Abstract
This review describes common features among diverse biological clocks in insects, including circadian, circatidal, circalunar/circasemilunar, and circannual clocks. These clocks control various behaviors, physiological functions, and developmental events, enabling adaptation to periodic environmental changes. Circadian clocks also function in time-compensation for celestial navigation and in the measurement of day or night length for photoperiodism. Phase response curves for such clocks reported thus far exhibit close similarities; specifically, the circannual clock in Anthrenus verbasci shows striking similarity to circadian clocks in its phase response. It is suggested that diverse biological clocks share physiological properties in their phase responses irrespective of period length. Molecular and physiological mechanisms are best understood for the optic-lobe and mid-brain circadian clocks, although there is no direct evidence that these clocks are involved in rhythmic phenomena other than circadian rhythms in daily events. Circadian clocks have also been localized in peripheral tissues, and research on their role in various rhythmic phenomena has been started. Although clock genes have been identified as controllers of circadian rhythms in daily events, some of these genes have also been shown to be involved in photoperiodism and possibly in time-compensated celestial navigation. In contrast, there is no experimental evidence indicating that any known clock gene is involved in biological clocks other than circadian clocks.
Highlights
Biological clocks are an essential mechanism by which organisms adapt to cyclic environmental changes
These results suggest that the theoretical basis of oscillation in the circannual rhythm in A. verbasci has many remarkable parallels to that of the circadian rhythm in D. pseudoobscura
There are two predominant hypotheses: One is that clock genes function in photoperiodism as components of the circadian clock and that the results provide the molecular basis of Bünning’s hypothesis [129,130,147,148]
Summary
Biological clocks are an essential mechanism by which organisms adapt to cyclic environmental changes. Miyazaki et al [47] showed that a 4-week long-day pulse administered at the phase of transition between delays and advances in the circannual PRC, i.e., near the middle of subjective winter, could evoke arrhythmicity (Figure 2B) These results suggest that the theoretical basis of oscillation in the circannual rhythm in A. verbasci has many remarkable parallels to that of the circadian rhythm in D. pseudoobscura. Circadian clock for celestial navigation In A. mellifera, general anesthesia for 6 h in daytime has a similar phase-shifting effect on per and cry-m expression in the brain, the phase of the circadian behavioral rhythms, and the orientation in solar compass navigation [55] From these results, Cheeseman et al [55] concluded that the circadian clocks for daily events and celestial navigation have a common molecular basis. Identification of the molecules involved in this circannual clock is awaited
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
