Abstract
Local activation of ryanodine receptors (RyRs) on the sarcoplasmic reticulum in vascular smooth muscle cells (VSMCs) generates rapid subcellular changes in cellular Ca2+ that are commonly known as Ca2+ sparks. These Ca2+ sparks are well regarded for their role in the autoregulation of vascular contractility and cerebral blood flow through activation of potassium channels and feedback modulation of the membrane potential. Gestational hypoxia disrupts cerebrovascular development, increasing the risk of intracranial hemorrhage and stroke in the newborn. Due to the role of RyR’s in regulating neonatal cerebrovascular blood flow, understanding intracellular Ca2+ release patterns in VSMCs can offer insight into hypoxia-related perinatal cerebrovascular disease. The central aim of this study is to determine the extent to which gestational hypoxia disrupts RyR activity. This was achieved through examination of RyR activity in VSMCs of fetal ovine middle cerebral arteries (MCAs). MCAs were isolated from term fetal sheep (~140 days of gestation) delivered by cesarean section from ewes held at low- (700 m) and high-altitude conditions (3801 m) for 100+ days of gestation. Arteries were bathed in a physiological buffer with 5 mm K+ (control) or were treated with either 30 mM K+ (30K), to depolarize myocytes and increase Ca2+ spark events, in the presence or absence of 10 μM ryanodine, to block RyR mediated Ca2+ release. Ca2+ spark activity was measured in situ using line scan confocal microscopy fluorescence imaging techniques. Automated analysis of Ca2+ sparks in the records was conducted using SparkLab 5.8. Membrane depolarization with 30K increased Ca2+ spark activity. Long term hypoxia, however, reduced spark activity in the 30K group. Ryanodine attenuated Ca2+ spark activity in both low- and high-altitude groups. Hypoxia’s influence on the spatial and temporal aspects of Ca2+ sparks in fetal myocytes varied. These findings corroborate previous evidence demonstrating that long-term hypoxia attenuates Ca2+ spark activity. The disruption in Ca2+ spark activity could impact brain blood flow in the neonate, potentially impacting brain development and the likelihood of a traumatic event. R01HL155295, R01HL149608, Advanced Imaging and Microscopy Core Loma Linda University School of Medicine. 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.
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