In cardiac myocytes, initiation of excitation-contraction coupling is highly localized near the T-tubule network. Myocytes with a dense T-tubule network exhibit rapid and homogeneous sarcoplasmic reticulum (SR) Ca2+ release throughout the cell. We examined whether progressive changes in T-tubule organization and Ca 2+ release synchrony occur in a murine model of congestive heart failure (CHF). Myocardial infarction (MI) was induced by ligation of the left coronary artery, and CHF was diagnosed by echocardiography (left atrial diameter >2.0 mm). CHF mice were killed at 1 or 3 weeks following MI (1-week CHF, 3-week CHF) and cardiomyocytes were isolated from viable regions of the septum, excluding the MI border zone. Septal myocytes from SHAM-operated mice served as controls. T-tubules were visualized by confocal microscopy in cells stained with di-8-ANEPPS. SHAM cells exhibited a regular striated T-tubule pattern. However, 1-week CHF cells showed slightly disorganized T-tubule structure, and more profound disorganization occurred in 3-week CHF with irregular gaps between adjacent T-tubules. The authors are indebted to Dr Gregory R. Ferrier who contributed immeasurably to the inception of this project during his sabbatical in Oslo. Sadly, he passed away before its completion. This manuscript is dedicated to his memory. channels (ryanodine receptors) are in close proximity (Flucher & Franzini-Armstrong, 1996). Thus, initiation of excitation-contraction coupling is highly localized near the T-tubule network (Shacklock et al. 1995).In myocytes with a high density of T-tubules, such as in rats and mice, SR Ca 2+ release occurs almost simultaneously throughout the cell (Berlin, 1995; Shacklock et al. 1995;Heinzel et al. 2002). However, myocytes with less-dense T-tubule networks exhibit less synchronous Ca 2+ transients, with regions of delayed Ca 2+ release occurring where T-tubules are not present (Heinzel et al. 2002) sarcolemma, but more slowly in the cell interior following propagation of Ca 2+ (Berlin, 1995;Cordeiro et al. 2001). Experimentally promoting loss of T-tubules by cell culture or de-tubulation techniques has also been shown to reduce the synchrony of Ca 2+ transients, which results in slower spatially averaged Ca 2+ release (Lipp et al. 1996;Yang et al. 2002;Louch et al. 2004). Thus, there is considerable evidence to suggest that a dense and intact T-tubular network is required for rapid and homogeneous SR Ca 2+ release.Several reports have suggested that the T-tubular network may be altered in heart failure. A marked loss of T-tubules has been observed in failing canine ventricular myocytes (He et al. 2001;Balijepalli et al. 2003), although it is unclear whether such changes occur in human heart failure (Kaprielian et al. 2000;Wong et al. 2001;Ohler et al. 2001). However, the structural organization of T-tubules may be altered in failing human cardiomyocytes (Kostin et al. 1998;Kaprielian et al. 2000;Wong et al. 2001;Louch et al. 2004). It is not known how such disorganization may influence excitation-...
Alterations in trans-sarcolemmal and sarcoplasmic reticulum (SR) Ca2+ fluxes may contribute to impaired cardiomyocyte contraction and relaxation in heart failure. We investigated the mechanisms underlying heart failure progression in mice with conditional, cardiomyocyte-specific excision of the SR Ca 2+ -ATPase (SERCA) gene. At 4 weeks following gene deletion (4-week KO) cardiac function remained near normal values. However, end-stage heart failure developed by 7 weeks (7-week KO) as systolic and diastolic performance declined. Contractions in isolated myocytes were reduced between 4-and 7-week KO, and relaxation was slowed.
Deterioration of cardiac contractility during congestive heart failure (CHF) is believed to involve decreased function of individual cardiomyocytes and may include reductions in contraction magnitude and/or kinetics. We examined the progression of in vivo and in vitro alterations in contractile function in CHF mice and investigated underlying alterations in Ca2+ homeostasis. Following induction of myocardial infarction (MI), mice with CHF were examined at early (1 wk post-MI) and chronic (10 wk post-MI) stages of disease development. Sham-operated mice served as controls. Global and local left ventricle function were assessed by echocardiography in sedated animals (∼2% isoflurane). Excitation-contraction coupling was examined in cardiomyocytes isolated from the viable septum. CHF progression between 1 and 10 wk post-MI resulted in increased mortality, development of hypertrophy, and deterioration of global left ventricular function. Local function in the noninfarcted myocardium also declined, as posterior wall shortening velocity was reduced in chronic CHF (1.2 ± 0.1 vs. 1.9 ± 0.2 cm/s in sham). Parallel alterations occurred in isolated cardiomyocytes since contraction and Ca2+ transient time to peak values were prolonged in chronic CHF (115 ± 6 and 158 ± 11% sham values, respectively). Surprisingly, contraction and Ca2+ transient magnitudes in CHF were larger than sham values at both time points, resulting from increased sarcoplasmic reticulum Ca2+ content and greater Ca2+ influx via L-type channels. We conclude that, in mice with CHF following myocardial infarction, declining myocardial function involves slowing of cardiomyocyte contraction without reduction in contraction magnitude. Corresponding alterations in Ca2+ transients suggest that slowing of Ca2+ release is a critical mediator of CHF progression.
