Externally imposed electric field enhances plant root tip regeneration

In plants, shoot and root regeneration can be induced in the distinctive conditions of tissue culture (in vitro) but is also observed in intact individuals (in planta) recovering from tissue damage. Roots, for example, can regenerate their fully excised meristems in planta, even in mutants with impa...

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Veröffentlicht in:	Regeneration 2016-06, Vol.3 (3), p.156-167
Hauptverfasser:	Kral, Nicolas, Hanna Ougolnikova, Alexandra, Sena, Giovanni
Format:	Artikel
Sprache:	eng
Schlagworte:	Arabidopsis Cell division Electric fields Plant regeneration plant root
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container_title	Regeneration
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creator	Kral, Nicolas Hanna Ougolnikova, Alexandra Sena, Giovanni
description	In plants, shoot and root regeneration can be induced in the distinctive conditions of tissue culture (in vitro) but is also observed in intact individuals (in planta) recovering from tissue damage. Roots, for example, can regenerate their fully excised meristems in planta, even in mutants with impaired apical stem cell niches. Unfortunately, to date a comprehensive understanding of regeneration in plants is still missing. Here, we provide evidence that an imposed electric field can perturb apical root regeneration in Arabidopsis. Crucially, we explored both spatial and temporal competences of the stump to respond to electrical stimulation, by varying respectively the position of the cut and the time interval between excision and stimulation. Our data indicate that a brief pulse of an electric field parallel to the root is sufficient to increase by up to two‐fold the probability of its regeneration, and to perturb the local distribution of the hormone auxin, as well as cell division regulation. Remarkably, the orientation of the root towards the anode or the cathode is shown to play a role.
doi_str_mv	10.1002/reg2.59
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subjects	Arabidopsis Cell division Electric fields Plant regeneration plant root
title	Externally imposed electric field enhances plant root tip regeneration
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