Wang Dandan, Wei Tianjiao, Cui Xiaona, Xia Li, Jiang Yafei, Yin Deshan, Liao Xinyue, Li Fei, Li Jian, Wu Qi, Lin Xiafang, Lang Shan, Le Yunyi, Yang Jichun, Yang Jin, Wei Rui, Hong Tianpei
Department of Endocrinology and Metabolism, State Key Laboratory of Female Fertility Promotion, Peking University Third Hospital, Beijing 100191, China.
Department of Physiology and Pathophysiology, School of Basic Medical Sciences, Peking University Health Science Center, Beijing 100191, China.
Metabolism. 2025 Jan;162:156042. doi: 10.1016/j.metabol.2024.156042. Epub 2024 Oct 1.
Fam3a has been demonstrated to regulate pancreatic β-cell function and glucose homeostasis. However, the role and mechanism of Fam3a in regulating α-cell function remain unexplored.
Glucagon and glucagon-like peptide-1 (GLP-1) levels in pancreas and plasma were measured in global Fam3a knockout (Fam3a) mice. Human islet single-cell RNA sequencing (scRNA-seq) datasets were utilized to analyze gene expression correlations between FAM3A and PCSK1 (encoding PC1/3, which processes proglucagon into GLP-1). Mouse pancreatic α-cell line αTC1.9 cells were transfected with Fam3a siRNA or plasmid for Fam3a knockdown or overexpression to explore the effects of Fam3a on PC1/3 expression and GLP-1 production. The downstream mediator (including Nr4a2) was identified by transcriptomic analysis, and its role was confirmed by Fam3a knockdown or overexpression in αTC1.9 cells. Based on the interacted protein of Nr4a2 and the direct binding to Pcsk1 promoter, the transcription factor Foxa2 was selected for further verification. Nuclear translocation assay and dual-luciferase reporter assay were used to clarify the involvement of Fam3a-Nr4a2-Foxa2 pathway in PC1/3 expression and GLP-1 production. Moreover, α-cell-specific Fam3a knockout (Fam3a) mice were constructed to evaluate the metabolic variables and hormone levels under normoglycemic, high-fat diet (HFD)-fed and streptozotocin (STZ)-induced diabetic conditions. Exendin 9-39 (Ex9), a GLP-1 receptor antagonist, was used to investigate GLP-1 paracrine effects in Fam3a mice and in their primary islets.
Compared with wild-type mice, pancreatic and plasma active GLP-1 levels were increased in Fam3a mice. Analysis of human islet scRNA-seq datasets showed a significant negative correction between FAM3A and PCSK1 in α-cells. Fam3a knockdown upregulated PC1/3 expression and GLP-1 production in αTC1.9 cells, while Fam3a overexpression displayed inverse effects. Transcriptomic analysis identified Nr4a2 as a key downstream mediator of Fam3a, and Nr4a2 expression in αTC1.9 cells was downregulated and upregulated by Fam3a knockdown and overexpression, respectively. Nr4a2 silencing increased PC1/3 expression, albeit Nr4a2 did not directly bind to Pcsk1 promoter. Instead, Nr4a2 formed a complex with Foxa2 to facilitate Fam3a-mediated Foxa2 nuclear translocation. Foxa2 negatively regulated PC1/3 expression and GLP-1 production. Besides, Foxa2 inhibited the transcriptional activity of Pcsk1 promoter at specific binding sites 10 and 6, and this inhibition was intensified by Nr4a2 in αTC1.9 cells. Compared with Flox/cre littermates, improved glucose tolerance, increased active GLP-1 level in pancreas and plasma, upregulated plasma insulin level in response to glucose, and decreased plasma glucagon level were observed in Fam3a mice. Primary islets isolated from Fam3a mice also showed an increase in active GLP-1 and insulin release. In addition, the insulinotropic effect of intra-islet GLP-1 was blocked by Ex9 in Fam3a mice and in their primary islets. Similarly, HFD-fed Fam3a mice also exhibited an improved glucose tolerance. Both HFD-fed and STZ-induced diabetic Fam3a mice showed an increased pancreatic active GLP-1 level, an elevated plasma insulin level and a reduced plasma glucagon level.
