Project description:The members of the phytochrome (phy) family of bilin-containing photoreceptors are major regulators of plant photomorphogenesis through their unique ability to photointerconvert between a biologically inactive red light-absorbing Pr state and an active far-red light-absorbing Pfr state. While the initial steps in Pfr signaling are unclear, an early event for the phyB isoform after photoconversion is its redistribution from the cytoplasm into subnuclear foci known as photobodies (PBs), which dissipate after Pfr reverts back to Pr by far-red irradiation or by temperature-dependent nonphotochemical reversion. Here we present evidence that PHOTOPERIODIC CONTROL OF HYPOCOTYL 1 (PCH1) functions both as an essential structural component of phyB-containing PBs and as a direct regulator of thermal reversion that is sufficient to stabilize phyB as Pfr in vitro. By examining the genetic interaction between a constitutively active phyBY276H-YFP allele (YHB-YFP) and PCH1, we show that the loss of PCH1 prevents YHB from coalescing into PBs without affecting its nuclear localization, whereas overexpression of PCH1 dramatically increases PB levels. Loss of PCH1, presumably by impacting phyB-PB assembly, compromises a number of events elicited in YHB-YFP plants, including their constitutive photomorphogenic phenotype, red light-regulated thermomorphogenesis, and input of phyB into the circadian clock. Conversely, elevated levels of both phyB and PCH1 generate stable, yet far-red light-reversible PBs that persisted for days. Collectively, our data demonstrate that the assembly of PCH1-containing PBs is critical for phyB signaling to multiple outputs and suggest that altering PB dynamics could be exploited to modulate plant responses to light and temperature.

Project description:Tissue-specific functions of the circadian clock in Arabidopsis have recently been revealed. The vasculature clock shows distinctive gene expression profiles compared to the clock in other tissues under light-dark cycles. However, it has not yet been established whether the vasculature clock also shows unique gene expression patterns that correlate with temperature cycles, another important environmental cue. Here, we detected diel phase of TIMING OF CAB EXPRESSION 1 (TOC1) expression in the vasculature and whole leaf under long-day light-dark cycles and temperature cycles. We found that the vasculature clock had advanced TOC1 phase under light-dark cycles but not under temperature cycles, suggesting that the vasculature clock has lower sensitivity against temperature signals. Furthermore, the phase advancement of TOC1 was seen only under long-day condition but not under short-day condition. These results support our previous conclusion that the circadian clock in vasculature preferentially senses photoperiodic signals.

Project description:The circadian pacemaker in the suprachiasmatic nucleus (SCN) yields photoperiodic response to transfer seasonal information to physiology and behavior. To identify the precise location involved in photoperiodic response in the SCN, we analyzed circadian Period1 and PERIOD2 rhythms in horizontally sectioned SCN of mice exposed to a long or short day. Statistical analyses of bioluminescence images with respective luciferase reporters on pixel level enabled us to identify the distinct localization of three oscillating regions; a large open-ring-shape region, the region at the posterior end and a sharply demarcated oval region at the center of the SCN. The first two regions are the respective sites for the so-called evening and morning oscillators, and the third region is possibly a site for mediating photic signals to the former oscillators. In these regions, there are two classes of oscillating cells in which Per1 and Per2 could play differential roles in photoperiodic responses.

Project description:Clock-regulated pathways coordinate the response of many developmental processes to changes in photoperiod and temperature. We model two of the best-understood clock output pathways in Arabidopsis, which control key regulators of flowering and elongation growth. In flowering, the model predicted regulatory links from the clock to cycling DOF factor 1 (CDF1) and flavin-binding, KELCH repeat, F-box 1 (FKF1) transcription. Physical interaction data support these links, which create threefold feed-forward motifs from two clock components to the floral regulator FT. In hypocotyl growth, the model described clock-regulated transcription of phytochrome-interacting factor 4 and 5 (PIF4, PIF5), interacting with post-translational regulation of PIF proteins by phytochrome B (phyB) and other light-activated pathways. The model predicted bimodal and end-of-day PIF activity profiles that are observed across hundreds of PIF-regulated target genes. In the response to temperature, warmth-enhanced PIF4 activity explained the observed hypocotyl growth dynamics but additional, temperature-dependent regulators were implicated in the flowering response. Integrating these two pathways with the clock model highlights the molecular mechanisms that coordinate plant development across changing conditions.

