Project description:This experiment was set up to evaluate the effect of the duration of a short photoperiod (winter-like conditions, 8 hours light, 14 hours dark) on the smolt transcriptome in liver and gill. Fish were kept at constant light before fish were split between treatment tank or control tanks. Treatment tanks either experienced 2 weeks of short photoperiod or 8 weeks of short photoperiod. The control fish were kept in constant winter-like conditions. After winter, the fish were brought back to constant light for 4 weeks. Sampling was done before transition to short photoperiod, at the end of winter period and four weeks after transition back to constant light. Control fish were sampled at the same time points as the treatment group.

Project description:Persistent free-running circannual (circa 1-year) rhythms have evolved in animals to regulate hormone cycles and time annual reproduction. In mammals, these are synchronized by environmental photoperiod and the melatonin signal. Long summer-like photoperiods (LP) activates thyrotrophs and thyroid-stimulating hormone (TSH) expression in the melatonin target tissue, the pars tuberalis (PT) region of the pituitary gland, driven by the transcriptional co-activator EYA3. TSH in turn stimulates thyroid hormone (TH) conversion in hypothalamic ependymal tanycytes, thus timing breeding seasons. In contrast to our new knowledge defining photoperiodic input, it is still not known which cells, tissues and pathways generate the underlying circannual cycle. We used seasonal sheep to characterise the circannual cycle, transferring animals from short winter-like photoperiods (SP) to prolonged LP conditions, and assaying prolactin to track circannual phase in individual animals. Using RNA-seq, we profiled PT cells at different phases of the circannual cycle, and defined extensive changes of cellular-remodeling pathways and genes encoding synaptic guidance proteins in the PT.

Project description:Persistent free-running circannual (circa 1-year) rhythms have evolved in animals to regulate hormone cycles and time annual reproduction. In mammals, these are synchronized by environmental photoperiod and the melatonin signal. Long summer-like photoperiods (LP) activates thyrotrophs and thyroid-stimulating hormone (TSH) expression in the melatonin target tissue, the pars tuberalis (PT) region of the pituitary gland, driven by the transcriptional co-activator EYA3. TSH in turn stimulates thyroid hormone (TH) conversion in hypothalamic ependymal tanycytes, thus timing breeding seasons. In contrast to our new knowledge defining photoperiodic input, it is still not known which cells, tissues and pathways generate the underlying circannual cycle. We used seasonal sheep to characterise the circannual cycle, transferring animals from short winter-like photoperiods (SP) to prolonged LP conditions, and assaying prolactin to track circannual phase in individual animals. Using RNA-seq, we profiled PT cells at different phases of the circannual cycle, and defined extensive changes of cellular-remodeling pathways and genes encoding synaptic guidance proteins in the PT.

Project description:Seasonal adaptation to changes in light:dark regimes (i.e., photoperiod) allows organisms living at temperate latitudes to anticipate environmental change and adjust their physiology and behavior accordingly. The circadian system has been implicated in measurement and response to changes in photoperiod in nearly all animals studied so far (Saunders, 2011). The use of both traditional and non-traditional model insects with robust seasonal responses has recently genetically demonstrated the central role that clock genes play in photoperiodic response. Yet, the molecular pathways involved in insect photoperiodic responses remain largely unknown. Here, using the Eastern North American monarch butterfly (Reppert et al, 2016; Denlinger et al, 2017), we identified the vitamin A pathway as a novel pathway downstream of the circadian clock mediating insect photoperiod responsiveness. We found that interrupting clock function by disrupting circadian activation and repression abolishes photoperiodic responses in reproductive output, providing a functional link between clock genes and photoperiodic responsiveness in the monarch. Through transcriptomic approaches, we identified a molecular signature of seasonal-specific rhythmic gene expression in the brain, the organ known to function in photoperiodic reception in both Lepidoptera and some flies (Bowen et al, 1984; Saunders & Cymborowski, 1996). Among genes differentially expressed between both long and short photoperiods and between seasonal forms, several were belonging to the vitamin A pathway. The rhythmic expression of all of these genes was abolished in clock-deficient mutants. We also showed that a CRISPR/Cas9-mediated loss-of-function mutation in the pathway’s rate-limiting enzyme, ninaB1, impaired the monarch ability to respond to the photoperiod independently of visual function in the compound eye and without affecting circadian rhythms. Our finding that the vitamin A pathway is a key mediator of photoperiodic responses in insects could have broad implications for understanding the molecular mechanisms underlying photoperiodism.

