Molecular characterization of the circadian clock elements during the development and senecence of Apis mellifera

The circadian clock is an advantageous adaptive system that enables organisms to anticipate and syncronize their biological activities during the daily environmental changes. The circadian clock acts through the ontogeny of circadian rhythms, which are generated by the cyclic expression of the clock genes in an autregulatory feedback loop. In insects, the circadian rhythms have important roles in the coordination of the developmental timing and behavior, interacting with the endocrine system. In the last years, researchers revealed that the molecular clock of social insects is more similar to mammals than to insects. In particular, the social honeybee is an excellent model to investigate how the circadian rhythms are modulated accordingly to the social context, behavioral plasticity, and taskrelated activities. While young bees (nurses) work arrhythmically around the clock inside the colony in brood-care activities, old bees (foragers) need to be strongly rhythmic to develop complex tasks. In this work, we characterized the expression patterns of the clock genes period (per), cryptochrome mammalian-like (cry-m), clock (clk), cycle (cyc), timeout 2 (tim2), par domain protein 1 (pdp1), vrille (vri) e clockwork orange (cwo) in the entire development of Apis mellifera. Our results revealed that the clock genes are expressed before the formation of the central nervous system in embryos and that their transcripts might be inherited maternally. The clock genes are diferentially modulated during the larval and pupal development and, except for tim2 and cwo, all of them respond to the treatment with Juvenile Hormone (JH) in white-eyed pupae. The positive response to JH by clk, cyc and pdp1 might be related to the involvement of these genes on the pathways of the JH signaling, interacting with Kruppel (Kr-h1) and Methoprene-tolerant (MET) genes. In the adult development, the clock genes per and cry-m are potential molecular markers of the behavioral plasticity and division of labor in a single-cohort colony, once they did not exhibit transcriptional oscillations in heads of young bees (3 and 7 days-old) during 24h, compared to the robust transcriptional oscillation in old bees (15 and 25 days-old). Additionally, we reconstructed protein-protein and miRNA-mRNA interaction networks and identified putative molecules involved in the post-transcriptional and translational regulation of the clock genes. Among those molecules, we validated interactions between the miR-34 and its binding sites in the 3`UTR of cyc and cwo by luciferase assay, showing that this miRNA is a negative regulator of both clock genes. We showed for the first time a broad analysis of the circadian clock elements in a social insect, and also identified news molecules with potential to act as modulators of the circadian rhythms. This work expands the knowledge about the biological roles of the circadian clock in honeybees. Our work also contributes to highlight the importance of honeybees as an ideal model to uncover the molecular mechanisms that govern the circadian rhythms, not only in bees, but in other organisms, including mammals. (AU)