Temperature Effect on Entrainment, Phase Shifting, and Amplitude of Circadian Clocks and Its Molecular Bases

Rensing, Ludger; Ruoff, Peter

doi:10.1081/cbi-120014569

Cited by 263 publications

(207 citation statements)

References 240 publications

Supporting

Mentioning

202

Contrasting

Order By: Relevance

“…These and many other experiments have shown that circannual clocks, like circadian clocks (e.g. Pengelley & Fisher 1963;Aschoff 1979;Thomas et al 1993;Sawyer et al 1997;Rensing & Ruof 2002), are not entirely temperature-compensated. That is, if environmental temperatures induce changes in energy turnover in some individuals, these individuals should have faster or slower endogenous circannual clocks.…”

Section: Discussionmentioning

confidence: 99%

Avian circannual clocks: adaptive significance and possible involvement of energy turnover in their proximate control

Wikelski

Martin

Scheuerlein

et al. 2007

Phil. Trans. R. Soc. B

View full text Add to dashboard Cite

Endogenous circannual clocks are found in many long-lived organisms, but are best studied in mammal and bird species. Circannual clocks are synchronized with the environment by changes in photoperiod, light intensity and possibly temperature and seasonal rainfall patterns. Annual timing mechanisms are presumed to have important ultimate functions in seasonally regulating reproduction, moult, hibernation, migration, body weight and fat deposition/stores. Birds that live in habitats where environmental cues such as photoperiod are poor predictors of seasons (e.g. equatorial residents, migrants to equatorial/tropical latitudes) rely more on their endogenous clocks than birds living in environments that show a tight correlation between photoperiod and seasonal events. Such population-specific/interspecific variation in reliance on endogenous clocks may indicate that annual timing mechanisms are adaptive. However, despite the apparent adaptive importance of circannual clocks, (i) what specific adaptive value they have in the wild and (ii) how they function are still largely untested. Whereas circadian clocks are hypothesized to be generated by molecular feedback loops, it has been suggested that circannual clocks are either based upon (i) a de-multiplication ('counting') of circadian days, (ii) a sequence of interdependent physiological states, or (iii) one or more endogenous oscillators, similar to circadian rhythms. We tested the de-multiplication of days (i) versus endogenous regulation hypotheses (ii) and (iii) in captive male and female house sparrows (Passer domesticus). We assessed the period of reproductive (testicular and follicular) cycles in four groups of birds kept either under photoperiods of LD 12 L : 12 D (period length: 24 h), 13.5 L : 13.5 D (27 h), 10.5 L : 10.5 D (23 h) or 12 D : 8 L : 3 D : 1 L (24-h skeleton photoperiod), respectively, for 15 months. Contrary to predictions from the de-multiplication hypothesis, individuals experiencing 27-h days did not differ (i.e. did not have longer) annual reproductive rhythms than individuals from the 21-or 24-h day groups. However, in line with predictions from endogenous regulation, birds in the skeleton group had significantly longer circannual period lengths than all other groups. Birds exposed to skeleton photoperiods experienced fewer light hours per year than all other groups (3285 versus 4380) and had a lower daily energy expenditure, as tested during one point of the annual cycle using respirometry. Although our results are tantalizing, they are still preliminary as birds were only studied over a period of 15 months. Nevertheless, the present data fail to support a 'counting of circadian days' and instead support hypotheses proposing whole-organism processes as the mechanistic basis for circannual rhythms. We propose a novel energy turnover hypothesis which predicts a dependence of the speed of the circannual clock on the overall energy expenditure of an organism.

show abstract

Section: Discussionmentioning

confidence: 99%

Avian circannual clocks: adaptive significance and possible involvement of energy turnover in their proximate control

Wikelski

Martin

Scheuerlein

et al. 2007

Phil. Trans. R. Soc. B

View full text Add to dashboard Cite

show abstract

“…Arabidopsis seedlings respond to 4°C steps in temperature, but the lower limit of responsiveness for temperature cues has not been defined in this species. Strikingly, temperature steps of 1°C entrain the Kalanchoë circadian oscillator (35). Given the possibility of similar sensitivity for Arabidopsis, we designed our experimental system to avoid zeitgeber information arising from unintended ambient temperature cycles or cues that could drive expression rhythms and mask the underlying state of the oscillator in elf3.…”

Section: Discussionmentioning

confidence: 99%

Ambient temperature response establishes ELF3 as a required component of the core Arabidopsis circadian clock

Thines

Harmon

2010

Proc. Natl. Acad. Sci. U.S.A.

