Aims
to investigate α2-AR subtype distribution and the relationship between receptor amounts and their functionality in normotensive and spontaneously hypertensive rats.
Conclusion
data indicate α2-AR dysfunction and ineffectiveness of α2-AR-mediated signaling pathways in this model of cardiovascular pathologies. Results can be used for clinical practice for more effective control of cardiovascular functions in various disease states.
Methods
experiments were performed on left ventricular cardiomyocytes isolated from Wistar rats and SHR (2-2.5 months). Molecular routine tools (RT-PCR, Western blotting, immunocytochemistry) were used for semi-quantitative estimation of α2-AR subtypes. Fluorescence of both the Ca2+-dependent and NO-sensitive probes were used to define functionality of α2-AR, evaluated by changes in the dynamics of spontaneous Ca2+-transients and NO production in cardiomyocytes in response to the α2-AR agonist application.
Results
percentage of the three known α2-AR subtypes in Wistar and SHR cardiomyocytes is not principally different. Total amounts of α2A-AR subtype in SHR increases, for both the sarcolemmal and intracellular receptor pools. Total number of α2B-AR is also significantly higher in hypertensive rats with an increase in the sarcolemmal, but not the intracellular immunoreactivity. For α2C-AR subtype, no significant differences between Wistar and SHR were identified, despite the fact that its amounts in cardiomyocytes are somewhat higher than the other two subtypes. Notwithstanding the increased expression of α2-AR subtypes in SHR, α2-AR-agonist guanabenz was ineffective in suppression of spontaneous Ca2+-transients, as well as the lowering of free calcium levels in the cytosol. Guanabenz-induced NO synthesis is well correlated with the Ca2+-loading into sarcoplasmic reticulum and actually decreased in SHR cardiomyocytes.