Intestinal and Renal Adaptations to Changes of Dietary Phosphate Concentrations in Rat

Function Pub Date : 2023-11-13 DOI:10.1093/function/zqad063

Susana Lucea, Gema Chopo-Escuin, Natalia Guillén, Cecilia Sosa, Víctor Sorribas

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Abstract

Abstract We have studied the role of the intestine, kidney, and several hormones when adapting to changes in dietary P concentration. Normal and parathyroidectomized (PTX) rats were fed pH-matched diets containing 0.1%, 0.6%, and 1.2% P concentrations. 32Pi uptake was determined in jejunum and kidney cortex brush border membrane vesicles. Several hormone and ion concentrations were determined in the blood and urine of rats. Both jejunum and kidney cortex Pi transport was regulated with 5 days of chronic feeding of P diets in normal rats. Acute adaptation was determined by switching foods on day six, which was only clearly observed in the kidney cortex of normal rats, with more statistical variability in the jejunum. However, no paradoxical increase of Pi uptake in the jejunum was reproduced after the acute switch to the 1.2% P diet. Pi uptake in the jejunum was PTH-independent, but in the kidney, the chronic adaptation was reduced, and no acute dietary adaptations were observed. The NaPi2a protein was more abundant in the PTX than the sham kidneys, but contrary to the modest or absent changes in Pi uptake adaptation, the transporter was similarly regulated by dietary P, as in the sham rats. PTH and FGF23 were the only hormones regulated by all diet changes, even in fasting animals, which exhibited regulated Pi transport despite similar phosphatemia. Evidence of Pi appetite effects was also observed. In brief, our results show new characteristics of Pi adaptations, including a lack of correlation between Pi transport, NaPi2a expression, and PTH/FGF23 concentrations.

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大鼠肠道和肾脏对饲粮磷酸盐浓度变化的适应

我们研究了肠道、肾脏和几种激素在适应饲粮磷浓度变化时的作用。正常大鼠和去甲状旁腺(PTX)大鼠分别饲喂ph匹配的饲粮，饲粮中磷浓度分别为0.1%、0.6%和1.2%。在空肠和肾皮质刷边膜小泡中检测32Pi的摄取。测定了大鼠血液和尿液中几种激素和离子的浓度。正常大鼠长期饲喂磷饲料5 d，可调节空肠和肾皮质Pi的转运。急性适应是通过在第六天更换食物来确定的，这只在正常大鼠的肾皮质中清楚地观察到，在空肠中有更多的统计变异性。然而，在急性切换到1.2%磷日粮后，空肠中磷摄取没有出现矛盾的增加。空肠中的Pi摄取与甲状旁腺素无关，但在肾脏中，慢性适应减少，没有观察到急性饮食适应。NaPi2a蛋白在PTX中比假肾更丰富，但与Pi摄取适应的适度或不存在变化相反，转运蛋白同样受到膳食P的调节，就像假大鼠一样。PTH和FGF23是唯一受所有饮食变化调节的激素，即使在禁食动物中，尽管类似的磷血症，它们也表现出受调节的Pi运输。还观察到Pi食欲效应的证据。简而言之，我们的研究结果显示了Pi适应的新特征，包括Pi运输，NaPi2a表达和PTH/FGF23浓度之间缺乏相关性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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