Co-existing feedback loops generate tissue-specific circadian rhythms

Gene regulatory feedback loops generate autonomous circadian rhythms in mammalian tissues. The well-studied core clock network contains many negative and positive regulations. Multiple feedback loops have been discussed as primary rhythm generators but the design principles of the core clock and differences between tissues are still under debate. Here we fit mathematical models to tissue-specific mammalian circadian gene expression profiles. For every investigated tissue multiple model parameter sets reproduce the experimental data. We extract the most essential feedback loops from each model version and find differences between tissues, pointing to specific design principles within the hierarchy of mammalian tissue clocks. Self-inhibitions of Per and Cry genes are characteristic for models of SCN clocks, while in liver models many loops act in synergy and are connected by a repressilator motif. Tissue-specific use of a network of co-existing synergistic feedback loops could account for functional differences between organs.