作者
Noam D Beckmann, Wei-Jye Lin, Minghui Wang, Ariella T Cohain, Alexander W Charney, Pei Wang, Weiping Ma, Ying-Chih Wang, Cheng Jiang, Mickael Audrain, Phillip H Comella, Amanda K Fakira, Siddharth P Hariharan, Gillian M Belbin, Kiran Girdhar, Allan I Levey, Nicholas T Seyfried, Eric B Dammer, Duc Duong, James J Lah, Jean-Vianney Haure-Mirande, Ben Shackleton, Tomas Fanutza, Robert Blitzer, Eimear Kenny, Jun Zhu, Vahram Haroutunian, Pavel Katsel, Sam Gandy, Zhidong Tu, Michelle E Ehrlich, Bin Zhang, Stephen R Salton, Eric E Schadt
发表日期
2020/8/7
期刊
Nature communications
卷号
11
期号
1
页码范围
3942
出版商
Nature Publishing Group UK
简介
Though discovered over 100 years ago, the molecular foundation of sporadic Alzheimer’s disease (AD) remains elusive. To better characterize the complex nature of AD, we constructed multiscale causal networks on a large human AD multi-omics dataset, integrating clinical features of AD, DNA variation, and gene- and protein-expression. These probabilistic causal models enabled detection, prioritization and replication of high-confidence master regulators of AD-associated networks, including the top predicted regulator, VGF. Overexpression of neuropeptide precursor VGF in 5xFAD mice partially rescued beta-amyloid-mediated memory impairment and neuropathology. Molecular validation of network predictions downstream of VGF was also achieved in this AD model, with significant enrichment for homologous genes identified as differentially expressed in 5xFAD brains overexpressing VGF. Our findings …
学术搜索中的文章
ND Beckmann, WJ Lin, M Wang, AT Cohain… - Nature communications, 2020