Nancy Ball

In Vivo Echocardiographic Detection of Enhanced Left Ventricular Function in Gene-Targeted Mice With Phospholamban Deficiency

We evaluated the ability of M-mode and Doppler echocardiography to assess left ventricular (LV) function reliably and repeatedly in mice and tested whether these techniques could detect physiological alterations in phospholamban (PLB)-deficient mice. Anesthetized wild-type mice (n = 7) and mice deficient in PLB (n = 8) were studied with two-dimensional guided M-mode and Doppler echocardiography using a 9-MHz imaging and 5- to 7.5-MHz Doppler transducer. Data were acquired in the baseline state and after intraperitoneal isoproterenol administration (2.0 micrograms/g IP). Interobserver and intraobserver variability and reproducibility were excellent. PLB-deficient mice were associated with significant (P < .05) increases in several physiological parameters (mean +/- SD) compared with wild-type control mice: normalized mean velocity of circumferential shortening (7.7 +/- 2.1 versus 5.5 +/- 1.0 circ/sec), peak aortic velocity (105 +/- 13 versus 75 +/- 9.2 cm/s), mean aortic acceleration (57 +/- 16 versus 31 +/- 4 m/s2), and peak early-diastolic transmitral velocity (80.0 +/- 7.2 versus 66.9 +/- 7.7 cm/s). LV dimensions, shortening fractions, heart rates, late diastolic transmitral (A) velocities, and early to late (E/A) diastolic velocity ratios were similar in both groups. Isoproterenol administration resulted in significant increases in Doppler indices of ventricular function in control but not PLB-deficient mice. These findings indicate that assessment of LV function can be performed noninvasively in mice under varying physiological conditions and that PLB regulates basal LV function in vivo.

Differential Changes in Cardiac Phospholamban and Sarcoplasmic Reticular Ca2+-ATPase Protein Levels Effects on Ca2+ Transport and Mechanics in Compensated Pressure-Overload Hypertrophy and Congestive Heart Failure

The objective of this study was to elucidate the role of the sarcoplasmic reticulum (SR) in the transition from compensated pressure-overload hypertrophy (increased left ventricular [LV] mass, normal LV function, and no pulmonary congestion) to congestive heart failure (increased LV mass, depressed LV function, and pulmonary congestion). To address this issue, the descending thoracic aorta was banded for 4 and 8 weeks in adult guinea pigs, and the changes in isovolumic LV mechanics, SR Ca2+ transport, and SR protein levels were determined and compared with age-matched sham-operated control animals. A subgroup of the 8-week banded animals manifested the congestive heart failure phenotype with diminished developed LV pressure normalized by LV mass, reduced rates of LV pressure development and relaxation, and markedly increased lung weight-to-body weight ratios. The cardiac mechanical and morphometric changes were associated with depressed protein levels of the SR Ca(2+)-ATPase (85% of the control) and phospholamban (65% of the control) assessed by quantitative immunoblotting. Resultant rates of SR Ca2+ uptake (Vmax) and the affinity of SR Ca(2+)-ATPase for Ca2+ (EC50) were significantly depressed [32 +/- 6 nmol Ca2+.min-1.mg-1 and 0.59 +/- 0.12 (mumol/L)/L, respectively] compared with the 8-week sham-operated control animals [40 +/- 1 nmol Ca2+.min-1.mg-1 and 0.40 +/- 0.05 (mumol/L)/L, respectively]. We conclude that this model of pressure overload-induced cardiac failure is associated with (1) diminished LV force development, rates of pressure development, and decay; (2) depressed protein expression of the Ca(2+)-cycling proteins SR Ca(2+)-ATPase and phospholamban; and (3) decreased Vmax and affinity of the SR Ca(2+)-ATPase for Ca2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in Ca2+ Cycling Proteins Underlie Cardiac Action Potential Prolongation in a Pressure-Overloaded Guinea Pig Model With Cardiac Hypertrophy and Failure

