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, Steven; Ölcer-Footitt, H; Hambidge, Angela J.

doi:10.1111/pce.12940

Cited by 39 publications

(58 citation statements)

References 57 publications

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“…A clear distinction between primary and secondary dormancy is not always made regarding the effect of the maternal environment on dormancy levels (Footitt et al , ). We hypothesize that the difference of the maternal effect on primary and secondary dormancy (i.e.…”

Section: Discussionmentioning

confidence: 99%

“…There are a few factors to take into account when comparing these studies. Experimental differences include: (i) secondary dormancy induction conditions , with prolonged dark and cold conditions in the field versus dark and warm conditions in the laboratory (Cadman et al , ; Ibarra et al , ; Footitt et al , ); (ii) dormancy induction is slower and the time between sampling is longer in the field (months), compared with days or weeks in the laboratory; (iii) gradual changes in dormancy levels (in the field) compared with two states, non‐dormant and secondary dormant (in the laboratory) (Ibarra et al , ). Genes in which expression is reduced in secondary dormancy in laboratory experiments, such as the GA signalling related genes REPRESSOR OF GA ( RGA ), RGL1 , RGL2 , GA INSENSITIVE ( GAI ) are also significantly reduced in expression during dormancy induction in the field (Ibarra et al , ).…”

Section: Discussionmentioning

confidence: 99%

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Dormancy cycling: translation‐related transcripts are the main difference between dormant and non‐dormant seeds in the field

et al. 2020

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Primary seed dormancy is a mechanism that orchestrates the timing of seed germination in order to prevent out-of-season germination. Secondary dormancy can be induced in imbibed seeds when they encounter prolonged unfavourable conditions. Secondary dormancy is not induced during dry storage, and therefore the mechanisms underlying this process have remained largely unexplored. Here, a 2-year seed burial experiment in which dormancy cycling was studied at the physiological and transcriptional level is presented. For these analyses six different Arabidopsis thaliana genotypes were used: Landsberg erecta (Ler) and the dormancy associated DELAY OF GERMINATION (DOG) near-isogenic lines 1, 2, 3, 6 and 22 (NILDOG1, 2, 3, 6 and 22). The germination potential of seeds exhumed from the field showed that these seeds go through dormancy cycling and that the dynamics of this cycling is genotype dependent. RNA-seq analysis revealed large transcriptional changes during dormancy cycling, especially at the time points preceding shifts in dormancy status. Dormancy cycling is driven by soil temperature and the endosperm is important in the perception of the environment. Genes that are upregulated in the low-to non-dormant stages are enriched for genes involved in translation, indicating that the non-dormant seeds are prepared for rapid seed germination.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Dormancy cycling: translation‐related transcripts are the main difference between dormant and non‐dormant seeds in the field

et al. 2020

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“…Alternating temperatures cycles are an environmental signal that relief seed dormancy and, consequently, contribute to define the dynamics of emergence of weed seedlings in the field (Benech‐Arnold et al, ). Unfortunately, this process has not been extensively studied in Arabidopsis ‐model‐seed system with recent exceptions (Footitt, Ölçer‐Footitt, Hambidge, & Finch‐Savage, ; Topham et al, ). By mathematical and experimental approaches, Bassel's team demonstrated that alternating temperatures act as an instructive signal in the root tip of Arabidopsis dormant seeds that define the distribution of hormone metabolites and ABA/GA transporter activity to break dormancy (Topham et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…In other words, shortly after imbibition, the daily temperature cycles might affect specific clock components that are linked to the regulation of dormancy and germination, rather than the overall performance of the circadian clock. In a dormancy cycling simulated experiment using clock mutants, Footitt et al () found that clock elements belonging to the central loop (i.e., CCA1, LHY, and TOC1) contribute to reduce the ABA sensitivity, and mutant seeds in these genes showed a faster entrance in secondary dormancy at 25 °C. In contrast, components of the clock belonging to the early loop (i.e., PRR5, PRR7, and PRR9) increased ABA sensitivity, and mutant seeds in PRR genes had a lower entrance in secondary dormancy.…”

Section: Discussionmentioning

confidence: 99%

Physiological and molecular mechanisms underlying the integration of light and temperature cues in Arabidopsis thaliana seeds

Arana

Tognacca

Estravis-Barcala

et al. 2017

Plant Cell & Environment

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The relief of dormancy and the promotion of seed germination are of extreme importance for a successful seedling establishment. Although alternating temperatures and light are signals promoting the relief of seed dormancy, the underlying mechanisms of their interaction in seeds are scarcely known. By exposing imbibed Arabidopsis thaliana dormant seeds to two-day temperature cycles previous of a red light pulse, we demonstrate that the germination mediated by phytochrome B requires the presence of functional PSEUDO-RESPONSE REGULATOR 7 (PRR7) and TIMING OF CAB EXPRESSION 1 (TOC1) alleles. In addition, daily cycles of alternating temperatures in darkness reduce the protein levels of DELAY OF GERMINATION 1 (DOG1), allowing the expression of TOC1 to induce seed germination. Our results suggest a functional role for some components of the circadian clock related with the action of DOG1 for the integration of alternating temperatures and light signals in the relief of seed dormancy. The synchronization of germination by the synergic action of light and temperature through the activity of circadian clock might have ecological and adaptive consequences.

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“…Notably, induction of primary dormancy was greatly influenced by the effect of maternal environments on embryo/endosperm Advances in Seed Biology [74,76,77] and/or on seed coat properties [78]. Dormancy intensity can be manipulated via controlling the daily circadian clock at reproduction [79]. Such effects can be passed down for multiple generations [80,81] and have been observed even in long-lived perennials, such as conifers [82].…”

Section: Seed Dormancymentioning

confidence: 99%

Roles of the Environment in Plant Life-History Trade-offs

Liu¹,

Walck²,

El‐Kassaby³

2017

Advances in Seed Biology

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Variation in plant life-history and functional traits at between-and within-species levels has key ecological consequences, in which environmental settings impose strong selective pressures and play a vital role throughout life cycles. Our general notion for plant life-history strategies may be that, relative to tall, long-lived plants, short-lived species have features of small stature, small-seededness, rapid growth, and low seedling survival (k-versus r-selection). Rate of evolution may be an important agent of selection and annals evolve more rapidly than perennial congeners. These empirical observations prompt a suite of enticing questions, such as how do life-history traits interplay with functional trait at late stages of regeneration? what are the primary trade-offs in a cohort of key life-history traits that may have undergone stabilizing selection? and how do environmental filters differently affect adaptive trait variation in annuals and perennials? In this chapter, we intend to address aforementioned questions via assembling our updated knowledge with emphasis on seed mass and temporal and spatial dimensions of seed dispersal. Through such synthesis, we wish to raise awareness about life-history trade-offs and provide a holistic understanding of the extent to which climate change is likely to impact plant adaptation and eco-evolutionary trajectories of life-history phenotypes.

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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

Cited by 39 publications

References 57 publications

Dormancy cycling: translation‐related transcripts are the main difference between dormant and non‐dormant seeds in the field

Dormancy cycling: translation‐related transcripts are the main difference between dormant and non‐dormant seeds in the field

Physiological and molecular mechanisms underlying the integration of light and temperature cues in Arabidopsis thaliana seeds

Roles of the Environment in Plant Life-History Trade-offs

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