The prostaglandin E₂ EP3 receptor has disparate effects on islet insulin secretion and content in β-cells in a high-fat diet-induced mouse model of obesity.

IF 4.2 2区医学 Q1 ENDOCRINOLOGY & METABOLISM

American journal of physiology. Endocrinology and metabolism Pub Date : 2024-05-01 Epub Date: 2024-03-13 DOI:10.1152/ajpendo.00061.2023

Joshua C Neuman, Austin Reuter, Kathryn A Carbajal, Michael D Schaid, Grant Kelly, Kelsey Connors, Cecilia Kaiser, Joshua Krause, Liam D Hurley, Angela Olvera, Dawn Belt Davis, Jaclyn A Wisinski, Maureen Gannon, Michelle E Kimple

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Abstract

Signaling through prostaglandin E₂ EP3 receptor (EP3) actively contributes to the β-cell dysfunction of type 2 diabetes (T2D). In T2D models, full-body EP3 knockout mice have a significantly worse metabolic phenotype than wild-type controls due to hyperphagia and severe insulin resistance resulting from loss of EP3 in extra-pancreatic tissues, masking any potential beneficial effects of EP3 loss in the β cell. We hypothesized β-cell-specific EP3 knockout (EP3 βKO) mice would be protected from high-fat diet (HFD)-induced glucose intolerance, phenocopying mice lacking the EP3 effector, Gα_z, which is much more limited in its tissue distribution. When fed a HFD for 16 wk, though, EP3 βKO mice were partially, but not fully, protected from glucose intolerance. In addition, exendin-4, an analog of the incretin hormone, glucagon-like peptide 1, more strongly potentiated glucose-stimulated insulin secretion in islets from both control diet- and HFD-fed EP3 βKO mice as compared with wild-type controls, with no effect of β-cell-specific EP3 loss on islet insulin content or markers of replication and survival. However, after 26 wk of diet feeding, islets from both control diet- and HFD-fed EP3 βKO mice secreted significantly less insulin as a percent of content in response to stimulatory glucose, with or without exendin-4, with elevated total insulin content unrelated to markers of β-cell replication and survival, revealing severe β-cell dysfunction. Our results suggest that EP3 serves a critical role in temporally regulating β-cell function along the progression to T2D and that there exist Gα_z-independent mechanisms behind its effects.NEW & NOTEWORTHY The EP3 receptor is a strong inhibitor of β-cell function and replication, suggesting it as a potential therapeutic target for the disease. Yet, EP3 has protective roles in extrapancreatic tissues. To address this, we designed β-cell-specific EP3 knockout mice and subjected them to high-fat diet feeding to induce glucose intolerance. The negative metabolic phenotype of full-body knockout mice was ablated, and EP3 loss improved glucose tolerance, with converse effects on islet insulin secretion and content.

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前列腺素 E2 EP3 受体对高脂饮食诱导的肥胖症小鼠模型中β细胞的胰岛素分泌和含量有不同影响

通过前列腺素 E2 EP3 受体（EP3）发出的信号是导致 2 型糖尿病（T2D）β 细胞功能障碍的主要原因。在 T2D 模型中，全身 EP3 基因敲除小鼠的代谢表型明显比野生型对照组差，原因是胰腺外组织中 EP3 的缺失导致多食和严重的胰岛素抵抗，从而掩盖了 β 细胞中 EP3 缺失的潜在有益效应。我们假设β细胞特异性EP3基因敲除（EP3 βKOO）小鼠会受到高脂饮食（HFD）诱导的葡萄糖不耐受的保护，其表型与缺乏EP3效应物Gɑz的小鼠相同，后者的组织分布更为有限。不过，当喂食高氟日粮 16 周时，EP3 βKO 小鼠可部分（而非完全）免受葡萄糖不耐受的影响。此外，与野生型对照组相比，增量激素胰高血糖素样肽 1 的类似物 exendin-4 能更强地增强葡萄糖刺激的 EP3 βKO 小鼠胰岛分泌胰岛素的能力，β细胞特异性 EP3 缺失对胰岛胰岛素含量或复制和存活标志物没有影响。然而，经过26周的饮食喂养后，对照组饮食喂养和HFD喂养的EP3 βKO小鼠的胰岛在有或没有外显子苷-4的葡萄糖刺激下分泌的胰岛素占胰岛素含量的百分比明显降低，胰岛素总含量升高与β细胞复制和存活标志物无关，显示出严重的β细胞功能障碍。我们的研究结果表明，EP3 在T2D进展过程中对时间性调节β细胞功能起着关键作用，其作用背后存在独立于Gɑz的机制。

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来源期刊

American journal of physiology. Endocrinology and metabolism 医学-内分泌学与代谢

CiteScore

9.80

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The American Journal of Physiology-Endocrinology and Metabolism publishes original, mechanistic studies on the physiology of endocrine and metabolic systems. Physiological, cellular, and molecular studies in whole animals or humans will be considered. Specific themes include, but are not limited to, mechanisms of hormone and growth factor action; hormonal and nutritional regulation of metabolism, inflammation, microbiome and energy balance; integrative organ cross talk; paracrine and autocrine control of endocrine cells; function and activation of hormone receptors; endocrine or metabolic control of channels, transporters, and membrane function; temporal analysis of hormone secretion and metabolism; and mathematical/kinetic modeling of metabolism. Novel molecular, immunological, or biophysical studies of hormone action are also welcome.