Dehydration‐induced expression of a 31‐kDa dehydrin in <i>Polypodium polypodioides</i> (Polypodiaceae) may enable large, reversible deformation of cell walls

Layton, Bradley E.; Boyd, M. Brent; Tripepi, Manuela; Bitonti, Beatrice M.; Dollahon, M. Norman R.; Balsamo, Ronald A.

doi:10.3732/ajb.0900285

Cited by 45 publications

(27 citation statements)

References 58 publications

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“…During desiccation, leaves and pinnae fold upward, since the adaxial side underwent negative strain to a greater extent than the abaxial side, resulting in the pinnae becoming highly concave (Layton et al 2010). Leaf folding has been reported in other resurrection plants such as the angiosperms Harberlea rhodopensis (Georgieva et al 2010), and Myrothamnus flabellifolius (Moore et al 2006) and the fern Polypodium polypodioides (Layton et al 2010), among others (Rascio & La Rocca 2005).…”

Section: Discussionmentioning

confidence: 98%

“…Resurrection plants use two different approaches to minimize this stress: 1) water replacement, where cells maintain their original volume and became packed with vacuoles filled with non-aqueous matter and 2) reduction in cellular volume by extensive cell wall folding, which should reduce tensions on structures enclosed by the wall (Willigen et al 2004). The mechanisms by which the cell walls of desiccation tolerant species manage to withstand the strain caused by massive loss of cellular water (and volume) and changes in mechanical properties of wet versus dry cell walls remain unresolved (Moore et al 2006, Layton et al 2010.…”

Section: Introductionmentioning

confidence: 99%

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Reversible in vivo cellular changes occur during desiccation and recovery: Desiccation tolerance of the resurrection filmy fern Hymenophyllum dentatum Cav.

Bravo

Parra²,

Castillo³

et al. 2016

Gayana Bot.

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Reversible in vivo cellular changes occur during desiccation and recovery: Desiccation tolerance of the resurrection filmy fern Hymenophyllum dentatum Cav.Cambios celulares reversibles observados in vivo durante la desecación y recuperación: Tolerancia a la desecación del helecho película de resurrección Hymenophyllum dentatum Cav. SORAYA ABSTRACTThe present work explores in vivo physiological, morphological and chemical features during full hydration, desiccation and rehydration of the filmy fern Hymenophyllum dentatum with two main objectives: 1) to get further insight about the mechanisms underlying its desiccation tolerance, and 2) to understand how this plant manages mechanical stress induced by water loss and recovery. With these purposes, physiological (relative water content and F v /F m chlorophyll fluorescence parameter), morphological (Confocal Laser Scanning Microscopy and 3D reconstruction) and chemical (FT-IR microspectroscopy) data were obtained and compared between fully hydrated, desiccated and rehydrated tissues of H. dentatum. Remarkable changes in cell architecture and chemical composition were observed in vivo in desiccated leaves. Cells were smaller, showed a collapsed general appearance, and were delimitated by apparently folded cell walls. Marked changes in chloroplasts location and decrease in the number of active chloroplasts were also evidenced. Chemical experiments showed that changes in the secondary structure of proteins and in the polysaccharide composition of the cell wall occur in desiccated cells. All changes were rapidly reversed upon rehydration. This study shows that H. dentatum presents an extreme case of desiccation tolerance, able to withdraw severe, rapid and consecutive dehydration/rehydration induced stress by the function of constitutive systems of protection and reparation, in which cell wall folding plays a relevant role as a protective system against mechanical and oxidative stress. Besides, H. dentatum is proposed as an excellent plant model for the study of dissection tolerance such as one cell layer fern, auto-fluorescence of cellular compartments, and simple long term storage under laboratory conditions, among others. KEYWORDS:Hymenophyllum, desiccation tolerance, confocal 3D microscopy, FT-IR microspectroscopy, rapid dehydration /rehydration. RESUMENEl presente trabajo muestra una exploración in vivo de los rasgos fisiológicos, morfológicos y químicos que caracterizan a los estados de hidratación completa, desecación y rehidratación del helecho película Hymenophyllum dentatum, que persigue 2 objetivos principales: 1) Adquirir conocimientos sobre los mecanismos que subyacen a la tolerancia a la desecación, y 2) entender cómo estas plantas manejan el estrés mecánico inducido por la pérdida y recuperación de agua. Con estos propósitos se obtuvo datos fisiológicos (contenido relativo de agua y parámetro de fluorescencia de clorofila Fv/Fm), ISSN 0016-5301 Gayana Bot. 73(2): [402][403][404][405][406][407][408][409][410][411][412][413] 2016 403In vivo cellular ch...

