Major flowering time gene,
            <i>FLOWERING LOCUS C</i>
            , regulates seed germination in
            <i>Arabidopsis thaliana</i>

Chiang, George C. K.; Barua, Deepak; Kramer, Elena M.; Amasino, Richard M.; Donohue, Kathleen

doi:10.1073/pnas.0901367106

Cited by 265 publications

(299 citation statements)

References 62 publications

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“…None of the seeds obtained germinated in the absence of GA (at least 200 seeds were tested). These results underscore the advantages of having used the ft background, which was recently shown to improve germination (28). The ft mutation caused a delay in flowering time in the quintuple phytochrome mutant background (Fig.…”

Section: Resultsmentioning

confidence: 66%

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Arabidopsis thaliana life without phytochromes

Strasser

Sánchez‐Lamas

Yanovsky

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

172

150

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Plants use light as a source of energy for photosynthesis and as a source of environmental information perceived by photoreceptors. Testing whether plants can complete their cycle if light provides energy but no information about the environment requires a plant devoid of phytochromes because all photosynthetically active wavelengths activate phytochromes. Producing such a quintuple mutant of Arabidopsis thaliana has been challenging, but we were able to obtain it in the flowering locus T ( ft ) mutant background. The quintuple phytochrome mutant does not germinate in the FT background, but it germinates to some extent in the ft background. If germination problems are bypassed by the addition of gibberellins, the seedlings of the quintuple phytochrome mutant exposed to red light produce chlorophyll, indicating that phytochromes are not the sole red-light photoreceptors, but they become developmentally arrested shortly after the cotyledon stage. Blue light bypasses this blockage, rejecting the long-standing idea that the blue-light receptors cryptochromes cannot operate without phytochromes. After growth under white light, returning the quintuple phytochrome mutant to red light resulted in rapid senescence of already expanded leaves and severely impaired expansion of new leaves. We conclude that Arabidopsis development is stalled at several points in the presence of light suitable for photosynthesis but providing no photomorphogenic signal.

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Section: Resultsmentioning

confidence: 66%

“…Previous failure could be due to the fact that the seeds of the quintuple mutant do not germinate if GA is not added to the substrate. Here, we initially obtained the quintuple phytochrome mutant in the ft mutant background, which has recently been shown to improve germination (28).…”

Section: Discussionmentioning

confidence: 99%

Arabidopsis thaliana life without phytochromes

Strasser

Sánchez‐Lamas

Yanovsky

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

172

150

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“…In particular, life history traits that comprise complex phenotypes such as phenology (Armbruster, Pélabon, Bolstad, & Hansen, 2014; Murren, 2012; Peiman & Robinson, 2017), may have both genetic and functional linkages. For example, in Arabidopsis thaliana , the FLOWERING LOCUS C (FLC) gene regulates flowering time and mediates germination time by affecting seed dormancy through a pleiotropic genetic correlation (Chiang et al., 2009). Simultaneously, in A. thaliana and many flowering plants, the sequential nature of expression of phenological traits results in functional linkage, as the timing of flowering affects traits later in development such as fruit maturation and seed dispersal (Donohue, 2009; Galloway & Burgess, 2009; Lacey & Pace, 1983; Lacey, Roach, Herr, Kincaid, & Perrott, 2003).…”

Section: Introductionmentioning

confidence: 99%

Response to joint selection on germination and flowering phenology depends on the direction of selection

Galloway

Watson

Prendeville

2018

Ecology and Evolution

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Flowering and germination time are components of phenology, a complex phenotype that incorporates a number of traits. In natural populations, selection is likely to occur on multiple components of phenology at once. However, we have little knowledge of how joint selection on several phenological traits influences evolutionary response. We conducted one generation of artificial selection for all combinations of early and late germination and flowering on replicated lines within two independent base populations in the herb Campanula americana. We then measured response to selection and realized heritability for each trait. Response to selection and heritability were greater for flowering time than germination time, indicating greater evolutionary potential of this trait. Selection for earlier phenology, both flowering and germination, did not depend on the direction of selection on the other trait, whereas response to selection to delay germination and flowering was greater when selection on the other trait was in the opposite direction (e.g., early germination and late flowering), indicating a negative genetic correlation between the traits. Therefore, the extent to which correlations shaped response to selection depended on the direction of selection. Furthermore, the genetic correlation between timing of germination and flowering varies across the trait distributions. The negative correlation between germination and flowering time found when selecting for delayed phenology follows theoretical predictions of constraint for traits that jointly determine life history schedule. In contrast, the lack of constraint found when selecting for an accelerated phenology suggests a reduction of the covariance due to strong selection favoring earlier flowering and a shorter life cycle. This genetic architecture, in turn, will facilitate further evolution of the early phenology often favored in warm climates.

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“…For instance, our model of Arabidopsis phenology is at present silent about the factors that influence the timing of germination, even though recent studies have shown that certain genes in the flowering time network are also involved in seed dormancy and germination behaviour (Heschel et al 2008;Chiang et al 2009). Both maternal environmental factors such as temperature ) and genetic factors (Alonso-Blanco et al 2003;Holdsworth et al 2008;Chiang et al 2009) affect germination behaviour in this species. Despite such advances, we still know relatively little about the natural seasonal and climatic conditions that are permissive for germination (see also review in Donohue 2009).…”

Section: (D) Model Limitations and Future Extensionsmentioning

confidence: 99%

Genetic and physiological bases for phenological responses to current and predicted climates

Wilczek

Burghardt

Cobb

et al. 2010

Phil. Trans. R. Soc. B

193

178

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We are now reaching the stage at which specific genetic factors with known physiological effects can be tied directly and quantitatively to variation in phenology. With such a mechanistic understanding, scientists can better predict phenological responses to novel seasonal climates. Using the widespread model species Arabidopsis thaliana, we explore how variation in different genetic pathways can be linked to phenology and life-history variation across geographical regions and seasons. We show that the expression of phenological traits including flowering depends critically on the growth season, and we outline an integrated life-history approach to phenology in which the timing of later life-history events can be contingent on the environmental cues regulating earlier life stages. As flowering time in many plants is determined by the integration of multiple environmentally sensitive gene pathways, the novel combinations of important seasonal cues in projected future climates will alter how phenology responds to variation in the flowering time gene network with important consequences for plant life history. We discuss how phenology models in other systems-both natural and agricultural-could employ a similar framework to explore the potential contribution of genetic variation to the physiological integration of cues determining phenology.

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Major flowering time gene, FLOWERING LOCUS C , regulates seed germination in Arabidopsis thaliana

Cited by 265 publications

References 62 publications

Arabidopsis thaliana life without phytochromes

Arabidopsis thaliana life without phytochromes

Response to joint selection on germination and flowering phenology depends on the direction of selection

Genetic and physiological bases for phenological responses to current and predicted climates

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