Aldosterone-induced salt appetite requires HSD2 neurons
Silvia Gasparini, Lila Peltekian, Miriam C. McDonough, Chidera J.A. Mitchell, Marco Hefti, Jon M. Resch, Joel C. Geerling
Silvia Gasparini, Lila Peltekian, Miriam C. McDonough, Chidera J.A. Mitchell, Marco Hefti, Jon M. Resch, Joel C. Geerling
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Research Article Endocrinology Neuroscience

Aldosterone-induced salt appetite requires HSD2 neurons

Abstract

Excessive aldosterone production increases the risk of heart disease, stroke, dementia, and death. Aldosterone increases both sodium retention and sodium consumption, and increased sodium consumption may worsen end-organ damage in patients with aldosteronism. Preventing this increase could improve outcomes, but the behavioral mechanisms of aldosterone-induced sodium appetite remain unclear. In rodents, we previously identified aldosterone-sensitive neurons, which express the mineralocorticoid receptor and its prereceptor regulator, 11-β-hydroxysteroid dehydrogenase 2 (HSD2). In the present study, we identified HSD2 neurons in the human brain and then used a mouse model to evaluate their role in aldosterone-induced salt intake. First, we confirmed that dietary sodium deprivation increases aldosterone production, salt intake, and HSD2 neuron activity. Next, we showed that continuous chemogenetic stimulation of HSD2 neurons causes a large and specific increase in salt intake. Finally, we used dose-response studies and genetically targeted ablation of HSD2 neurons to show that these neurons are necessary for aldosterone-induced salt intake. Identifying HSD2 neurons in the human brain and establishing their necessity for aldosterone-induced salt intake in mice improves our understanding of appetitive circuits and highlights this small cell population as a therapeutic target for moderating dietary sodium.

Authors

Silvia Gasparini, Lila Peltekian, Miriam C. McDonough, Chidera J.A. Mitchell, Marco Hefti, Jon M. Resch, Joel C. Geerling

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Figure 6

Effect of HSD2 neuron ablation on aldosterone-induced salt intake.

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Effect of HSD2 neuron ablation on aldosterone-induced salt intake. (A) I...
(A) Intact distribution of 11-β-hydroxysteroid dehydrogenase-expressing neurons (HSD2, green) after bilateral injections of AAV-mCherry-DIO-dtA into the NTS of a Cre control mouse. (B) Few HSD2 neurons remained in an Hsd11b2-Cre+ experimental mice. Scale bar: 100 μm. In both A and B, neighboring catecholaminergic neurons are evident by their immunoreactivity for tyrosine hydroxylase (TH, blue). (C) This ablation method successfully reduced the number of HSD2 neurons (P < 0.0001). Gray dot indicates experimental case #3383, which we excluded from subsequent analysis because it did not meet the prespecified criterion of fewer than 50% of the average HSD2 neuron number in control mice. (DF) Effects of HSD2 neuronal ablation on 3% NaCl and water intake in mice receiving i4V aldosterone (10 ng/h). Gray dot in E again represents case #3383. In D, inset, P = 0.0034. In F, inset, P = 0.1368. (GI) Effects of HSD2 neuron ablation on 3% NaCl and water intake in mice receiving s.c. aldosterone (1,000 ng/h). In G, inset, P < 0.0001. In I, inset, P = 0.2106. (J) Scatter plot showing saline (y axis) versus water (x axis) intake of every experimental and control mouse receiving i4V or s.c. aldosterone. (K) Hsd11b2-Cre–dependent ablation did not alter the number of neurons NTS catecholaminergic (TH-immunoreactive) neurons (P = 0.1584). *P < 0.05 by unpaired, 2-tailed t test.