Project description:In response to environmental light signals, transcriptomic adjustment plays an important role in Arabidopsis seed germination and seedling development. G-box cis-element is commonly present in promoters of genes positively or negatively responding to the light signal. For the pursuit of additional transcriptional regulator modulating light-mediated transcriptome changes, we have identified AtbZIP16, a basic region/leucine zipper motif transcription factor, via G-box DNA affinity chromatography. We have confirmed that AtbZIP16 possesses G-box-specific binding activity. Analyses of atbzip16 mutants indicate that AtbZIP16 is a negative regulator in phyB-mediated inhibition of cell elongation, but a positive regulator in phytochrome-mediated seed germination process. Transcriptomic analysis supports that AtbZIP16 is primarily a transcriptional repressor regulating light-, GA- and ABA-responsive genes. Chromatin immunoprecipitation study revealed that AtbZIP16 could directly target RGL2, a DELLA gene, and indirectly repress the expression of PIL5 gene, which encodes a bHLH protein inhibiting seed germination in Arabidopsis. Our study indicated that, through repressing the expression of RGL2 and the antagonizing the expression of PIL5, AtbZIP16 functions to promote seed germination and hypocotyl elongation during early stages of Arabidopsis seedling development. In response to environmental light signals, transcriptomic adjustment plays an important role in Arabidopsis seed germination and seedling development. G-box cis-element is commonly present in promoters of genes positively or negatively responding to the light signal. For the pursuit of additional transcriptional regulator modulating light-mediated transcriptome changes, we have identified AtbZIP16, a basic region/leucine zipper motif transcription factor, via G-box DNA affinity chromatography. We have confirmed that AtbZIP16 possesses G-box-specific binding activity. Analyses of atbzip16 mutants indicate that AtbZIP16 is a negative regulator in phyB-mediated inhibition of cell elongation, but a positive regulator in phytochrome-mediated seed germination process. Transcriptomic analysis supports that AtbZIP16 is primarily a transcriptional repressor regulating light-, GA- and ABA-responsive genes. Chromatin immunoprecipitation study revealed that AtbZIP16 could directly target RGL2, a DELLA gene, and indirectly repress the expression of PIL5 gene, which encodes a bHLH protein inhibiting seed germination in Arabidopsis. Our study indicated that, through repressing the expression of RGL2 and the antagonizing the expression of PIL5, AtbZIP16 functions to promote seed germination and hypocotyl elongation during early stages of Arabidopsis seedling development.

Project description:Circadian clocks regulate many aspects of plant physiology and development that contribute to essential agronomic traits. Circadian clocks contain transcriptional feedback loops that are thought to generate circadian timing. There is considerable similarity in the genes that comprise the transcriptional and translational feedback loops of the circadian clock in the plant Kingdom. Functional characterisation of circadian clock genes has been restricted to a few model species. Here we provide a functional characterisation of the Hordeum vulgare (barley) circadian clock genes Hv circadian clock associated 1 (HvCCA1) and Hv photoperiodh1, which are respectively most similar to Arabidopsis thaliana circadian clock associated 1 (AtCCA1) and pseudo response regulator 7 (AtPRR7). This provides insight into the circadian regulation of one of the major crop species of Northern Europe. Through a combination of physiological assays of circadian rhythms in barley and heterologous expression in wild type and mutant strains of A. thaliana we demonstrate that HvCCA1 has a conserved function to AtCCA1. We find that Hv photoperiod H1 has AtPRR7-like functionality in A. thaliana and that the effects of the Hv photoperiod h1 mutation on photoperiodism and circadian rhythms are genetically separable.

Project description:The translation of mRNA into protein is tightly regulated by the light environment as well as by the circadian clock. Although changes in translational efficiency have been well documented at the level of mRNA-ribosome loading, the underlying mechanisms are unclear. The reversible phosphorylation of RIBOSOMAL PROTEIN OF THE SMALL SUBUNIT 6 (RPS6) has been known for 40 years, but the biochemical significance of this event remains unclear to this day. Here, we confirm using a clock-deficient strain of Arabidopsis thaliana that RPS6 phosphorylation (RPS6-P) is controlled by the diel light-dark cycle with a peak during the day. Strikingly, when wild-type, clock-enabled, seedlings that have been entrained to a light-dark cycle are placed under free-running conditions, the circadian clock drives a cycle of RPS6-P with an opposite phase, peaking during the subjective night. We show that in wild-type seedlings under a light-dark cycle, the incoherent light and clock signals are integrated by the plant to cause an oscillation in RPS6-P with a reduced amplitude with a peak during the day. Sucrose can stimulate RPS6-P, as seen when sucrose in the medium masks the light response of etiolated seedlings. However, the diel cycles of RPS6-P are observed in the presence of 1% sucrose and in its absence. Sucrose at a high concentration of 3% appears to interfere with the robust integration of light and clock signals at the level of RPS6-P. Finally, we addressed whether RPS6-P occurs uniformly in polysomes, non-polysomal ribosomes and their subunits, and non-ribosomal protein. It is the polysomal RPS6 whose phosphorylation is most highly stimulated by light and repressed by darkness. These data exemplify a striking case of contrasting biochemical regulation between clock signals and light signals. Although the physiological significance of RPS6-P remains unknown, our data provide a mechanistic basis for the future understanding of this enigmatic event.

