雌雄小鼠肾小管中前列腺素 EP3 受体的诱导性缺失对水稳态无重大影响

Cristina Esteva-Font, Frank Geurts, Toke P K Hansen, Ewout J Hoorn, Robert A Fenton
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摘要

前列腺素 E2(PGE2)受体 EP3 在肾脏的粗升支(TAL)和集合管中被检测到,其作用被认为是抑制水的重吸收。然而,EP3 也在其他细胞类型中表达,包括血管内皮细胞。本研究的目的是通过对一种在整个肾小管中多西环素依赖性地缺失 EP3 的新型小鼠模型(EP3-/- 小鼠)进行表型分析,确定 EP3 在雄性和雌性成年小鼠肾脏水处理中的贡献。RNAscope 显示,EP3 在成年小鼠的皮质和髓质 TAL 中高度表达。与对照组相比,EP3-/-小鼠全肾(RT-qPCR)中 EP3 mRNA 表达量减少了 80%以上,肾小管中则检测不到(RNAscope)。在基础条件下,对照组小鼠和 EP3-/- 小鼠在食物和水的摄入量、体重、尿量或临床生化指标方面均无显著差异。在处理急性水负荷或对血管加压素类似物 dDAVP 的反应方面,也检测不到基因型之间的差异。当使用 1% NaCl 负荷增强 PGE2 的产生时,也没有观察到水处理方面的差异。参与肾脏水处理的蛋白质的表达在不同基因型之间没有差异。这项研究表明,即使在 PGE2 水平较高的情况下,肾小管 EP3 对雄性或雌性动物的体液平衡也不是必不可少的。该小鼠模型是研究 EP3 在肾功能中的作用而不受潜在发育异常或全身影响的一种新工具。
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Inducible deletion of the prostaglandin EP3 receptor in kidney tubules of male and female mice has no major effect on water homeostasis.

The prostaglandin E2 (PGE2) receptor EP3 has been detected in the thick ascending limb (TAL) and the collecting duct of the kidney, where its actions are proposed to inhibit water reabsorption. However, EP3 is also expressed in other cell types, including vascular endothelial cells. The aim here was to determine the contribution of EP3 in renal water handling in male and female adult mice by phenotyping a novel mouse model with doxycycline-dependent deletion of EP3 throughout the kidney tubule (EP3-/- mice). RNAscope demonstrated that EP3 was highly expressed in the cortical and medullary TAL of adult mice. Compared with controls EP3 mRNA expression was reduced by >80% in whole kidney (RT-qPCR) and nondetectable (RNAscope) in renal tubules of EP3-/- mice. Under basal conditions, there were no significant differences in control and EP3-/- mice of both sexes in food and water intake, body weight, urinary output, or clinical biochemistries. No differences were detectable between genotypes in handling of an acute water load or in their response to the vasopressin analog 1-deamino-8-d-arginine-vasopressin (dDAVP). No differences in water handling were observed when PGE2 production was enhanced using 1% NaCl load. Expression of proteins involved in kidney water handling was not different between genotypes. This study demonstrates that renal tubular EP3 is not essential for body fluid homeostasis in males or females, even when PGE2 levels are high. The mouse model is a novel tool for examining the role of EP3 in kidney function independently of potential developmental abnormalities or systemic effects.NEW & NOTEWORTHY The prostanoid EP3 receptor is proposed to play a key role in the kidney tubule and antagonize the effects of vasopressin on aquaporin-mediated water reabsorption. Here, we phenotyped a kidney tubule-specific inducible knockout mouse model of the EP3 receptor. Our major finding is that, even under physiological stress, tubular EP3 plays no detectable role in renal water or solute handling. This suggests that other EP receptors must be important for renal salt and water handling.

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