Emerging Roots Alter Epidermal Cell Fate through Mechanical and Reactive Oxygen Species Signaling

Steffens, Bianka; Kovalev, Alexander; Gorb, Stanislav N.; Sauter, Margret

doi:10.1105/tpc.112.101790

Cited by 153 publications

(145 citation statements)

References 47 publications

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“…Much is unknown about the perception of stimuli that are mechanical in nature, such as touch, gravity, and membrane stretch (i.e., mechanotransduction), though it is clear that these types of signals are important regulators of growth and development in bacteria, plants, and animals (Nakayama et al, 2012;Steffens et al, 2012;Lai et al, 2013;Mousavi et al, 2013;Yan et al, 2013). A particularly well-studied molecular mechanism for the perception and transduction of mechanical signals is provided by mechanosensitive (MS) ion channels, channels that open directly or indirectly in response to membrane tension (Arnadóttir and Chalfie, 2010;Kung et al, 2010;Sukharev and Sachs, 2012).…”

Section: Introductionmentioning

confidence: 99%

Arabidopsis MSL10 Has a Regulated Cell Death Signaling Activity That Is Separable from Its Mechanosensitive Ion Channel Activity

et al. 2014

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Members of the MscS superfamily of mechanosensitive ion channels function as osmotic safety valves, releasing osmolytes under increased membrane tension. MscS homologs exhibit diverse topology and domain structure, and it has been proposed that the more complex members of the family might have novel regulatory mechanisms or molecular functions. Here, we present a study of MscS-Like (MSL)10 from Arabidopsis thaliana that supports these ideas. High-level expression of MSL10-GFP in Arabidopsis induced small stature, hydrogen peroxide accumulation, ectopic cell death, and reactive oxygen species-and cell death-associated gene expression. Phosphomimetic mutations in the MSL10 N-terminal domain prevented these phenotypes. The phosphorylation state of MSL10 also regulated its ability to induce cell death when transiently expressed in Nicotiana benthamiana leaves but did not affect subcellular localization, assembly, or channel behavior. Finally, the N-terminal domain of MSL10 was sufficient to induce cell death in tobacco, independent of phosphorylation state. We conclude that the plant-specific N-terminal domain of MSL10 is capable of inducing cell death, this activity is regulated by phosphorylation, and MSL10 has two separable activities-one as an ion channel and one as an inducer of cell death. These findings further our understanding of the evolution and significance of mechanosensitive ion channels.

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Section: Introductionmentioning

confidence: 99%

Arabidopsis MSL10 Has a Regulated Cell Death Signaling Activity That Is Separable from Its Mechanosensitive Ion Channel Activity

et al. 2014

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“…Adventitious roots can form via de novo meristem initiation or the emergence of preexisting root primordia. In the case of adventitious root emergence at lower stem internodes of flooded rice, the process involves signal transduction within the growing root and the overlying epidermal cells Sauter, 2009, 2010;Steffens et al, 2012). It was shown that in the adventitious root primordium, ethylene-and ROS-dependent signaling orchestrated the promotion of growth by signaling via mechanical force to the overlying epidermal cells.…”

Section: Morphological and Anatomical Adaptations That Increase Floodmentioning

confidence: 99%

Waterproofing Crops: Effective Flooding Survival Strategies

2012

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“…Although microarray studies revealed that the epidermal cells overlaying root primordia have a very distinct cellular identity (Steffens and Sauter, 2009), the precise signal that caused only these specific cells to die remained unknown. It is now clear that this trigger is the mechanical stimulus provided by the underlying root primordia when they start growing (Steffens et al, 2012). The growing ARs exert a mechanical force on the epidermal cells overlying them in a process that also requires ethylene-mediated ROS formation (Fig.…”

Section: Ethylene-mediated Flooding-adaptive Traitsmentioning

confidence: 99%

Ethylene-Mediated Acclimations to Flooding Stress

2015

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Flooding is detrimental for plants, primarily because of restricted gas exchange underwater, which leads to an energy and carbohydrate deficit. Impeded gas exchange also causes rapid accumulation of the volatile ethylene in all flooded plant cells. Although several internal changes in the plant can signal the flooded status, it is the pervasive and rapid accumulation of ethylene that makes it an early and reliable flooding signal. Not surprisingly, it is a major regulator of several flood-adaptive plant traits. Here, we discuss these major ethylene-mediated traits, their functional relevance, and the recent progress in identifying the molecular and signaling events underlying these traits downstream of ethylene. We also speculate on the role of ethylene in postsubmergence recovery and identify several questions for future investigations.

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Emerging Roots Alter Epidermal Cell Fate through Mechanical and Reactive Oxygen Species Signaling

Cited by 153 publications

References 47 publications

Arabidopsis MSL10 Has a Regulated Cell Death Signaling Activity That Is Separable from Its Mechanosensitive Ion Channel Activity

Arabidopsis MSL10 Has a Regulated Cell Death Signaling Activity That Is Separable from Its Mechanosensitive Ion Channel Activity

Waterproofing Crops: Effective Flooding Survival Strategies

Ethylene-Mediated Acclimations to Flooding Stress

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