Rat cardiac contractile dysfunction induced by Ca2+ overload: possible link to the proteolysis of α-fodrin
The aim of the present study was to examine the mechanisms of Ca2+ overload-induced contractile dysfunction in rat hearts independent of ischemia and acidosis. Experiments were performed on 30 excised cross-circulated rat heart preparations. After hearts were exposed to high Ca2+, there was a contractile failure associated with a parallel downward shift of the linear relation between myocardial O(2) consumption per beat and systolic pressure-volume area (index of a total mechanical energy per beat) in left ventricles from all seven hearts that underwent the protocol. This result suggested a decrease in O(2) consumption for total Ca2+ handling in excitation-contraction coupling. In the hearts that underwent the high Ca2+ protocol and had contractile failure, we found marked proteolysis of a cytoskeleton protein, alpha-fodrin, whereas other proteins were unaffected. A calpain inhibitor suppressed the contractile failure by high Ca2+, the decrease in O(2) consumption for total Ca2+ handling, and membrane alpha-fodrin degradation. We conclude that the exposure to high Ca2+ may induce contractile dysfunction possibly by suppressing total Ca2+ handling in excitation-contraction coupling and degradation of membrane alpha-fodrin via activation of calpain.
Recently, we have consistently observed curved endsystolic pressure-volume relations (ESPVRs) of the left ventricle (LV) in rat blood-perfused [1][2][3] and crystalloid-perfused whole heart preparations [4] and in situ ejecting rat hearts [5,6], like those of the puppy LV [7] and adult canine LV in supernormal contractility [8,9]. These studies suggest more generality of the curvilinear than linear ESPVR in different animal species. Despite this curvilinearity, we have obtained a linear myocardial oxygen consumption per Japanese Journal of Physiology, 49, 513-520, 1999 Key words: excitation-contraction coupling, oxygen consumption, E max (end-systolic pressure-volume ratio), systolic pressure-volume area (PVA). Abstract:We have already reported the linear oxygen consumption per beat (VO 2 )-systolic pressure-volume area (PVA) relation from the curved left ventricular (LV) end-systolic pressure-volume relation (ESPVR) in the cross-circulated rat heart. The VO 2 intercept (PVA-independent VO 2 ) is primarily composed of VO 2 for Ca 2ϩ handling in excitation-contraction (E-C) coupling and basal metabolism. The aim of the present study was to obtain the oxygen cost of LV contractility that indicates VO 2 for Ca 2ϩ handling in E-C coupling per unit LV contractility change in the rat heart. Oxygen cost of LV contractility is obtainable as a slope of a linear relation between PVA-independent VO 2 and LV contractility. We obtained a composite VO 2 -PVA relation line at a mid-range LV volume (mLVV) under gradually enhanced LV contractility by stepwise increased Ca 2ϩ infusion and thus the gradually increased PVA-independent VO 2 values. As a LV contractility index, we could not use E max (ESP-V ratio; ESP/ESV) for the linear ESPVR because of the curved ESPVR in the rat LV. A PVA at a mLVV (PVA mLVV ) has been proposed as a good index for assessing rat LV mechanoenergetics. Since the experimentally obtained PVA mLVV was not triangular due to the curved ESPVR, we propose an equivalent ESP-V ratio at a mLVV, (eESP/ ESV) mLVV , as a LV contractility index. This index was calculated as an ESP-V ratio of the specific virtual triangular PVA mLVV that is energetically equivalent to the real PVA mLVV . The present approach enabled us to obtain a linear relation between PVA-independent VO 2 and (eESP/ ESV) mLVV and the oxygen cost of LV contractility as the slope of this relation.
To gain insight into the pathogenesis of diabetic cardiomyopathy, we investigated cardiac function in terms of the coupling of left ventricular mechanical work and the energetics in Otsuka Long-Evans Tokushima Fatty rats, which are well known as a model of type 2 diabetes mellitus (DM). Neither left ventricular systolic function and mean coronary flow nor coronary flow reserve differed even in late DM rats. The amount of oxygen required for mechanical work and contraction was unaltered, although myosin isozyme was finally transformed from V(1) to V(3). The maximum pacing rate was decreased from 300 to 240 beats/min, and the left ventricular relaxation rate was significantly (P < 0.05) slower only in late DM rats, resulting in decreased oxygen consumption per minute for total Ca(2+) handling in excitation-contraction coupling mainly consumed by sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA2) without significant changes in basal metabolism or in mitochondrial oxidative phosphorylation. The protein level of SERCA2 in membranes was significantly (P < 0.001) lower in severe DM rats. We conclude that the only lusitropic dysfunction due to the depressed expression of SERCA2 is related to generating diabetic cardiomyopathy even in the present type 2 diabetic rats.
