Study sheds new light on link between salt intake and blood pressure
While the link between salt and hypertension is well known, scientists until now haven’t understood how high salt intake increased blood pressure. By studying the brains of rats, a team led by Prof. Charles Bourque of McGill’s Faculty of Medicine and researcher of the Centre for Research in Neurosciences at the Research Institute of the McGill University Health Centre (RI-MUHC) discovered that ingesting large amounts of dietary salt causes changes in key brain circuits.
“We found that a period of high dietary salt intake in rats causes a biochemical change in the neurons that release vasopressin (VP) into the systemic circulation”, says Bourque. “This change, which involves a neurotrophic molecule called BDNF (brain-derived neurotrophic factor), prevents the inhibition of these particular neurons by other cells”.
The team’s findings, published today in the journal Neuron, found that high salt intake prevents the inhibition of VP neurons by the body’s arterial pressure detection circuit. The disabling of this natural safety mechanism allows blood pressure to rise when a high amount of salt is ingested over a long period of time.
While the team’s discovery advances the understanding of the link between salt intake and blood pressure, more work is needed to define new targets that could potentially be explored for therapeutic intervention. Among the questions for further research: Does the same reprogramming effect hold true for humans? If so, how might it be reversed?
In the meantime, Bourque says, the message remains: limit dietary salt.
Scientists from the University of North Texas Health Sciences Centre, Neurocentre Magendie, France and Centre for Neuroendocrinology, University of Otago, New Zealand also contributed to this study.
The research was supported by the Canadian Institutes of Health Research, National Institutes of Health, and the Fonds de recherche du Québec – Santé.
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Original research article
“High Salt Intake Increases Blood Pressure via BDNF Mediated Downregulation ofKCC2 and Impaired Baroreflex Inhibition of Vasopressin Neurons” Katrina Y. Choe, Su Y. Han, Perrine Gaub, Brent Shell, Daniel L. Voisin, Blayne A. Knapp, Philip A. Barker, Colin H. Brown, J. Thomas Cunningham, and Charles W. Bourque. Neuron, Jan. 22, 2015.
More from the lab of Prof. Bourque:
http://www.mcgill.ca/reporter/39/06/bourque/
Source of text: McGill University