• DocumentCode
    2915144
  • Title

    Modeling diurnal rhythms with an array of phase dynamic oscillators

  • Author

    Wang, Wenxue ; Pakrasi, Himadri B. ; Ghosh, Bijoy K.

  • Author_Institution
    Dept. of Math. & Stat., Texas Tech Univ., Lubbock, TX
  • fYear
    2008
  • fDate
    17-20 Dec. 2008
  • Firstpage
    1391
  • Lastpage
    1396
  • Abstract
    Behavior of living organisms is strongly modulated by light especially by the day and night cycle giving rise to a cyclic pattern of activities. Such a pattern helps the organism to coordinate their activities and maintain a balance between what could be performed during the dasiadaypsila and what could be relegated to dasianightpsila. This cyclic pattern, called the dasiacircadian rhythmpsila, is a biological phenomenon observed in a large number of organisms ranging from unicellular bacteria to human beings and is present in data collected at various levels viz. transcriptome, proteome etc. In this paper, our goal is to analyze transcriptome data from cyanothece, a photosynthetic cyanobacteria, for the purpose of discovering genes whose expressions are rhythmic, especially those for which these rhythms have a 24 hours cycle. Subsequently we propose a model with a network of three phase oscillators for each one of the twenty four hours cycle. Each of the three phase oscillators is chosen to maintain a phase difference of 120 degrees between each other. All the oscillators are connected to an internal clock that is designed to maintain a phase activity close to a master clock derived using KaiC proteins. In cyanobacteria it is believed that the KaiC proteins provide the internal rhythm. The model parameters, viz. connection strengths between the master clock and peripheral oscillators and the parameters computing the linear combinations of the oscillator phase variables, are optimized to provide a close match to the observed gene expressions even when the frequency of the internal clock and the natural frequencies of the oscillators vary within a certain range. As a final step, the oscillator network model has been used to isolate genes, and hence the associated subprocesses, whose expression cycles are robust with respect to variations in the oscillator frequencies.
  • Keywords
    circadian rhythms; oscillators; physiological models; time series; biological phenomenon; cyanothece; diurnal rhythms modeling; gene expressions; oscillator network model; oscillator phase variables; peripheral oscillators; phase dynamic oscillators; photosynthetic cyanobacteria; three phase oscillators; Clocks; Frequency; Humans; Microorganisms; Optical modulation; Organisms; Oscillators; Phased arrays; Proteins; Rhythm; Circadian rhythm; Cyanothece; Diurnal cycle; Gene expression; KaiC protein; Microarray time series; Oscillator Network; Phase oscillation;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Control, Automation, Robotics and Vision, 2008. ICARCV 2008. 10th International Conference on
  • Conference_Location
    Hanoi
  • Print_ISBN
    978-1-4244-2286-9
  • Electronic_ISBN
    978-1-4244-2287-6
  • Type

    conf

  • DOI
    10.1109/ICARCV.2008.4795726
  • Filename
    4795726