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Molecular Bases for Circadian Clocks

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Presentation on theme: "Molecular Bases for Circadian Clocks"— Presentation transcript:

1 Molecular Bases for Circadian Clocks
Jay C Dunlap  Cell  Volume 96, Issue 2, Pages (January 1999) DOI: /S (00)

2 Figure 1 Circadian Systems in the Universal Tree of Life
Shown is an unrooted universal phylogenetic framework reflecting a maximum-likelihood analysis for the relationships among living things. Line segment lengths correspond to evolutionary distance as measured by rates of change in small subunit rRNA genes (Sogin 1994). The three major assemblages of organisms, Archaebacteria, Eubacteria, and Eukaryota, diverge from a single ancestor. The portion of the tree representing the “Crown Eukaryotes” that emerged (relatively) rapidly about half a billion years ago is reproduced in greater detail in the upper left. Shown in blue are phylogenetic groups where circadian rhythms have been described and/or that correspond to the well-studied experimental circadian systems, and in red are given the names and placements of those systems where the genetic and molecular analysis of clock mechanism has progressed significantly. Cell  , DOI: ( /S (00) )

3 Figure 2 Common Elements in the Design of Circadian Oscillatory Loops
Cell  , DOI: ( /S (00) )

4 Figure 3 Identity and Regulation of Elements in the Synechococcus Clock (Top) Temporal regulation of the kai genes. Yellow, positive element; blue, negative element. (Bottom) Elements in the regulatory network comprising the core oscillator in Synechococcus. Cell  , DOI: ( /S (00) )

5 Figure 4 Identity and Regulation of Elements in the Neurospora Oscillator and Their Roles in Entrainment (A) Temporal regulation of the frq gene and the large (lFRQ) and small (sFRQ) proteins. Here, as in subsequent figures, shades of blue denote negative elements in the oscillator, and yellow denotes positive elements. Thin lines correspond to mRNA and thick lines to protein. Care has been taken concerning the relative amplitude of the oscillation and in the timing of peaks. (B) How light resets the Neurospora clock. Light rapidly transcriptionally induces the frq gene. If frq mRNA levels are already slowly rising, this rapid induction results in an advance into the day phase; if frq mRNA levels are slowly falling, this rapid increase results in a delay back to the day phase. (C) How temperature resets the Neurospora clock. Yellow lines follow the cycle of FRQ protein levels through the day at low temperature (lower curve) and at higher temperatures (upper curve) within the physiological range; red arrows track the effect of temperature steps up, and blue arrows track steps down. For steps up, all the points on the lower temperature curve are low compared to the high-temperature curve, so the clock is reset to the time corresponding to the low point in FRQ—near to subjective dawn. For steps down, the reverse is true: all the points on the higher temperature curve are high compared to the low-temperature curve, so the clock is reset to the time corresponding to the high point in FRQ—late day to subjective dusk. (D) Elements and control logic in the circadian oscillatory loop of Neurospora. Arrows denote positive regulation, and lines terminating in bars denote negative regulation. CCRE, circadian clock regulatory element. Cell  , DOI: ( /S (00) )

6 Figure 5 Identity and Regulation of Elements in the Drosophila Oscillator and Their Roles in Entrainment (A) Temporal regulation of the per, tim, Clk, and cyc genes and proteins. Care has been taken concerning the relative amplitude of the oscillation and in the timing of peaks. (B) How light resets the Drosophila clock. Light results in the rapid destruction of TIM whose loss destabilizes PER. If TIM levels are already slowly rising, this rapid loss results in a delay back to the previous day phase; if TIM levels are slowly falling, this rapid loss results in an advance into the next day phase. (C) Elements and control logic in the circadian oscillatory loop of Drosophila. Arrows denote positive regulation, and lines terminating in bars denote negative regulation. Cell  , DOI: ( /S (00) )

7 Figure 6 Identity and Regulation of Elements in the Mammalian Oscillator and Their Roles in Entrainment (A) Temporal regulation of the Per1, Per2, Per3, tim, Clock, and bmal1(mop3) genes. (B) How light resets the mammalian clock. Light results in the induction of Per1 and Per2 but to different extents at different times, so the effect of light on the clock components and therefore on the clock is very much influenced by the time of day; see text for details. (C) Elements and control logic in the circadian oscillatory loop of mammals. Arrows denote positive regulation, and lines terminating in bars denote negative regulation. Dashed lines indicate possible regulatory connections. Cell  , DOI: ( /S (00) )

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