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Project description:This SuperSeries is composed of the SubSeries listed below.

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Project description:The diurnal peak of phagocytosis by the retinal pigment epithelium (RPE) of photoreceptor outer segments is under circadian control, and it is believed that this process involves interactions from both the retina and RPE. Previous studies have demonstrated that a functional circadian clock exists within multiple retinal cell types and RPE cells. Thereby, the aim of the current study was to determine whether the circadian clock in the retina and or RPE controls the diurnal phagocytic peak of photoreceptor outer segments and whether selective disruption of the circadian clock in the RPE would affect RPE cells function and the viability during aging. To that aim, we first generated and validated an RPE tissue-specific KO of the essential clock gene, Bmal1, and then we determined the daily rhythm in phagocytic activity by the RPE in mice lacking a functional circadian clock in the retina or RPE. Then using electroretinography, spectral domain-optical coherence tomography, and optomotor response measurements of visual function we determined the effect of Bmal1 removal in young (6-month-old) and old (18-months old) mice. RPE morphology and lipofuscin accumulation was also determined in young and old mice. Our data show that the circadian clock in the RPE controls the daily diurnal phagocytic peak of POS. Surprisingly, the lack of a functional RPE circadian clock or the diurnal phagocytic peak does not result in any detectable age-related degenerative phenotype in the retina or RPE. Thus, our results demonstrate that the circadian clock in the RPE controls the daily peak in the phagocytic activity. However, the loss of the circadian clock in the RPE does not result in deterioration of photoreceptors or the RPE during aging.

Project description:To preserve a state of health, mammals employ an integrated network of molecular oscillators to drive daily rhythms of tissue-specific homeostatic processes. Importantly, the output, structure and coherence of this network is compromised by physiological ageing, disease and lifestyle changes. Yet, the key signalling nodes in this network, their underlying mechanisms of communication, and potential for therapeutic intervention, remain undefined. To dissect this system, we construct a minimal clock network consisting of two communicating nodes: the peripheral epidermal clock and central brain clock. We show that communication between the brain and epidermal clocks is sufficient for wild-type core clock activity and specific homeostatic processes, but inputs from other clock nodes are essential for full daily physiology. Unexpectedly, we find evidence that the epidermal clock selectively suppresses or interprets systemic signals to ensure coherence of specific homeostatic processes, identifying an unrecognised gatekeeper role for peripheral clocks. Together, we introduce a novel approach for dissecting a tissues daily physiology, and in turn identify key signalling nodes required to maintain epidermal homeostasis.