Myofibrillar ATPase activity, maximum unloaded shortening velocity, and isometric tension development were evaluated in left ventricular preparations of 5-week-old rats with a high endogeneous level of thyroid hormones and hypothyroid rats after 4-week treatment with propylthiouracil (PTU). The range of possible alterations of the above functional parameters was defined in relation to myosin isoenzyme distribution. The mechanical behaviour of the ventricular preparations was investigated in native myocardium as well as in the glycerinated state. The essential results of the present study is that alterations of myofibrillar ATPase activity and mechanical Vmax, evaluated in glycerinated preparations, are limited to a well-defined range of similar magnitude for both functional parameters: 32-40% of maximum values (obtained from rat myocardium with homogeneous myosin V1). Isometric tension was only insignificantly decreased in glycerinated preparations of the PTU-treated group. The alteration in the apparent maximum shortening velocity of native myocardium (V0) was of the same magnitude as changes in Vmax of chemically skinned preparations. Physical training revealed a shift in the direction of V1-type myosin with increased ATPase activity and shortening velocity; aging and pressure overload showed an opposite effect. The documented mechanical alterations do not contradict an adaptational interpretation of the myosin isoenzyme redistribution in pressure-induced hypertrophy.
Based on mechanical, biochemical and electron microscopic studies performed in the same stage of experimental cardiac hypertrophy, an attempt is made to define the significance of individual factors responsible for the alterations in myocardial function. Using swimming rats, it is demonstrated that a load-induced increase in cardiac mass is not necessarily connected with an impairment of contractile capability on a cellular level. Yet, also, the reduction of specific ATPase activity and unloaded shortening velocity in pressure-induced hypertrophy (goldblatt rats; aortic stenosis) seems to be the expression of adaptation rather than of cellular damage, at least in the earlier stages. Although there are distinct indications of alterations in Ca-dependent activation and deactivation, in the Goldblatt model electromechanical coupling does not seem to be the main cause of altered contraction parameters. The correlation between specific ATPase activity of actomyosin and unloaded shortening velocity as well as the persistance of decrease in shortening velocity, also under optimal electromechanical coupling conditions, point to an inner relationship between the two values. A discrepancy between unloaded shortening velocity on the one hand and developed tension on the other is mainly due to an increased content of contractile structures. In later stages, an increased connective tissue content influences both isometric and isotonic parameters.
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