and CycB by an activated anaphase promoting complex/cyclosome (APC/C) bound to Cdh1 (also known as FZR1 in mammals; denoted APC/C:Cdh1). Because CDKs phosphorylate and inactivate Cdh1, these two phases are mutually exclusive. This 'toggle switch' is flipped from G1 to S by cyclin-E bound to a CDK (CycE:CDK), which is not degraded by APC/C:Cdh1, and from M to G1 by Cdc20-bound APC/C (APC/C:Cdc20), which is not inactivated by CycA:CDK or CycB:CDK. After flipping the switch, cyclin E is degraded and APC/C:Cdc20 is inactivated. Combining mathematical modelling with single-cell timelapse imaging, we show that dysregulation of CycB:CDK disrupts strict alternation of the G1-S and M-G1 switches. Inhibition of CycB:CDK results in Cdc20-independent Cdh1 'endocycles', and sustained activity of CycB:CDK drives Cdh1-independent Cdc20 endocycles. Our model provides a mechanistic explanation for how wholegenome doubling can arise, a common event in tumorigenesis that can drive tumour evolution. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Bifurcation analysis of a model of the budding yeast cell cycle

Author

Battogtokh, Dorjsuren and Tyson, John J.

Subjects
Quantitative Biology - Molecular Networks
Abstract

We study the bifurcations of a set of nine nonlinear ordinary differential equations that describe the regulation of the cyclin-dependent kinase that triggers DNA synthesis and mitosis in the budding yeast, Saccharomyces cerevisiae. We show that Clb2-dependent kinase exhibits bistability (stable steady states of high or low kinase activity). The transition from low to high Clb2-dependent kinase activity is driven by transient activation of Cln2-dependent kinase, and the reverse transition is driven by transient activation of the Clb2 degradation machinery. We show that a four-variable model retains the main features of the nine-variable model. In a three-variable model exhibiting birhythmicity (two stable oscillatory states), we explore possible effects of extrinsic fluctuations on cell cycle progression., Comment: 31 pages,13 figures

Published
2004
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20. Turbulence near cyclic fold bifurcations in birhythmic media

Author

Battogtokh, Dorjsuren and Tyson, John J.

Subjects
Quantitative Biology - Subcellular Processes
Abstract

We show that at the onset of a cyclic fold bifurcation, a birhythmic medium composed of glycolytic oscillators displays turbulent dynamics. By computing the largest Lyapunov exponent, the spatial correlation function, and the average transient lifetime, we classify it as a weak turbulence with transient nature. Virtual heterogeneities generating unstable fast oscillations are the mechanism of the transient turbulence. In the presence of wavenumber instability, unstable oscillations can be reinjected leading to stationary turbulence. We also find similar turbulence in a cell cycle model. These findings suggest that weak turbulence may be universal in biochemical birhythmic media exhibiting cyclic fold bifurcations., Comment: 14 pages 10 figures

Published
2004
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31. Evolutionary Stability of Small Molecular Regulatory Networks That Exhibit Near-Perfect Adaptation

Author

Singhania, Rajat and Tyson, John J.

Abstract

Large-scale protein regulatory networks, such as signal transduction systems, contain small-scale modules (‘motifs’) that carry out specific dynamical functions. Systematic characterization of the properties of small network motifs is therefore of great interest to molecular systems biologists. We simulate a generic model of three-node motifs in search of near-perfect adaptation, the property that a system responds transiently to a change in an environmental signal and then returns near-perfectly to its pre-signal state (even in the continued presence of the signal). Using an evolutionary algorithm, we search the parameter space of these generic motifs for network topologies that score well on a pre-defined measure of near-perfect adaptation. We find many high-scoring parameter sets across a variety of three-node topologies. Of all possibilities, the highest scoring topologies contain incoherent feed-forward loops (IFFLs), and these topologies are evolutionarily stable in the sense that, under ‘macro-mutations’ that alter the topology of a network, the IFFL motif is consistently maintained. Topologies that rely on negative feedback loops with buffering (NFLBs) are also high-scoring; however, they are not evolutionarily stable in the sense that, under macro-mutations, they tend to evolve an IFFL motif and may—or may not—lose the NFLB motif. Published version

Published
2023

36. Feedback in the β-catenin destruction complex imparts bistability and cellular memory

Author

Cantoria, Mary Jo, primary, Alizadeh, Elaheh, additional, Ravi, Janani, additional, Varghese, Reeba P., additional, Bunnag, Nawat, additional, Pond, Kelvin W., additional, Kettenbach, Arminja N., additional, Ahmed, Yashi, additional, Paek, Andrew L., additional, Tyson, John J., additional, Doubrovinski, Konstantin, additional, Lee, Ethan, additional, and Thorne, Curtis A., additional

Published
2023
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38. Cell Cycle, Budding Yeast

Author

Tyson, John J., Chen, Katherine C., Novák, Béla, Dubitzky, Werner, editor, Wolkenhauer, Olaf, editor, Cho, Kwang-Hyun, editor, and Yokota, Hiroki, editor

Published
2013
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43. Biochemical Oscillations

Author

Tyson, John J., Antman, S. S., editor, Marsden, J. E., editor, Sirovich, L., editor, Wiggins, S., editor, Fall, Christopher P., editor, Marland, Eric S., editor, Wagner, John M., editor, and Tyson, John J., editor

Published
2002
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44. Cell Cycle Controls

Author

Tyson, John J., Novák, Béla, Antman, S. S., editor, Marsden, J. E., editor, Sirovich, L., editor, Wiggins, S., editor, Fall, Christopher P., editor, Marland, Eric S., editor, Wagner, John M., editor, and Tyson, John J., editor

Published
2002
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