Temperature-dependent regulation of flowering by antagonistic FLM variants

Posé, David; Verhage, Leonie; Ott, Felix; Yant, Levi; Mathieu, Johannes; Angenent, Gerco C.; Immink, Richard G. H.; Schmid, Markus

doi:10.1038/nature12633

Cited by 381 publications

(484 citation statements)

References 35 publications

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“…For example, SVP complexes with FLOWERING LOCUS C (FLC) to permit flowering only once FLC levels are sufficiently reduced by progressive chromatin changes in response to prolonged vernalization (Michaels and Amasino, 1999;Bastow et al, 2004;Sung and Amasino, 2004;Li et al, 2008). In addition, repressive complexes of SVP with FLOWERING LOCUS M or MADS AFFECTING FLOWERING2 decline at warmer temperatures, contributing to thermoresponsive flowering (Ratcliffe et al, 2003;Gu et al, 2013;Lee et al, 2013;Posé et al, 2013;Airoldi et al, 2015;Sureshkumar et al, 2016).…”

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confidence: 99%

Seasonal Regulation of Petal Number

et al. 2017

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Four petals characterize the flowers of most species in the Brassicaceae family, and this phenotype is generally robust to genetic and environmental variation. A variable petal number distinguishes the flowers of Cardamine hirsuta from those of its close relative Arabidopsis (Arabidopsis thaliana), and allelic variation at many loci contribute to this trait. However, it is less clear whether C. hirsuta petal number varies in response to seasonal changes in environment. To address this question, we assessed whether petal number responds to a suite of environmental and endogenous cues that regulate flowering time in C. hirsuta. We found that petal number showed seasonal variation in C. hirsuta, such that spring flowering plants developed more petals than those flowering in summer. Conditions associated with spring flowering, including cool ambient temperature, short photoperiod, and vernalization, all increased petal number in C. hirsuta. Cool temperature caused the strongest increase in petal number and lengthened the time interval over which floral meristems matured. We performed live imaging of early flower development and showed that floral buds developed more slowly at 15°C versus 20°C. This extended phase of floral meristem formation, coupled with slower growth of sepals at 15°C, produced larger intersepal regions with more space available for petal initiation. In summary, the growth and maturation of floral buds is associated with variable petal number in C. hirsuta and responds to seasonal changes in ambient temperature.

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confidence: 99%

Seasonal Regulation of Petal Number

et al. 2017

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“…We used model 3 to predict the flowering times for various mutations at 16 • C, 23 • C and 27 • C and compared these with available experimental data [Pose13]. Loss of temperature dependence is seen both in experiment and in prediction of the FLM knockout.…”

Section: Application: Modeling Mutationsmentioning

confidence: 99%

“…Expression time series (qPCR) of FLM-β and FLM-δ at 23 • C, as well as relative expression of these splice variants after 10 days at 16 • C, 23 • C and 27 • C were obtained from [Pose13]. The equation describing how FLM-β and FLM-δ concentrations change with temperature was approximated by a linear fit between these data points.…”

Section: Datamentioning

confidence: 99%

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Scientific report: Training workshop interdisciplinary life sciences

Akudibillah

Boas

Carrères

et al. 2014

Preprint

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This preprint is the outcome of the “Training Workshop Interdisciplinary Life Sciences”, held in October 2013 in the Lorentz Center, Leiden, The Netherlands. The motivation to organize this event stems from the following considerations: The enormous progress in laboratory techniques and facilities leads to the availability of huge amounts of data at all levels of complexity (molecules, cells, tissues, organs, organisms, populations, ecosystems). Especially data at the cellular level reveal details of life processes we were unconscious of until recently. However, it becomes clear that huge amounts of data alone do not automatically lead to understanding. The data explosion in Life Sciences teaches one lesson: life processes are of a highly intricate and integrative nature. To really understand the dynamic processes in living organisms one must integrate experimental data sets in quantitative and predictive models. Only then one may hope to grasp the functioning of these complex systems and be able to convert information in understanding. In the field of physics, for instance, this strong interaction between experiment and theory is already common practice since centuries, culminating in the 20th century being called the ’Century of Physics’. In contrast to physics, the complex nature of the Life Sciences forces us to work in an interdisciplinary fashion. The necessary expertise is available, but scattered over many scientific disciplines. Only the combined efforts of biologists, chemists, mathematicians, physicists, engineers, and informaticians will lead to progress in tackling the huge challenge of understanding the complexity of life. Researchers in the Life Sciences often focus their research on a rather narrow research field. However, the majority of the upcoming generation of researchers in the Life Sciences should be trained to expand their skills, becoming able to tackle complex, multi-dimensional systems. The knowledge they have to incorporate in their research will stem from a diverse range of disciplines, So, they should be trained to integrate a broad range of modelling approaches in order to deduce quantitative, predictive and often multi-scale models from highly diverse data sets. Present curricula in the Life Sciences hardly offer this kind of training yet. This workshop intends to start filling this gap. Three teams worked on the following open problems: 1) Modeling the influence of temperature on the Regulation of flowering time in Arabidopsis thaliana; 2) Validation of computational models of angiogenesis to experimental data; 3) Reconstructing the gene network that regulates branching in Tomato. This preprint bundles the reports of the three teams.

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“…23 Previous studies have shown that the MADS-box TF genes FLOWERING LOCUS M (FLM), MADS AFFECTING FLOWERING 2 (MAF2) and SHORT VEGETATIVE PHASE (SVP) play key roles in the temperature-dependent regulation of flowering, with the alternative splicing of FLM and MAF2 working as a molecular thermometer to prevent or induce precocious flowering. 24,25 Alice Pajoro, postdoc in Richard Immink's group (Wageningen University, The Netherlands), reported her work on the epigenetic regulation behind this temperature-mediated alternative splicing process. Using RNA-seq, numerous temperature-mediated alternative splicing events, including many flowering time regulators, were identified.…”

Section: Microscopy Molecules and Modeling: Elucidating Nuclear Orgmentioning

confidence: 99%

Chromatin and epigenetics in all their states: Meeting report of the first conference on Epigenetic and Chromatin Regulation of Plant Traits - January 14 – 15, 2016 - Strasbourg, France

Bey

Jamge²,

Klemme

et al. 2016

Epigenetics

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In January 2016, the first Epigenetic and Chromatin Regulation of Plant Traits conference was held in Strasbourg, France. An all-star lineup of speakers, a packed audience of 130 participants from over 20 countries, and a friendly scientific atmosphere contributed to make this conference a meeting to remember. In this article we summarize some of the new insights into chromatin, epigenetics, and epigenomics research and highlight nascent ideas and emerging concepts in this exciting area of research.

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Temperature-dependent regulation of flowering by antagonistic FLM variants

Cited by 381 publications

References 35 publications

Seasonal Regulation of Petal Number

Seasonal Regulation of Petal Number

Scientific report: Training workshop interdisciplinary life sciences

Chromatin and epigenetics in all their states: Meeting report of the first conference on Epigenetic and Chromatin Regulation of Plant Traits - January 14 – 15, 2016 - Strasbourg, France

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