Identification of Alzheimer’s disease–associated rare coding variants in the ECE2 gene
Xinxin Liao, Fang Cai, Zhanfang Sun, Yun Zhang, Juelu Wang, Bin Jiao, Jifeng Guo, Jinchen Li, Xixi Liu, Lina Guo, Yafang Zhou, Junling Wang, Xinxiang Yan, Hong Jiang, Kun Xia, Jiada Li, Beisha Tang, Lu Shen, Weihong Song
Xinxin Liao, Fang Cai, Zhanfang Sun, Yun Zhang, Juelu Wang, Bin Jiao, Jifeng Guo, Jinchen Li, Xixi Liu, Lina Guo, Yafang Zhou, Junling Wang, Xinxiang Yan, Hong Jiang, Kun Xia, Jiada Li, Beisha Tang, Lu Shen, Weihong Song
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Research Article Neuroscience

Identification of Alzheimer’s disease–associated rare coding variants in the ECE2 gene

Abstract

Accumulation of amyloid β protein (Aβ) due to increased generation and/or impaired degradation plays an important role in Alzheimer’s disease (AD) pathogenesis. In this report, we describe the identification of rare coding mutations in the endothelin-converting enzyme 2 (ECE2) gene in 1 late-onset AD family, and additional case-control cohort analysis indicates ECE2 variants associated with the risk of developing AD. The 2 mutations (R186C and F751S) located in the peptidase domain in the ECE2 protein were found to severely impair the enzymatic activity of ECE2 in Aβ degradation. We further evaluated the effect of the R186C mutation in mutant APP–knockin mice. Overexpression of wild-type ECE2 in the hippocampus reduced amyloid load and plaque formation, and improved learning and memory deficits in the AD model mice. However, the effect was abolished by the R186C mutation in ECE2. Taken together, the results demonstrated that ECE2 peptidase mutations contribute to AD pathogenesis by impairing Aβ degradation, and overexpression of ECE2 alleviates AD phenotypes. This study indicates that ECE2 is a risk gene for AD development and pharmacological activation of ECE2 could be a promising strategy for AD treatment.

Authors

Xinxin Liao, Fang Cai, Zhanfang Sun, Yun Zhang, Juelu Wang, Bin Jiao, Jifeng Guo, Jinchen Li, Xixi Liu, Lina Guo, Yafang Zhou, Junling Wang, Xinxiang Yan, Hong Jiang, Kun Xia, Jiada Li, Beisha Tang, Lu Shen, Weihong Song

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Figure 5

Overexpressed ECE2WT, but not ECE2R186C mutant, alleviated cognitive deficits in APPNL-G-F/NL-G-F-knockin mice.

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Overexpressed ECE2WT, but not ECE2R186C mutant, alleviated cognitive def...
(AE) A Morris water maze test consisted of 1 day of visible platform trials and 4 days of hidden platform trials, plus a probe trial 24 hours after the last hidden platform trial. Animal movement was traced and recorded by ANY-maze tracking software. In the visible platform tests, mice in each group exhibited a similar (A) escape latency and (B) swimming path length to escape onto the visible platform. In hidden platform tests, mice were trained with 5 trials per day for 4 days. ECE2WT group mice showed shorter latency (C) and path length (D) to escape onto the visible platform on the third and fourth days, but without statistically significant differences. (E) In the probe trial on the sixth day, ECE2WT group mice traveled into the third quadrant, where the hidden platform was previously placed, significantly more times than GFP and ECE2R186C groups. (F and G) The Y-maze test was performed. ECE2WT-injected mice exhibited significantly higher percentage alternation than GFP-injected mice, whereas ECE2R186C-injected mice and GFP-injected mice performed similarly (F). No difference between arm entries was observed between groups (G). Data represented as mean ± SEM (for behavior tests, n = 10 GFP, 9 ECE2WT, and 10 ECE2R186C). Significance was assessed by 1-way ANOVA with Newman-Keuls post hoc test.