Brown Melissa L, Andrzejewski Danielle, Burnside Amy, Schneyer Alan L
Departments of Nutrition (M.L.B.) and Veterinary and Animal Science (D.A., A.B., A.L.S.), University of Massachusetts-Amherst, Amherst, Massachusetts 01003.
Endocrinology. 2016 Mar;157(3):1043-54. doi: 10.1210/en.2015-1793. Epub 2016 Jan 4.
Diabetes results from inadequate β-cell number and/or function to control serum glucose concentrations so that replacement of lost β-cells could become a viable therapy for diabetes. In addition to embryonic stem cell sources for new β-cells, evidence for transdifferentiation/reprogramming of non-β-cells to functional β-cells is accumulating. In addition, de-differentiation of β-cells observed in diabetes and their subsequent conversion to α-cells raises the possibility that adult islet cell fate is malleable and controlled by local hormonal and/or environmental cues. We previously demonstrated that inactivation of the activin antagonist, follistatin-like 3 (FSTL3) resulted in β-cell expansion and improved glucose homeostasis in the absence of β-cell proliferation. We recently reported that activin directly suppressed expression of critical α-cell genes while increasing expression of β-cell genes, supporting the hypothesis that activin is one of the local hormones controlling islet cell fate and that increased activin signaling accelerates α- to β-cell transdifferentiation. We tested this hypothesis using Gluc-Cre/yellow fluorescent protein (YFP) α-cell lineage tracing technology combined with FSTL3 knockout (KO) mice to label α-cells with YFP. Flow cytometry was used to quantify unlabeled and labeled α- and β-cells. We found that Ins+/YFP+ cells were significantly increased in FSTL3 KO mice compared with wild type littermates. Labeled Ins+/YFP+ cells increased significantly with age in FSTL3 KO mice but not wild type littermates. Sorting results were substantiated by counting fluorescently labeled cells in pancreatic sections. Activin treatment of isolated islets significantly increased the number of YFP+/Ins+ cells. These results suggest that α- to β-cell transdifferentiation is influenced by activin signaling and may contribute substantially to β-cell mass.
糖尿病是由于β细胞数量不足和/或功能缺陷,无法控制血糖浓度,因此替代丢失的β细胞可能成为治疗糖尿病的可行方法。除了胚胎干细胞可作为新β细胞的来源外,非β细胞转分化/重编程为功能性β细胞的证据也在不断积累。此外,在糖尿病中观察到β细胞去分化并随后转化为α细胞,这增加了一种可能性,即成年胰岛细胞的命运具有可塑性,并受局部激素和/或环境信号的控制。我们之前证明,激活素拮抗剂卵泡抑素样3(FSTL3)失活会导致β细胞扩张,并在没有β细胞增殖的情况下改善葡萄糖稳态。我们最近报道,激活素直接抑制关键α细胞基因的表达,同时增加β细胞基因的表达,支持了激活素是控制胰岛细胞命运的局部激素之一,且激活素信号增强会加速α细胞向β细胞转分化的假说。我们使用Gluc-Cre/黄色荧光蛋白(YFP)α细胞谱系追踪技术结合FSTL3基因敲除(KO)小鼠,用YFP标记α细胞,来验证这一假说。流式细胞术用于定量未标记和标记的α细胞和β细胞。我们发现,与野生型同窝小鼠相比,FSTL3 KO小鼠中Ins+/YFP+细胞显著增加。在FSTL3 KO小鼠中,标记的Ins+/YFP+细胞数量随年龄显著增加,而野生型同窝小鼠则不然。通过对胰腺切片中荧光标记细胞进行计数,证实了分选结果。用激活素处理分离的胰岛,显著增加了YFP+/Ins+细胞的数量。这些结果表明,α细胞向β细胞的转分化受激活素信号影响,可能对β细胞量有很大贡献。
