Hannah Costello, G. Crislip, K. Cheng, Annalisse R. Mckee, Victor M. Mendez, Lauren A. Douma, M. Gumz
{"title":"肾上腺昼夜节律时钟蛋白 BMAL1 以性别和时间依赖的方式调节醛固酮和肾脏排泄功能","authors":"Hannah Costello, G. Crislip, K. Cheng, Annalisse R. Mckee, Victor M. Mendez, Lauren A. Douma, M. Gumz","doi":"10.1152/physiol.2024.39.s1.639","DOIUrl":null,"url":null,"abstract":"BMAL1 is a core circadian clock protein that is important for circadian rhythms of physiological function, as well as maintaining physiological homeostasis, including aspects of kidney function. Global Bmal1 knockout (KO) male mice exhibit loss of diurnal rhythm of renal sodium (Na) excretion in response to a normal or high salt diet. However, renal Na excretion rhythm remained intact in kidney-specific Bmal1 KO male mice. The adrenal gland synthesizes hormones, such as aldosterone, which influence renal electrolyte handling. The role of adrenal BMAL1 in the regulation of renal function remains unknown. The study objective was to test the hypothesis that adrenal BMAL1 is required for normal rhythms of aldosterone and renal Na handling. Male and female adrenal-specific aldosterone synthase Cre positive (AS) Bmal1 KO and littermate Cre negative, floxed control mice ( n=5-9/genotype) were acclimated to metabolic cages for 3 days then samples were collected for three days with mice on a normal salt diet followed by 7 days on a low salt diet to challenge the mice to stimulate aldosterone production. Twelve-hour food intake was measured, and urine samples were collected to measure night/day patterns in renal Na balance. Urinary aldosterone excretion was measured by ELISA. Both day and night urinary aldosterone excretion were increased following a low salt diet in control and KO male mice (ANOVA main effect of diet, p<0.05). Male AS Bmal1 KO mice displayed a significant increase in day urinary aldosterone excretion following a normal and low salt diet (ANOVA main effect of genotype, p=0.0230), with a trend for an increase in night urinary aldosterone excretion ( p=0.0571). Interestingly, these genotype effects were not seen in female AS Bmal1 KO mice. Urinary aldosterone was increased following a low salt diet in female mice, but only during the nighttime in control and KO mice ( p=0.0205). Sex differences were also observed in renal Na balance, where Na balance was more positive during the day in male, but not female, AS Bmal1 KO vs. control mice (ANOVA main effect of genotype, p=0.0282). Together, these data suggest adrenal BMAL1 is required for normal rhythms of aldosterone and renal Na balance in a sex-dependent manner. Future work will investigate whether the changes in aldosterone contribute to changes in renal Na balance. This work was supported by the American Heart Association (Postdoctoral FellowshipP0240441 to H.C.; Established Investigator Award 19EIA34660135 to M.G), theRobert and Mary Cade Professorship in Physiology (to M.G.) and the NIH(F32DK121424 to G.R.C.). 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Male and female adrenal-specific aldosterone synthase Cre positive (AS) Bmal1 KO and littermate Cre negative, floxed control mice ( n=5-9/genotype) were acclimated to metabolic cages for 3 days then samples were collected for three days with mice on a normal salt diet followed by 7 days on a low salt diet to challenge the mice to stimulate aldosterone production. Twelve-hour food intake was measured, and urine samples were collected to measure night/day patterns in renal Na balance. Urinary aldosterone excretion was measured by ELISA. Both day and night urinary aldosterone excretion were increased following a low salt diet in control and KO male mice (ANOVA main effect of diet, p<0.05). Male AS Bmal1 KO mice displayed a significant increase in day urinary aldosterone excretion following a normal and low salt diet (ANOVA main effect of genotype, p=0.0230), with a trend for an increase in night urinary aldosterone excretion ( p=0.0571). 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引用次数: 0