Ventricular arrhythmias are common in both cardiac hypertrophy and failure; cardiac failure in particular is associated with a significant increase in the risk of sudden cardiac death. We studied the electrophysiologic changes in a guinea pig model with aortic banding resulting in cardiac hypertrophy at 4 weeks and progressing to cardiac failure at 8 weeks using whole-cell patch-clamp and biochemical techniques. Action potential durations (APDs) were significantly prolonged in banded animals at 4 and 8 weeks compared with age-matched sham-operated animals. APDs at 50% and 90% repolarization (APD(50) and APD(90) in ms) were the following: 4 week, banded, 208+/-51 and 248+/-49 (n = 15); 4 week, sham, 189+/-68 and 213+/-69 (n = 16); 8 week, banded, 197+/-40 and 226+/-40 (n = 21); and 8 week, sham, 156+/-42 and 189+/-45 (n = 22), respectively; P<0.05 comparing banded versus sham-operated animals. We observed no significant differences in the K(+) currents between the 2 groups of animals at 4 and 8 weeks. However, banded animals exhibited a significant increase in Na(+) and Na(+)-Ca(2+) exchange current densities compared with controls. Furthermore, we have found a significant attenuation in the Ca(2+)-dependent inactivation of the L-type Ca(2+) current in the banded compared with sham-operated animals, likely as a result of the significant downregulation of the sarcoplasmic reticulum Ca(2+) ATPase, which has been documented previously in the heart failure animals. Our data provide an alternate mechanism for APD prolongation in cardiac hypertrophy and failure and support the notion that there is close interaction between Ca(2+) handling and action potential profile.

Left Ventricular Stretch Stimulates Angiotensin II– Mediated Phosphatidylinositol Hydrolysis and Protein Kinase C ε Isoform Translocation in Adult Guinea Pig Hearts

Stretch of neonatal cardiomyocytes activates phospholipase C with production of inositol trisphosphate and diacylglycerol in part by formation of angiotensin II (Ang II). However, the response of this pathway to physical stimuli in the adult heart is poorly understood. Thus, in isovolumic perfused guinea pig hearts, we characterized stretch-mediated phosphatidylinositol (PI) hydrolysis and protein kinase C (PKC) isoform translocation using elevated diastolic pressure. Balloon dilatation (minimum diastolic pressure, 25 mm Hg) of the left ventricle (LV) stimulated PI hydrolysis. Pretreatment of stretched hearts with the specific angiotensin (AT1) receptor antagonist losartan abolished stretch-mediated accumulation of inositol phosphates. To examine PKC isoform expression and activation under these conditions, whole-heart extracts were examined by immunoblot analysis. Ang II translocated PKC epsilon to the particulate fraction. 4 beta-Phorbol 12-myristate 13-acetate but not an inactive congener translocated PKC epsilon to the particulate fraction and produced a decrease in myocardial contractile function. Mechanical stretch also translocated PKC epsilon to the particulate fraction; however, this was attenuated but not abolished by losartan. We conclude that in the adult heart, LV dilation produced stretch-mediated activation of phospholipase C, which resulted in PI hydrolysis and PKC epsilon activation in part by stimulation of the local renin angiotensin system. In contrast to stretch-mediated inositol phosphate accumulation, PKC epsilon translocation is not prevented by AT1 receptor blockade, indicating that this PKC isoform can be activated in response to mechanical deformation by an Ang II-independent mechanism in the adult myocardium.

Invasive hemodynamics and force-frequency relationships in open- versus closed-chest mice

We compared hemodynamics, ventricular function, and force-frequency relationships in six open-chest and six closed-chest anesthetized mice (FVB/N strain). Left ventricular (LV) pressure was measured with a 1.8- or 1.4-Fr Millar catheter placed via the right carotid artery and the LV apex in the closed- and open-chest state, respectively. Pacing was performed with electrodes placed either directly on atrial appendages (open chest) or with a 1-Fr bipolar catheter via the jugular vein (closed chest). Closed-chest animals had greater spontaneous heart rate (267 ± 106 vs. 147 ± 27 beats/min), LV systolic (81 ± 14 vs. 48 ± 9 mmHg) and diastolic pressures (11.2 ± 4.8 vs. 5.6 ± 2.4 mmHg), and maximal rise (+dP/d t max: 6,208 ± 2,519 vs. 3,682 ± 671 mmHg/s) and fall in pressure development (-dP/d t max: -6,094 ± 2,386 vs. -3,001 ± 399 mmHg/s). LV systolic pressure (98 ± 18 vs. 52 ± 11 mmHg), +dP/d t max (9,240 ± 2,459 vs. 5,777 ± 2,473 mmHg/s), and -dP/d t max(-8,375 ± 2,551 vs. -3,753 ± 1,170 mmHg/s) were significantly higher when animals were matched at a heart rate of 420 beats/min in closed-chest vs. open-chest animals. Biphasic force-frequency relationships were seen in all animals, but the critical heart rate was greater in the closed- than open-chest animals (432 ± 42 vs. 318 ± 42 beats/min). We conclude that 1) there are significant differences between invasive indexes of systolic and diastolic function between the closed- and open-chest preparations, 2) there is a biphasic force-frequency relationship in the anesthetized mouse, and 3) dP/d t max can be used to assess the cardiovascular phenotype.