183

184

View full text Add to dashboard Cite

Circadian clocks synchronize internal processes with environmental cycles to ensure optimal timing of biological events on daily and seasonal time scales. External light and temperature cues set the core molecular oscillator to local conditions. In Arabidopsis, EARLY FLOWERING 3 (ELF3) is thought to act as an evening-specific repressor of light signals to the clock, thus serving a zeitnehmer function. Circadian rhythms were examined in completely darkgrown, or etiolated, null elf3-1 seedlings, with the clock entrained by thermocycles, to evaluate whether the elf3 mutant phenotype was light-dependent. Circadian rhythms were absent from etiolated elf3-1 seedlings after exposure to temperature cycles, and this mutant failed to exhibit classic indicators of entrainment by temperature cues, consistent with global clock dysfunction or strong perturbation of temperature signaling in this background. Warm temperature pulses failed to elicit acute induction of temperatureresponsive genes in elf3-1. In fact, warm temperature-responsive genes remained in a constitutively "ON" state because of clock dysfunction and, therefore, were insensitive to temperature signals in the normal time of day-specific manner. These results show ELF3 is broadly required for circadian clock function regardless of light conditions, where ELF3 activity is needed by the core oscillator to allow progression from day to night during either light or temperature entrainment. Furthermore, robust circadian rhythms appear to be a prerequisite for etiolated seedlings to respond correctly to temperature signals.temperature signaling | temperature entrainment | luciferase | circadian rhythms | transcription T he rotation of Planet Earth creates predictable daily environmental fluctuations of light and dark along with concomitant oscillations in temperature. The circadian clock is an endogenous timekeeper that anticipates these predictable changes in the environment, confers rhythmic behavior to biological processes, and optimally phases biological activities to specific times of the day. Circadian clocks are widespread in nature, and processes under their control range from sleep-wake cycles in humans to daily expression of photosynthetic genes in plants. Clocks also time seasonal responses, such as the flowering transition in many plant species.Core molecular oscillators in eukaryotes incorporate interlocked transcription-translation feedback loops. In the model plant Arabidopsis thaliana, three such loops are critical to generation and maintenance of circadian rhythms. The loop first discovered is composed of the pseudoresponse regulator TOC1 (1) and two partially redundant Myb-like transcription factors, CCA1 (2) and LHY (3). Morning expression of CCA1 and LHY represses TOC1 expression by binding to its promoter (4), and circadian accumulation of TOC1 in the evening helps to induce CCA1 and LHY. A second morning-phased loop includes two TOC1-related proteins, PRR7 and PRR9 (5, 6). CCA1 and LHY induce PRR7 and PRR9 expression, whereas the two PRRs subseq...

show abstract

“…Abundant evidence supports the importance of temperature cycles in clock entrainment. Temperature steps as small as 0.5°C can entrain the Kalanchoe¨clock, showing the exquisite sensitivity of the system (Rensing and Ruoff, 2002). In Arabidopsis, gene expression and cotyledon movement can be entrained by temperature cycles Salomé et al, 2002;Salomé and McClung, 2005a), but the mechanism of action is currently unknown.…”

Section: Entrainmentmentioning

confidence: 99%

Plant Circadian Rhythms

2006

View full text Add to dashboard Cite

Temperature Effect on Entrainment, Phase Shifting, and Amplitude of Circadian Clocks and Its Molecular Bases

Cited by 263 publications

References 240 publications

Avian circannual clocks: adaptive significance and possible involvement of energy turnover in their proximate control

Avian circannual clocks: adaptive significance and possible involvement of energy turnover in their proximate control

Ambient temperature response establishes ELF3 as a required component of the core Arabidopsis circadian clock

Plant Circadian Rhythms

Contact Info

Product

Resources

About