The mission of our proposed Autism Center of Excellence (ACE) is to examine if dysregulation of sleep is central to the development and exacerbation of symptoms in ASD. Animal data demonstrate that sleep is essential for the maturation of fundamental brain structures, neuronal development and synaptic plasticity. Sleep dysregulation is one of the most burdensome symptoms in individuals with ASD. Late sleep onset, frequent nighttime awakening, sleep fragmentation and abnormal sleep quantity hallmark sleep in ASD. Sleep EEG studies indicate less REM sleep and increased Non-REM Sleep. Despite its central role in brain development and function, sleep impairments are frequently considered as secondary. The main goal of our Center for Sleep in ASD is to determine if sleep disturbances reflect convergent pathways that can act as causal for, and/or co-aggravating factors of, core, behavioral and cognitive symptoms in ASD. We propose a multi-modal, human subjects and animal models program which encompasses four synergistic projects aimed at characterizing the role of sleep fragmentation and physiology on the core symptoms of ASD. We will examine Sleep EEG, daytime awake, resting EEG, and actigraphy in 150 individuals with ASD, 4 to 17 years, compared to 75 age- and sex-matched Typical Developing (TD) controls and determine the impact of these sleep parameters on core symptoms (Project 1). Using a target engagement approach, we will determine if normalization of sleep is associated with improvements in the core symptoms (Project 2). We will examine if these findings are recapitulated in genetic animal models of ASD (Mice: Project 3; & Zebrafish: Project 4). The evolutionary conservation of Sleep EEG signatures and behavior makes this a powerful translational approach as the same physiological parameters, biological endpoints and behavioral phenotypes can be compared across species, revealing if there is a convergence of the impact of sleep phenotypes across different genetic models of ASD, or alternatively differential pathways from sleep phenotypes to core symptoms. Specific Aim 1: To leverage comparative biology across humans with ASD and controls and complementary genetic animal models of ASD and wild type to examine if multisystem sleep measurements across species a) converge on a common phenotype of sleep fragmentation and architecture in ASD; or b) capture different sub- phenotypes of sleep dysregulation and sleep architecture across species. Specific Aim 2: Examine if a) the sleep phenotypes identified are differentially associated with the core, behavioral and cognitive symptoms of ASD across humans with ASD and complementary genetic animal models of ASD; b) if sleep normalization in humans with ASD and in complementary genetic animal models of ASD, alleviate the core, behavioral and cognitive symptoms of ASD; and c) if these effects are moderated by age and/or sex. Specific Aim 3: Provide research and collaborative opportunities to junior and esta...