Simulating Turgor-Induced Stress Patterns in Multilayered Plant Tissues

Ali, Olivier; Oliveri, Hadrien; Traas, Jan; Godin, Christophe

doi:10.1007/s11538-019-00622-z

Cited by 6 publications

(7 citation statements)

References 49 publications

(60 reference statements)

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“…Considering known estimates of the thickness of the Arabidopsis SAM outer cell wall, the authors estimated a stiffness ratio of outer to inner walls to be in the range of 3–10:1. Given these ratios, simulations demonstrate that the periclinal stress patterns (i.e., parallel to the tissue surface) in the outer walls of multilayered SAM models resemble those produced by shell models, thus validating earlier approaches ( Ali et al, 2019 ). A second important conclusion from this work is that maximal stress patterns in the anticlinal walls (i.e., perpendicular to the tissue surface) of both the epidermis and underlying cell layers are predominantly oriented anticlinally ( Ali et al, 2019 ), again matching observed microtubule and cellulose orientations ( Sakaguchi et al, 1988 ; Figure 1B ).…”

Section: A Mechanical Stress Cellulose Fibril Feedback Loop Patterns Plant Morphogenesissupporting

confidence: 77%

“…Given these ratios, simulations demonstrate that the periclinal stress patterns (i.e., parallel to the tissue surface) in the outer walls of multilayered SAM models resemble those produced by shell models, thus validating earlier approaches ( Ali et al, 2019 ). A second important conclusion from this work is that maximal stress patterns in the anticlinal walls (i.e., perpendicular to the tissue surface) of both the epidermis and underlying cell layers are predominantly oriented anticlinally ( Ali et al, 2019 ), again matching observed microtubule and cellulose orientations ( Sakaguchi et al, 1988 ; Figure 1B ). This a priori indicates that loosening the walls of subepidermal cells or randomizing cellulose orientations may result in anticlinal cellular growth, which would account for the initial outward bulge associated with lateral organ formation (see further discussion on auxin’s influence on microtubules see below).…”

Section: A Mechanical Stress Cellulose Fibril Feedback Loop Patterns Plant Morphogenesissupporting

confidence: 77%

“…Apart from finding that the stress/cell wall feedback loop operates in additional tissue contexts ( Sampathkumar et al, 2014 ; Hervieux et al, 2017 ; Belteton et al, 2021 ), an important recent advance has been in developing mechanical models to simulate more complex tissue structures. Rather than assuming pressurized shells, multilayered tissue models have been constructed and compared to simpler models ( Ali et al, 2019 ). Perhaps the most important conclusion from this work has been that the degree to which multilayered models generate similar surface stress patterns to those of shell models depends on the relative stiffness of inner cell layer walls compared to the outer epidermal cell layer walls.…”

Section: A Mechanical Stress Cellulose Fibril Feedback Loop Patterns Plant Morphogenesismentioning

confidence: 99%

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Integration of Core Mechanisms Underlying Plant Aerial Architecture

Heisler

2021

Front. Plant Sci.

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Over the last decade or so important progress has been made in identifying and understanding a set of patterning mechanisms that have the potential to explain many aspects of plant morphology. These include the feedback loop between mechanical stresses and interphase microtubules, the regulation of plant cell polarity and the role of adaxial and abaxial cell type boundaries. What is perhaps most intriguing is how these mechanisms integrate in a combinatorial manner that provides a means to generate a large variety of commonly seen plant morphologies. Here, I review our current understanding of these mechanisms and discuss the links between them.

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Section: A Mechanical Stress Cellulose Fibril Feedback Loop Patterns Plant Morphogenesissupporting

confidence: 77%

Section: A Mechanical Stress Cellulose Fibril Feedback Loop Patterns Plant Morphogenesissupporting

confidence: 77%

Section: A Mechanical Stress Cellulose Fibril Feedback Loop Patterns Plant Morphogenesismentioning

confidence: 99%

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Integration of Core Mechanisms Underlying Plant Aerial Architecture

Heisler

2021

Front. Plant Sci.

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“…2011; Hervieux et al, 2017;Fox et al, 2018;Ali et al, 2019). Abstraction of cellular-scale FEM to a continuous sheet of material with defined cell scale information is also used to discretize tissuelevel details for simulation purposes (Bozorg et al, 2014;Hervieux et al, 2017;Kennaway and Coen, 2019).…”

Section: Box 3 Finite Element Modelsmentioning

confidence: 99%

Mechanical feedback-loop regulation of morphogenesis in plants

Sampathkumar

2020

Development

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Morphogenesis is a highly controlled biological process that is crucial for organisms to develop cells and organs of a particular shape. Plants have the remarkable ability to adapt to changing environmental conditions, despite being sessile organisms with their cells affixed to each other by their cell wall. It is therefore evident that morphogenesis in plants requires the existence of robust sensing machineries at different scales. In this Review, I provide an overview on how mechanical forces are generated, sensed and transduced in plant cells. I then focus on how such forces regulate growth and form of plant cells and tissues.

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“…However, at the cellular scale, plant mechanobiology is affected by physical connections to neighboring cells. Wall-to-wall adhesion adds external forces and responses that complicate mechanical characterization of any one cell 5,6 . Here, we employ pollen grains as a neighbor-less model system for biomechanical characterization of plant cells.…”

Section: Introductionmentioning

confidence: 99%

In vitro experiments and kinetic models of pollen hydration show that MSL8 is not a simple tension-gated osmoregulator

Miller

Strychalski

Nickaeen

et al. 2021

Preprint

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SummaryPollen, a neighbor-less cell that contains the male gametes, undergoes multiple mechanical challenges during plant sexual reproduction, including desiccation and rehydration. It was previously showed that the pollen-specific mechanosensitive ion channel MscS-Like (MSL)8 is essential for pollen survival during hydration and proposed that it functions as a tension-gated osmoregulator. Here we test this hypothesis with a combination of mathematical modeling and laboratory experiments. Time-lapse imaging revealed that wild-type pollen grains swell and then stabilize in volume rapidly during hydration. msl8 mutant pollen grains, however, continue to expand and eventually burst. We found that a mathematical model wherein MSL8 acts as a simple tension-gated osmoregulator does not replicate this behavior. A better fit was obtained from variations of the model wherein MSL8 inactivation is independent of its membrane tension gating threshold or MSL8 strengthens the cell wall without osmotic regulation. Experimental and computational testing of several perturbations, including hydration in an osmolyte-rich solution, hyper-desiccation of the grains, and MSL8-YFP overexpression, indicated that the Cell Wall Strengthening Model best simulated experimental responses. Finally, expression of a non-conducting MSL8 variant did not complement the msl8 overexpansion phenotype. These data indicate that, contrary to our hypothesis and to known MS ion channel function in single-cell systems, MSL8 does not act as a simple membrane tension-gated osmoregulator. Instead, they support a model wherein ion flux through MSL8 is required to alter pollen cell wall properties. These results demonstrate the utility of pollen as a cellular-scale model system and illustrate how mathematical models can correct intuitive hypotheses.

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Simulating Turgor-Induced Stress Patterns in Multilayered Plant Tissues

Cited by 6 publications

References 49 publications

Integration of Core Mechanisms Underlying Plant Aerial Architecture

Integration of Core Mechanisms Underlying Plant Aerial Architecture

Mechanical feedback-loop regulation of morphogenesis in plants

In vitro experiments and kinetic models of pollen hydration show that MSL8 is not a simple tension-gated osmoregulator

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