Project description:Wild tobacco flowers wave rhythmically to facilitate specific pollinator interactions. This movement behavior is controlled by a regulatory network that involves the circadian clock- and auxin-signaling pathways. The plant hormone auxin, similarly to its function in tropic movements, acts as growth regulator in the circadian regulation of floral movement. Dorsoventral asymmetry in auxin levels and auxin transcriptional responses mediate the growth responses in the floral peduncle that make flowers move. Multiple components of the auxin-signaling pathway and auxin responses are under the control of circadian clock. However, it is unclear where these two pathways intersect and how collectively contribute to regulate specific rhythmic outputs. Here we found that the blue light photoreceptor and circadian clock component ZEITLUPE (ZTL) controls auxin responses through the regulation of the auxin-signaling pathway in a time-of-day and blue light specific manner. Abrogation of ZTL expression abolishes flower movement and the temporal gating of auxin-induced growth responses in the floral peduncle. ZTL regulates transcription and directly interacts with indole-3-acetic acid inducible 19 (IAA19), a circadian controlled gene that regulates development of curvature in moving organs. Indicating that ZTL modulates auxin sensitivity in part through the regulation of AUX/IAA transcriptional repressors. At night, growth responses in the peduncle to the synthetic auxin 2,4-D revealed that ZTL additionally controls auxin responses regulating auxin homeostasis. These results indicate that ZTL conveys temporal and environmental information, at multiple levels, into the auxin signaling-pathway and in this way sculpts the temporal gating of auxin responses that allow flowers to move. To gain further insight into the molecular basis of temporal regulation of the movement of flowers we used a whole genome microarray as a discovery platform to identify genes differentially expressed in a RNAi knockdown line silenced in the expression of the circadian clock component ZEITLUPE (irZTL-314).

Project description:Wild tobacco flowers wave rhythmically to facilitate specific pollinator interactions. This movement behavior is controlled by a regulatory network that involves the circadian clock- and auxin-signaling pathways. The plant hormone auxin, similarly to its function in tropic movements, acts as growth regulator in the circadian regulation of floral movement. Dorsoventral asymmetry in auxin levels and auxin transcriptional responses mediate the growth responses in the floral peduncle that make flowers move. Multiple components of the auxin-signaling pathway and auxin responses are under the control of circadian clock. However, it is unclear where these two pathways intersect and how collectively contribute to regulate specific rhythmic outputs. Here we found that the blue light photoreceptor and circadian clock component ZEITLUPE (ZTL) controls auxin responses through the regulation of the auxin-signaling pathway in a time-of-day and blue light specific manner. Abrogation of ZTL expression abolishes flower movement and the temporal gating of auxin-induced growth responses in the floral peduncle. ZTL regulates transcription and directly interacts with indole-3-acetic acid inducible 19 (IAA19), a circadian controlled gene that regulates development of curvature in moving organs. Indicating that ZTL modulates auxin sensitivity in part through the regulation of AUX/IAA transcriptional repressors. At night, growth responses in the peduncle to the synthetic auxin 2,4-D revealed that ZTL additionally controls auxin responses regulating auxin homeostasis. These results indicate that ZTL conveys temporal and environmental information, at multiple levels, into the auxin signaling-pathway and in this way sculpts the temporal gating of auxin responses that allow flowers to move. To gain further insight into the molecular basis of the movement of flowers we used a whole genome microarray as a discovery platform to identify genes differentially expressed in adaxial and abaxial sides of the floral peduncle at different stages of the movement.

Project description:The circadian clock is comprised of proteins that form negative feedback loops, which regulate the timing of global gene expression in a coordinated 24 hour cycle. As a result, the plant circadian clock is responsible for regulating numerous physiological processes central to growth and survival. To date, most plant circadian clock studies have relied on diurnal transcriptome changes to elucidate molecular connections between the circadian clock and observable phenotypes in wild-type plants. Here, we have combined high-throughput RNA-sequencing and mass spectrometry to comparatively characterize the lhycca1, prr7prr9, gi and toc1 circadian clock mutant rosette transcriptome and proteome at the end-of-day and end-of-night.

Project description:The circadian clock represents a critical regulatory network, which allows plants to anticipate environmental changes as inputs and promote plant survival by regulating various physiological outputs. Here, we examine the function of the clock-regulated transcription factor, CYCLING DOF FACTOR 6 (CDF6), during cold stress in Arabidopsis thaliana. We found that the clock gates CDF6 transcript accumulation in the vasculature during cold stress. CDF6 mis-expression results in an altered flowering phenotype during both ambient and cold stress. A genome-wide transcriptome analysis links CDF6 to genes associated with flowering and seed germination during cold and ambient temperatures, respectively. Analysis of key floral regulators indicates that CDF6 alters flowering during cold stress by repressing photoperiodic flowering components, FLOWERING LOCUS T (FT), CONSTANS (CO), and BROTHER OF FT (BFT). Gene ontology enrichment further suggests that CDF6 regulates circadian and developmental associated genes. These results provide insight into how the clock-controlled CDF6 modulates plant development during moderate cold stress.

