Growth-induced hormone dilution can explain the dynamics of plant root cell elongation

Band, Leah R.; Úbeda-Tomás, Susana; Dyson, Rosemary; Middleton, A.; Hodgman, Charlie; Owen, Markus R.; Jensen, Oliver E.; Bennett, Malcolm J.; King, John R.

doi:10.1073/pnas.1113632109

Cited by 100 publications

(121 citation statements)

References 40 publications

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“…A recent analysis in this vein was performed on gibberellin perception in [86]. The authors embedded the model developed in [78] in a multi-scale spatial framework to analyse the interplay between GA signalling and root growth.…”

Section: Multi-scale Analysis Of Plant Signallingmentioning

confidence: 99%

Mathematical Modelling Plant Signalling Networks

Muraro

Byrne

King

et al. 2013

Math. Model. Nat. Phenom.

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Abstract. During the last two decades, molecular genetic studies and the completion of the sequencing of the Arabidopsis thaliana genome have increased knowledge of hormonal regulation in plants. These signal transduction pathways act in concert through gene regulatory and signalling networks whose main components have begun to be elucidated. Our understanding of the resulting cellular processes is hindered by the complex, and sometimes counter-intuitive, dynamics of the networks, which may be interconnected through feedback controls and crossregulation. Mathematical modelling provides a valuable tool to investigate such dynamics and to perform in silico experiments that may not be easily carried out in a laboratory. In this article, we firstly review general methods for modelling gene and signalling networks and their application in plants. We then describe specific models of hormonal perception and cross-talk in plants. This sub-cellular analysis paves the way for more comprehensive mathematical studies of hormonal transport and signalling in a multi-scale setting.

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Section: Multi-scale Analysis Of Plant Signallingmentioning

confidence: 99%

Mathematical Modelling Plant Signalling Networks

Muraro

Byrne

King

et al. 2013

Math. Model. Nat. Phenom.

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“…Spatial gradients in growth hormones (auxin and GA) were proposed (Went and Thimann, 1937;Sánchez-Bravo et al, 1992;Band et al, 2012), but hormones are several steps removed from the biochemical and biophysical processes that drive cell growth (e.g. cell wall loosening and stress relaxation, leading to water uptake and concomitant expansion of the cell wall; Cosgrove, 2016).…”

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confidence: 99%

Gradients in Wall Mechanics and Polysaccharides along Growing Inflorescence Stems

et al. 2017

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At early stages of Arabidopsis (Arabidopsis thaliana) flowering, the inflorescence stem undergoes rapid growth, with elongation occurring predominantly in the apical ;4 cm of the stem. We measured the spatial gradients for elongation rate, osmotic pressure, cell wall thickness, and wall mechanical compliances and coupled these macroscopic measurements with molecular-level characterization of the polysaccharide composition, mobility, hydration, and intermolecular interactions of the inflorescence cell wall using solid-state nuclear magnetic resonance spectroscopy and small-angle neutron scattering. Force-extension curves revealed a gradient, from high to low, in the plastic and elastic compliances of cell walls along the elongation zone, but plots of growth rate versus wall compliances were strikingly nonlinear. Neutron-scattering curves showed only subtle changes in wall structure, including a slight increase in cellulose microfibril alignment along the growing stem. In contrast, solid-state nuclear magnetic resonance spectra showed substantial decreases in pectin amount, esterification, branching, hydration, and mobility in an apical-to-basal pattern, while the cellulose content increased modestly. These results suggest that pectin structural changes are connected with increases in pectin-cellulose interaction and reductions in wall compliances along the apical-to-basal gradient in growth rate. These pectin structural changes may lessen the ability of the cell wall to undergo stress relaxation and irreversible expansion (e.g. induced by expansins), thus contributing to the growth kinematics of the growing stem.

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“…The combination of experimental and modelling analysis enables the study of plant hormone gradients as an integrated system, in which the causal relationships of all components can be established. To date, this approach has led to an improved understanding of, for example, how PIN proteins play a key role in auxin patterning and root growth (Grieneisen et al, 2007); how asymmetric auxin gradients link to gravitropsim (Band et al 2012; see also doi: 10.1002/9780470015902.a0025267);…”

Section: Discussionmentioning

confidence: 99%

“…It has also been shown that growth-induced hormone dilution can explain the dynamics of plant root cell elongation (Band et al, 2012).…”

Section: B Interaction Of Growth and Hormone Gradientsmentioning

confidence: 99%

Modelling Plant Hormone Gradients

Moore

Zhang

Lindsey

2015

Encyclopedia of Life Sciences

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Cellular patterning in the Arabidopsis root is coordinated via a localised auxin concentration maximum in the root tip, requiring the regulated expression of specific genes. The activities of plant hormones such as auxin, ethylene and cytokinin depend on cellular context and exhibit either synergistic or antagonistic interactions. Due to the complexity and nonlinearity of spatiotemporal interactions between both hormones and gene expression in root development, modelling plant hormone gradients requires a systems approach in which experimental data and modelling analysis are closely combined. Modelling therefore allows a predictive interrogation of highly complex and nonintuitive interactions between components in the system. Important factors to be considered when modelling hormone gradients include the construction of a hormonal crosstalk network, the formulation of kinetic equations and the construction of an in silico root map. A modelling approach enables the analysis of relationships between multiple hormone gradients, predictions on how hormone gradients emerge under the action of hormonal crosstalk, and the prediction and elucidation of experimental results from mutant roots. Key Concepts Patterning in Arabidopsis root development is coordinated via a localised auxin concentration maximum in the root tip, requiring the regulated expression of specific genes. The activities of plant hormones such as auxin, ethylene, cytokinin, abscisic acid, gibberellin and brassinosteroids depend on cellular context and exhibit either synergistic or antagonistic interactions. Auxin concentration and the associated regulatory and target genes are regulated by diverse interacting hormones and gene expression and therefore cannot change independently of the various crosstalk components in space and time. Other hormone concentrations, such as ethylene and cytokinin concentrations, and expression of the associated regulatory and target genes are also interlinked. Modelling plant hormone gradients requires a systems approach where experimental data and modelling analysis are closely combined. A hormonal crosstalk network describes the regulatory relationships between hormones and their associated genes. A kinetic equation can be formulated for any regulatory relationship following thermodynamic and kinetic principles. Construction of an in silico root map enables the study of multicellular cell–cell communications in Arabidopsis root development. Modelling hormone gradients enables the analysis of relationships between multiple hormone gradients, predictions on how hormone gradients emerge under the action of hormonal crosstalk, and the prediction and elucidation of experimental results from mutant roots. Modelling auxin gradients can also incorporate different mechanisms of polar auxin transport and the interaction of hormone gradients and root growth.

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Growth-induced hormone dilution can explain the dynamics of plant root cell elongation

Cited by 100 publications

References 40 publications

Mathematical Modelling Plant Signalling Networks

Mathematical Modelling Plant Signalling Networks

Gradients in Wall Mechanics and Polysaccharides along Growing Inflorescence Stems

Modelling Plant Hormone Gradients

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