Comprehensive Modelling of the Neurospora Circadian Clock and Its Temperature Compensation

Circadian clocks provide an internal measure of external time allowing organisms to anticipate and exploit predictable daily changes in the environment. Rhythms driven by circadian clocks have a temperature compensated periodicity of approximately 24 hours that persists in constant conditions and can be reset by environmental time cues. Computational modelling has aided our understanding of the molecular mechanisms of circadian clocks, nevertheless it remains a major challenge to integrate the large number of clock components and their interactions into a single, comprehensive model that is able to account for the full breadth of clock phenotypes. Here we present a comprehensive dynamic model of the Neurospora crassa circadian clock that incorporates its key components and their transcriptional and post-transcriptional regulation. The model accounts for a wide range of clock characteristics including: a periodicity of 21.6 hours, persistent oscillation in constant conditions, arrhythmicity in constant light, resetting by brief light pulses, and entrainment to full photoperiods. Crucial components influencing the period and amplitude of oscillations were identified by control analysis. Furthermore, simulations enabled us to propose a mechanism for temperature compensation, which is achieved by simultaneously increasing the translation of frq RNA and decreasing the nuclear import of FRQ protein.

• Publication year

  2012

• Venue

  PLoS Comput. Biol.

• Publication date

  2012-03-01

• Fields of study

  Biology, Medicine, Computer Science, Environmental Science

• Identifiers
  DOI 10.1371/journal.pcbi.1002437PMID 22496627PMCID 3320131
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• Modelling the dual role of Per phosphorylation and its effect on the period and phase of the mammalian circadian clock.

  2011cited by this paper
• Temperature controls nuclear import of Tam3 transposase in Antirrhinum.

  2011cited by this paper
• Regulation of the Activity and Cellular Localization of the Circadian Clock Protein FRQ*

  2011cited by this paper
• Functional Significance of FRH in Regulating the Phosphorylation and Stability of Neurospora Circadian Clock Protein FRQ*

  2010cited by this paper
• The Role of the Arabidopsis Morning Loop Components CCA1, LHY, PRR7, and PRR9 in Temperature Compensation[W]

  2010cited by this paper
• Physical interaction between VIVID and white collar complex regulates photoadaptation in Neurospora

  2010cited by this paper
• Neurospora illuminates fungal photoreception.

  2010cited by this paper
• Photoadaptation in Neurospora by competitive interaction of activating and inhibitory LOV domains.

  2010influential reference
• VIVID interacts with the WHITE COLLAR complex and FREQUENCY-interacting RNA helicase to alter light and clock responses in Neurospora

  2010influential reference
• Synchronization of circadian oscillation of phosphorylation level of KaiC in vitro.

  2010cited by this paper
• The exosome regulates circadian gene expression in a posttranscriptional negative feedback loop.

  2009cited by this paper
• Phosphorylation modulates rapid nucleocytoplasmic shuttling and cytoplasmic accumulation of Neurospora clock protein FRQ on a circadian time scale.

  2009cited by this paper
• Circadian regulation of ion channels and their functions

  2009cited by this paper
• Delayed fluorescence as a universal tool for the measurement of circadian rhythms in higher plants.

  2009cited by this paper
• Activity of the circadian transcription factor White Collar Complex is modulated by phosphorylation of SP‐motifs

  2009cited by this paper
• Setting the pace of the Neurospora circadian clock by multiple independent FRQ phosphorylation events

  2009cited by this paper
• A role for casein kinase 2 in the mechanism underlying circadian temperature compensation.

  2009influential reference
• CKIε/δ-dependent phosphorylation is a temperature-insensitive, period-determining process in the mammalian circadian clock

  2009cited by this paper
• Simulating dark expressions and interactions of frq and wc-1 in the Neurospora circadian clock.

  2008influential reference
• Probing the Relative Importance of Molecular Oscillations in the Circadian Clock

  2008cited by this paper
• Circadian activity and abundance rhythms of the Neurospora clock transcription factor WCC associated with rapid nucleo-cytoplasmic shuttling.

  2008influential reference
• How a cyanobacterium tells time.

  2008cited by this paper
• Transcriptional regulation and function of the Neurospora clock gene white collar 2 and its isoforms

  2008influential reference
• Integrating Circadian Timekeeping with Cellular Physiology

  2008cited by this paper
• CellDesigner 3.5: A Versatile Modeling Tool for Biochemical Networks

  2008influential reference
• Molecular Circadian Rhythms in Central and Peripheral Clocks in Mammals

  2007cited by this paper
• The PAS/LOV protein VIVID controls temperature compensation of circadian clock phase and development in Neurospora crassa.

  2007influential reference
• Temperature compensation through systems biology

  2007cited by this paper
• A cyanobacterial circadian clock based on the Kai oscillator.

  2007cited by this paper
• ATPase activity of KaiC determines the basic timing for circadian clock of cyanobacteria

  2007cited by this paper
• The Neurospora crassa circadian clock.