Project description:Light is the most important environmental cue to entrain the circadian clock in most animals. In the fruit fly Drosophila melanogaster, the light entrainment mechanisms of the clock have been well-studied. The Drosophila brain contains approximately 150 neurons that rhythmically express circadian clock genes. These neurons are called "clock neurons" and control behavioral activity rhythms. Many clock neurons express the Cryptochrome (CRY) protein, which is sensitive to UV and blue light, and thus enables clock neurons deep in the brain to directly perceive light. In addition to the CRY protein, external photoreceptors in the Drosophila eyes play an important role in circadian light-input pathways. Recent studies have provided new insights into the mechanisms that integrate these light inputs into the circadian network of the brain. In this review, we will summarize the current knowledge on the light entrainment pathways in the Drosophila circadian clock.

Project description:Plant growth is driven by photosynthetic carbon fixation during the day. Some photosynthate is accumulated, often as starch, to support nocturnal metabolism and growth at night. The rate of starch degradation in Arabidopsis leaves at night is essentially linear, and is such that almost all of the starch is used by dawn. We have investigated the timer that matches starch utilization to the duration of the night. The rate of degradation adjusted immediately and appropriately to an unexpected early onset of night. Starch was still degraded in an appropriate manner when the preceding light period was interrupted by a period of darkness. However, when Arabidopsis was grown in abnormal day lengths (28 h or 17 h) starch was exhausted approximately 24 h after the last dawn, irrespective of the actual dawn. A mutant lacking the LHY and CCA1 clock components exhausted its starch at the dawn anticipated by its fast-running circadian clock, rather than the actual dawn. Reduced growth of wild-type plants in 28-h days and lhy/cca1 mutants in 24-h days was attributable to the inappropriate rate of starch degradation and the consequent carbon starvation at the end of night. Thus, starch degradation is under circadian control to ensure that carbohydrate availability is maintained until the next anticipated dawn, and this control is necessary for maintaining plant productivity.

Project description:In response to environmental light signals, transcriptomic adjustment plays an important role in Arabidopsis seed germination and seedling development. G-box cis-element is commonly present in promoters of genes positively or negatively responding to the light signal. For the pursuit of additional transcriptional regulator modulating light-mediated transcriptome changes, we have identified AtbZIP16, a basic region/leucine zipper motif transcription factor, via G-box DNA affinity chromatography. We have confirmed that AtbZIP16 possesses G-box-specific binding activity. Analyses of atbzip16 mutants indicate that AtbZIP16 is a negative regulator in phyB-mediated inhibition of cell elongation, but a positive regulator in phytochrome-mediated seed germination process. Transcriptomic analysis supports that AtbZIP16 is primarily a transcriptional repressor regulating light-, GA- and ABA-responsive genes. Chromatin immunoprecipitation study revealed that AtbZIP16 could directly target RGL2, a DELLA gene, and indirectly repress the expression of PIL5 gene, which encodes a bHLH protein inhibiting seed germination in Arabidopsis. Our study indicated that, through repressing the expression of RGL2 and the antagonizing the expression of PIL5, AtbZIP16 functions to promote seed germination and hypocotyl elongation during early stages of Arabidopsis seedling development. In response to environmental light signals, transcriptomic adjustment plays an important role in Arabidopsis seed germination and seedling development. G-box cis-element is commonly present in promoters of genes positively or negatively responding to the light signal. For the pursuit of additional transcriptional regulator modulating light-mediated transcriptome changes, we have identified AtbZIP16, a basic region/leucine zipper motif transcription factor, via G-box DNA affinity chromatography. We have confirmed that AtbZIP16 possesses G-box-specific binding activity. Analyses of atbzip16 mutants indicate that AtbZIP16 is a negative regulator in phyB-mediated inhibition of cell elongation, but a positive regulator in phytochrome-mediated seed germination process. Transcriptomic analysis supports that AtbZIP16 is primarily a transcriptional repressor regulating light-, GA- and ABA-responsive genes. Chromatin immunoprecipitation study revealed that AtbZIP16 could directly target RGL2, a DELLA gene, and indirectly repress the expression of PIL5 gene, which encodes a bHLH protein inhibiting seed germination in Arabidopsis. Our study indicated that, through repressing the expression of RGL2 and the antagonizing the expression of PIL5, AtbZIP16 functions to promote seed germination and hypocotyl elongation during early stages of Arabidopsis seedling development. Three biological replicates for 4-d-old seedlings grown under dark or red-light and long-day (0.5 ?mole m-2 sec-1) contitions.