Genetic and genomic investigations have yielded important findings as to the genetic contributions to major psychiatric illnesses, illustrating significant etiological heterogeneity, as well as cross-disorder overlap. It has also become clear that understanding how this genetic variation leads to alterations in brain development and function that underlies psychiatric disease pathophysiology will be greatly advanced by a roadmap of the transcriptomic and epigenetic landscape of the human cerebral cortex across key developmental windows. Here, we propose, via a highly collaborative group of investigators, each with distinct areas of expertise and research focus, to create a scaffold of genomic data for understanding ASD pathophysiology, and psychiatric disorders more broadly. The work proposed here represents an ambitious multi-PI project (Yale, UCLA, and UCSF) that brings together three principal investigators and collaborators with strong publication records and expertise in all approaches necessary to perform this work using state-of-the-art and novel methodologies. We will perform time-, region-, and cell type-specific molecular profiling of control and ASD brains (Aim 1), including RNA-seq based transcriptomics, identifying cis-regulatory elements via ChIP-seq, and use Hi-C to determine the 3D chromatin architecture and physical relationships that underlie transcriptional regulation in three major regions implicated in neuropsychiatric disease (frontal and temporal cortex and striatum) across five major epochs representing disease-relevant stages in human brain development. This will include complementary genomic analyses in controls and matched post mortem ASD brain to identify genetic mechanisms underlying processes altered in ASD brain. We will address cellular heterogeneity via fluorescence-activated nuclear sorting (FANS) so as to profile neurons and non-neural cells separately, which will complement the whole tissue analyses. We will analyze and integrate these datasets to identify regional, developmental, and ASD-related processes to gain insight into underlying mechanisms, harmonizing these multi-omic data with other psychENCODE studies, as well as other large scale data sets, such as BrainSpan, ENCODE, GTEx and Roadmap Epigenomics Project (Aim 2). We will perform integrated analysis of germ-line ASD variations identified in more than 1000 families from the Simons Simplex Collection to characterize causal enrichments in developmental periods, brain regions, and cell types to better characterize the mechanisms by which genetic variation in humans alters brain development and function in health and disease (Aim 3). Completion of these aims will lead to a well-integrated resource across major periods in human cortical and striatal development that will permit generation of concrete testable hypotheses of ASD mechanisms, and inform our pathophysiological understanding of other related neuropsychiatric disorders.

Public Health Relevance

Autism Spectrum Disorder (ASD) is a group of complex disorders of brain development, characterized by impairments in social communication and restricted or repetitive behavior or interests. For most patients the genetic causes and molecular underpinnings of ASD are not known. The work proposed in this application will help determine which parts of the developing brain and molecular processes are involved in ASD, thus improving our understanding of the disease and contributing to the development of diagnostic tests to detect such changes.

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
3R01MH110927-03S1
Application #
9548445
Study Section
Special Emphasis Panel (ZMH1)
Program Officer
Arguello, Alexander
Project Start
2016-08-10
Project End
2020-04-30
Budget Start
2018-08-20
Budget End
2019-04-30
Support Year
3
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of California Los Angeles
Department
Neurology
Type
Schools of Medicine
DUNS #
092530369
City
Los Angeles
State
CA
Country
United States
Zip Code
90095
Gandal, Michael J; Haney, Jillian R; Parikshak, Neelroop N et al. (2018) Shared molecular neuropathology across major psychiatric disorders parallels polygenic overlap. Science 359:693-697
Short, Patrick J; McRae, Jeremy F; Gallone, Giuseppe et al. (2018) De novo mutations in regulatory elements in neurodevelopmental disorders. Nature 555:611-616
de la Torre-Ubieta, Luis; Stein, Jason L; Won, Hyejung et al. (2018) The Dynamic Landscape of Open Chromatin during Human Cortical Neurogenesis. Cell 172:289-304.e18
Zhu, Ying; Sousa, André M M; Gao, Tianliuyun et al. (2018) Spatiotemporal transcriptomic divergence across human and macaque brain development. Science 362:
Amiri, Anahita; Coppola, Gianfilippo; Scuderi, Soraya et al. (2018) Transcriptome and epigenome landscape of human cortical development modeled in organoids. Science 362:
Cantor, R M; Navarro, L; Won, H et al. (2018) ASD restricted and repetitive behaviors associated at 17q21.33: genes prioritized by expression in fetal brains. Mol Psychiatry 23:993-1000
Rhie, Suhn K; Schreiner, Shannon; Witt, Heather et al. (2018) Using 3D epigenomic maps of primary olfactory neuronal cells from living individuals to understand gene regulation. Sci Adv 4:eaav8550
Wang, Daifeng; Liu, Shuang; Warrell, Jonathan et al. (2018) Comprehensive functional genomic resource and integrative model for the human brain. Science 362:
Li, Mingfeng; Santpere, Gabriel; Imamura Kawasawa, Yuka et al. (2018) Integrative functional genomic analysis of human brain development and neuropsychiatric risks. Science 362:
Gusev, Alexander; Mancuso, Nicholas; Won, Hyejung et al. (2018) Transcriptome-wide association study of schizophrenia and chromatin activity yields mechanistic disease insights. Nat Genet 50:538-548

Showing the most recent 10 out of 17 publications