Project description:Circadian clocks are the time-keeping cellular apparatuses that are photoentrained according to the day-night photocycles on Earth 1,2. Cryptochromes (CRYs) are photoreceptors mediating photoentrainment of the circadian clock in plants and animals but how CRYs mediate light regulation of the molecular clock remains unclear 1,3. Here we show that CRYs mediate photoresponses of the circadian clock by regulating the activity of N6-methyladenosine (m6A) RNA methyltransferase and photoresponses of the epitranscriptome. In contrast to the presently known CRY complexome, the CRY2-methyltransferase complex exbibits multivalent interactions and photoresponsive condensation in response to blue light. We show that photoexcited CRY2 undergoes phosphorylation-assisted demixing to form photobodies with the properties of condensed liquid phase, which facilitates assembly of the CRY2-methyltransferase complex in the condensed liquid phase of CRY2 in vivo. The mta mutant impaired in m6A methyltransferase and the cry1cry2 mutant missing CRY photoreceptors share common defects of lengthened circadian period, reduced m6A RNA methylation, and accelerated degradation of mRNAs encoding core components of the molecular clock. These results argue for a photoentrainment mechanism by which blue light elicits liquid-liquid phase separation of the CRY2-methyltransferase complex to regulate m6A mRNA methylation, consequently suppressing mRNA degradation and period lengthening of the circadian clock

Project description:Circadian clocks are the time-keeping cellular apparatuses that are photoentrained according to the day-night photocycles on Earth 1,2. Cryptochromes (CRYs) are photoreceptors mediating photoentrainment of the circadian clock in plants and animals but how CRYs mediate light regulation of the molecular clock remains unclear 1,3. Here we show that CRYs mediate photoresponses of the circadian clock by regulating the activity of N6-methyladenosine (m6A) RNA methyltransferase and photoresponses of the epitranscriptome. In contrast to the presently known CRY complexome, the CRY2-methyltransferase complex exbibits multivalent interactions and photoresponsive condensation in response to blue light. We show that photoexcited CRY2 undergoes phosphorylation-assisted demixing to form photobodies with the properties of condensed liquid phase, which facilitates assembly of the CRY2-methyltransferase complex in the condensed liquid phase of CRY2 in vivo. The mta mutant impaired in m6A methyltransferase and the cry1cry2 mutant missing CRY photoreceptors share common defects of lengthened circadian period, reduced m6A RNA methylation, and accelerated degradation of mRNAs encoding core components of the molecular clock. These results argue for a photoentrainment mechanism by which blue light elicits liquid-liquid phase separation of the CRY2-methyltransferase complex to regulate m6A mRNA methylation, consequently suppressing mRNA degradation and period lengthening of the circadian clock

Project description:Light modulates expression of nuclear-encoded chloroplast proteins to promote chlorophyll biosynthesis and photosynthesis in plants. Photoregulatory mechanisms regulating transcription and protein stability of nuclear-encoded chloroplast proteins have been extensively studied, but how photoresponsive mRNA metabolism affecting chloroplast proteins remains not well understood. We performed a systematic analysis of the photoresponsive transcriptomes, m6A epitranscriptomes, translatomes, and proteomes in Arabidopsis, leading to a hypothesis that the blue light receptor cryptochromes activate the RNA methyltransferase, FIONA 1 (FIO1), to increase RNA methylation, translation of the nuclear-encoded chlorophyll synthesis enzymes (CSEs), and chlorophyll synthesis. We further demonstrate that the photoresponsive CRY2-interacting protein, SPA1, acts as a chaperone to mediate co-condensation of the CRY2/FIO1 complex, activating the FIO1 methyltransferase activity. This finding demonstrates a previously unknown photoregulatory mechanism controlling chlorophyll biosynthesis in plants.

