Acetaldehyde dehydrogenase 2 interactions with LDLR and AMPK regulate foam cell formation
Shanshan Zhong, Luxiao Li, Yu-Lei Zhang, Lili Zhang, Jianhong Lu, Shuyuan Guo, Ningning Liang, Jing Ge, Mingjiang Zhu, Yongzhen Tao, Yun-Cheng Wu, Huiyong Yin
Shanshan Zhong, Luxiao Li, Yu-Lei Zhang, Lili Zhang, Jianhong Lu, Shuyuan Guo, Ningning Liang, Jing Ge, Mingjiang Zhu, Yongzhen Tao, Yun-Cheng Wu, Huiyong Yin
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Research Article Cell biology Metabolism

Acetaldehyde dehydrogenase 2 interactions with LDLR and AMPK regulate foam cell formation

Abstract

Acetaldehyde dehydrogenase 2 (ALDH2) is a mitochondrial enzyme detoxifying acetaldehyde and endogenous lipid aldehydes; previous studies suggest a protective role of ALDH2 against cardiovascular disease (CVD). Around 40% of East Asians carrying the single nucleotide polymorphism (SNP) ALDH2 rs671 have an increased incidence of CVD. However, the role of ALDH2 in CVD beyond alcohol consumption remains poorly defined. Here we report that ALDH2/LDLR double knockout (DKO) mice have decreased atherosclerosis compared with LDLR-KO mice, whereas ALDH2/APOE-DKO mice have increased atherosclerosis, suggesting an unexpected interaction of ALDH2 with LDLR. Further studies demonstrate that in the absence of LDLR, AMPK phosphorylates ALDH2 at threonine 356 and enables its nuclear translocation. Nuclear ALDH2 interacts with HDAC3 and represses transcription of a lysosomal proton pump protein ATP6V0E2, critical for maintaining lysosomal function, autophagy, and degradation of oxidized low-density lipid protein. Interestingly, an interaction of cytosolic LDLR C-terminus with AMPK blocks ALDH2 phosphorylation and subsequent nuclear translocation, whereas ALDH2 rs671 mutant in human macrophages attenuates this interaction, which releases ALDH2 to the nucleus to suppress ATP6V0E2 expression, resulting in increased foam cells due to impaired lysosomal function. Our studies reveal a novel role of ALDH2 and LDLR in atherosclerosis and provide a molecular mechanism by which ALDH2 rs671 SNP increases CVD.

Authors

Shanshan Zhong, Luxiao Li, Yu-Lei Zhang, Lili Zhang, Jianhong Lu, Shuyuan Guo, Ningning Liang, Jing Ge, Mingjiang Zhu, Yongzhen Tao, Yun-Cheng Wu, Huiyong Yin

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Figure 7

Nuclear translocated ALDH2 regulates the transcription of ATP6V0E2, a critical protein for lysosomal function, endocytosis, and autophagy, and ALDH2 rs671 polymorphism decreases ATP6V0E2 expression.

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Nuclear translocated ALDH2 regulates the transcription of ATP6V0E2, a cr...
(A) ALDH2/LDLR-DKO leads to significant upregulation of ATP6V0E2 expression compared with LDLR-KO (LKO; n = 3). (B) ATP6V0E2 (red) colocalizes with macrophages (CD68, green) and ATP6V0E2 expression is significantly increased in the aorta of DKO mice. Scale bars: 100 μm. (C) Overexpressed AMPK and ALDH2 decrease ATP6V0E2 expression in 293T cells (n = 3). (D) ALDH2 T356A not Y148A mutant rescues decreased ATP6V0E2 expression, which is caused by overexpressed ALDH2 and AMPK (n = 3). (E) Nuclear translocated ALDH2 binds to HDAC3. (F and G) Nuclear translocated ALDH2 regulates transcription of ATP6V0E2. In the absence of LDLR, nuclear translocated ALDH2 binds to ATP6V0E2 promoter (F) and regulates transcriptional activity (G), which is enhanced by AMPK activation (n = 3). (H) ALDH2 rs671 enhanced transcriptional activity of ATP6V0E2. (I) The rs671 mutant decreased ATP6V0E2 protein expression (n = 3). Statistical comparisons were made using 2-tailed Student’s t test (I) or ANOVA (A, C, D, G, and H). All data are mean ± SD. *P < 0.05, **P < 0.01, ***P < 0.001.