Project description:Young Drosophila females respond to low temperature and short photoperiod by developmental arrest of the ovaries. This form of reproductive diapause is a winter adaptation. Here we used Affymetrix microarrays to study global expression in female heads associated with long vs. short day.

Project description:Winter season with reduced day length (photoperiod); led to the growth cessation, dormancy induction and cold acclimation in woody perennial plants. To develop an understanding of the photoperiod signal transduction in Vitis riparia; shoot tip transcriptome profiling was performed under differential photoperiod treatments (long (LD, 15h) and short day (SD, 13h)) for 7 or 21 days after shoots reached 10 nodes (LD7, SD7, LD21 or SD21).

Project description:Annual cycles in daylength provide an initial predictive environmental cue that plants and animals use to time seasonal biology. Seasonal changes in photoperiodic information acts to entrain endogenous programs in physiology to optimize an animal’s fitness. Attempts to identify the neural and molecular substrates of photoperiodic time measurement in birds have, to date, focussed on blunt changes in light exposure during a restricted period of photoinducibility. The objectives of these studies were first to characterise a molecular seasonal clock in Japanese quail and second, to identify the key transcripts involved in endogenously generated interval timing that underlies photosensitivity in birds. We hypothesized that the mediobasal hypothalamus (MBH) provides the neuroendocrine control of photoperiod-induced changes in reproductive physiology, and that the pars distalis of the pituitary gland contains an endogenous internal timer for the short photoperiod dependent development of reproductive photosensitivity. Here we report distinct seasonal waveforms of transcript expression in the MBH, and pituitary gland and discovered the patterns were not synchronized across tissues. Follicle-stimulating hormone-β (FSHβ) expression increased during the simulated spring equinox, prior to photoinduced increases in prolactin, thyrotropin-stimulating hormone-β and testicular growth. Diurnal analyses of transcript expression showed sustained elevated levels of FSHβ under conditions of the spring equinox, compared to autumnal equinox, short (<12L) and long (>12L) photoperiods. FSHβ expression increased in quail held in non-stimulatory short photoperiod, indicative of the initiation of an endogenously programmed interval timer. These data identify that FSHβ establishes a state of photosensitivity for the external coincidence timing of seasonal physiology. The independent regulation of FSHβ expression provides an alternative pathway through which other supplementary environmental cues, such as temperature, can fine tune seasonal reproductive maturation and involution.

Project description:Annual cycles in daylength provide an initial predictive environmental cue that plants and animals use to time seasonal biology. Seasonal changes in photoperiodic information acts to entrain endogenous programs in physiology to optimize an animal’s fitness. Attempts to identify the neural and molecular substrates of photoperiodic time measurement in birds have, to date, focussed on blunt changes in light exposure during a restricted period of photoinducibility. The objectives of these studies were first to characterise a molecular seasonal clock in Japanese quail and second, to identify the key transcripts involved in endogenously generated interval timing that underlies photosensitivity in birds. We hypothesized that the mediobasal hypothalamus (MBH) provides the neuroendocrine control of photoperiod-induced changes in reproductive physiology, and that the pars distalis of the pituitary gland contains an endogenous internal timer for the short photoperiod dependent development of reproductive photosensitivity. Here we report distinct seasonal waveforms of transcript expression in the MBH, and pituitary gland and discovered the patterns were not synchronized across tissues. Follicle-stimulating hormone-β (FSHβ) expression increased during the simulated spring equinox, prior to photoinduced increases in prolactin, thyrotropin-stimulating hormone-β and testicular growth. Diurnal analyses of transcript expression showed sustained elevated levels of FSHβ under conditions of the spring equinox, compared to autumnal equinox, short (<12L) and long (>12L) photoperiods. FSHβ expression increased in quail held in non-stimulatory short photoperiod, indicative of the initiation of an endogenously programmed interval timer. These data identify that FSHβ establishes a state of photosensitivity for the external coincidence timing of seasonal physiology. The independent regulation of FSHβ expression provides an alternative pathway through which other supplementary environmental cues, such as temperature, can fine tune seasonal reproductive maturation and involution.

Project description:Accurate timing and anticipation of seasonal changes are required to initiate physiological adaptations over the course of the year such as hibernation, changes in metabolism, fattening and reproductive activity. To achieve this, organisms have evolved complex seasonal timekeeping systems that rely on day length sensing (photoperiodism). The aim of this project is to investigate the role of the circadian clock in photoperiodism within the crucial photoperiod sensing tissue the pars tuberalis.

Project description:Young Drosophila females respond to low temperature and short photoperiod by developmental arrest of the ovaries. This form of reproductive diapause is a winter adaptation. Here we used Affymetrix microarrays to study global expression in female heads associated with diapause.