Autism spectrum disorder (ASD) is a major public health problem affecting 1 out 110 children. There is a fundamental gap in understanding the cellular and molecular mechanisms underlying the diverse clinical presentation of ASD. Understanding these mechanisms is critical for developing novel therapeutic approaches. The limitations inherent in human studies make it difficult to study cellular and molecular mechanisms, providing a rationale for the study of animal models. Recent genetic evidence implicates the SHANK3 gene in ASD. SHANK3 is a scaffolding protein that organizes a signaling complex at postsynaptic density of excitatory synapses. An array of SHANK3 isoforms result from 6 alternative promoters and splicing of coding exons. Deletion of the SHANK3 gene is a major contributor to ASD features in the 22q13.3 deletion Phelan-McDermid syndrome. Microdeletions of the entire SHANK3 gene and point mutations of SHANK3 disrupting specific isoforms have been identified in patients with ASD and intellectual disability. We and others reported Shank3 isoform-knockout mice with different exonic deletions. Reduced postsynaptic response of excitatory synapses in hippocampus, striatum, and neocortex as well as ASD-like behaviors is found in these mice, but there were also notable phenotypic differences. This phenotypic heterogeneity could be explained by the different impact that each mutation has on isoform-specific expression of Shank3. However, interpretation of these differences is complicated by the fact that the existing mutant mice are not Shank3 complete knockout and were analyzed in different brain regions and using different protocols. Because >95% of SHANK3 molecular defects in humans delete the entire SHANK3 gene, and these patients have more severe phenotypes than those with point mutations of SHANK3, we have generated Shank3 complete knockout mice by deleting exons 4-22, and also Shank3 conditional knockout mice, with floxed exons 4-22. These models are more valid for dissecting the cellular mechanism arising from SHANK3 deletion than existing isoform-knockout mice. The objective of this proposal is to analyze Shank3 complete knockout mice using an interdisciplinary approach. The central hypothesis is that the primary path by which SHANK3 molecular defects lead to ASD in humans is via cellular and synaptic defects of reduced glutamatergic receptor-mediated postsynaptic responses in different brain regions. With these mutant mice, we are uniquely positioned to study the following Specific Aims: 1) To model major clinical features of SHANK3 deletion in Shank3 complete knockout mice;2). To delineate the cellular and molecular mechanism underlying Shank3 deficiency;3) To analyze the temporal- and spatial-requirements of SHANK3 deficiency underlying the pathogenesis of ASD. The proposed studies are significant because analysis of Shank3 complete knockout mice may uncover the cellular and circuit mechanism of ASD caused by SHANK3 deletion. The knowledge gained from studying Shank3 will provide insights that may be generalizable and applicable to understanding the pathophysiology of other causes of ASD.

Public Health Relevance

The proposed project is to understand the cellular and synaptic mechanism underlying autism spectrum disorder by analyzing Shank3 complete knockout mice. This project will lead to better understanding the pathogenesis and developing treatment for ASD.

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
1R01MH098114-01
Application #
8346356
Study Section
Special Emphasis Panel (ZRG1-MDCN-P (57))
Program Officer
Asanuma, Chiiko
Project Start
2012-06-01
Project End
2017-04-30
Budget Start
2012-06-01
Budget End
2013-04-30
Support Year
1
Fiscal Year
2012
Total Cost
$481,448
Indirect Cost
$171,526
Name
Duke University
Department
Pediatrics
Type
Schools of Medicine
DUNS #
044387793
City
Durham
State
NC
Country
United States
Zip Code
27705
Zhao, Hui; Jiang, Yong-Hui; Zhang, Yong Q (2018) Modeling autism in non-human primates: Opportunities and challenges. Autism Res 11:686-694
Bey, Alexandra L; Wang, Xiaoming; Yan, Haidun et al. (2018) Brain region-specific disruption of Shank3 in mice reveals a dissociation for cortical and striatal circuits in autism-related behaviors. Transl Psychiatry 8:94
Luo, Weijun; Zhang, Chaolin; Jiang, Yong-Hui et al. (2018) Systematic reconstruction of autism biology from massive genetic mutation profiles. Sci Adv 4:e1701799
Cheng, Ying; Li, Ziyi; Manupipatpong, Sasicha et al. (2018) 5-Hydroxymethylcytosine alterations in the human postmortem brains of autism spectrum disorder. Hum Mol Genet 27:2955-2964
Hulbert, Samuel W; Bey, Alexandra L; Jiang, Yong-Hui (2018) Environmental enrichment has minimal effects on behavior in the Shank3 complete knockout model of autism spectrum disorder. Brain Behav 8:e01107
Duffney, Lara J; Valdez, Purnima; Tremblay, Martine W et al. (2018) Epigenetics and autism spectrum disorder: A report of an autism case with mutation in H1 linker histone HIST1H1E and literature review. Am J Med Genet B Neuropsychiatr Genet 177:426-433
Chung, Leeyup; Bey, Alexandra L; Towers, Aaron J et al. (2018) Lovastatin suppresses hyperexcitability and seizure in Angelman syndrome model. Neurobiol Dis 110:12-19
Chung, Changuk; Ha, Seungmin; Kang, Hyojin et al. (2018) Early Correction of N-Methyl-D-Aspartate Receptor Function Improves Autistic-like Social Behaviors in Adult Shank2-/- Mice. Biol Psychiatry :
Tan, Queenie K-G; McConkie-Rosell, Allyn; Juusola, Jane et al. (2017) The importance of managing the patient and not the gene: expanded phenotype of GLE1-associated arthrogryposis. Cold Spring Harb Mol Case Stud 3:
Hulbert, Samuel W; Jiang, Yong-Hui (2017) Cellular and Circuitry Bases of Autism: Lessons Learned from the Temporospatial Manipulation of Autism Genes in the Brain. Neurosci Bull 33:205-218

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