Coronary artery constriction in rats affects the activation of alpha 1 adrenergic receptors in cardiac myocytes

Chronic coronary artery stenosis induces impaired function of remote myocardium: MRI and spectroscopy study in rat

Our purpose was to study morphological, functional, and metabolic changes induced by chronic ischemia in myocardium supplied by the stenotic vessel and in the remote area by MR techniques. A new technique of image fusion is proposed for analysis of coronary artery stenosis involving coronary MR angiography and spectroscopic imaging. Cine-MRI was performed 2 wk after induction of coronary stenosis. Global heart function and regional wall thickening were determined in 11 Wistar rats with stenosis and compared with 7 control rats. Two weeks after stenosis was induced, spin-labeling MRI for measurement of perfusion was performed in 14 isolated hearts. In eight isolated hearts with coronary stenosis, MR spectroscopy was performed, followed by angiography. 31P metabolite maps were fused with three-dimensional coronary angiograms. Induction of stenosis led to reduced segmental wall thickening (control: 75 +/- 9%, ischemic region: 9 +/- 3%, P < 0.05 vs. control) but also to impaired function of the remote region and lower cardiac output. Perfusion was reduced by 74.9 +/- 4.0% within ischemic segments compared with a septal control region. The phosphocreatine (PCr)/ATP ratio as a marker of ischemia was reduced in the region associated with stenosis (1.09 +/- 0.09) compared with remote (1.27 +/- 0.08) and control hearts (1.43 +/- 0.08; P < 0.05). The histological fraction of fibrosis within the ischemic region (12.8 +/- 1.4%) correlated to ATP signal reduction from remote to the ischemic region (r = 0.71, P < 0.05), but not to reduced wall thickening. Coronary narrowing caused declining function accompanied by diminished PCr/ATP, indicating impaired energy metabolism. Neither decline of function nor PCr signal decline correlated to fraction of fibrosis in histology. In contrast, reduction of ATP correlated to fibrosis and therefore to loss of viability. Impaired function within the ischemic region is associated with decreased PCr. Function of the remote region was affected as well. The fusion of PCr metabolite maps and the coronary angiogram may help to assess coronary morphology and resulting metabolic changes simultaneously.

Ischemic cardiomyopathy and the cellular renin-angiotensin system

BACKGROUND

Ischemic cardiomyopathy produced by non-occlusive coronary artery constriction is characterized by left ventricular failure and right ventricular dysfunction, but whether the local renin-angiotensin system (RAS) is implicated in myocyte dysfunction and cell death remains unclear.

METHODS

Changes in single-cell mechanics, the localization of the various constituents of RAS in the myocardium, and the effects of angiotensin II (Ang II) stimulation on myocyte performance and cell death were measured.

RESULTS

Chronic ischemia is coupled with alterations in the mechanical properties and calcium (Ca2+) transients of the remaining viable myocytes. The abnormalities in myocyte mechanics consist of depression in peak shortening and velocity of shortening. Moreover, peak systolic Ca2+ is significantly decreased in the cells. In vitro stimulation with Ang II ameliorates myocyte function and systolic Ca2+. Additionally, adult myocytes express genes for renin, angiotensinogen, angiotensin-converting enzyme (ACE), and Ang II receptors. Renin, ACE, and Ang II receptors mRNAs increase under the setting of impaired coronary perfusion. Similarly, the percentage of myocytes containing renin, Ang I, and Ang II increases as well. In vitro studies of neonatal and adult ventricular myocytes indicate that Ang II triggers programmed myocyte cell death and this phenomenon is mediated by activation of the AT1 receptor sub-type. Importantly, the AT1-receptor blocker, losartan, completely inhibits apoptosis.

CONCLUSIONS

These multiple observations are consistent with the notion that Ang II may exert 3 separate functions on the heart: (1) stimulation of myocyte hypertrophy, (2) amelioration of myocyte contractile performance, and (3) activation of the suicide program of myocytes.