Project description:Cryptochromes are blue-light receptors in plants and animals. Homodimers are the physiologically active form of plant cryptochromes that mediates blue light regulation of gene expression and photomorphogenesis, but how light regulates the photoreceptor activation and inactivation remains unclear. We identified an Arabidopsis protein BIC1 (Blue-light Inhibitor of Cryptochromes 1) that inhibits all photoreactions of plant cryptochrome 2 (CRY2) examined, allowing direct tests of the photoactivation and inactivation mechanisms of CRY2. We found that blue light stimulates homodimerization of CRY2, whereas BIC1 binds to CRY2 to suppress CRY2 dimerization and the interaction of CRY2 with its signaling partners. We further show that cryptochromes and phytochromes mediate light induction of BIC1 transcription, evoking the negative feedback circuitry to control homeostasis of the active cryptochromes under the broad spectra of solar radiation in nature.

Project description:Light is a crucial exogenous signal sensed by cryptochrome (CRY) blue light receptors to modulate growth and the circadian clock in plants and animals. However, how CRYs interpret light quantity to regulate growth in plants remains poorly understood. Furthermore, CRY2 protein levels and activity are tightly regulated in light to fine-tune hypocotyl growth; however, details of the mechanisms that explain precise control of CRY2 levels are not fully understood. We show that in Arabidopsis, UBP12 and UBP13 deubiquitinases physically interact with CRY2 in light. UBP12/13 negatively regulates CRY2 by promoting its ubiquitination and turnover to modulate hypocotyl growth. Growth and development were explicitly affected in blue light when UBP12/13 were disrupted or overexpressed, indicating their role alongside CRY2. UBP12/13 also interacted with and stabilized COP1, which is partially required for CRY2 turnover. Our combined genetic and molecular data support a mechanistic model in which UBP12/13 interact with CRY2 and COP1, leading to the stabilization of COP1. Stabilized COP1 then promotes the ubiquitination and degradation of CRY2 under blue light. Despite decades of studies on deubiquitinases, the knowledge of how their activity is regulated is limited. Our study provides insight into how exogenous signals and ligands, along with their receptors, regulate deubiquitinase activity by protein-protein interaction. Collectively, our results provide a framework of cryptochromes and deubiquitinases to detect and interpret light signals to control plant growth at the most appropriate time.

Project description:Total RNA was extracted from samples including dark-grown WT and tir1 afb123, blue light-grown WT and cry1 cry2 seedlings in continuous conditions for 4.5 days and subjected to high throughput sequencing. Light and auxin co-regulate a variety of developmental processes. This study reveals the molecular basis for light and auxin crosstalk by analyzing gene expression profile under control of both signals. mRNA from dark-grown WT, BL-grown WT, BL-grown BL photoreceptors, and dark-grown auxin receptors was sequenced to analyze the genes regulated by CRY-mediated BL signaling and TIR1/AFBs-mediated auxin signaling.

Project description:Cryptochromes are blue light receptors in plants and animals. m6A methyltransferase FIO1 and MTA interact with CRYs, here we show the RNA-seq data of cry1cry2, fio1 and mta mutants in dark and blue light.

Project description:Analysis of differential gene splicing and differential gene expression regulated by blue light. The hypothesis tested in the present study was that blue light regulated multiple genes splicing were mediated by CRY and CIS1

Project description:We have studied the transcriptional, metabolic and photo-physiological responses to light of different spectral quality in the marine diatom Phaeodactylum tricornutum through time-series studies of cultures exposed to equal doses of photosynthetically usable radiation of blue, green and red light. The experiments showed that short-term differences in gene expression and profiles are mainly light quality-dependent. Transcription of photosynthesis-associated nuclear genes was activated mainly through a light quality-independent mechanism likely to rely on chloroplast-to-nucleus signaling. In contrast, genes encoding proteins important for photoprotection and PSII repair were highly dependent on a blue light receptor-mediated signal. Changes in energy transfer efficiency by light-harvesting pigments were spectrally dependent; furthermore, a declining trend in photosynthetic efficiency was observed in red light. The combined results suggest that diatoms possess a light quality-dependent ability to activate photoprotection and efficient repair of photodamaged PSII. In spite of approximately equal numbers of PSII-absorbed quanta in blue, green and red light, the spectral quality of light is important for diatom responses to ambient light conditions.

Project description:Using m6A-seq, we present transcriptome-wide distribution of m6A in wild type, cry1 and cry1 cry2 seedlings with or without blue light treatment. Analysis of m6A distribution reveals CRY1 and CRY1 are involved blue light induced changes of m6A distribution in Arabidopsis