Spatial pattern of long-distance symplasmic transport and communication in trees

Symplasmic short- and long-distance communication may be regulated at different levels of plant body organization. It depends on cell-to-cell transport modulated by plasmodesmata conductivity and frequency but above all on morphogenetic fields that integrate a plant at the supracellular level. Their...

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Veröffentlicht in:	Plant signaling & behavior 2013-11, Vol.8 (11), p.e26191-e26191
Hauptverfasser:	Sokołowska, Katarzyna, Brysz, Alicja Maria, Zagórska-Marek, Beata
Format:	Artikel
Sprache:	eng
Schlagworte:	Acer - metabolism Biological Transport branches callose cambium Cambium - cytology Cambium - metabolism Fluoresceins - metabolism fluorescence Glucans - metabolism plasmodesmata Short Communication Signal Transduction stem cells trees Trees - metabolism Xylem - cytology Xylem - metabolism
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container_title	Plant signaling & behavior
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creator	Sokołowska, Katarzyna Brysz, Alicja Maria Zagórska-Marek, Beata
description	Symplasmic short- and long-distance communication may be regulated at different levels of plant body organization. It depends on cell-to-cell transport modulated by plasmodesmata conductivity and frequency but above all on morphogenetic fields that integrate a plant at the supracellular level. Their control of physiological and developmental processes is especially important in trees, where the continuum consists of 3-dimensional systems of: 1) stem cells in cambium, and 2) living parenchyma cells in the secondary conductive tissues. We found that long-distance symplasmic transport in trees is spatially regulated. Uneven distribution of fluorescent tracer in cambial cells along the branches examined illustrates an unknown intrinsic phenomenon that can possibly be important for plant organism integration. Here we illustrate the spatial dynamics of symplasmic transport in cambium, test and exclude the role of callose in its regulation, and discuss the mechanism that could possibly be responsible for the maintenance of this spatial pattern.
doi_str_mv	10.4161/psb.26191
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subjects	Acer - metabolism Biological Transport branches callose cambium Cambium - cytology Cambium - metabolism Fluoresceins - metabolism fluorescence Glucans - metabolism plasmodesmata Short Communication Signal Transduction stem cells trees Trees - metabolism Xylem - cytology Xylem - metabolism
title	Spatial pattern of long-distance symplasmic transport and communication in trees
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