Seed dormancy is a dynamic state: variable responses to pre- and post-shedding environmental signals in seeds of contrasting<i>Arabidopsis</i>ecotypes

Huang, Ziyue; Ölcer-Footitt, H; Footitt, Steven

doi:10.1017/s096025851500001x

Cited by 31 publications

(30 citation statements)

References 37 publications

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“…). In the experiments presented, ecotypic differences in the relief and induction of dormancy by the temperatures used in the simulation were consistent with those previously shown for Bur, Col‐0, Ler and Cvi (Cone and Spruit ; Huang et al , Springthorpe and Penfield ; Penfield & Springthorpe ). These differences presumably arose during adaptation to their specific climates from a common underlying species response.…”

Section: Discussionsupporting

confidence: 88%

“…; Huang et al . ). This is apparently in direct contrast to the results with the summer annual ecotypes Bur, Col‐0 and Ler in which increasing temperature accelerated the induction of secondary dormancy (Fig.…”

Section: Discussionmentioning

confidence: 97%

“…Seeds first sense the maternal environment to set the depth of primary dormancy at maturity (e.g. temperature) (Kendall et al ; Penfield and Springthorpe ; He et al ; Huang et al , ; Chen et al . ).…”

Section: Introductionmentioning

confidence: 99%

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A laboratory simulation of Arabidopsis seed dormancy cycling provides new insight into its regulation by clock genes and the dormancy‐related genes DOG1, MFT, CIPK23 and PHYA

Footitt

Ölcer-Footitt

Hambidge

2017

Plant Cell & Environment

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Environmental signals drive seed dormancy cycling in the soil to synchronize germination with the optimal time of year, a process essential for species' fitness and survival. Previous correlation of transcription profiles in exhumed seeds with annual environmental signals revealed the coordination of dormancy‐regulating mechanisms with the soil environment. Here, we developed a rapid and robust laboratory dormancy cycling simulation. The utility of this simulation was tested in two ways: firstly, using mutants in known dormancy‐related genes [DELAY OF GERMINATION 1 (DOG1), MOTHER OF FLOWERING TIME (MFT), CBL‐INTERACTING PROTEIN KINASE 23 (CIPK23) and PHYTOCHROME A (PHYA)] and secondly, using further mutants, we test the hypothesis that components of the circadian clock are involved in coordination of the annual seed dormancy cycle. The rate of dormancy induction and relief differed in all lines tested. In the mutants, dog1‐2 and mft2, dormancy induction was reduced but not absent. DOG1 is not absolutely required for dormancy. In cipk23 and phyA dormancy, induction was accelerated. Involvement of the clock in dormancy cycling was clear when mutants in the morning and evening loops of the clock were compared. Dormancy induction was faster when the morning loop was compromised and delayed when the evening loop was compromised.

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Section: Discussionsupporting

confidence: 88%

Section: Discussionmentioning

confidence: 97%

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A laboratory simulation of Arabidopsis seed dormancy cycling provides new insight into its regulation by clock genes and the dormancy‐related genes DOG1, MFT, CIPK23 and PHYA

Footitt

Ölcer-Footitt

Hambidge

2017

Plant Cell & Environment

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“…Seeds commonly exhibit one of several types of dormancy, such that germination is controlled by endogenous and environmental factors which break dormancy when conditions are favourable (Finch‐Savage & Leubner‐Metzger, ; Bentsink & Koornneef, ; Footitt et al ., ; Willis et al ., ). Physiological dormancy is established during seed development and can be lost and re‐imposed after dispersal from the mother plant in response to combinations of environmental factors, including water, light, temperature, nutrients and biotic signals (Huang et al ., ; Penfield, ). Such control of dormancy is achieved by complex interactions between the environmental factors and endogenous hormone signalling systems, which determine when a seed will germinate (Footitt et al ., ).…”

Section: Introductionmentioning

confidence: 98%

Karrikin‐KAI2 signalling provides Arabidopsis seeds with tolerance to abiotic stress and inhibits germination under conditions unfavourable to seedling establishment

2018

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The control of seed germination in response to environmental conditions is important for plant success. We investigated the role of the karrikin receptor KARRIKIN INSENSITIVE2 (KAI2) in the response of Arabidopsis seeds to osmotic stress, salinity and high temperature. Germination of the kai2 mutant was examined in response to NaCl, mannitol and elevated temperature. The effect of karrikin on germination of wild-type seeds, hypocotyl elongation and the expression of karrikin-responsive genes was also examined in response to such stresses. The kai2 seeds germinated less readily than wild-type seeds and germination was more sensitive to inhibition by abiotic stress. Karrikin-induced KAI2 signalling stimulated germination of wild-type seeds under favourable conditions, but, surprisingly, inhibited germination in the presence of osmolytes or at elevated temperature. By contrast, GA stimulated germination of wild-type seeds and mutants under all conditions. Karrikin induced expression of DLK2 and KUF1 genes and inhibited hypocotyl elongation independently of osmotic stress. Under mild osmotic stress, karrikin enhanced expression of DREB2A, WRKY33 and ERF5 genes, but not ABA signalling genes. Thus, the karrikin-KAI2 signalling system can protect against abiotic stress, first by providing stress tolerance, and second by inhibiting germination under conditions unfavourable to seedling establishment.

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“…Decreasing the temperature during seed development results in increased levels of dormancy (i.e. decreased probability of germinating; Donohue et al ., ; Kendall et al ., ; Penfield & Springthorpe, ; Huang et al ., ). The changes in dormancy are mediated by altered gene expression (Kendall et al ., ), seed provisioning, (Finch‐Savage & Leubner‐Metzger, ), and seed coat properties (MacGregor et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Multiple paths to similar germination behavior in Arabidopsis thaliana

2015

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SummaryGermination timing influences plant fitness, and its sensitivity to temperature may cause it to change as climate shifts. These changes are likely to be complex because temperatures that occur during seed maturation and temperatures that occur post-dispersal interact to define germination timing.We used the model organism Arabidopsis thaliana to determine how flowering time (which defines seed-maturation temperature) and post-dispersal temperature influence germination and the expression of genetic variation for germination.Germination responses to temperature (germination envelopes) changed as seeds aged, or after-ripened, and these germination trajectories depended on seed-maturation temperature and genotype. Different combinations of genotype, seed-maturation temperature, and afterripening produced similar germination envelopes. Likewise, different genotypes and seedmaturation temperatures combined to produce similar germination trajectories. Differences between genotypes were most likely to be observed at high and low germination temperatures.The germination behavior of some genotypes responds weakly to maternal temperature but others are highly plastic. We hypothesize that weak dormancy induction could synchronize germination of seeds dispersed at different times. By contrast, we hypothesize that strongly responsive genotypes may spread offspring germination over several possible germination windows. Considering germination responses to temperature is important for predicting phenology expression and evolution in future climates.

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Seed dormancy is a dynamic state: variable responses to pre- and post-shedding environmental signals in seeds of contrastingArabidopsisecotypes

Cited by 31 publications

References 37 publications

A laboratory simulation of Arabidopsis seed dormancy cycling provides new insight into its regulation by clock genes and the dormancy‐related genes DOG1, MFT, CIPK23 and PHYA

A laboratory simulation of Arabidopsis seed dormancy cycling provides new insight into its regulation by clock genes and the dormancy‐related genes DOG1, MFT, CIPK23 and PHYA

Karrikin‐KAI2 signalling provides Arabidopsis seeds with tolerance to abiotic stress and inhibits germination under conditions unfavourable to seedling establishment

Multiple paths to similar germination behavior in Arabidopsis thaliana

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