Fam3a deficiency in α-cells enhances pancreatic GLP-1 production to improve β-cell function via paracrine signaling in an Nr4a2-Foxa2-PC1/3-dependent manner. Our study unveils a novel strategy for reprogramming α-cell proglucagon processing output from glucagon to GLP-1 and deepen the understanding of crosstalk between α-cells and β-cells.
Fam3a已被证明可调节胰腺β细胞功能和葡萄糖稳态。然而,Fam3a在调节α细胞功能中的作用和机制仍未被探索。
在全身性Fam3a基因敲除(Fam3a-/-)小鼠中测量胰腺和血浆中的胰高血糖素和胰高血糖素样肽-1(GLP-1)水平。利用人类胰岛单细胞RNA测序(scRNA-seq)数据集分析FAM3A与PCSK1(编码PC1/3,其将胰高血糖素原加工成GLP-1)之间的基因表达相关性。用Fam3a siRNA或Fam3a质粒转染小鼠胰腺α细胞系αTC1.9细胞以敲低或过表达Fam3a,探讨Fam3a对PC1/3表达和GLP-1产生的影响。通过转录组分析鉴定下游介质(包括Nr4a2),并在αTC1.9细胞中通过敲低或过表达Fam3a来证实其作用。基于Nr4a2的相互作用蛋白以及与Pcsk1启动子的直接结合,选择转录因子Foxa2进行进一步验证。采用核转位测定和双荧光素酶报告基因测定来阐明Fam3a-Nr4a2-Foxa2途径参与PC1/3表达和GLP-1产生。此外,构建α细胞特异性Fam3a基因敲除(Fam3a-/-)小鼠,以评估在正常血糖、高脂饮食(HFD)喂养和链脲佐菌素(STZ)诱导的糖尿病条件下的代谢变量和激素水平。使用GLP-1受体拮抗剂艾塞那肽9-39(Ex9)研究Fam3a-/-小鼠及其原代胰岛中GLP-1的旁分泌作用。
与野生型小鼠相比,Fam3a-/-小鼠胰腺和血浆中活性GLP-1水平升高。对人类胰岛scRNA-seq数据集的分析显示,α细胞中FAM3A与PCSK1之间存在显著的负相关。敲低Fam3a可上调αTC1.9细胞中PC1/3的表达和GLP-1的产生,而过表达Fam3a则表现出相反的作用。转录组分析确定Nr4a2是Fam3a的关键下游介质,在αTC1.9细胞中,敲低Fam3a会下调Nr4a2的表达,而过表达Fam3a则会上调Nr4a2的表达。沉默Nr4a2可增加PC1/3的表达,尽管Nr4a2不直接结合Pcsk1启动子。相反,Nr4a2与Foxa2形成复合物,促进Fam3a介导的Foxa二核转位。Foxa2负向调节PC1/3的表达和GLP-1的产生。此外,Foxa2在特定结合位点10和6抑制Pcsk1启动子的转录活性,并且在αTC1.9细胞中,Nr4a2会增强这种抑制作用。与Flox/cre同窝小鼠相比,Fam3a-/-小鼠的葡萄糖耐量得到改善,胰腺和血浆中活性GLP-1水平升高,对葡萄糖反应的血浆胰岛素水平上调,血浆胰高血糖素水平降低。从Fam3a-/-小鼠分离的原代胰岛也显示活性GLP-1和胰岛素释放增加。此外,在Fam3a-/-小鼠及其原代胰岛中,胰岛内GLP-1的促胰岛素作用被Ex9阻断。同样,HFD喂养的Fam3a-/-小鼠也表现出葡萄糖耐量改善。HFD喂养和STZ诱导的糖尿病Fam3a-/-小鼠均显示胰腺活性GLP-1水平升高,血浆胰岛素水平升高,血浆胰高血糖素水平降低。
α细胞中Fam3a缺乏通过Nr4a2-Foxa2-PC1/3依赖性旁分泌信号增强胰腺GLP-1的产生,从而改善β细胞功能。我们的研究揭示了一种将α细胞胰高血糖素原加工输出从胰高血糖素重编程为GLP-1的新策略,并加深了对α细胞与β细胞之间相互作用的理解。
