Identification of adrenal genes regulated in a potassium-dependent manner

Potassium and angiotensin II are the main stimulators of aldosterone secretion from the adrenal cortex. As potassium-induced in vivo gene regulation in the adrenal cortex has not been studied in detail, we applied a stepwise screening approach: first, we investigated the effects of chronic potassium...

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Bibliographic Details
Published in:	Journal of molecular endocrinology Vol. 45; no. 4; pp. 193 - 206
Main Authors:	Dierks, Alexander, Lichtenauer, Urs D, Sackmann, Simone, Spyroglou, Ariadni, Shapiro, Igor, Geyer, Marcel, Manonopoulou, Jenny, Reincke, Martin, Hantel, Constanze, Beuschlein, Felix
Format:	Journal Article
Language:	English
Published:	England Society for Endocrinology 01-10-2010 BioScientifica
Subjects:	Adenoma - blood Adenoma - genetics Adenoma - secretion Adrenal Glands - drug effects Adrenal Glands - metabolism Adrenal Glands - pathology Aldosterone - blood Aldosterone - secretion Animals Cytochrome P-450 CYP11B2 - genetics Cytochrome P-450 CYP11B2 - metabolism Gene Expression Regulation - drug effects Gene Expression Regulation, Neoplastic - drug effects Mice Oligonucleotide Array Sequence Analysis Potassium - pharmacology Promoter Regions, Genetic - genetics Regular papers Time Factors Up-Regulation - drug effects
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Summary:	Potassium and angiotensin II are the main stimulators of aldosterone secretion from the adrenal cortex. As potassium-induced in vivo gene regulation in the adrenal cortex has not been studied in detail, we applied a stepwise screening approach: first, we investigated the effects of chronic potassium substitution in mice. Microarray analysis of adrenal glands revealed a set of genes (set A) that were counter-regulated in a high potassium (HP) and low potassium substitution group, while others (set B) were highly upregulated in the HP intake group. In a second step, time dependency of expression changes of these pre-defined genes was studied following short-term potassium stimulation experiments in vivo. Thirdly, dose dependency of potassium-induced gene regulation was investigated in vitro. Finally, to provide indirect evidence for the potential relevance of the detected changes for autonomous aldosterone secretion, expression analysis of aldosterone-producing adenomas was compared with normal adrenal glands. While most investigated genes were similarly regulated following long- and short-term potassium stimulation in vivo, observed changes were reproducible in NCI h295R adrenocortical cells mostly for the set of genes identified in the HP group (set B). Similarly, in Conn's adenomas, mostly genes from set B displayed changes in expression pattern in comparison to normal adrenal glands, while genes from set A were mostly unchanged. Thus, while in vivo models can help in identifying genes potentially involved in potassium-dependent aldosterone secretion, these findings also underline the necessity to interpret potassium-induced gene regulation on the basis of the experimental setting.
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ISSN:	0952-5041 1479-6813
DOI:	10.1677/JME-09-0171