Regression of capillary network in atrophied soleus muscle induced by hindlimb unweighting
Little is known about the mechanisms responsible for the adaptation and changes in the capillary network of hindlimb unweighting (HU)-induced atrophied skeletal muscle, especially the coupling between functional and structural alterations of intercapillary anastomoses and tortuosity of capillaries. We hypothesized that muscle atrophy by HU leads to the apoptotic regression of the capillaries and intercapillary anastomoses with their functional alteration in hemodynamics. To clarify the three-dimensional architecture of the capillary network, contrast medium-injected rat soleus muscles were visualized clearly using a confocal laser scanning microscope, and sections were stained by terminal deoxynucleotidyltransferase-mediated dUTP nick-end labeling (TUNEL) and with anti-von Willebrand factor. In vivo, the red blood cell velocity of soleus muscle capillaries were determined with a pencil-lens intravital microscope brought into direct contact with the soleus surface. After HU, the total muscle mass, myofibril protein mass, and slow-type myosin heavy chain content were significantly lower. The number of capillaries paralleling muscle fiber and red blood cells velocity were higher in atrophied soleus. However, the mean capillary volume and capillary luminal diameter were significantly smaller after HU than in the age-matched control group. In addition, we found that the number of anastomoses and the tortuosity were significantly lower and TUNEL-positive endothelial cells were observed in atrophied soleus muscles, especially the anastomoses and/or tortuous capillaries. These results indicate that muscle atrophy by HU generates structural alterations in the capillary network, and apoptosis appears to occur in the endothelial cell of the muscle capillaries. intercapllary anastomosis; tortuosity; capillary volume; capillary lumen; erythrocyte velocity; disuse atrophy; endothelial terminal deoxynucleotidyltransferase-mediated dUTP nick-end labeling SKELETAL MUSCLE CAPILLARIES run tortuously along muscle fibers in the relaxed resting state (2,4,18,20,33). These capillaries are connected with anastomoses, which run orthogonally to muscle fiber direction like parallel rungs of ladder (12, 33). Capillary-to-fiber (C/F) ratio is frequently used to evaluate O 2 supply capacity in skeletal muscle (27). In fact, the C/F ratio is higher in rat soleus muscle, which mainly contains slow oxidative fibers (type I), than in extensor digitorum longus, which is predominantly comprised of fast glycolytic fibers (type IIb) (1, 8, 13). C/F ratio was increased by the augmentation of muscle activity, e.g., exercise or electrical stimulation (9,14,20,25), and was decreased by disuse (14, 31, 33). Histological sections from earlier studies of capillary remodeling in skeletal muscle with disuse atrophy demonstrate a decrease in capillary luminal diameter (16,36) and in the C/F ratio (13, 31, 32) despite an increase in capillary density (13,31,32).Although the regression of anastomoses in atrophied skeletal muscle has not been well studied, it wa...
We have already reported that a linear myocardial oxygen consumption per beat (VO 2 )-systolic pressurevolume area (PVA) relation in the rat left ventricle (LV) [1][2][3][4] is obtainable from a curved end-systolic pressure-volume relation as in the adult canine LV, which has normal contractility [5][6][7][8][9]. PVA is the specific area defined as a total mechanical energy per beat [8,9]. The VO 2 intercept of the VO 2 -PVA relation (PVA-independent VO 2 ) mainly consists of VO 2 for calcium (Ca 177Japanese Journal of Physiology, 51, 177-185, 2001 Key words: end-systolic pressure-volume relation, excitation-contraction coupling, myocardial oxygen consumption, systolic pressure-volume area (PVA). Abstract:We have reported the linear relation of myocardial oxygen consumption per beat (VO 2 ) and systolic pressure-volume area (PVA) in the left ventricle of the cross-circulated rat heart. The VO 2 intercept (PVA-independent VO 2 ) is primarily composed of VO 2 for Ca 2ϩ handling in excitation-contraction coupling and basal metabolism. Recently, we proposed a new index for oxygen cost of contractility obtainable as a slope of a linear relation between PVA-independent VO 2 and left ventricular contractility. This index indicates the Ca 2ϩ handling VO 2 per unit contractility change. However, a dependency of this index on heart rate has not yet been investigated. The aim of the present study was to investigate the dependency of oxygen cost of contractility on heart rate. This is a critical point to compare this cost under different heart rates. At first we found no differences of VO 2 -PVA relations at 240 and 300 beats/min (bpm). Therefore, after control VO 2 -PVA relation at 300 bpm, we gradually enhanced left ventricular contractility by Ca 2ϩ at a midrange left ventricular volume and obtained the gradually increased PVA-independent VO 2 . At each contractility level, the pacing rate was alternately changed at 240 and 300 bpm. We obtained the two composite VO 2 -PVA relation lines and found no significant differences between the slopes of PVA-independent VO 2 and left ventricular contractility relations at 240 and 300 bpm. The present results indicated no dependency of oxygen cost of left ventricular contractility on heart rates within 240-300 bpm. Based on this fact, we concluded that even under the different pacing rates within 240-300 bpm, this oxygen cost is valid for assessing cardiac mechanoenergetics, especially the economy of total Ca 2ϩ handling in E-C coupling. [Japanese Journal of Physiology, 51, 177-185, 2001] No Dependency of a New Index for Oxygen Cost of Left Ventricular Contractility on Heart Rates in the Blood-Perfused Excised Rat HeartSusumu SAKATA, Yoshimi OHGA, Takehisa ABE*, Nobuoki TABAYASHI*, Shuichi KOBAYASHI*, Tsuyoshi TSUJI*, Hisaharu KOHZUKI, Hiromi MISAWA, Shigeki TANIGUCHI*, and Miyako TAKAKI , calcium ion; E-C, excitation-contraction; eE max , equivalent maximal elastance; (eESP/ESV) mLVV , equivalent end-systolic pressure-volume ratio at a midrange left ventricular volume; E m...
