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Phosducin influences sympathetic activity and prevents stress-induced hypertension in humans and mice
Nadine Beetz, Michael D. Harrison, Marc Brede, Xiangang Zong, Michal J. Urbanski, Anika Sietmann, Jennifer Kaufling, Michel Barrot, Mathias W. Seeliger, Maria Augusta Vieira-Coelho, Pavel Hamet, Daniel Gaudet, Ondrej Seda, Johanne Tremblay, Theodore A. Kotchen, Mary Kaldunski, Rolf Nüsing, Bela Szabo, Howard J. Jacob, Allen W. Cowley Jr., Martin Biel, Monika Stoll, Martin J. Lohse, Ulrich Broeckel, Lutz Hein
Nadine Beetz, Michael D. Harrison, Marc Brede, Xiangang Zong, Michal J. Urbanski, Anika Sietmann, Jennifer Kaufling, Michel Barrot, Mathias W. Seeliger, Maria Augusta Vieira-Coelho, Pavel Hamet, Daniel Gaudet, Ondrej Seda, Johanne Tremblay, Theodore A. Kotchen, Mary Kaldunski, Rolf Nüsing, Bela Szabo, Howard J. Jacob, Allen W. Cowley Jr., Martin Biel, Monika Stoll, Martin J. Lohse, Ulrich Broeckel, Lutz Hein
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Research Article

Phosducin influences sympathetic activity and prevents stress-induced hypertension in humans and mice

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Abstract

Hypertension and its complications represent leading causes of morbidity and mortality. Although the cause of hypertension is unknown in most patients, genetic factors are recognized as contributing significantly to an individual’s lifetime risk of developing the condition. Here, we investigated the role of the G protein regulator phosducin (Pdc) in hypertension. Mice with a targeted deletion of the gene encoding Pdc (Pdc–/– mice) had increased blood pressure despite normal cardiac function and vascular reactivity, and displayed elevated catecholamine turnover in the peripheral sympathetic system. Isolated postganglionic sympathetic neurons from Pdc–/– mice showed prolonged action potential firing after stimulation with acetylcholine and increased firing frequencies during membrane depolarization. Furthermore, Pdc–/– mice displayed exaggerated increases in blood pressure in response to post-operative stress. Candidate gene–based association studies in 2 different human populations revealed several SNPs in the PDC gene to be associated with stress-dependent blood pressure phenotypes. Individuals homozygous for the G allele of an intronic PDC SNP (rs12402521) had 12–15 mmHg higher blood pressure than those carrying the A allele. These findings demonstrate that PDC is an important modulator of sympathetic activity and blood pressure and may thus represent a promising target for treatment of stress-dependent hypertension.

Authors

Nadine Beetz, Michael D. Harrison, Marc Brede, Xiangang Zong, Michal J. Urbanski, Anika Sietmann, Jennifer Kaufling, Michel Barrot, Mathias W. Seeliger, Maria Augusta Vieira-Coelho, Pavel Hamet, Daniel Gaudet, Ondrej Seda, Johanne Tremblay, Theodore A. Kotchen, Mary Kaldunski, Rolf Nüsing, Bela Szabo, Howard J. Jacob, Allen W. Cowley Jr., Martin Biel, Monika Stoll, Martin J. Lohse, Ulrich Broeckel, Lutz Hein

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Figure 7

Action potential firing in sympathetic neurons isolated from Pdc-deficient mice.

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Action potential firing in sympathetic neurons isolated from Pdc-deficie...
(A and B) Histology of SCG of Pdc–/– and wild-type mice. Arrows indicate perikarya of postganglionic sympathetic neurons (scale bars: 20 μm). (C and D) Response of sympathetic neurons from Pdc+/+ (C) and Pdc–/– (D) mice to acetylcholine. Application of 10 μM acetylcholine (ACh, indicated by thin bar) depolarized the membrane potential and induced a short train of action potentials (the inset shows the burst at a higher time resolution). Ten of 12 tested cells responded similar to the cell shown (bursting time <5 seconds in the presence of 10 μM acetylcholine). Sympathetic neurons from Pdc–/– mice produced extended trains of action potentials in the presence of 10 μM acetylcholine. Seven of 8 cells revealed bursting times between 10 and 40 seconds. (E) Action potential firing after membrane depolarization by current injection in isolated neurons from SCG. Neurons from Pdc–/– animals displayed a significantly higher firing frequency than wild-type neurons (n = 8 per genotype; *P < 0.05). (F–H) Currents constituting the action potentials were examined. (F) Ih currents (HCN) did not differ between Pdc–/– and wild-type neurons (n = 8 per genotype). (G) Peak Na+ currents evoked by membrane depolarization did not differ between genotypes (Pdc+/+n = 8, Pdc–/–n = 9). (H) Depolarization evoked K+ currents in the presence of Na+ and Ca2+ channel blockers. With increasing membrane depolarization, K+ currents in neurons from Pdc–/– mice were significantly larger than currents in Pdc+/+ neurons (Pdc+/+n = 5, Pdc–/–n = 8; *P < 0.05).

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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