Abstract:Experience and memory of environmental stimuli that indicate future stress can prepare (prime) organismic stress responses even in species lacking a nervous system. The process through which such organisms prepare their phenotype for an improved response to future stress has been termed 'priming'. However, other terms are also used for this phenomenon, especially when considering priming in different types of organisms and when referring to different stressors. Here we propose a conceptual framework for primin… Show more
“…1). Consistent with the definition of priming74 and with the previous hypothesis that priming acts independently from cold acclimation and is of importance in nature in spring10, the cold pretreatment resulted in higher Φ PS-II in the intermediate cold-adapted accessions WS, Col-0 and Van-0 than in the most cold-adapted accessions N13, Ms-0 and Kas-1 (Fig. 4).…”
Priming improves an organism's performance upon a future stress. To test whether cold priming supports protection in spring and how it is affected by cold acclimation, we compared seven Arabidopsis accessions with different cold acclimation potentials in the field and in the greenhouse for growth, photosynthetic performance and reproductive fitness in March and May after a 14 day long cold-pretreatment at 4 °C. In the plants transferred to the field in May, the effect of the cold pretreatment on the seed yield correlated with the cold acclimation potential of the accessions. In the March transferred plants, the reproductive fitness was most supported by the cold pretreatment in the accessions with the weakest cold acclimation potential. The fitness effect was linked to long-term effects of the cold pretreatment on photosystem II activity stabilization and leaf blade expansion. The study demonstrated that cold priming stronger impacts on plant fitness than cold acclimation in spring in accessions with intermediate and low cold acclimation potential.
“…1). Consistent with the definition of priming74 and with the previous hypothesis that priming acts independently from cold acclimation and is of importance in nature in spring10, the cold pretreatment resulted in higher Φ PS-II in the intermediate cold-adapted accessions WS, Col-0 and Van-0 than in the most cold-adapted accessions N13, Ms-0 and Kas-1 (Fig. 4).…”
Priming improves an organism's performance upon a future stress. To test whether cold priming supports protection in spring and how it is affected by cold acclimation, we compared seven Arabidopsis accessions with different cold acclimation potentials in the field and in the greenhouse for growth, photosynthetic performance and reproductive fitness in March and May after a 14 day long cold-pretreatment at 4 °C. In the plants transferred to the field in May, the effect of the cold pretreatment on the seed yield correlated with the cold acclimation potential of the accessions. In the March transferred plants, the reproductive fitness was most supported by the cold pretreatment in the accessions with the weakest cold acclimation potential. The fitness effect was linked to long-term effects of the cold pretreatment on photosystem II activity stabilization and leaf blade expansion. The study demonstrated that cold priming stronger impacts on plant fitness than cold acclimation in spring in accessions with intermediate and low cold acclimation potential.
“…Such conditions may be caused, for example, by extreme temperatures, too little or too much water (drought or flooding, respectively), or pathogen and herbivore attack. Priming of organismal responses to stress describes the phenomenon by which a temporally limited environmental stimulus (a ‘priming stress cue’) modifies a plant for future stress exposure (a ‘triggering stress cue’) [5, 6]. The term priming was originally coined in the context of immunity against pathogens (biotic stress), but was later also applied to responses to abiotic environmental conditions.…”
Section: Priming and Stress Memorymentioning
confidence: 99%
“…1). Priming acts at the phenotypic level and does not introduce changes in DNA sequence and is thus reversible eventually [5, 6]. Generally, such priming is evidenced by a stronger or faster response pattern, as can be exemplified by the modified activation kinetics of defense gene expression.Fig.…”
Plants frequently have to weather both biotic and abiotic stressors, and have evolved sophisticated adaptation and defense mechanisms. In recent years, chromatin modifications, nucleosome positioning, and DNA methylation have been recognized as important components in these adaptations. Given their potential epigenetic nature, such modifications may provide a mechanistic basis for a stress memory, enabling plants to respond more efficiently to recurring stress or even to prepare their offspring for potential future assaults. In this review, we discuss both the involvement of chromatin in stress responses and the current evidence on somatic, intergenerational, and transgenerational stress memory.
“…This ability is relayed by various intricate intercellular and intracellular mechanisms, including hormone signaling and organelle-nuclear retrograde pathways that allow plants to perceive and respond to biotic and abiotic stresses (Karpinski et al, 1999;Fernández and Strand, 2008;Cutler et al, 2010;Goodger and Schachtman, 2010;Chan et al, 2016;Martín et al, 2016). Additionally, repeated exposure to stress can lead to plant stress priming, whereby prior stress exposure conveys an enhanced ability to respond to future events (Conrath et al, 2006;Ding et al, 2012;Gordon et al, 2013;Sani et al, 2013;Wang et al, 2014;Virlouvet and Fromm, 2015;Hilker et al, 2016;Wibowo et al, 2016). This notion has been extended to numerous considerations of the formation of plant stress memory, in which a state of altered stress responsivity is mitotically or meiotically transmissible (Bruce et al, 2007;Hauser et al, 2011b;Probst and Mittelsten Scheid, 2015;Crisp et al, 2016;van Loon, 2016).…”
Improving the responsiveness, acclimation, and memory of plants to abiotic stress holds substantive potential for improving agriculture. An unresolved question is the involvement of chromatin marks in the memory of agriculturally relevant stresses. Such potential has spurred numerous investigations yielding both promising and conflicting results. Consequently, it remains unclear to what extent robust stress-induced DNA methylation variation can underpin stress memory. Using a slow-onset water deprivation treatment in Arabidopsis (Arabidopsis thaliana), we investigated the malleability of the DNA methylome to drought stress within a generation and under repeated drought stress over five successive generations. While drought-associated epialleles in the methylome were detected within a generation, they did not correlate with drought-responsive gene expression. Six traits were analyzed for transgenerational stress memory, and the descendants of drought-stressed lineages showed one case of memory in the form of increased seed dormancy, and that persisted one generation removed from stress. With respect to transgenerational drought stress, there were negligible conserved differentially methylated regions in drought-exposed lineages compared with unstressed lineages. Instead, the majority of observed variation was tied to stochastic or preexisting differences in the epigenome occurring at repetitive regions of the Arabidopsis genome. Furthermore, the experience of repeated drought stress was not observed to influence transgenerational epi-allele accumulation. Our findings demonstrate that, while transgenerational memory is observed in one of six traits examined, they are not associated with causative changes in the DNA methylome, which appears relatively impervious to drought stress.
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