Sprint training attenuates myocyte hypertrophy and improves Ca2+ homeostasis in postinfarction myocytes

Myocytes isolated from rat hearts 3 wk after myocardial infarction (MI) had decreased Na+/Ca2+ exchange currents (I Na/Ca; 3 Na+ out:1 Ca2+ in) and sarcoplasmic reticulum (SR)-releasable Ca2+ contents. These defects in Ca2+ regulation may contribute to abnormal contractility in MI myocytes. Because exercise training elicits positive adaptations in cardiac contractile function and myocardial Ca2+ regulation, the present study examined whether 6-8 wk of high-intensity sprint training (HIST) would ameliorate some of the cellular maladaptations observed in post-MI rats with limited exercise activity (Sed). In MI rats, HIST did not affect citrate synthase activities of plantaris muscles but significantly increased the percentage of cardiac alpha-myosin heavy chain (MHC) isoforms (57.2 +/- 1.9 vs. 49.3 +/- 3.5 in MI-HIST vs. MI-Sed, respectively; P < or = 0.05). At the single myocyte level, HIST attenuated cellular hypertrophy observed post-MI, as evidenced by reductions in cell lengths (112 +/- 4 vs. 130 +/- 5 micrograms in MI-HIST vs. MI-Sed, respectively; P < or = 0.005) and cell capacitances (212 +/- 8 vs. 242 +/- 9 pF in MI-HIST vs. MI-Sed, respectively; P < or = 0.015). Reverse I Na/Ca was significantly lower (P < or = 0.0001) in myocytes from MI-Sed rats compared with those from rats that were sham operated and sedentary. HIST significantly increased reverse I Na/Ca (P < or = 0.05) without affecting the amount of Na+/Ca2+ exchangers (detected by immunoblotting) in MI myocytes. SR-releasable Ca2+ content, as estimated by integrating forward I Na/Ca during caffeine-induced SR Ca2+ release, was also significantly increased (P < or = 0.02) by HIST in MI myocytes. We conclude that the enhanced cardiac output and stroke volume in post-MI rats subjected to HIST are mediated, at least in part, by reversal of cellular maladaptations post-MI.

Comparison of the Ca2+ movement by activation of alpha1-adrenoceptor subtypes in HEK-293 cells

We studied the Ca2+ movement induced by activation of alpha1A-, alpha1B- and alpha1D-adrenoceptor subtypes in transfected HEK-293 cells with the fura-2 probe. All these alpha1-AR subtypes induced both Ca2+ release and Ca2+ entry. The effect on Ca2+ release in alpha1b transfected HEK-293 cells was bigger than that in alpha1a and alpha1d transfected HEK-293 cells, and the effects on Ca2+ entry were the same in alpha1a, alpha1b and alpha1d transfected HEK-293 cells. The Ca2+ entry was inhibited by 1 mM NiSO4, but not by nifedipine. Cyclopiazonic acid (CPA) produced a biphasic Ca2+ signal response in Ca2+ medium, and only induced a transient response in Ca2+-free medium. After depletion of CPA-sensitive Ca2+ pool by 10 microM CPA in Ca2+-free medium, 10 microM adrenaline (Adr) still transiently increased [Ca2+]i in three different alpha1-adrenoceptor subtype transfected HEK-293 cells. However, after depletion of adrenaline-sensitive Ca2+ pool by 10 microM Adr, CPA transiently elevated [Ca2+]i only in alpha1a and alpha1d transfected HEK-293 cells, not in alpha1b transfected HEK-293 cells. U73122, a phospholipase C (PLC) inhibitor, inhibited both Ca2+ release and Ca2+ entry induced by activation of alpha1A alpha1B and alpha1D subtypes in transfected HEK-293 cells. These results suggest that HEK-293 cell line contains two functionally separate intracellular Ca2+ pools, CPA-sensitive and Adr-sensitive pools. Activation of alpha1B-AR stimulates Ca2+ release from both CPA-sensitive and Adr-sensitive Ca2+ pools. Alpha1A and alpha1D subtypes induce Ca2+ release only from Adr-sensitive Ca2+ pool.

Chronic hypoxia increases beta 1-adrenergic receptor mRNA and density but not signaling in neonatal rat cardiac myocytes

BACKGROUND

It is well recognized that the beta-adrenergic receptor-adenylylcyclase system is altered during myocardial ischemia/hypoxia. However, there are no data regarding either regulation of beta-adrenergic receptors, particularly at the mRNA level, or adenylylcyclase activity in isolated cardiac myocytes exposed to chronic hypoxia.