Trigger Ca(2+) is considered to be the Ca(2+) current through the L-type Ca(2+) channel (LTCC) that causes release of Ca(2+) from the sarcoplasmic reticulum. However, cell contraction also occurs in the absence of the LTCC current (I(Ca)). In this article, we investigate the contribution of the Na(+)/Ca(2+) exchanger (NCX) to the trigger Ca(2+). Experimental data from rat cardiomyocytes using confocal microscopy indicating that inhibition of reverse mode Na(+)/Ca(2+) exchange delays the Ca(2+) transient by 3-4 ms served as a basis for the mathematical model. A detailed computational model of the dyadic cleft (fuzzy space) is presented where the diffusion of both Na(+) and Ca(2+) is taken into account. Ionic channels are included at discrete locations, making it possible to study the effect of channel position and colocalization. The simulations indicate that if a Na(+) channel is present in the fuzzy space, the NCX is able to bring enough Ca(2+) into the cell to affect the timing of release. However, this critically depends on channel placement and local diffusion properties. With fuzzy space diffusion in the order of four orders of magnitude lower than in water, triggering through LTCC alone was up to 5 ms slower than with the presence of a Na(+) channel and NCX.
Tissue-specific and time-dependent control of in vivo gene disruption may be achieved using conditional knockout strategies in transgenic mice. Fusion of mutant estrogen receptor ligand-binding domains to Cre recombinase (Cre-ER(T), MerCreMer) combined with cardiac-directed gene expression has been used to generate several cardiac-specific tamoxifen-inducible Cre-expressing mouse lines. Such mice have successfully been used to generate Cre-loxP-mediated gene disruption in an inducible manner in the myocardium in vivo. However, information is sparse regarding the tamoxifen dosage, the time course of gene disruption and whether different administration routes differ in efficiency in obtaining gene disruption in the myocardium. We have evaluated these parameters in Serca2 ( flox/flox ) Tg(alphaMHC-MerCreMer) transgenic mice (SERCA2 KO). Serca2 mRNA transcript abundance was used as a sensitive indicator of Cre-loxP-dependent gene disruption in the myocardium. We found that 2 i.p. injections of tamoxifen in oil (1 mg/day, approximate total dose 80 mg/kg) was sufficient for efficient gene disruption with maximal reduction of Serca2 mRNA as early as 4 days after tamoxifen induction. Moreover, a simple protocol using tamoxifen-supplemented non-pelleted dry feed p.o. was comparable to i.p. injections in inducing gene disruption. These improvements may significantly improve animal welfare and reduce the workload in the production of cardiac conditional knockout mice.
Cardiomyocytes from failing hearts exhibit spatially nonuniform or dyssynchronous sarcoplasmic reticulum (SR) Ca(2+) release. We investigated the contribution of action potential (AP) prolongation in mice with congestive heart failure (CHF) after myocardial infarction. AP recordings from CHF and control myocytes were included in a computational model of the dyad, which predicted more dyssynchronous ryanodine receptor opening during stimulation with the CHF AP. This prediction was confirmed in cardiomyocyte experiments, when cells were alternately stimulated by control and CHF AP voltage-clamp waveforms. However, when a train of like APs was used as the voltage stimulus, the control and CHF AP produced a similar Ca(2+) release pattern. In this steady-state condition, greater integrated Ca(2+) entry during the CHF AP lead to increased SR Ca(2+) content. A resulting increase in ryanodine receptor sensitivity synchronized SR Ca(2+) release in the mathematical model, thus offsetting the desynchronizing effects of reduced driving force for Ca(2+) entry. A modest nondyssynchronous prolongation of Ca(2+) release was nevertheless observed during the steady-state CHF AP, which contributed to increased time-to-peak measurements for Ca(2+) transients in failing cells. Thus, dyssynchronous Ca(2+) release in failing mouse myocytes does not result from electrical remodeling, but rather other alterations such as T-tubule reorganization.
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