摘要
BMAL1是一种核心昼夜节律钟蛋白,对生理功能的昼夜节律以及维持生理平衡(包括肾功能的各个方面)非常重要。全球 Bmal1 基因敲除(KO)雄性小鼠在正常或高盐饮食条件下,肾脏钠(Na)排泄的昼夜节律消失。然而,肾脏特异性 Bmal1 KO 雄性小鼠的肾脏钠排泄节律保持不变。肾上腺合成的激素(如醛固酮)会影响肾电解质的处理。肾上腺 BMAL1 在肾功能调节中的作用尚不清楚。本研究的目的是验证肾上腺 BMAL1 是醛固酮和肾钠处理正常节律所必需的这一假设。将雄性和雌性肾上腺特异性醛固酮合成酶 Cre 阳性(AS)Bmal1 KO 小鼠和同窝 Cre 阴性、Floxed 对照小鼠(n=5-9/基因型)在代谢笼中驯化 3 天,然后在小鼠摄入正常盐饮食的 3 天内采集样本,随后摄入低盐饮食 7 天,以刺激小鼠产生醛固酮。对小鼠 12 小时的食物摄入量进行测量,并收集尿样以测量肾脏钠平衡的日夜模式。尿液中醛固酮的排泄量是通过酶联免疫吸附法测定的。对照组和 KO 雄性小鼠在低盐饮食后,昼夜尿醛固酮排泄量均增加(饮食的方差分析主效应,P<0.05)。雄性 AS Bmal1 KO 小鼠在正常和低盐饮食后,日尿醛固酮排泄量显著增加(方差分析基因型的主效应,p=0.0230),夜尿醛固酮排泄量也有增加趋势(p=0.0571)。有趣的是,这些基因型效应在雌性 AS Bmal1 KO 小鼠中未见。雌性小鼠在低盐饮食后尿醛固酮增加,但对照组和 KO 小鼠仅在夜间增加(p=0.0205)。在肾脏 Na 平衡方面也观察到了性别差异,雄性 AS Bmal1 KO 小鼠与对照组相比,在白天 Na 平衡更积极,而雌性则不然(基因型的方差分析主效应,p=0.0282)。总之,这些数据表明肾上腺 BMAL1 是醛固酮和肾钠平衡正常节律所必需的,且具有性别依赖性。未来的工作将研究醛固酮的变化是否会导致肾脏 Na 平衡的变化。这项工作得到了美国心脏协会(H.C.获博士后奖学金P0240441;M.G.获19EIA34660135设立的研究者奖)、罗伯特和玛丽-凯德生理学教授职位(M.G.)以及美国国立卫生研究院(G.R.C.获F32DK121424)的支持。这是在 2024 年美国生理学峰会上发表的摘要全文,只有 HTML 格式。本摘要没有附加版本或附加内容。生理学》未参与同行评审过程。
Adrenal circadian clock protein BMAL1 regulates aldosterone and renal excretory function in a sex- and time-dependent manner
BMAL1 is a core circadian clock protein that is important for circadian rhythms of physiological function, as well as maintaining physiological homeostasis, including aspects of kidney function. Global Bmal1 knockout (KO) male mice exhibit loss of diurnal rhythm of renal sodium (Na) excretion in response to a normal or high salt diet. However, renal Na excretion rhythm remained intact in kidney-specific Bmal1 KO male mice. The adrenal gland synthesizes hormones, such as aldosterone, which influence renal electrolyte handling. The role of adrenal BMAL1 in the regulation of renal function remains unknown. The study objective was to test the hypothesis that adrenal BMAL1 is required for normal rhythms of aldosterone and renal Na handling. Male and female adrenal-specific aldosterone synthase Cre positive (AS) Bmal1 KO and littermate Cre negative, floxed control mice ( n=5-9/genotype) were acclimated to metabolic cages for 3 days then samples were collected for three days with mice on a normal salt diet followed by 7 days on a low salt diet to challenge the mice to stimulate aldosterone production. Twelve-hour food intake was measured, and urine samples were collected to measure night/day patterns in renal Na balance. Urinary aldosterone excretion was measured by ELISA. Both day and night urinary aldosterone excretion were increased following a low salt diet in control and KO male mice (ANOVA main effect of diet, p<0.05). Male AS Bmal1 KO mice displayed a significant increase in day urinary aldosterone excretion following a normal and low salt diet (ANOVA main effect of genotype, p=0.0230), with a trend for an increase in night urinary aldosterone excretion ( p=0.0571). Interestingly, these genotype effects were not seen in female AS Bmal1 KO mice. Urinary aldosterone was increased following a low salt diet in female mice, but only during the nighttime in control and KO mice ( p=0.0205). Sex differences were also observed in renal Na balance, where Na balance was more positive during the day in male, but not female, AS Bmal1 KO vs. control mice (ANOVA main effect of genotype, p=0.0282). Together, these data suggest adrenal BMAL1 is required for normal rhythms of aldosterone and renal Na balance in a sex-dependent manner. Future work will investigate whether the changes in aldosterone contribute to changes in renal Na balance. This work was supported by the American Heart Association (Postdoctoral FellowshipP0240441 to H.C.; Established Investigator Award 19EIA34660135 to M.G), theRobert and Mary Cade Professorship in Physiology (to M.G.) and the NIH(F32DK121424 to G.R.C.). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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