{"database":"biostudies-other","file_versions":[],"scores":null,"additional":{"omics_type":["Unknown"],"volume":["7"],"submitter":["Lucian Smith"],"journal":["BMC systems biology"],"pagination":["23"],"species":["Arabidopsis thaliana"],"full_dataset_link":["https://www.ebi.ac.uk/biostudies/studies/MODEL1209110002"],"repository":["biostudies-other"],"additional_accession":["23506153"],"pubmed_authors":["Lucian Smith","Alexandra Pokhilko"]},"is_claimable":false,"name":"Pokhilko2013 - TOC1 signalling in Arabidopsis circadian clock","description":"<notes xmlns=\"http://www.sbml.org/sbml/level2/version4\">      <body xmlns=\"http://www.w3.org/1999/xhtml\">        <div class=\"dc:title\">Pokhilko2013 - TOC1 signalling in Arabidopsiscircadian clock</div><div class=\"dc:description\">  <p>In this model, Pokhilko   <em>et al.</em> has incorporated the negative transcriptional  regulations of the core clock genes by TOC1 and the up-regulation  of TOC1 expression by ABA signalling, to their previous model   <a href=\"http://identifiers.org/biomodels.db/BIOMD0000000412\">BIOMD0000000412</a></p></div><div class=\"dc:bibliographicCitation\">  <p>This model is described in the article:</p>  <div class=\"bibo:title\">    <a href=\"http://identifiers.org/pubmed/23506153\" title=\"Access to this publication\">Modelling the widespread    effects of TOC1 signalling on the plant circadian clock and its    outputs.</a>  </div>  <div class=\"bibo:authorList\">Pokhilko A, Mas P, Millar AJ.</div>  <div class=\"bibo:Journal\">BMC Syst Biol 2013; 7: 23</div>  <p>Abstract:</p>  <div class=\"bibo:abstract\">    <p>BACKGROUND: 24-hour biological clocks are intimately    connected to the cellular signalling network, which complicates    the analysis of clock mechanisms. The transcriptional regulator    TOC1 (TIMING OF CAB EXPRESSION 1) is a founding component of    the gene circuit in the plant circadian clock. Recent results    show that TOC1 suppresses transcription of multiple target    genes within the clock circuit, far beyond its    previously-described regulation of the morning transcription    factors LHY (LATE ELONGATED HYPOCOTYL) and CCA1 (CIRCADIAN    CLOCK ASSOCIATED 1). It is unclear how this pervasive effect of    TOC1 affects the dynamics of the clock and its outputs. TOC1    also appears to function in a nested feedback loop that    includes signalling by the plant hormone Abscisic Acid (ABA),    which is upregulated by abiotic stresses, such as drought. ABA    treatments both alter TOC1 levels and affect the clock's timing    behaviour. Conversely, the clock rhythmically modulates    physiological processes induced by ABA, such as the closing of    stomata in the leaf epidermis. In order to understand the    dynamics of the clock and its outputs under changing    environmental conditions, the reciprocal interactions between    the clock and other signalling pathways must be integrated.    RESULTS: We extended the mathematical model of the plant clock    gene circuit by incorporating the repression of multiple clock    genes by TOC1, observed experimentally. The revised model more    accurately matches the data on the clock's molecular profiles    and timing behaviour, explaining the clock's responses in TOC1    over-expression and toc1 mutant plants. A simplified    representation of ABA signalling allowed us to investigate the    interactions of ABA and circadian pathways. Increased ABA    levels lengthen the free-running period of the clock,    consistent with the experimental data. Adding stomatal closure    to the model, as a key ABA- and clock-regulated downstream    process allowed to describe TOC1 effects on the rhythmic gating    of stomatal closure. CONCLUSIONS: The integrated model of the    circadian clock circuit and ABA-regulated environmental sensing    allowed us to explain multiple experimental observations on the    timing and stomatal responses to genetic and environmental    perturbations. These results crystallise a new role of TOC1 as    an environmental sensor, which both affects the pace of the    central oscillator and modulates the kinetics of downstream    processes.</p>  </div></div><div class=\"dc:publisher\">  <p>This model is hosted on   <a href=\"http://www.ebi.ac.uk/biomodels/\">BioModels Database</a>  and identified by:   <a href=\"http://identifiers.org/biomodels.db/BIOMD0000000445\">BIOMD0000000445</a>.</p>  <p>To cite BioModels Database, please use:   <a href=\"http://identifiers.org/pubmed/20587024\" title=\"Latest BioModels Database publication\">BioModels Database:  An enhanced, curated and annotated resource for published  quantitative kinetic models</a>.</p></div><div class=\"dc:license\">  <p>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   <a href=\"http://creativecommons.org/publicdomain/zero/1.0/\" title=\"Access to: CC0 1.0 Universal (CC0 1.0), Public Domain Dedication\">CC0  Public Domain Dedication</a> for more information.</p></div></body>    </notes>","dates":{"release":"2012-09-11T00:00:00Z","modification":"2025-07-15T10:04:48.466Z","creation":"2025-03-29T12:42:53.905Z"},"accession":"MODEL1209110002","cross_references":{"biomodels___db":["BIOMD0000000445","BIOMD0000000412"],"pubmed":["23506153"],"mod":["MOD:00000"],"chebi":["CHEBI:33699"],"mamo":["MAMO_0000046"],"go":["GO:0005623","GO:0005634","GO:0009299","GO:0006461","GO:0005737","GO:0030163","GO:0015031","GO:0042752","GO:0006402","GO:0003575","GO:0006412","GO:0031401"],"taxonomy":["3702"],"bto":["BTO:0000316"],"uniprot":["Q9LVG4","Q8L500","Q9FNB0","Q93WK5","Q940H6","O82804","Q94BT6","Q9SQI2","Q6LA42","P92973","Q9LKL2","F4J959","O04211","Q9CAJ0","P43254","Q6R0H1"],"cco":["CCO:U0000010"]}}