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OBJECTIVE

Bile acids have been implicated as important regulators of glucose metabolism via activation of FXR and GPBAR1. We have previously shown that FGF19 can modulate glucose handling by suppressing the activity of hypothalamic AGRP/NPY neurons. As bile acids stimulate the release of FGF19/FGF15 into the circulation, we pursued the potential of bile acids to improve glucose tolerance via a gut-brain axis involving FXR and FGF15/FGF19 within enterocytes and FGF receptors on hypothalamic AGRP/NPY neurons.

METHODS

A 5-day gavage of taurocholic acid, mirroring our previous protocol of a 5-day FGF19 treatment, was performed. Oral glucose tolerance tests in mice with genetic manipulations of FGF signaling and melanocortin signaling were used to define a gut-brain axis responsive to bile acids.

RESULTS

The taurocholic acid gavage led to increased serum concentrations of taurocholic acid as well as increases of FGF15 mRNA in the ileum and improved oral glucose tolerance in obese (ob/ob) mice. In contrast, lithocholic acid, an FXR antagonist but a potent agonist for GPBAR1, did not improve glucose tolerance. The positive response to taurocholic acid is dependent upon an intact melanocortinergic system as obese MC4R-null mice or ob/ob mice without AGRP did not show improvements in glucose tolerance after taurocholate gavage. We also tested the FGF receptor isoform necessary for the bile acid response, using AGRP:Fgfr1-/- and AGRP:Fgfr2-/- mice. While the absence of FGFR1 in AGRP/NPY neurons did not alter glucose tolerance after taurocholate gavage, manipulations of Fgfr2 caused bidirectional changes depending upon the experimental model. We hypothesized the existence of an endogenous hypothalamic FGF, most likely FGF17, that acted as a chronic activator of AGRP/NPY neurons. We developed two short peptides based on FGF8 and FGF17 that should antagonize FGF17 action. Both of these peptides improved glucose homeostasis after a 4-day course of central and peripheral injections. Significantly, daily average blood glucose from continuous glucose monitoring was reduced in all tested animals but glucose concentrations remained in the euglycemia range.

CONCLUSIONS

We have defined a gut-brain axis that regulates glucose metabolism mediated by antagonistic fibroblast growth factors. From the intestine, bile acids stimulate FGF15 secretion, leading to activation of the FGF receptors in hypothalamic AGRP/NPY neurons. FGF receptor intracellular signaling subsequently silences AGRP/NPY neurons, leading to improvements of glucose tolerance that are likely mediated by the autonomic nervous system. Finally, short peptides that antagonize homodimeric FGF receptor signaling within the hypothalamus have beneficial effects on glucose homeostasis without inducing hypoglycemia. These peptides could provide a new mode of regulating glucose metabolism.

OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

目的

胆汁酸通过激活 FXR 和 GPBAR1 被认为是调节葡萄糖代谢的重要调节剂。我们之前已经表明，FGF19 可以通过抑制下丘脑 AGRP/NPY 神经元的活性来调节葡萄糖处理。由于胆汁酸刺激 FGF19/FGF15 进入循环的释放，我们研究了胆汁酸通过涉及肠上皮细胞内的 FXR 和 FGF15/FGF19 以及下丘脑 AGRP/NPY 神经元上的 FGF 受体的肠-脑轴来改善葡萄糖耐量的潜力。

方法

进行了为期 5 天的牛磺胆酸灌胃，这与我们之前进行的为期 5 天的 FGF19 治疗方案相匹配。使用具有 FGFR 信号和黑皮质素信号遗传操作的小鼠的口服葡萄糖耐量试验来定义对胆汁酸有反应的肠-脑轴。

结果

牛磺胆酸灌胃导致牛磺胆酸血清浓度升高，回肠中 FGF15mRNA 增加，肥胖（ob/ob）小鼠的口服葡萄糖耐量改善。相比之下，石胆酸，一种 FXR 拮抗剂但 GPBAR1 的有效激动剂，并没有改善葡萄糖耐量。对牛磺胆酸的阳性反应取决于完整的黑皮质素能系统，因为肥胖 MC4R 敲除小鼠或没有 AGRP 的 ob/ob 小鼠在牛磺胆酸盐灌胃后葡萄糖耐量没有改善。我们还使用 AGRP:Fgfr1-/-和 AGRP:Fgfr2-/-小鼠测试了胆汁酸反应所需的 FGFR 同工型。虽然 AGRP/NPY 神经元中 FGFR1 的缺失不会改变牛磺胆酸盐灌胃后的葡萄糖耐量，但 Fgfr2 的操作会根据实验模型导致双向变化。我们假设存在一种内源性下丘脑 FGF，很可能是 FGF17，它作为 AGRP/NPY 神经元的慢性激活物。我们基于 FGF8 和 FGF17 开发了两种短肽，它们应该拮抗 FGF17 的作用。这两种肽都在中枢和外周注射 4 天后改善了葡萄糖稳态。值得注意的是，所有测试动物的连续血糖监测的平均日常血糖均降低，但血糖浓度仍保持在正常范围内。

结论

我们已经定义了一个调节葡萄糖代谢的肠-脑轴，该轴由拮抗的成纤维细胞生长因子介导。从肠道开始，胆汁酸刺激 FGF15 的分泌，导致下丘脑 AGRP/NPY 神经元中 FGF 受体的激活。FGF 受体细胞内信号随后使 AGRP/NPY 神经元沉默，导致葡萄糖耐量改善，这可能是通过自主神经系统介导的。最后，在下丘脑内拮抗同源二聚体 FGFR 信号的短肽对葡萄糖稳态具有有益作用，而不会引起低血糖。这些肽可以提供一种调节葡萄糖代谢的新模式。