J. Scheuer

Effects of gonadectomy and hormonal replacement on rat hearts.

To evaluate the effects of sex hormones on heart function and biochemistry, gonadectomy (GX) was performed in postpubertal male (M) and female (F) rats and compared with sham-operated controls (SH). The groups were MSH; MGX; MGX replaced with testosterone 3 mg/day s.c. (MGX + T), FSH, and FGX replaced with estrogen 2 mg/day (FGX + E), progesterone 0.4 mg/day (FGX + P), estrogen and progesterone (FGX + EP), or testosterone 2 mg/day (FGX + T). Body weight was decreased in MGX and was decreased further in MGX + T. Heart weight was decreased in both MGX and MGX + T. Body weights were increased in FGX and FTX + P and were increased further in FGX + T but were normal in FGX + E and FGX + EP. Heart weights were unchanged in F groups except in FGX + T, where it was increased. Cardiac performance in perfused hearts, as measured by stroke work, ejection fraction, fractional shortening and mean velocity of circumferential fiber shortening, was decreased in MGX but was slightly increased in MGX + T. Papillary muscle studies showed increases in time to peak tension and one-half relaxation in MGX, but these were decreased in MGX + T. Isotonic shortening studies showed decreased velocity of shortening in MGX and increased velocity in MGX + T. Heart function was significantly decreased in FGX and FGX + P compared with FSH but was similar to FSH in FGX + E and FGX + EP. FGX + T had greater stroke work and ejection fraction than FSH and FGX.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of aging and hypertension on myosin biochemistry and gene expression in the rat heart.

The mechanisms by which the aged heart adapts to a superimposed pressure load such as hypertension have not been described. We therefore investigated biochemical and molecular genetic adaptations in the 24-month-old rat heart subjected to renovascular hypertension. Compared with 4-month-old rats, aging was associated with a 68% increase in left ventricular mass without any change in heart weight-to-body weight ratio, a 33% reduction in calcium-activated myosin ATPase activity, and a shift from a V1 to a V3 predominant myosin heavy chain (MHC) isoform distribution. A 46% reduction in alpha-MHC mRNA and a reciprocal increase in beta-MHC mRNA was seen. When hypertension was superimposed, there was a further 75% increase in ventricular mass, a 63% increase in heart weight-to-body weight ratio, and a 19% reduction in myosin ATPase. Myosin isozyme distribution was further shifted to V3, and the ratio of alpha-MHC to beta-MHC mRNA was reduced. In addition, with hypertension a significant (greater than 50%) reduction in the mRNA level of the cardiac sarcoplasmic reticular calcium-activated ATPase was seen. These data demonstrate that the aged myocardium is able to respond to a superimposed pressure load with a molecular genetic and protein synthetic pattern of hypertrophy analogous to that seen in younger animals.

Effects of chronic dobutamine administration on hearts of normal and hypertensive rats.

We have previously shown that physical conditioning in the rat improves cardiac mechanics and biochemistry and normalizes the cardiac contractile protein abnormalities associated with renovascular hypertension. Since chronic adrenergic stimulation with dobutamine simulates some aspects of physical conditioning, this study was undertaken to investigate the effects of chronic dobutamine administration on normal and hypertensive rat hearts. Four groups of female animals were studied: controls, dobutamine-treated (2 mg/kg twice daily), renovascular hypertensives, and dobutamine-treated hypertensives. Animals were killed after 8-10 weeks and cardiac histology, myosin biochemistry, and mechanics in an isolated heart perfusion apparatus were studied. Dobutamine, unlike hypertension, was not associated with histological evidence of myocardial damage but did increase cardiac mass by 10% and calcium-activated myosin ATPase activity by 13%. Hypertension was associated with a 24% increase in mass, a 24% decrease in ATPase activity, and a shift in the myosin isoenzyme pattern from V1 to V3. The combined stimuli caused additive hypertrophy (44%) and normalized myosin biochemistry and isomyosin distribution. Dobutamine treatment was not associated with significant improvements in pump or muscle function in control or hypertensive hearts. Thus chronic dobutamine treatment, like physical conditioning, induces a physiological cardiac hypertrophy in rats that is associated with improved myosin enzymology and normalization of the contractile protein abnormalities associated with hypertension. Unlike physical conditioning, however, these biochemical alterations do not result in improved contractile function as measured in an isolated buffer-perfused heart apparatus.

Increased heart rate prevents the isomyosin shift after cardiac transplantation in the rat.

The heterotopically transplanted rat heart undergoes significant atrophy and a shift from V1 to V3 isomyosin. The purpose of this study was to pace the cardiac isograft and determine whether an increase in heart rate would attenuate the changes in cardiac mass and isoenzyme distribution. Nonpaced transplanted hearts were compared with hearts in which pacing was initiated at 7 Hz, 24 hours after transplantation, and continued for 7 days. There was a 29% decrease in myosin ATPase activity and a 22% decrease in alpha-myosin in the nonpaced isograft; both decreases were completely prevented by pacing. The decrease in cardiac mass was also significantly attenuated. Pacing did not alter intrinsic heart rate, systolic pressure, dP/dt, or norepinephrine concentration in the isograft. These results suggest that the adaptation in both cardiac mass and isoenzymes may be related to the rate or the rate-pressure product in the transplanted paced heart independent of left ventricular pressure, tissue catecholamines, or neural activity.

Swimming causes myosin adaptations in the rat cardiac isograft.

To investigate the contributions of humoral and hemodynamic factors to cardiac adaptations associated with chronic exercise, female Fischer 344 rats were subjected to chronic swimming, infrarenal cardiac transplantation, or both. Swimming resulted in hypertrophy (11-12%) of the in situ hearts in both the unoperated and operated animals compared with the matched sedentary controls. The cardiac isograft exhibited atrophy (32-35%), which was not attenuated by swimming. The cardiac isograft was also associated with a decrease in the percent of V1 myosin isoenzyme, which was attenuated by swimming (45 +/- 5% versus 66 +/- 6%). Swimming also increased the percent of this isomyosin in the in situ hearts of operated rats. These data suggest that hemodynamic load and/or neural innervation are necessary for hypertrophy associated with chronic conditioning by swimming, whereas myosin isoenzyme control is significantly mediated by humoral factors.