3D imaging and mechanical modeling of helical buckling in
            <i>Medicago truncatula</i>
            plant roots

Silverberg, Jesse L.; Noar, Roslyn D.; Packer, Michael S.; Harrison, Maria J.; Henley, Christopher L.; Cohen, Itai; Gerbode, Sharon J.

doi:10.1073/pnas.1209287109

Cited by 75 publications

(66 citation statements)

References 26 publications

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“…When root tips encounter obstacles in soil, they avoid the obstacles by changing the direction of their growth (Monshausen and Gilroy, 2009b). Besides, the positive gravitropism and touch stimuli can affect many growth patterns of plant roots on the surface of agar, such as waving, skewing, helix and circumnutation (Chehab et al, 2009;Migliaccio et al, 2013;Okada and Shimura, 1990;Silverberg et al, 2012). Therefore, exploring the cellular and molecular basis of roots mechanoresponses is of great importance for fundamental plant biology and agricultural practice.…”

Section: Introductionmentioning

confidence: 99%

Mechanical touch responses of Arabidopsis TCH1-3 mutant roots on inclined hard-agar surface

Zha

Wang

Liu

et al. 2016

International Agrophysics

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A b s t r a c t. The gravity-induced mechanical touch stimulus can affect plant root architecture. Mechanical touch responses of plant roots are an important aspect of plant root growth and development. Previous studies have reported that Arabidopsis TCH1-3 genes are involved in mechano-related events, however, the physiological functions of TCH1-3 genes in Arabidopsis root mechanoresponses remain unclear. In the present study, we applied an inclined hard agar plate method to produce mechanical touch stimulus, and provided evidence that altered mechanical environment could influence root growth. Furthermore, tch1-3 Arabidopsis mutants were investigated on inclined agar surfaces to explore the functions of TCH1-3 genes on Arabidopsis root mechanoresponses. The results showed that two tch2 mutants, cml24-2 and cml24-4, exhibited significantly reduced root length, biased skewing, and decreased density of lateral root. In addition, primary root length and density of lateral root of tch3 (cml12-2) was significantly decreased on inclined agar surfaces. This study indicates that the tch2 and tch3 mutants are hypersensitive to mechanical touch stimulus, and TCH2 (CML24-2 and CML24-4) and TCH3 (CML12-2) genes may participate in the mechanical touch response of Arabidopsis roots.K e y w o r d s: mechanical touch stimulation, TCH1-3 genes, root growth, Arabidopsis

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Section: Introductionmentioning

confidence: 99%

Mechanical touch responses of Arabidopsis TCH1-3 mutant roots on inclined hard-agar surface

Zha

Wang

Liu

et al. 2016

International Agrophysics

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“…De Langre (2012) investigates plant response to wind loads. Silverberg et al (2012) present experimental and theoretical results on root buckling in plants. Latz et al (2008) and Kutschera & Niklas (2013) report cell "mechanosensing" in response to external stresses.…”

Section: Literature Reviewmentioning

confidence: 99%

Stress, Strain-Rate Analysis of Sub-Surface Driveway Plants

Greene

Greene²

2017

JPS

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Sub-surface driveway plants are strong enough to penetrate a macadam surface of thickness 7 -9 cm. The mechanics of how the Taraxacum officinale accomplishes this feat remain a mystery. Using the Maxwell model for pavement yielding over time, data are presented which may shed some light on this phenomenon. The post-buckling behavior of the plant stalk is quantified. Euler bending and buckling theory enables calculation of the cellular stress field, compared to turgor pressure, indicating impending cell buckling. Post-buckling plastic strain of the plant stem is 19%. At the cell wall, the stress concentration factor is 3-times greater than the applied external field, so the cell's internal turgor pressure is overwhelmed by imposed external stress. An Impulse Integral is developed for the surface whereby the product of applied FORCE times TIME is CONSTANT, in order to produce a given amount of surface deflection. Taraxacum officinale stems and leaf stalks are strong enough, in buckling mode, to lift and push apart the fractured macadam crater through which they erupt, but not strong enough to initially crack the surface. The purpose of this work is to determine the mechanisms underlying this unusual plant survival phenomenon, backed by quantified data.

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“…There are, on the other hand, functional-structural plant models [16] that describe plant growth and incorporate biological and environmental factors but do not account for the soil strength. Many experiments and observations at the grain scale have shown that grain configuration and local cracks or obstacles have crucial effect on root growth [17][18][19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Modeling root growth in granular soils: effects of root stiffness and packing fraction

et al. 2017

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Abstract. We use molecular dynamics simulations to investigate the effects of root bending stiffness and packing fraction on the path followed by a growing root in 2D packings of grains representing a soil. The root is modeled as a chain of elements that can grow in length and change their direction depending on the forces exerted by soil grains. We show that the root shape is mainly controlled by the bending stiffness of its apex. At low stiffness, the root randomly explores the pore space whereas at sufficiently high stiffness, of the order of soil hardness multiplied by mean grain size, the root follows a straight path across the soil. Between these two limits, the root shape can be characterized by the standard deviation of its re-directions at the scale of soil grains. We find that this shape parameter varies as a power-law function of the normalized bending stiffness.

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3D imaging and mechanical modeling of helical buckling in Medicago truncatula plant roots

Cited by 75 publications

References 26 publications

Mechanical touch responses of Arabidopsis TCH1-3 mutant roots on inclined hard-agar surface

Mechanical touch responses of Arabidopsis TCH1-3 mutant roots on inclined hard-agar surface

Stress, Strain-Rate Analysis of Sub-Surface Driveway Plants

Modeling root growth in granular soils: effects of root stiffness and packing fraction

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