Disruption of the ATXN1–CIC complex causes a spectrum of neurobehavioral phenotypes in mice and humans

Lu, Hsiang Chih; Tan, Qingrong; Rousseaux, Maxime W.C.; Wang, Wei; Kim, Ji Yoen; Richman, Ronald; Wan, Ying; Yeh, Szu-Ying; Patel, Jay; Liu, Xiuyun; Lin, Tao; Lee, Yoontae; Fryer, John Denis; Han, Jing; Chahrour, Maria H.; Finnell, Richard H.; Lei, Yunping; Zurita-Jimenez, Maria E.; Ahimaz, Priyanka; Anyane‐Yeboa, Kwame; Maldergem, Lionel Van; Lehalle, Daphné; Jean-Marçais, Nolwenn; Mosca-Boidron, Anne Laure; Thévenon, Julien; Cousin, Margot A.; Bro, Della E.; Lanpher, Brendan C.; Klee, Eric W.; Alexander, Nora; Bainbridge, Matthew N.; Orr, Harry T.; Sillitoe, Roy V.; Ljungberg, M. Cecilia; Liu, Zhandong; Schaaf, Christian P.; Zoghbi, Huda Y.

doi:10.1038/ng.3808

Cited by 126 publications

(188 citation statements)

References 49 publications

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“…Interaction between CIC and ATXN1 protein family is also important for brain development. Disruption of the ATXN1/CIC complex affects thickness of cerebral cortex, inducing multiple behavioral abnormalities in mice . In human, the germline heterozygous CIC truncating mutations were reported in patients of intellectual disability, attention deficit hyperactivity disorder, and autism spectrum disorder .…”

Section: Structure and Function Of Capicua/cicmentioning

confidence: 99%

“…Disruption of the ATXN1/CIC complex affects thickness of cerebral cortex, inducing multiple behavioral abnormalities in mice . In human, the germline heterozygous CIC truncating mutations were reported in patients of intellectual disability, attention deficit hyperactivity disorder, and autism spectrum disorder . The Cic‐L knockout homozygous mutant also shows downregulation of transporter genes such as Bsep and Mdr2 in hepatocytes showing bile acid accumulation .…”

Section: Structure and Function Of Capicua/cicmentioning

confidence: 99%

“…(26) In human, the germline heterozygous CIC truncating mutations were reported in patients of intellectual disability, attention deficit hyperactivity disorder, and autism spectrum disorder. (26) The Cic-L knockout homozygous mutant also shows downregulation of transporter genes such as Bsep and Mdr2 in hepatocytes showing bile acid accumulation. (27) CIC is ubiquitously expressed in many organs except for kidney, and thus its function is important for homeostasis of multiple organs.…”

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confidence: 99%

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A double‐edged sword: The world according to Capicua in cancer

2017

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CIC/Capicua is an HMG‐box transcription factor that is well conserved during evolution. CIC recognizes the T(G/C)AATG(A/G)A sequence and represses its target genes, such as PEA3 family genes. The receptor tyrosine kinase/RAS/MAPK signals downregulate CIC and relieves CIC's target genes from the transrepressional activity; CIC thus acts as an important downstream molecule of the pathway and as a tumor suppressor. CIC loss‐of‐function mutations are frequently observed in several human neoplasms such as oligodendroglioma, and lung and gastric carcinoma. CIC is also involved in chromosomal translocation‐associated gene fusions in highly aggressive small round cell sarcoma that is biologically and clinically distinct from Ewing sarcoma. In these mutations, PEA3 family genes and other important target genes are upregulated, inducing malignant phenotypes. Downregulation of CIC abrogates the effect of MAPK inhibitors, suggesting its potential role as an important modifier of molecular target therapies for cancer. These data reveal the importance of CIC as a key molecule in signal transduction, carcinogenesis, and developing novel therapies.

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Section: Structure and Function Of Capicua/cicmentioning

confidence: 99%

Section: Structure and Function Of Capicua/cicmentioning

confidence: 99%

mentioning

confidence: 99%

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A double‐edged sword: The world according to Capicua in cancer

2017

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“…This strategy is key to the discovery or co-discovery of the genetic basis of many disorders and understanding the mechanisms of disease. Frequent interactions and collaborations between clinical medicine and biomedical research at the NRI fostered our understanding of several diseases including Fragile X syndrome, Angelman syndrome, Rett syndrome, MECP2 duplication syndrome, myotonic dystrophy, Parkinson’s disease, Alzheimer’s disease, Spinocerebellar ataxia type 1, Friederich’s ataxia, amyotrophic lateral sclerosis, Leigh syndrome, Charcot-Marie-Tooth, other inherited ataxias, neuropathies, lysosomal storage disorders, epilepsies, and syndromic neurodevelopmental disorders [21, 28, 35–42]. …”

Section: Collaborative Efforts Bridging Clinical Medicine and Biomedimentioning

confidence: 99%

Building dialogues between clinical and biomedical research through cross-species collaborations

Chao

Liu

Bellen

2017

Seminars in Cell & Developmental Biology

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Today, biomedical science is equipped with an impressive array of technologies and genetic resources that bolster our basic understanding of fundamental biology and enhance the practice of modern medicine by providing clinicians with a diverse toolkit to diagnose, prognosticate, and treat a plethora of conditions. Many significant advances in our understanding of disease mechanisms and therapeutic interventions have arisen from fruitful dialogues between clinicians and biomedical research scientists. However, the increasingly specialized scientific and medical disciplines, globalization of science and technology, and complex datasets often hinder the development of effective interdisciplinary collaborations between clinical medicine and biomedical research. The goal of this review is to provide examples of diverse strategies to enhance communication and collaboration across diverse disciplines. First, we discuss examples of efforts to foster interdisciplinary collaborations at institutional and multi-institutional levels. Second, we explore resources and tools for clinicians and research scientists to facilitate effective bi-directional dialogues. Third, we use our experiences in neurobiology and human genetics to highlight how communication between clinical medicine and biomedical research lead to effective implementation of cross-species model organism approaches to uncover the biological underpinnings of health and disease.

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“…In mammals, CIC has been implicated in the pathogenesis of spinocerebellar ataxia type 1 neurodegenerative disease, as well as regulation of essential processes such as lung alveolarization, liver homeostasis, learning and memory, and follicular helper T‐cell differentiation . CIC has also been studied in several cancer contexts, and mutations of it have been found in soft tissue, brain, lung, gastric, prostate, and breast cancers .…”

mentioning

confidence: 99%