O2 consumption of mechanically unloaded contractions of mouse left ventricular myocardial slices
Left ventricular (LV) myocardial slices were isolated from murine hearts (300 microm thick) and were stimulated at 1 Hz without external load. Mean myocardial slice O(2) consumption (MVo(2)) per minute (mMVo(2)) without stimulation was 0.97 +/- 0.14 ml O(2).min(-1).100 g LV(-1) and mean mMVo(2) with stimulation increased to 1.80 +/- 0.17 ml O(2).min(-1).100 g LV(-1) in normal Tyrode solution. Mean DeltamVo(2) (the mMVo(2) with stimulation - the mMVo(2) without stimulation) was 0.83 +/- 0.12 ml O(2).min(-1).100 g LV(-1). There were no differences between mean mMVo(2) with and without stimulation in Ca(2+)-free solution. The increases in extracellular Ca(2+) concentrations up to 14.4 mM did not affect the mMVo(2) without stimulation but significantly increased the mMVo(2) with stimulation up to 140% of control. The DeltamMVo(2) significantly increased up to 190% of the control in a dose-dependent manner. In contrast, the shortening did not increase in a dose-dependent manner. Cyclopiazonic acid (CPA; 30 microM) significantly reduced the DeltamMVo(2) to 0.27 +/- 0.06 ml O(2).min(-1).100 g LV(-1) (35% of control). The combination of 5 mM 2,3-butanedione monoxime (BDM) and 30 microM CPA did not further decrease DeltamMVo(2). Although BDM (3-5 mM) decreased the DeltamMVo(2) by 28-30% of control in a dose-independent manner, 3-5 mM BDM decreased shortening in a dose-dependent manner. Our results indicate that the DeltamMVo(2) of mouse LV slices during shortening under mechanically unloaded conditions consists of energy expenditure for total Ca(2+) handling during excitation-contraction coupling, basal metabolism, but no residual cross-bridge cycling.
Energy expenditure by Ba2+contracture in rat ventricular slices derives from cross-bridge cycling
To clarify the energy-expenditure mechanism during Ba2+ contracture of mechanically unloaded rat left ventricular (LV) slices, we measured myocardial O2 consumption (V˙o 2) of quiescent slices in Ca2+-free Tyrode solution andV˙o 2 during Ba2+ contracture by substituting Ca2+ with Ba2+. We then investigated the effects of cyclopiazonic acid (CPA) and 2,3-butanedione monoxime (BDM) on the Ba2+ contractureV˙o 2. The Ca2+-freeV˙o 2 corresponds to that of basal metabolism (2.32 ± 0.53 ml O2 ⋅ min−1 ⋅ 100 g LV−1). Ba2+ increased theV˙o 2 in a dose-dependent manner (from 0.3 to 3.0 mmol/l) from 110 to 150% of basal metabolic V˙o 2. Blockade of the sarcoplasmic reticulum (SR) Ca2+ pump by CPA (10 μmol/l) did not at all decrease the Ba2+-activatedV˙o 2. BDM (5 mmol/l), which specifically inhibits cross-bridge cycling, reduced the Ba2+activatedV˙o 2 almost to basal metabolic V˙o 2. These energetic results revealed that the Ba2+-activatedV˙o 2 was used for the cross-bridge cycling but not for the Ca2+ handling by the SR Ca2+ pump.
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