MTOR Inhibition Ameliorates Cognitive and Affective Deficits Caused by Disc1 Knockdown in Adult-Born Dentate Granule Neurons

Miou Zhou; Weidong Li; Shan Huang; Juan Song; Ju Young Kim; Xiaoli Tian; Eunchai Kang; Yoshitake Sano; Cindy Liu; J. Balaji; Shumin Wu; Yu Zhou; Ying Zhou; Sherveen N. Parivash; Dan Ehninger; Lin He; Hongjun Song; Guo li Ming; Alcino J. Silva

doi:10.1016/j.neuron.2012.12.033

MTOR Inhibition Ameliorates Cognitive and Affective Deficits Caused by Disc1 Knockdown in Adult-Born Dentate Granule Neurons

Miou Zhou
, Weidong Li^*
, Shan Huang
, Juan Song
, Ju Young Kim
, Xiaoli Tian
, Eunchai Kang
, Yoshitake Sano
, Cindy Liu
, J. Balaji
, Shumin Wu
, Yu Zhou
, Ying Zhou
, Sherveen N. Parivash
, Dan Ehninger
, Lin He
, Hongjun Song
, Guo li Ming
, Alcino J. Silva

^*Corresponding author for this work

University of California at Los Angeles
Shanghai Jiao Tong University
Wuxi Mental Health Center
Johns Hopkins University
Qingdao University
German Center for Neurodegenerative Diseases

Research output: Contribution to journal › Article › peer-review

90 Citations (Scopus)

Abstract

Abnormalities during brain development are thought to cause psychiatric illness and other neurodevelopmental disorders. However, developmental processes such as neurogenesis continue in restricted brain regions of adults, and disruptions of these processes could contribute to the phenotypes of neurodevelopmental disorders. As previously reported, we show that . Disc1 knockdown specifically in adult-born dentate gyrus (DG) neurons results in increased mTOR signaling, hyperexcitability, and neuronal structure deficits. . Disc1 knockdown also resulted in pronounced cognitive and affective deficits, which could be reversed when the affected DG neurons were inactivated. Importantly, reversing increases in mTOR signaling with an FDA-approved inhibitor both prevented and treated these behavioral deficits, even when associated structural deficits were not reversed. Our findings suggest that a component of the affective and cognitive phenotypes in neurodevelopmental disorders may be caused by disruptions in adult-born neurons. Consequently, treatments directed at this cell population may have a significant impact on these phenotypes

Original language	English
Pages (from-to)	647-654
Number of pages	8
Journal	Neuron
Volume	77
Issue number	4
DOIs	https://doi.org/10.1016/j.neuron.2012.12.033
Publication status	Published - 20 Feb 2013
Externally published	Yes

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10.1016/j.neuron.2012.12.033

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Zhou, M., Li, W., Huang, S., Song, J., Kim, J. Y., Tian, X., Kang, E., Sano, Y., Liu, C., Balaji, J., Wu, S., Zhou, Y., Zhou, Y., Parivash, S. N., Ehninger, D., He, L., Song, H., Ming, G. L., & Silva, A. J. (2013). MTOR Inhibition Ameliorates Cognitive and Affective Deficits Caused by Disc1 Knockdown in Adult-Born Dentate Granule Neurons. Neuron, 77(4), 647-654. https://doi.org/10.1016/j.neuron.2012.12.033

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title = "MTOR Inhibition Ameliorates Cognitive and Affective Deficits Caused by Disc1 Knockdown in Adult-Born Dentate Granule Neurons",

abstract = "Abnormalities during brain development are thought to cause psychiatric illness and other neurodevelopmental disorders. However, developmental processes such as neurogenesis continue in restricted brain regions of adults, and disruptions of these processes could contribute to the phenotypes of neurodevelopmental disorders. As previously reported, we show that . Disc1 knockdown specifically in adult-born dentate gyrus (DG) neurons results in increased mTOR signaling, hyperexcitability, and neuronal structure deficits. . Disc1 knockdown also resulted in pronounced cognitive and affective deficits, which could be reversed when the affected DG neurons were inactivated. Importantly, reversing increases in mTOR signaling with an FDA-approved inhibitor both prevented and treated these behavioral deficits, even when associated structural deficits were not reversed. Our findings suggest that a component of the affective and cognitive phenotypes in neurodevelopmental disorders may be caused by disruptions in adult-born neurons. Consequently, treatments directed at this cell population may have a significant impact on these phenotypes",

author = "Miou Zhou and Weidong Li and Shan Huang and Juan Song and Kim, \{Ju Young\} and Xiaoli Tian and Eunchai Kang and Yoshitake Sano and Cindy Liu and J. Balaji and Shumin Wu and Yu Zhou and Ying Zhou and Parivash, \{Sherveen N.\} and Dan Ehninger and Lin He and Hongjun Song and Ming, \{Guo li\} and Silva, \{Alcino J.\}",

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Zhou, M, Li, W, Huang, S, Song, J, Kim, JY, Tian, X, Kang, E, Sano, Y, Liu, C, Balaji, J, Wu, S, Zhou, Y, Zhou, Y, Parivash, SN, Ehninger, D, He, L, Song, H, Ming, GL & Silva, AJ 2013, 'MTOR Inhibition Ameliorates Cognitive and Affective Deficits Caused by Disc1 Knockdown in Adult-Born Dentate Granule Neurons', Neuron, vol. 77, no. 4, pp. 647-654. https://doi.org/10.1016/j.neuron.2012.12.033

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AU - Zhou, Miou

AU - Li, Weidong

AU - Huang, Shan

AU - Song, Juan

AU - Kim, Ju Young

AU - Tian, Xiaoli

AU - Kang, Eunchai

AU - Sano, Yoshitake

AU - Liu, Cindy

AU - Balaji, J.

AU - Wu, Shumin

AU - Zhou, Yu

AU - Zhou, Ying

AU - Parivash, Sherveen N.

AU - Ehninger, Dan

AU - He, Lin

AU - Song, Hongjun

AU - Ming, Guo li

AU - Silva, Alcino J.

PY - 2013/2/20

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N2 - Abnormalities during brain development are thought to cause psychiatric illness and other neurodevelopmental disorders. However, developmental processes such as neurogenesis continue in restricted brain regions of adults, and disruptions of these processes could contribute to the phenotypes of neurodevelopmental disorders. As previously reported, we show that . Disc1 knockdown specifically in adult-born dentate gyrus (DG) neurons results in increased mTOR signaling, hyperexcitability, and neuronal structure deficits. . Disc1 knockdown also resulted in pronounced cognitive and affective deficits, which could be reversed when the affected DG neurons were inactivated. Importantly, reversing increases in mTOR signaling with an FDA-approved inhibitor both prevented and treated these behavioral deficits, even when associated structural deficits were not reversed. Our findings suggest that a component of the affective and cognitive phenotypes in neurodevelopmental disorders may be caused by disruptions in adult-born neurons. Consequently, treatments directed at this cell population may have a significant impact on these phenotypes

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MTOR Inhibition Ameliorates Cognitive and Affective Deficits Caused by Disc1 Knockdown in Adult-Born Dentate Granule Neurons

Abstract

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