  2007cited by this paper
• A circadian clock in Neurospora: how genes and proteins cooperate to produce a sustained, entrainable, and compensated biological oscillator with a period of about a day.

  2007cited by this paper
• Cyanobacterial circadian pacemaker: Kai protein complex dynamics in the KaiC phosphorylation cycle in vitro.

  2006cited by this paper
• How fungi keep time: circadian system in Neurospora and other fungi.

  2006cited by this paper
• CKI and CKII mediate the FREQUENCY-dependent phosphorylation of the WHITE COLLAR complex to close the Neurospora circadian negative feedback loop.

  2006cited by this paper
• Transcriptional and post-transcriptional regulation of the circadian clock of cyanobacteria and Neurospora.

  2006cited by this paper
• Transcriptional regulation of the Neurospora circadian clock gene wc‐1 affects the phase of circadian output

  2006cited by this paper
• Lithium Leads to an Increased FRQ Protein Stability and to a Partial Loss of Temperature Compensation in the Neurospora Circadian Clock

  2006cited by this paper
• The relationship between FRQ-protein stability and temperature compensation in the Neurospora circadian clock.

  2005influential reference
• Circadian rhythms from multiple oscillators: lessons from diverse organisms

  2005cited by this paper
• A model for the Neurospora circadian clock.

  2005cited by this paper
• Using process diagrams for the graphical representation of biological networks

  2005influential reference
• Transcriptional feedback of Neurospora circadian clock gene by phosphorylation-dependent inactivation of its transcription factor.

  2005cited by this paper
• Regulation of the Neurospora circadian clock by an RNA helicase.

  2005cited by this paper
• Degradation of the Neurospora circadian clock protein FREQUENCY through the ubiquitin-proteasome pathway.

  2005cited by this paper
• The PAS/LOV protein VIVID supports a rapidly dampened daytime oscillator that facilitates entrainment of the Neurospora circadian clock.

  2005cited by this paper
• Rhythmic binding of a WHITE COLLAR-containing complex to the frequency promoter is inhibited by FREQUENCY

  2003cited by this paper
• VIVID is a flavoprotein and serves as a fungal blue light photoreceptor for photoadaptation

  2003cited by this paper
• CellDesigner: a process diagram editor for gene-regulatory and biochemical networks

  2003influential reference
• White Collar-1, a Circadian Blue Light Photoreceptor, Binding to the frequency Promoter

  2002cited by this paper
• White Collar-1, a DNA Binding Transcription Factor and a Light Sensor

  2002cited by this paper
• Genetic and molecular analysis of circadian rhythms in Neurospora.

  2001cited by this paper
• Circadian regulation of the light input pathway in Neurospora crassa

  2001cited by this paper
• Interlocked feedback loops contribute to the robustness of the Neurospora circadian clock

  2001cited by this paper
• The PAS protein VIVID defines a clock-associated feedback loop that represses light input, modulates gating, and regulates clock resetting.

  2001influential reference
• A PEST‐like element in FREQUENCY determines the length of the circadian period in Neurospora crassa

  2001cited by this paper
• Circadian Clock-Specific Roles for the Light Response Protein WHITE COLLAR-2

  2001influential reference
• WC‐2 mediates WC‐1–FRQ interaction within the PAS protein‐linked circadian feedback loop of Neurospora

  2001cited by this paper
• Interconnected feedback loops in the Neurospora circadian system.

  2000cited by this paper
• Phosphorylation of the Neurospora clock protein FREQUENCY determines its degradation rate and strongly influences the period length of the circadian clock.

  2000cited by this paper
• Automated recordings of bioluminescence with special reference to the analysis of circadian rhythms.

  2000cited by this paper
• Forty years of PRCs--what have we learned?

  1999cited by this paper
• Limit Cycle Models for Circadian Rhythms Based on Transcriptional Regulation in Drosophila and Neurospora

  1999cited by this paper
• Molecular bases for circadian clocks.

  1999cited by this paper
• timrit Lengthens Circadian Period in a Temperature-Dependent Manner through Suppression of PERIOD Protein Cycling and Nuclear Localization

  1999cited by this paper
• How temperature changes reset a circadian oscillator.

  1998influential reference
• Alternative initiation of translation and time-specific phosphorylation yield multiple forms of the essential clock protein FREQUENCY.

  1997influential reference
• White collar 2, a partner in blue‐light signal transduction, controlling expression of light–regulated genes in Neurospora crassa

  1997cited by this paper
• White collar‐1, a central regulator of blue light responses in Neurospora, is a zinc finger protein.

  1996cited by this paper
• The Temperature-Compensated Goodwin Model Simulates Many Circadian Clock Properties

  1996cited by this paper
• Circadian rhythms and protein turnover: The effect of temperature on the period lengths of clock mutants simulated by the Goodwin oscillator

  1996cited by this paper
• Light-induced resetting of a circadian clock is mediated by a rapid increase in frequency transcript.