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Section: Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Reversible in vivo cellular changes occur during desiccation and recovery: Desiccation tolerance of the resurrection filmy fern Hymenophyllum dentatum Cav.

Bravo

Parra²,

Castillo³

et al. 2016

Gayana Bot.

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“…The highly hydrophilic pectin can attract and sequester water and may behave as a lubricant between individual CW layers and thus avoid the CW collapse and damage from water loss. In addition, the hydrophilic protein dehydrin, which is supposed to be localized in the CW, may also play a role similar to pectin in preventing the CW from water deficit-caused mechanical fracture (Layton et al 2010), maintaining the elastic extension (reversible stretching) properties and, consequently, the porosity of the CW. Also, CW structural proteins such as the hydroxyproline-rich Yang et al (2010Yang et al ( , 2011c glycoprotein extensin, can cross-link with other polymers in the CW and thus affect CW porosity (Brett and Waldron 1996).…”

Section: Cell-wall Porositymentioning

confidence: 99%

Interaction of aluminium and drought stress on root growth and crop yield on acid soils

2013

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Background Aluminium (Al) toxicity and drought stress are two major constraints for crop production in the world, particularly in the tropics. The variation in rainfall distribution and longer dry spells in much of the tropics during the main growing period of crops are becoming increasingly important yield-limiting factors with the global climate change. As a result, crop genotypes that are tolerant of both drought and Al toxicity need to be developed. Scope The present review mainly focuses on the interaction of Al and drought on root development, crop growth and yield on acid soils. It summarizes evidence from our own studies and other published/related work, and provides novel insights into the breeding for the adaptation to these combined abiotic stresses. The primary symptom of Al phytotoxicity is the inhibition of root growth. The impeded root system will restrict the roots for exploring the acid subsoil to absorb water and nutrients which is particularly important under condition of low soil moisture in the surface soil under drought. Whereas drought primarily affects shoot growth, effects of phytotoxic Al on shoot growth are mostly secondary effects that are induced by Al affecting root growth and function, while under drought stress root growth may even be promoted. Much progress has recently been made in the understanding of the physiology and molecular biology of the interaction between Al toxicity and drought stress in common bean (Phaseolus vulgaris L.) in hydroponics and in an Al-toxic soil. Conclusions Crops growing on acid soils yield less than their potential because of the poorly developed root system that limits nutrient and water uptake. Breeding for drought resistance must be combined with Al resistance, to assure that drought resistance is expressed adequately in crops grown on soils with acid Al-toxic subsoils.

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“…However, it has been possible, based on homology inferences, to define four broad categories of C. plantagineum genes induced by dehydration: protective proteins including such as hydrophilins, regulatory proteins and RNA, carbohydrate metabolism enzymes, and proteins involved in water transport (Bartels 2005). Other insights have come from naturally occurring desiccation tolerant plants, recently a 31-kDa putative dehydrin polypeptide was discovered in the desiccation-tolerant fern Polypodium polypodioide, found to be localized at the cell walls and present only during drying (Layton et al 2010). The protein rapidly dissipated upon tissue rehydration, along with changing the hydrophilicity of leaf surfaces and enabling reversible cell wall deformation.…”

Section: Droughtmentioning

confidence: 99%

Plant Abiotic Stress: Insights from the Genomics Era

Rowley¹,

Mockler²

2011

Abiotic Stress Response in Plants - Physiological, Biochemical and Genetic Perspectives

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Dehydration‐induced expression of a 31‐kDa dehydrin in Polypodium polypodioides (Polypodiaceae) may enable large, reversible deformation of cell walls

Cited by 45 publications

References 58 publications

Reversible in vivo cellular changes occur during desiccation and recovery: Desiccation tolerance of the resurrection filmy fern Hymenophyllum dentatum Cav.

Reversible in vivo cellular changes occur during desiccation and recovery: Desiccation tolerance of the resurrection filmy fern Hymenophyllum dentatum Cav.

Interaction of aluminium and drought stress on root growth and crop yield on acid soils

Plant Abiotic Stress: Insights from the Genomics Era

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