调节器
细胞外基质
巩膜
细胞生物学
生物
人口
表型
内分泌学
细胞外
基因
病态的
代谢物
内科学
等位基因
线粒体
小RNA
遗传学
医学
成纤维细胞
转化生长因子
化学
基因座(遗传学)
新陈代谢
基因表达调控
细胞代谢
缺氧(环境)
药理学
调节基因
SMAD公司
作者
Wei Gong,Zhi Shen,Lingyi Zhao,Tianyu Cheng,Bo Zhang,Jun Chen,Jingjing Wang,Zhiqiang Li,Xuemin Jian,Yongyong Shi,Yanqin Wen,Xun Xu,Xiangui He
出处
期刊:Research
[American Association for the Advancement of Science]
日期:2025-01-01
卷期号:8: 0969-0969
被引量:1
标识
DOI:10.34133/research.0969
摘要
The excessive elongation of eye axis is a primary contributing factor of myopia, yet the underlying genetic mechanisms remain not fully understood. The study was to explore risk-associated genes of myopia and identified that N-acetyltransferase 2 (NAT2) acted as a regulator in the pathological process of myopia. The genome-wide association study analysis was performed for axial length of eyes in a Chinese population aged 4 to 18 years (n = 6,345), and the most significant locus was 8p22, with NAT2 identified as a potential risk-associated gene for myopia. NAT2 was down-regulated by hypoxia in form deprivation-induced murine myopia, and the adeno-associated virus-induced genetic intervention of NAT2 in sclera influenced myopia progression. For mechanism, NAT2 could regulate the phenotypic transition and extracellular matrix remodeling of scleral fibroblasts by maintaining mitochondrial metabolism and inhibiting the ROS/TGF-β pathway, which also had effects on choroidal vascular function. Additionally, administration with α-ketoglutarate, a downstream metabolite of NAT2, effectively suppressed myopia progression in murine models. These findings highlight NAT2 as a critical regulator of myopia pathogenesis, offering new insights into potential therapeutic strategies targeting mitochondrial metabolism.
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