Manipulation of photosensory and circadian signaling restricts phenotypic plasticity in response to changing environmental conditions in Arabidopsis.

Plants exploit phenotypic plasticity to adapt their growth and development to prevailing environmental conditions. Interpretation of light and temperature signals is aided by the circadian system, which provides a temporal context. Phenotypic plasticity provides a selective and competitive advantage in nature but is obstructive during large-scale, intensive agricultural practices since economically important traits (including vegetative growth and flowering time) can vary widely depending on local environmental conditions.

Integrating analog and digital modes of gene expression at .

Quantitative gene regulation at the cell population level can be achieved by two fundamentally different modes of regulation at individual gene copies. A 'digital' mode involves binary ON/OFF expression states, with population-level variation arising from the proportion of gene copies in each state, while an 'analog' mode involves graded expression levels at each gene copy. At the floral repressor 'digital' Polycomb silencing is known to facilitate quantitative epigenetic memory in response to cold.

Natural temperature fluctuations promote regulation of .

Plants monitor many aspects of their fluctuating environments to help align their development with seasons. Molecular understanding of how noisy temperature cues are registered has emerged from dissection of vernalization in , which involves a multiphase cold-dependent silencing of the floral repressor locus (). Cold-induced transcriptional silencing precedes a low probability PRC2 epigenetic switching mechanism.

Feeling Every Bit of Winter - Distributed Temperature Sensitivity in Vernalization.

Temperature intrinsically influences all aspects of biochemical and biophysical processes. Organisms have therefore evolved strategies to buffer themselves against thermal perturbations. Many organisms also use temperature signals as cues to align behavior and development with certain seasons.

Natural variation in autumn expression is the major adaptive determinant distinguishing Arabidopsis FLC haplotypes.

In winter is registered during vernalization through the temperature-dependent repression and epigenetic silencing of floral repressor . Natural Arabidopsis accessions show considerable variation in vernalization. However, which aspect of the repression mechanism is most important for adaptation to different environments is unclear.

Publisher Correction: Temperature-dependent growth contributes to long-term cold sensing.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Temperature-dependent growth contributes to long-term cold sensing.

Temperature is a key factor in the growth and development of all organisms. Plants have to interpret temperature fluctuations, over hourly to monthly timescales, to align their growth and development with the seasons. Much is known about how plants respond to acute thermal stresses, but the mechanisms that integrate long-term temperature exposure remain unknown.

Noncoding SNPs influence a distinct phase of Polycomb silencing to destabilize long-term epigenetic memory at .

In , the cold-induced epigenetic regulation of () involves distinct phases of Polycomb repressive complex 2 (PRC2) silencing. During cold, a PHD-PRC2 complex metastably and digitally nucleates H3K27me3 within On return to warm, PHD-PRC2 spreads across the locus delivering H3K27me3 to maintain long-term silencing. Here, we studied natural variation in this process in accessions, exploring Lov-1, which shows reactivation on return to warm, a feature characteristic of in perennial This analysis identifies an additional phase in this Polycomb silencing mechanism downstream from H3K27me3 spreading.

Temperature Sensing Is Distributed throughout the Regulatory Network that Controls FLC Epigenetic Silencing in Vernalization.

Many organisms need to respond to complex, noisy environmental signals for developmental decision making. Here, we dissect how Arabidopsis plants integrate widely fluctuating field temperatures over month-long timescales to progressively upregulate VERNALIZATION INSENSITIVE3 (VIN3) and silence FLOWERING LOCUS C (FLC), aligning flowering with spring. We develop a mathematical model for vernalization that operates on multiple timescales-long term (month), short term (day), and current (hour)-and is constrained by experimental data.

Absence of warmth permits epigenetic memory of winter in Arabidopsis.

Plants integrate widely fluctuating temperatures to monitor seasonal progression. Here, we investigate the temperature signals in field conditions that result in vernalisation, the mechanism by which flowering is aligned with spring. We find that multiple, distinct aspects of the temperature profile contribute to vernalisation.

Buckling as an origin of ordered cuticular patterns in flower petals.

The optical properties of plant surfaces are strongly determined by the shape of epidermal cells and by the patterning of the cuticle on top of the cells. Combinations of particular cell shapes with particular nanoscale structures can generate a wide range of optical effects. Perhaps most notably, the development of ordered ridges of cuticle on top of flat petal cells can produce diffraction-grating-like structures.