Lithocholic acid binds TULP3 to activate sirtuins and AMPK to slow down ageing

Lithocholic acid (LCA) is accumulated in mammals during calorie restriction and it can activate AMP-activated protein kinase (AMPK) to slow down ageing . However, the molecular details of how LCA activates AMPK and induces these biological effects are unclear. Here we show that LCA enhances the acti...

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Veröffentlicht in:	Nature (London) 2024-12
Hauptverfasser:	Qu, Qi, Chen, Yan, Wang, Yu, Wang, Weiche, Long, Shating, Yang, Heng-Ye, Wu, Jianfeng, Li, Mengqi, Tian, Xiao, Wei, Xiaoyan, Liu, Yan-Hui, Xu, Shengrong, Xiong, Jinye, Yang, Chunyan, Wu, Zhenhua, Huang, Xi, Xie, Changchuan, Wu, Yaying, Xu, Zheni, Zhang, Cixiong, Zhang, Baoding, Feng, Jin-Wei, Chen, Junjie, Feng, Yuanji, Fang, Huapan, Lin, Liyun, Xie, Z K, Sun, Beibei, Tian, Huayu, Yu, Yong, Piao, Hai-Long, Xie, Xiao-Song, Deng, Xianming, Zhang, Chen-Song, Lin, Sheng-Cai
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creator	Qu, Qi Chen, Yan Wang, Yu Wang, Weiche Long, Shating Yang, Heng-Ye Wu, Jianfeng Li, Mengqi Tian, Xiao Wei, Xiaoyan Liu, Yan-Hui Xu, Shengrong Xiong, Jinye Yang, Chunyan Wu, Zhenhua Huang, Xi Xie, Changchuan Wu, Yaying Xu, Zheni Zhang, Cixiong Zhang, Baoding Feng, Jin-Wei Chen, Junjie Feng, Yuanji Fang, Huapan Lin, Liyun Xie, Z K Sun, Beibei Tian, Huayu Yu, Yong Piao, Hai-Long Xie, Xiao-Song Deng, Xianming Zhang, Chen-Song Lin, Sheng-Cai
description	Lithocholic acid (LCA) is accumulated in mammals during calorie restriction and it can activate AMP-activated protein kinase (AMPK) to slow down ageing . However, the molecular details of how LCA activates AMPK and induces these biological effects are unclear. Here we show that LCA enhances the activity of sirtuins to deacetylate and subsequently inhibit vacuolar H -ATPase (v-ATPase), which leads to AMPK activation through the lysosomal glucose-sensing pathway. Proteomics analyses of proteins that co-immunoprecipitated with sirtuin 1 (SIRT1) identified TUB-like protein 3 (TULP3), a sirtuin-interacting protein , as a LCA receptor. In detail, LCA-bound TULP3 allosterically activates sirtuins, which then deacetylate the V1E1 subunit of v-ATPase on residues K52, K99 and K191. Muscle-specific expression of a V1E1 mutant (3KR), which mimics the deacetylated state, strongly activates AMPK and rejuvenates muscles in aged mice. In nematodes and flies, LCA depends on the TULP3 homologues tub-1 and ktub, respectively, to activate AMPK and extend lifespan and healthspan. Our study demonstrates that activation of the TULP3-sirtuin-v-ATPase-AMPK pathway by LCA reproduces the benefits of calorie restriction.
doi_str_mv	10.1038/s41586-024-08348-2
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However, the molecular details of how LCA activates AMPK and induces these biological effects are unclear. Here we show that LCA enhances the activity of sirtuins to deacetylate and subsequently inhibit vacuolar H -ATPase (v-ATPase), which leads to AMPK activation through the lysosomal glucose-sensing pathway. Proteomics analyses of proteins that co-immunoprecipitated with sirtuin 1 (SIRT1) identified TUB-like protein 3 (TULP3), a sirtuin-interacting protein , as a LCA receptor. In detail, LCA-bound TULP3 allosterically activates sirtuins, which then deacetylate the V1E1 subunit of v-ATPase on residues K52, K99 and K191. Muscle-specific expression of a V1E1 mutant (3KR), which mimics the deacetylated state, strongly activates AMPK and rejuvenates muscles in aged mice. In nematodes and flies, LCA depends on the TULP3 homologues tub-1 and ktub, respectively, to activate AMPK and extend lifespan and healthspan. 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title	Lithocholic acid binds TULP3 to activate sirtuins and AMPK to slow down ageing
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