Real-time conversion of tissue-scale mechanical forces into an interdigitated
                    growth pattern

Belteton, Samuel A.; Li, W.; Yanagisawa, Makoto; Afshar-Hatam, Faezeh; Quinn, Madeline I.; Szymanski, Margaret K.; Marley, Matthew W.; Turner, Joseph A.; Szymanski, Daniel B.

doi:10.1101/2021.02.06.428645

Cited by 8 publications

(33 citation statements)

References 55 publications

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“…Notably, PHGAPs preferentially accumulate in the anticlinal face on the indentation side, where they form stripes at the plasma membrane 7 . This localization pattern strikingly resembles that of the microtubules that populate the cortical anticlinal face in the indentation and then extend to the outer periclinal face of the cell (i.e., transfacial, Figure 1) 9 . Indeed, PHGAPs largely colocalize with microtubules and are dependent on microtubules for their association with the anticlinal face in the indentation region 7 .…”

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confidence: 66%

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Cell shape: A ROP regulatory tug-of-war in pavement cell morphogenesis

2022

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confidence: 66%

“…Transfacial microtubule bundles connect the indentation regions of pavement cells, which correspond to zones of predicted maximal tensile stresses 9,14 . This co-alignment of microtubules with mechanical stress patterns is dependent on the microtubule severing enzyme Katanin (KTN1) 14 , which is itself regulated by ROP6 15 .…”

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confidence: 92%

Cell shape: A ROP regulatory tug-of-war in pavement cell morphogenesis

2022

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“…The observed anticlinal wall alignment of microtubules is strongly correlated with the magnitude and direction of tensile forces in the wall predicted by finite element (FE) modeling (8).…”

Section: Introductionmentioning

confidence: 76%

“…Tensile force patterns in cell wall are sensitive to the geometry of the cell or tissue organization (25, 36, 48, 49). Therefore, we tested if stress patterns obtained from the validated FE model of a polarized plant cell (25) could bias the cellular scale organization of the microtubule array.…”

Section: Resultsmentioning

confidence: 99%

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Probing stress-regulated ordering of the plant cortical microtubule array via a computational approach

Szymanski

Kim

2022

Preprint

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Functional properties of cells, tissues, and organs rely on predictable growth outputs. A shape change in plant cells is determined by properties of a tough cell wall that deforms anisotropically in response to high turgor pressure. This morphogenesis requires tight coordination and feedback controls among cytoskeleton-dependent wall patterning, its material properties, and stresses in the wall. Cortical microtubules bias the mechanical anisotropy of cell wall by defining the trajectories of cellulose synthase motility as they polymerize bundled microfibrils in their wake. Cortical microtubules could locally align and orient relative to cell geometry; however, the means by this orientation occurs is not known. Correlations between the microtubule orientation, cell geometry, and predicted tensile forces are strongly established, and here we simulate how different attributes of tensile force can orient and pattern the microtubule array in the cortex. We implemented a discrete model with three-state transient microtubule behaviors influenced by local mechanical stress in order to probe the mechanisms of stress-dependent patterning. We varied the sensitivity of four types of dynamic behaviors observed on the plus ends of microtubules - growth, shrinkage, catastrophe, and rescue - to local stress and then evaluated the extent and rate of microtubule alignments in a square computational domain. We optimized constitutive relationships between local stress and the plus-end dynamics and employed a biomechanically well-characterized cell wall to analyze how stress can influence the density and orientation of microtubule arrays. Our multiscale modeling approaches predict that spatial variability in stress magnitude and anisotropy mediate mechanical feedback between the wall and organization of the cortical microtubule array.

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A theoretical framework for the ecological role of three‐dimensional structural diversity

LaRue

Fahey

Alveshere

et al. 2023

Frontiers in Ecol & Environ

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The three-dimensional (3D) physical aspects of ecosystems are intrinsically linked to ecological processes. Here, we describe structural diversity as the volumetric capacity, physical arrangement, and identity/traits of biotic components in an ecosystem. Despite being recognized in earlier ecological studies, structural diversity has been largely overlooked due to an absence of not only a theoretical foundation but also effective measurement tools. We present a framework for conceptualizing structural diversity and suggest how to facilitate its broader incorporation into ecological theory and practice. We also discuss how the interplay of genetic and environmental factors underpin structural diversity, allowing for a potentially unique synthetic approach to explain ecosystem function. A practical approach is then proposed in which scientists can test the ecological role of structural diversity at biotic-environmental interfaces, along with examples of structural diversity research and future directions for integrating structural diversity into ecological theory and management across scales.

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Real-time conversion of tissue-scale mechanical forces into an interdigitated growth pattern

Cited by 8 publications

References 55 publications

Cell shape: A ROP regulatory tug-of-war in pavement cell morphogenesis

Cell shape: A ROP regulatory tug-of-war in pavement cell morphogenesis

Probing stress-regulated ordering of the plant cortical microtubule array via a computational approach

A theoretical framework for the ecological role of three‐dimensional structural diversity

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