Jing Li1, Mohan K Raizada, Elaine M Richards. 1. Department of Physiology and Functional Genomics, University of Florida College of Medicine, Gainesville, FL, USA.
Abstract
PURPOSE OF REVIEW: Rapidly emerging evidence implicates an important role of gut-brain-bone marrow (BM) axis involving gut microbiota (GM), gut epithelial wall permeability, increased production of pro-inflammatory BM cells and neuroinflammation in hypertension (HTN). However, the precise sequence of events involving these organs remains to be established. Furthermore, whether an impaired gut-brain-BM axis is a cause or consequence of HTN is actively under investigation. This will be extremely important for translation of this fundamental knowledge to novel, innovative approaches for the control and management of HTN. Therefore, our objectives are to summarize the latest hypothesis, provide evidence for and against the impaired gut, BM and brain interactions in HTN and discuss perspectives and future directions. RECENT FINDINGS: Hypertensive stimuli activate autonomic neural pathways resulting in increased sympathetic and decreased parasympathetic cardiovascular modulation. This directly affects the functions of cardiovascular-relevant organs to increase blood pressure. Increases in sympathetic drive to the gut and BM also trigger sequences of signaling events that ultimately contribute to altered GM, increased gut permeability, enhanced gut- and brain-targeted pro-inflammatory cells from the BM in perpetuation and establishment of HTN. SUMMARY: In this review, we present the mechanisms involving the brain, gut, and BM, whose dysfunctional interactions may be critical in persistent neuroinflammation and key in the development and establishment of HTN.
PURPOSE OF REVIEW: Rapidly emerging evidence implicates an important role of gut-brain-bone marrow (BM) axis involving gut microbiota (GM), gut epithelial wall permeability, increased production of pro-inflammatory BM cells and neuroinflammation in hypertension (HTN). However, the precise sequence of events involving these organs remains to be established. Furthermore, whether an impaired gut-brain-BM axis is a cause or consequence of HTN is actively under investigation. This will be extremely important for translation of this fundamental knowledge to novel, innovative approaches for the control and management of HTN. Therefore, our objectives are to summarize the latest hypothesis, provide evidence for and against the impaired gut, BM and brain interactions in HTN and discuss perspectives and future directions. RECENT FINDINGS: Hypertensive stimuli activate autonomic neural pathways resulting in increased sympathetic and decreased parasympathetic cardiovascular modulation. This directly affects the functions of cardiovascular-relevant organs to increase blood pressure. Increases in sympathetic drive to the gut and BM also trigger sequences of signaling events that ultimately contribute to altered GM, increased gut permeability, enhanced gut- and brain-targeted pro-inflammatory cells from the BM in perpetuation and establishment of HTN. SUMMARY: In this review, we present the mechanisms involving the brain, gut, and BM, whose dysfunctional interactions may be critical in persistent neuroinflammation and key in the development and establishment of HTN.
Authors: Marta Toral; Iñaki Robles-Vera; Néstor de la Visitación; Miguel Romero; Manuel Sánchez; Manuel Gómez-Guzmán; Alba Rodriguez-Nogales; Tao Yang; Rosario Jiménez; Francesca Algieri; Julio Gálvez; Mohan K Raizada; Juan Duarte Journal: Acta Physiol (Oxf) Date: 2019-06-02 Impact factor: 6.311
Authors: Vitor U De Melo; Rayssa R M Saldanha; Carla R Dos Santos; Josiane De Campos Cruz; Vitor A Lira; Valter J Santana-Filho; Lisete C Michelini Journal: Front Physiol Date: 2016-10-13 Impact factor: 4.566
Authors: Nicola Wilck; Mariana G Matus; Sean M Kearney; Scott W Olesen; Kristoffer Forslund; Hendrik Bartolomaeus; Stefanie Haase; Anja Mähler; András Balogh; Lajos Markó; Olga Vvedenskaya; Friedrich H Kleiner; Dmitry Tsvetkov; Lars Klug; Paul I Costea; Shinichi Sunagawa; Lisa Maier; Natalia Rakova; Valentin Schatz; Patrick Neubert; Christian Frätzer; Alexander Krannich; Maik Gollasch; Diana A Grohme; Beatriz F Côrte-Real; Roman G Gerlach; Marijana Basic; Athanasios Typas; Chuan Wu; Jens M Titze; Jonathan Jantsch; Michael Boschmann; Ralf Dechend; Markus Kleinewietfeld; Stefan Kempa; Peer Bork; Ralf A Linker; Eric J Alm; Dominik N Müller Journal: Nature Date: 2017-11-15 Impact factor: 49.962