RESUMO
The circadian clock is the inner rhythm of life activities and is controlled by a self-sustained and endogenous molecular clock, which maintains a ~ 24 h internal oscillation. As the core element of the circadian clock, BMAL1 is susceptible to degradation through the ubiquitin-proteasome system (UPS). Nevertheless, scant information is available regarding the UPS enzymes that intricately modulate both the stability and transcriptional activity of BMAL1, affecting the cellular circadian rhythm. In this work, we identify and validate UBR5 as a new E3 ubiquitin ligase that interacts with BMAL1 by using affinity purification, mass spectrometry, and biochemical experiments. UBR5 overexpression induced BMAL1 ubiquitination, leading to diminished stability and reduced protein level of BMAL1, thereby attenuating its transcriptional activity. Consistent with this, UBR5 knockdown increases the BMAL1 protein. Domain mapping discloses that the C-terminus of BMAL1 interacts with the N-terminal domains of UBR5. Similarly, cell-line-based experiments discover that HYD, the UBR5 homolog in Drosophila, could interact with and downregulate CYCLE, the BMAL1 homolog in Drosophila. PER2-luciferase bioluminescence real-time reporting assay in a mammalian cell line and behavioral experiments in Drosophila reveal that UBR5 or hyd knockdown significantly reduces the period of the circadian clock. Therefore, our work discovers a new ubiquitin ligase UBR5 that regulates BMAL1 stability and circadian rhythm and elucidates the underlying molecular mechanism. This work provides an additional layer of complexity to the regulatory network of the circadian clock at the post-translational modification level, offering potential insights into the modulation of the dysregulated circadian rhythm.
RESUMO
Autism spectrum disorder is a group of genetically-related developmental disorders of the nervous system. Patients mainly present with core symptoms such as social behavior defects, repetitive stereotyped behaviors, and learning and memory disorders. The mouse models are critical for the studies of the pathogenic mechanisms and potential therapeutic strategies of autism spectrum disorder. The assessments of mouse behaviors provide understandings of the effects of different genetic manipulations as well as pathogenic mechanisms of these diseases. This article describes various mouse behavioral assays corresponding to the core symptoms of ASD patients and provides a detailed description of protocols, cautions, and data analysis for those assays, thereby helping researchers to establish their own experimental designs. In addition, behavioral phenotypes of currently known ASD mouse models are summarized to provide a reference for researchers in the field.