Modulation of force-frequency relation by phospholamban in genetically engineered mice

Phospholamban levels regulate cardiac sarcoplasmic reticulum Ca2+ pump activity and myocardial contractility. To determine whether and to what extent phospholamban modulates the force-frequency relation and ventricular relaxation in vivo, we studied transgenic mice overexpressing phospholamban (PLBOE), gene-targeted mice without phospholamban (PLBKO), and isogenic wild-type controls. Contractility was assessed by the peak rate of left ventricular (LV) isovolumic contraction (+dP/dtmax), and diastolic function was assessed by both the peak rate (-dP/dtmax) and the time constant (tau) of isovolumic LV relaxation, using a high-fidelity LV catheter. Incremental atrial pacing was used to generate heart rate vs. -dP/dtmax (force-frequency) relations. Biphasic force-frequency relations were produced in all animals, and the critical heart rate (HRcrit) was taken as the heart rate at which dP/dtmax was maximal. The average LV +dP/dtmax increased in both PLBKO and PLBOE compared with their isogenic controls (both P < 0.05). The HRcrit for LV +dP/dtmax was significantly higher in PLBKO (427 +/- 20 beats/min) compared with controls (360 +/- 18 beats/min), whereas the HRcrit in PLBOE (340 +/- 30 beats/min) was significantly lower compared with that in isogenic controls (440 +/- 25 beats/min). The intrinsic heart rates were significantly lower, and the HRcrit and the +/-dP/dtmax at HRcrit were significantly greater in FVB/N than in SvJ control mice. We conclude that 1) the level of phospholamban is a critical negative determinant of the force-frequency relation and myocardial contractility in vivo, and 2) contractile parameters may differ significantly between strains of normal mice.Phospholamban levels regulate cardiac sarcoplasmic reticulum Ca2+ pump activity and myocardial contractility. To determine whether and to what extent phospholamban modulates the force-frequency relation and ventricular relaxation in vivo, we studied transgenic mice overexpressing phospholamban (PLBOE), gene-targeted mice without phospholamban (PLBKO), and isogenic wild-type controls. Contractility was assessed by the peak rate of left ventricular (LV) isovolumic contraction (+dP/d t max), and diastolic function was assessed by both the peak rate (-dP/d t max) and the time constant (τ) of isovolumic LV relaxation, using a high-fidelity LV catheter. Incremental atrial pacing was used to generate heart rate vs. -dP/d t max(force-frequency) relations. Biphasic force-frequency relations were produced in all animals, and the critical heart rate (HRcrit) was taken as the heart rate at which dP/d t max was maximal. The average LV +dP/d t maxincreased in both PLBKO and PLBOE compared with their isogenic controls (both P < 0.05). The HRcrit for LV +dP/d t max was significantly higher in PLBKO (427 ± 20 beats/min) compared with controls (360 ± 18 beats/min), whereas the HRcrit in PLBOE (340 ± 30 beats/min) was significantly lower compared with that in isogenic controls (440 ± 25 beats/min). The intrinsic heart rates were significantly lower, and the HRcrit and the ±dP/d t max at HRcrit were significantly greater in FVB/N than in SvJ control mice. We conclude that 1) the level of phospholamban is a critical negative determinant of the force-frequency relation and myocardial contractility in vivo, and 2) contractile parameters may differ significantly between strains of normal mice.