Changes in cardiac mechanics with heat acclimation: adrenergic signaling and SR-Ca regulatory proteins.

The involvement of adrenergic signaling and sarcoplasmic calcium regulatory proteins in the development of heat acclimation-induced adaptations in cardiac mechanics was studied in heat-acclimated (34 degrees C) rats for 2, 5, and 30 days (AC(2), AC(5), and AC(30), respectively). Control (C) rats were held at 24 +/- 1 degrees C. Systolic pressure (LVP) and velocities of contraction (dP/dt/P) and relaxation (-dP/dt/P) were measured using a Langendorff system. For adrenergic signaling, beta-adrenoreceptor (AR) density and affinity (Scatchard plots) and cardiac inotropic response to norepinephrine (10(-7) mM, +/- 10(-6) mM propranolol) were measured. For the regulatory proteins, steady-state levels of Ca(2+)-ATPase and phospholamban (PLB) mRNAs and the encoded proteins Ca(2+)-ATPase [sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA)] and PLB were measured using semiquantitative RT-PCR and Western immunoblotting, respectively. Both short (STHA; AC(2) and AC(5))- and long-term heat acclimation (LTHA; AC(30)) enhanced LVP. However, dP/dt. P and -dP/dt. P in STHA hearts resembled that of the controls, whereas on LTHA, both parameters decreased (P < 0.05), implying decreased velocity of contraction and relaxation. beta-AR density remained unchanged with their affinity markedly decreased (P < 0.05). AR responsiveness, however, diminished in AC(2) but was markedly enhanced on LTHA. During STHA, PLB and sarcoplasmic reticulum Ca(2+)-ATPase transcripts were upregulated with no change in the encoded proteins except for SERCA downregulation on AC(5), leading to an increased PLB/SERCA ratio (P < 0.05). This mismatched preacclimation lusitropic state on STHA and increased PLB/SERCA ratio was evident (P < 0.05) due to downregulation of SERCA and upregulation of PLB. Our data fit a biphasic acclimation model in which desensitized adrenergic signaling is dominant during STHA, whereas on LTHA, the contractile machinery is influenced by altered expression of the calcium regulatory proteins leading to both augmented adrenergic inotropic response (via PLB elevation) and decreased velocity of relaxation. The sustained low thyroxin measured on LTHA causally associates with this response.

Heat acclimation induces changes in cardiac mechanical performance: the role of thyroid hormone.

The involvement of reduced thyroxine level in the emergence of heat acclimation-induced negative lusitropic effect was examined. Experiments were carried out on 1) control rat hearts maintained at 24 +/- 1 degreesC (C); 2) rat hearts acclimated at 34 degreesC for 1 mo (AC); 3) AC-euthyroid rat hearts, via administration of thyroxine in the drinking water (AT); and 4) hypothyroid rat hearts, maintained at 24 +/- 1 degreesC, via administration of thiouracil in the drinking water (CP). Systolic pressure and velocities of contraction (dP/dt. P) and relaxation (-dP/dt. P) were measured using the Langendorff perfusion system. The steady-state levels of Ca2+-ATPase and phospholamban mRNAs and the expression of the encoded proteins Ca2+-ATPase (SERCA) and phospholamban (PLB) were measured, using semi-quantitative RT-PCR and Western immunoblotting, respectively. Rat thyroxine levels were measured using RIA. Heat acclimation, which brought about a reduced thyroxine level, led to downregulation of Ca2+-ATPase mRNA expression and translation and upregulation of phospholamban mRNA and PLB. Consequently, the PLB-to-SERCA ratio (PLB/SERCA) of the AC hearts showed a significant increase. These changes, as well as the greater pressure generation and the reduced dP/dt. P and -dP/dt. P observed in AC hearts were blunted in the AT hearts. Our data suggest that sustained heat acclimation-induced low thyroxine level has a decisive effect on the contractile machinery of the AC heart. Elevated PLB/SERCA apparently explains the negative lusitropic effect observed in these hearts.