METHODS AND RESULTS

In a chronic hypoxia model in which neonatal rat ventricular myocytes were exposed to a 1% O2 environment for 72 hours, we investigated (1) beta 1-mRNA and receptor expression and adenylylcyclase activity and (2) beta 1-mRNA and receptor downregulation and adenylylcyclase desensitization induced by prolonged norepinephrine incubation. We found that hypoxia for 72 hours increased myocardial membrane beta 1-adrenergic receptor density by 44%. This increase was not associated with a corresponding decrease in cytosolic beta 1-adrenergic receptors. RNase protection assays demonstrated that hypoxia increased the steady-state levels of beta 1-mRNA by 109%. Adenylylcyclase activity stimulated by isoproterenol, sodium fluoride, guanyl-5'-imidodiphosphate, and forskolin in hypoxic membranes was not altered compared with normoxic controls. Hypoxia for 72 hours also did not affect norepinephrine-induced beta 1-mRNA and receptor downregulation and adenylylcyclase desensitization in response to isoproterenol, guanyl-5'-imidodiphosphate, or forskolin.

CONCLUSIONS

In neonatal rat cardiac myocytes, chronic hypoxia (1) increases beta 1-mRNA and receptor expression but does not alter adenylylcyclase activity stimulated at either the receptor or the postreceptor level and (2) does not affect agonist-induced beta 1-mRNA and receptor downregulation and desensitization of the adenylylcyclase response.

Chronic hypoxia differentially regulates alpha 1-adrenergic receptor subtype mRNAs and inhibits alpha 1-adrenergic receptor-stimulated cardiac hypertrophy and signaling

BACKGROUND

After myocardial ischemia and/or infarction, surviving cardiac myocytes in and around the injured zone develop hypertrophy to compensate for the loss of contractile units due to myocyte injury and death. One of the factors that may be involved in the development of hypertrophy after ischemic injury is norepinephrine (NE), an agent that induces hypertrophy of cardiac myocytes through the alpha 1-adrenergic receptor (AR). It is not known, however, whether hypoxia, a major component of ischemia, has any direct effect on NE-stimulated hypertrophy. Therefore, we sought to determine whether chronic hypoxia could alter NE-stimulated hypertrophy and if so, whether this alteration was related to alpha 1-AR-mediated signaling and alpha 1-AR changes at both the protein and mRNA levels.

METHODS AND RESULTS

We developed a model of chronic hypoxia in cultured neonatal rat cardiac myocytes in which myocytes were exposed to 1% oxygen for 72 hours. Initially, we observed that chronic hypoxia inhibited NE-stimulated hypertrophy, as reflected by decreases in both new protein synthesis and total protein content during chronic hypoxia. Then we found that chronic hypoxia also inhibited alpha 1-AR-transduced phosphatidylinositol hydrolysis, as indicated by a reduction in alpha 1-AR-stimulated inositol phosphate production in hypoxic cells. These observations suggested that the inhibition of NE-stimulated hypertrophy seen during chronic hypoxia was due to impairment of alpha 1-AR-mediated signaling and could result from changes in alpha 1-AR numbers and/or subtype distribution. To address this issue, we determined alpha 1-AR density and subtype distribution by radioligand binding and alpha 1-AR subtype mRNAs, including alpha 1A/D-, alpha 1B-, and alpha 1C-ARs, by RNase protection assays. We found that chronic hypoxia differentially regulated both the pharmacologically defined alpha 1-AR subtypes and the mRNAs for the alpha 1-AR subtypes. Thus, hypoxia for 72 hours coordinately downregulated both the pharmacologically defined alpha 1A-AR density and the alpha 1C-AR mRNA level. During normoxia, NE increased the pharmacologically defined alpha 1A-AR density and the alpha 1C-AR mRNA level, but hypoxia for 72 hours prevented these NE-mediated changes.

CONCLUSIONS

Chronic hypoxia (1) inhibits alpha 1-AR-mediated hypertrophy of cardiac myocytes and alpha 1-AR-transduced phosphatidylinositol hydrolysis and (2) downregulates both the pharmacologically defined alpha 1A-AR density and the alpha 1C-AR mRNA level.