Topological analysis of multicellular complexity in the plant hypocotyl

Jackson, Matthew D. B.; Xu, Hao; Duran-Nebreda, Salva; Stamm, Petra; Bassel, George W.

doi:10.7554/elife.26023

Cited by 39 publications

(43 citation statements)

References 55 publications

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“…Nevertheless, another recent study supports the cell type-specific functions in Arabidopsis hypocotyls. Trichoblasts form hair-like structures and acquire nutrients from the external environment, while the neighboring atrichoblasts provide shortcut routes for these nutrients to be unloaded and moved up the stem (Jackson et al, 2017).…”

Section: The Hypocotylmentioning

confidence: 99%

Seedling Establishment: A Dimmer Switch-Regulated Process between Dark and Light Signaling

2017

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Section: The Hypocotylmentioning

confidence: 99%

Seedling Establishment: A Dimmer Switch-Regulated Process between Dark and Light Signaling

2017

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“…Studies on plant symplastic transport are now becoming multi‐disciplinary, promoting collaboration between biologists, engineers and computer modellers (Jackson et al ., ). Current work on both short and long distance symplastic transport in plants in relation to plant–plant, plant–microbe, and plant–environment interactions highlights the usefulness of molecular tools such as the over‐active, PD‐located callose synthase icals3m (Vatén et al ., ) and calcium biosensors (Nakai et al ., ) in root and shoot cellular patterning and signalling.…”

Section: Resultsmentioning

confidence: 97%

Peeking at a plant through the holes in the wall – exploring the roles of plasmodesmata

Danila

Cho

et al. 2018

New Phytologist

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Plasmodesmata (PD) are membrane-lined pores that connect neighbouring plant cells and allow molecular exchange via the symplast. Past studies have revealed the basic structure of PD, some of the transport mechanisms for molecules through PD, and a variety of physiological processes in which they function. Recently, with the help of newly developed technologies, several exciting new features of PD have been revealed. New PD structures were observed during early formation of PD and between phloem sieve elements and phloem pole pericycle cells in roots. Both observations challenge our current understanding of PD structure and function. Research into novel physiological responses, which are regulated by PD, indicates that we have not yet fully explored the potential contribution of PD to overall plant function. In this Viewpoint article, we summarize some of the recent advances in understanding the structure and function of PD and propose the challenges ahead for the community.

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“…Lattices were used to represent immobilized cells within tissues, as observed in spatially constrained organs, with typically homogeneous connectomes [36]. The premise is that vasculature formation is equivalent to the strings of cells being fused into a single node, which reduces network distances within the graph [6,37], and that only contiguous cells can be fused together in this process. This process would be analogous to the formation of a cavity in animal vascular systems, where solutes and cells in suspension can move freely inside vascular vessels.…”

Section: A General Model To Simulate Vascular Development In Cell Conmentioning

confidence: 99%

Efficient vasculature investment in tissues can be determined without global information

Duran-Nebreda

Johnston

Bassel

2020

J. R. Soc. Interface.

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Cells are the fundamental building blocks of organs and tissues. Information and mass flow through cellular contacts in these structures is vital for the orchestration of organ function. Constraints imposed by packing and cell immobility limit intercellular communication, particularly as organs and organisms scale up to greater sizes. In order to transcend transport limitations, delivery systems including vascular and respiratory systems evolved to facilitate the movement of matter and information. The construction of these delivery systems has an associated cost, as vascular elements do not perform the metabolic functions of the organs they are part of. This study investigates a fundamental trade-off in vascularization in multicellular tissues: the reduction of path lengths for communication versus the cost associated with producing vasculature. Biologically realistic generative models, using multicellular templates of different dimensionalities, revealed a limited advantage to the vascularization of two-dimensional tissues. Strikingly, scale-free improvements in transport efficiency can be achieved even in the absence of global knowledge of tissue organization. A point of diminishing returns in the investment of additional vascular tissue to the increased reduction of path length in 2.5- and three-dimensional tissues was identified. Applying this theory to experimentally determined biological tissue structures, we show the possibility of a co-dependency between the method used to limit path length and the organization of cells it acts upon. These results provide insight as to why tissues are or are not vascularized in nature, the robustness of developmental generative mechanisms and the extent to which vasculature is advantageous in the support of organ function.

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Topological analysis of multicellular complexity in the plant hypocotyl

Cited by 39 publications

References 55 publications

Seedling Establishment: A Dimmer Switch-Regulated Process between Dark and Light Signaling

Seedling Establishment: A Dimmer Switch-Regulated Process between Dark and Light Signaling

Peeking at a plant through the holes in the wall – exploring the roles of plasmodesmata

Efficient vasculature investment in tissues can be determined without global information

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