Neuro-inflammatory interactions as a mediator of the Exaggerated Exercise Pressor Reflex (EPR) in a mouse model of Peripheral Artery Disease

Abstract

Introduction and rationale: The Exercise pressor reflex (EPR) is a physiological mechanism in which the contraction of skeletal muscle results in a rise in heart rate (HR) and mean arterial pressure (MAP). In patients with Peripheral Artery Disease (PAD), this reflex is exaggerated, leading to abnormally high elevations in blood pressure during exercise. These cardiovascular responses in patients with PAD have been linked to increased morbidity and mortality, thus limiting the prescription of exercise for these patients. Using a novel murine model of the EPR, our laboratory has demonstrated that mice with femoral artery ligation (a well-established model of PAD), exhibit augmented increases in MAP which is mediated by PIEZO2 positive, mechanosensitive afferent neurons. We have demonstrated that inhibition of PIEZO2 expressing channels normalizes the MAP response to exercise. Patients with PAD also display increased macrophage infiltration in their ischemia-injured limbs, indicating a pro-inflammatory environment. Sensory neurons have been reported to detect various signals produced by immune cells including IL-1β and TNFα. The immune-derived signals can sensitize the peripheral terminals of the sensory neurons, thereby reducing their firing threshold and increasing their responsiveness. Previous studies have also reported the enhancement of Piezo2-mediated mechanosensitive currents in the presence of inflammatory signals. Hypothesis: We, therefore, hypothesize that in mice with femoral artery ligation, muscle inflammation increases the expression and activation of resident ion channels (e.g., Piezo2) in mechanosensitive afferent neurons to mediate the exaggerated EPR in PAD.Study objective: To mechanistically investigate the interaction between muscle inflammation and Piezo2 in mechanosensitive afferent neurons.Methods: We performed sham surgery or ligation of the femoral artery ipsilaterally in C57BL/6 mice. After 72 hours, we harvested the gastrocnemius muscle for histological and molecular analyses.Data and summary and results: Our preliminary findings reveal that there is significantly increased expression of pro-inflammatory genes and infiltrating immune cells in the ischemic muscle when compared to non-ischemic muscle.Specifically, H&E staining revealed the presence and accumulation of inflammatory cells, including macrophages, in the ischemic muscle compared to control, along with observed necrosis. Transcript analysis of the ischemic gastrocnemius muscle showed significantly increased IL-1β and TNFα, two pan-proinflammatory genes that encode cytokines released by macrophages. TNFα is known to induce the synthesis of adhesion molecules (E-selectin and ICAM-1) on endothelial cells, allowing leukocytes to adhere and cross the endothelial wall into the injured tissue. Indeed, we observed significantly increased ICAM-1 and E-selectin transcripts in the ischemic muscle compared to controls. MCP1, a well-established chemokine, was also significantly increased, further emphasizing the recruitment of leukocytes to the ischemic muscle. In addition, inducible NOS ( iNOS), which is known to be expressed in IL-1β- and TNFα-rich proinflammatory environment was also significantly increased in our FAL model compared to Sham. These data establish that the ischemic muscle of a femoral-artery ligated mouse has a high proinflammatory phenotype. We are currently exploring the impact of proinflammatory mediators on Piezo2 channel expression and activity, as well as the effect of macrophage depletion on Piezo2 in afferent neurons. The data from these studies will provide novel insights regarding the influence of neuroimmune interactions on cardiovascular responses to exercise in PAD. These data hold the potential to reveal innovative therapies enabling safe prescription of exercise, thus alleviating the burden of PAD, and improving the quality of life for those affected by this condition. Internal sources. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.