POMC 神经元 BBSome 对体重的调节与其纤毛功能无关

Function Pub Date : 2023-12-23 DOI:10.1093/function/zqad070
D. Guo, Paul A Williams, Connor Laule, Charles Seaby, Qihong Zhang, V. Sheffield, Kamal Rahmouni
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引用次数: 0

摘要

BBSome 是由包括 BBS1 在内的多个巴尔德-比德尔综合征(BBS)蛋白组成的复合体,已成为能量平衡的关键调节因子。虽然 BBSome 因其参与纤毛贩运而最为人熟知,但通过 BBS3 的参与过程,它还能调节细胞膜受体的定位,从而为新陈代谢调节提供基础。在这里,我们发现,在前绒毛膜促皮质素(POMC)神经元中选择性地缺失诱导性 Bbs1 基因会导致体重逐渐增加,这与脂肪量增加有关。相比之下,诱导性删除 POMC 神经元中的 Bbs3 基因则不会影响体重和脂肪含量。有趣的是,POMC 神经元中 BBS1 基因缺失会导致葡萄糖不耐受和胰岛素不敏感,而这些神经元中 BBS3 基因缺失会导致葡萄糖处理轻微受损,但胰岛素敏感性正常。BBS1 缺乏会改变血清素 5-HT2C 受体(5-HT2CR)的质膜定位和神经肽 Y2 受体(NPY2R)的纤毛运输。另一方面,缺乏 BBS3 会破坏 BBSome 的纤毛定位,但不会干扰 5-HT2CR 的质膜表达,反而会减少 NPY2R 向纤毛的贩运。我们还发现,BBS1(而非 BBS3)的缺乏会改变线粒体的动力学,这与类达因蛋白 1(DRP1)蛋白的总量和磷酸化水平下降有关。重要的是,挽救 DRP1 的活性可恢复线粒体动力学以及 5-HT2CR 和 NPY2R 在 BBS1 缺陷细胞中的定位。POMC 神经元缺失 BBS1 和 BBS3 对能量和葡萄糖稳态的影响截然不同,这表明 BBSome 对新陈代谢的调控与其在这些神经元中的纤毛功能无关。
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POMC Neuron BBSome Regulation of Body Weight is Independent of its Ciliary Function
The BBSome, a complex of several Bardet-Biedl syndrome (BBS) proteins including BBS1, has emerged as a critical regulator of energy homeostasis. Although the BBSome is best known for its involvement in cilia trafficking, through a process that involve BBS3, it also regulates the localization of cell membrane receptors underlying metabolic regulation. Here, we show that inducible Bbs1 gene deletion selectively in proopiomelanocortin (POMC) neurons cause a gradual increase in body weight which was associated with higher fat mass. In contrast, inducible deletion of Bbs3 gene in POMC neurons failed to affect body weight and adiposity. Interestingly, loss of BBS1 in POMC neurons led to glucose intolerance and insulin insensitivity, whereas BBS3 deficiency in these neurons is associated with slight impairment in glucose handling, but normal insulin sensitivity. BBS1 deficiency altered the plasma membrane localization of serotonin 5-HT2C receptor (5-HT2CR) and ciliary trafficking of neuropeptide Y2 receptor (NPY2R). On the other hand, BBS3 deficiency which disrupted the ciliary localization of the BBSome did not interfere with plasma membrane expression of 5-HT2CR, but reduced the trafficking of NPY2R to cilia. We also show that deficiency in BBS1, but not BBS3, alters mitochondria dynamics associated with decreased total and phosphorylated levels of dynamin-like protein 1 (DRP1) protein. Importantly, rescuing DRP1 activity restored mitochondria dynamics and localization of 5-HT2CR and NPY2R in BBS1 deficient cells. The contrasting effects on energy and glucose homeostasis evoked by POMC neuron deletion of BBS1 versus BBS3 indicate that BBSome regulation of metabolism is not related to its ciliary function in these neurons.
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