  1995cited by this paper
• Introducing temperature‐compensation in any reaction kinetic oscillator model

  1992cited by this paper
• Induction of growth arrest by a temperature-sensitive p53 mutant is correlated with increased nuclear localization and decreased stability of the protein

  1991influential reference
• Temperature Compensation of Circadian Period Length in Clock Mutants of Neurospora crassa.

  1981cited by this paper
• The geometry of biological time

  1980cited by this paper
• [4] Genetic and microbiological research techniques for Neurospora crassa

  1970cited by this paper
• The effects of light on a circadian rhythm of conidiation in neurospora.

  1967cited by this paper
• Effects of Temperature upon Diurnal Rhythms

  1960cited by this paper
• Effects of temperature upon diurnal rhythms.

  1960cited by this paper
• ON THE MECHANISM OF TEMPERATURE INDEPENDENCE IN A BIOLOGICAL CLOCK.

  1957cited by this paper
• ON TEMPERATURE INDEPENDENCE IN THE CLOCK SYSTEM CONTROLLING EMERGENCE TIME IN DROSOPHILA.

  1954cited by this paper
• Molecular Systems Biology 6; Article number 416; doi:10.1038/msb.2010.69 Citation: Molecular Systems Biology 6:416

  year unknowncited by this paper

• Unraveling circadian rhythms-computational insights into molecular mechanisms.

  2026cites this paper
• Clock Regulation and Fungal Physiology: Molecular Mechanisms Underpinning the Timely Control of Just About Everything.

  2025cites this paper
• Approximate constrained lumping of chemical reaction networks

  2025cites this paper
• Comparative mathematical modeling reveals the differential effects of high-fat diet and ketogenic diet on the PI3K-Akt signaling pathway in heart

  2024cites this paper
• Circadian regulation of metabolism across photosynthetic organisms

  2023cites this paper
• period Translation as a Core Mechanism Controlling Temperature Compensation in an Animal Circadian Clock

  2022cites this paper
• Data-driven modelling captures dynamics of the circadian clock of Neurospora crassa

  2022cites this paper
• A Unified Model for Entrainment by Circadian Clocks: Dynamic Circadian Integrated Response Characteristic (dCiRC)

  2021cites this paper
• Mechanisms Underlying the Complex Dynamics of Temperature Entrainment by a Circadian Clock

  2021cites this paper
• Circadian rhythm shows potential for mRNA efficiency and self-organized division of labor in multinucleate cells

  2021cites this paper
• On Periodic Oscillation and Its Period of a Circadian Rhythm Model

  2021cites this paper
• Principles underlying the complex dynamics of temperature entrainment by a circadian clock

  2021cites this paper
• On Periodic Oscillation and Its Period of a Circadian Rhythm Model

  2021cites this paper
• Rapid Circadian Entrainment in Models of Clock Gene Transcription

  2019cites this paper
• Non-sinusoidal Waveform in Temperature-Compensated Circadian Oscillations.

  2019cites this paper
• Rapid Circadian Entrainment in Models of Circadian Genes Regulation

  2019cites this paper
• ECHO: an Application for Detection and Analysis of Oscillators Identifies Metabolic Regulation on Genome-Wide Circadian Output

  2019cites this paper
• FRQ-CK1 interaction determines the period of circadian rhythms in Neurospora

  2019cites this paper
• Modeling the crosstalk between the circadian clock and ROS in Neurospora crassa.

  2018cites this paper
• Modeling Reveals a Key Mechanism for Light-Dependent Phase Shifts of Neurospora Circadian Rhythms.

  2018cites this paper
• Systems Biology-Derived Discoveries of Intrinsic Clocks

  2017cites this paper
• Evolution of circadian rhythms: from bacteria to human.

  2017cites this paper
• Cohesion: a method for quantifying the connectivity of microbial communities

  2017cites this paper
• Circadian Rhythms in Neurospora Exhibit Biologically Relevant Driven and Damped Harmonic Oscillations

  2017cites this paper
• Asynchronous τ-leaping.

  2016cites this paper
• How to stop a biological clock: Point of singularity

  2016cites this paper
• Protein sequestration versus Hill-type repression in circadian clock models.

  2016cites this paper
• Molecular and computational analysis of temperature compensation of the Neurospora crassa circadian clock

  2016influential citation
• How Light Resets Circadian Clocks

  2015cites this paper
• Circadian systems biology: When time matters

  2015cites this paper
• Rhythms, Clocks and Deterministic Chaos in Unicellular Organisms

  2015cites this paper
• Engineered temperature compensation in a synthetic genetic clock

  2014cites this paper
• Mathematical modeling of an oscillating gene circuit to unravel the circadian clock network of Arabidopsis thaliana

  2013cites this paper
• Analysing how the Arabidopsis circadian network responds to temperature

  2013cites this paper
• Exploring the genetic control of glycolytic oscillations in Saccharomyces Cerevisiae

  2012cites this paper