Seed dormancy and germination

Penfield, Steven

doi:10.1016/j.cub.2017.05.050

Cited by 263 publications

(213 citation statements)

References 9 publications

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“…Environmental signals perceived before and after seed dispersal determine the depth of physiological dormancy and therefore the germination response to the ambient conditions (Penfield, ). Furthermore, seed dormancy is a dynamic state, subject to changes in the local environment, and can undergo cycles of dormancy breaking and re‐imposition as conditions change, especially water availability and temperature (Finch‐Savage & Footitt, ).…”

Section: Discussionmentioning

confidence: 99%

“…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: 97%

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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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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

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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“…For instance, the mutant abi3 seed is known to exhibit shorter dormancy and shorter seed longevity (Mao & Sun, ), suggesting that the degree of seed dormancy level may be positively associated with seed longevity. Cell metabolism is largely inactive during seed dormancy so that much of the energy stored in the seed is maintained (Penfield, ), and this may be one of the most important factors to explain the relationship between seed dormancy and longevity, but the underlying regulatory mechanism and relationship between seed dormancy and longevity are still largely unknown. Whether or not seed dormancy and longevity are directly and causally associated is an interesting and important question.…”

Section: Concluding Remarks and Perspectivesmentioning

confidence: 99%

A matter of life and death: Molecular, physiological, and environmental regulation of seed longevity

Zhou

Chen

Luo

et al. 2019

Plant Cell & Environment

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Both seed germination and early seedling establishment are important biological processes in a plant's lifecycle. Seed longevity is a key trait in agriculture, which directly influences seed germination and ultimately determines crop productivity and hence food security. Numerous studies have demonstrated that seed deterioration is regulated by complex interactions between diverse endogenous genetically controlled factors and exogenous environmental cues, including temperature, relative humidity, and oxygen partial pressure during seed storage. The endogenous factors, including the chlorophyll concentration, the structure of the seed coat, the balance of phytohormones, the concentration of reactive oxygen species, the integrity of nucleic acids and proteins and their associated repair systems, are also involved in the control of seed longevity. A precise understanding of the regulatory mechanisms underlying seed longevity is becoming a hot topic in plant molecular biology. In this review, we describe recent research into the regulation of seed longevity and the interactions between the various environmental and genetic factors. Based on this, the current state‐of‐play regarding seed longevity regulatory networks will be presented, particularly with respect to agricultural seed storage, and the research challenges to be faced in the future will be discussed.

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“…Before germination, seeds contain carbohydrates, proteins, lipids, and phosphates as energy sources and remain in a metabolically quiescent and desiccation‐tolerant state (Bentsink & Koornneef, ). Once the seed senses environmental signals favourable for the release of dormancy, such as water imbibition or stratification, the radicle emerges through the seed coat in the process known as germination (Penfield, ). During a postgermination phase lasting 2–3 days, activation of metabolism results in the gradual hydrolysis and release of storage materials.…”

Section: Introductionmentioning

confidence: 99%

“…. Once the seed senses environmental signals favourable for the release of dormancy, such as water imbibition or stratification, the radicle emerges through the seed coat in the process known as germination (Penfield, 2017). During a postgermination phase lasting 2-3 days, activation of metabolism results in the gradual hydrolysis and release of storage materials.…”

mentioning

confidence: 99%

Abscisic acid‐dependent histone demethylation during postgermination growth arrest in Arabidopsis

Ichihashi

Suzuki

et al. 2019

Plant Cell & Environment

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After germination, seedlings undergo growth arrest in response to unfavourable conditions, a critical adaptation enabling plants to survive harsh environments. The plant hormone abscisic acid (ABA) plays a key role in this arrest. To arrest growth, ABA‐dependent transcription factors change gene expression patterns in a flexible and reversible manner. Although the control of gene expression has important roles in growth arrest, the epigenetic mechanisms in the response to ABA are not fully understood. Here, we show that the histone demethylases JUMONJI‐C domain‐containing protein 30 (JMJ30) and JMJ32 control ABA‐mediated growth arrest in Arabidopsis thaliana. During the postgermination stage (2–3 days after germination), the ABA‐dependent transcription factor ABA‐insensitive3 (ABI3) activates the expression of JMJ30 in response to ABA. JMJ30 then removes a repressive histone mark, H3 lysine 27 trimethylation (H3K27me3), from the SNF1‐related protein kinase 2.8 (SnRK2.8) promoter, and hence activates SnRK2.8 expression. SnRK2.8 encodes a kinase that activates ABI3 and is responsible for JMJ30‐ and JMJ32‐mediated growth arrest. A feed‐forward loop involving the ABI3 transcription factor, JMJ histone demethylases, and the SnRK2.8 kinase fine‐tunes ABA‐dependent growth arrest in the postgermination phase. Our findings highlight the importance of the histone demethylases in mediating adaptation of plants to the environment.

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Seed dormancy and germination

Cited by 263 publications

References 9 publications

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

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

A matter of life and death: Molecular, physiological, and environmental regulation of seed longevity

Abscisic acid‐dependent histone demethylation during postgermination growth arrest in Arabidopsis

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