Project description:Plants are sessile organisms that have acquired highly plastic developmental strategies to adapt to the environment. Among these processes, the floral transition is essential to ensure reproductive success and is finely regulated by several internal and external genetic networks. The photoperiodic pathway, which controls the plant response to day length, is one of the most important pathways controlling flowering. In Arabidopsis photoperiodic flowering, CONSTANS (CO) is the central gene activating the expression of the florigen FLOWERING LOCUS T (FT) in the leaves at the end of a long day. CO expression is strongly regulated by the circadian clock. However, to date, no evidence has been reported regarding a feedback loop from the photoperiod pathway back to the circadian clock. Using transcriptional networks, we have identified relevant network motifs regulating the interplay between the circadian clock and the photoperiod pathway. Gene expression, chromatin immunoprecipitation experiments and phenotypic analysis allowed us to elucidate the role of CO over the circadian clock. Plants with altered CO expression showed a different internal clock period, measured by daily rhythmic movements in the leaves. We show that CO is able to activate key genes related to the circadian clock, such as CCA1, LHY, PRR5 and GI, at the end of a long day by binding to specific sites on their promoters. Moreover, a significant number of PRR5 repressed target genes are upregulated by CO, and this could explain the phase transition promoted by CO. The CO-PRR5 complex interacts with the bZIP transcription factor HY5 and helps to localize the complex in the promoters of clock genes. Our results indicate that there may be a feedback loop in which CO communicates back to the circadian clock, feeding seasonal information to the circadian system.

Project description:Chinese narcissus is well-known monocot plants with beautiful color, fresh and sweet floral scent. A lack of transcriptomic and genomic information hinders our understanding of the molecular mechanisms of narcissus floral scent volatiles biosynthesis. Hence, we hypothesized the functions of the significant differentially expressed genes (DEGs) identified using Illumina RNA-Seq technology, according to public protein annotation databases in this study.

Project description:Gould2011 - Temperature Sensitive Circadian Clock This model is a temperature sensitive version of Pokhilko et al.  2010 (PMID: 20865009), which is BIOMD0000000273 in BioModels. This model is described in the article: Network balance via CRY signalling controls the Arabidopsis circadian clock over ambient temperatures. Gould PD, Ugarte N, Domijan M, Costa M, Foreman J, Macgregor D, Rose K, Griffiths J, Millar AJ, Finkenstädt B, Penfield S, Rand DA, Halliday KJ, Hall AJ. Mol. Syst. Biol. 2013; 9: 650 Abstract: Circadian clocks exhibit 'temperature compensation', meaning that they show only small changes in period over a broad temperature range. Several clock genes have been implicated in the temperature-dependent control of period in Arabidopsis. We show that blue light is essential for this, suggesting that the effects of light and temperature interact or converge upon common targets in the circadian clock. Our data demonstrate that two cryptochrome photoreceptors differentially control circadian period and sustain rhythmicity across the physiological temperature range. In order to test the hypothesis that the targets of light regulation are sufficient to mediate temperature compensation, we constructed a temperature-compensated clock model by adding passive temperature effects into only the light-sensitive processes in the model. Remarkably, this model was not only capable of full temperature compensation and consistent with mRNA profiles across a temperature range, but also predicted the temperature-dependent change in the level of LATE ELONGATED HYPOCOTYL, a key clock protein. Our analysis provides a systems-level understanding of period control in the plant circadian oscillator. This model is hosted on BioModels Database and identified by: BIOMD0000000564. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Costus floral scent transcriptomics

Project description:Floral Scent Gynandropsis gynandra

Project description:Plants are sessile organisms that have acquired highly plastic developmental strategies to adapt to the environment. Among these processes, the floral transition is essential to ensure reproductive success and is finely regulated by several internal and external genetic networks. The photoperiodic pathway, which controls the plant response to day length, is one of the most important pathways controlling flowering. In Arabidopsis photoperiodic flowering, CONSTANS (CO) is the central gene activating the expression of the florigen FLOWERING LOCUS T (FT) in the leaves at the end of a long day. CO expression is strongly regulated by the circadian clock. However, to date, no evidence has been reported regarding a feedback loop from the photoperiod pathway back to the circadian clock. Using transcriptional networks, we have identified relevant network motifs regulating the interplay between the circadian clock and the photoperiod pathway. Gene expression, chromatin immunoprecipitation experiments and phenotypic analysis allowed us to elucidate the role of CO over the circadian clock. Plants with altered CO expression showed a different internal clock period, measured by daily rhythmic movements in the leaves. We show that CO is able to activate key genes related to the circadian clock, such as CCA1, LHY, PRR5 and GI, at the end of a long day by binding to specific sites on their promoters. Moreover, a significant number of PRR5 repressed target genes are upregulated by CO, and this could explain the phase transition promoted by CO. The CO-PRR5 complex interacts with the bZIP transcription factor HY5 and helps to localize the complex in the promoters of clock genes. Our results indicate that there may be a feedback loop in which CO communicates back to the circadian clock, feeding seasonal information to the circadian system.