Robert L. Kent

Load responsiveness of protein synthesis in adult mammalian myocardium: role of cardiac deformation linked to sodium influx.

Exposure of adult mammalian myocardium to increased hemodynamic loads augments cardiac protein synthesis, ultimately leading to hypertrophy of the affected chamber. This established relationship between loading conditions and protein synthesis was examined in terms of two questions. First, is there a basic difference between the anabolic effect of a passive load imposed on diastolic myocardium and that of an active load generated by systolic myocardium? This issue was addressed by measuring [3H]phenylalanine incorporation into muscle protein in either quiescent or contracting ferret papillary muscles, set at known isometric lengths. Myocardial protein synthesis increased in proportion to total muscle tension in each case, with an equivalent relation describing both quiescent and contracting muscles. Synthesis of two contractile proteins, actin and myosin heavy chain, were enhanced by muscle loading. Thus, a quantitative rather than qualitative difference between the anabolic effects of diastolic and systolic loading was demonstrated. Second, since increased sodium influx is an initial cellular response requisite to the growth-inducing activity of many substances, and since sodium entry through stretch-activated ion channels is stimulated by deformation of the sarcolemma, does cardiac deformation during increased loading promote sodium influx as a signal to increase anabolic activity? In either quiescent or contracting papillary muscles, the rate of 24Na+ uptake was found to increase with load. Streptomycin, a cationic blocker of the mechanotransducer ion channels, was without effect on protein synthesis in stimulated but slack muscles; however, it inhibited, in a dose-related manner, the augmented protein synthesis otherwise observed in contracting muscles developing tension. At 500 μM, streptomycin did not reduce active tension, but it did reduce the synthesis of both actin and myosin heavy chain. In a second pharmacologic approach, inotropic agents were chosen which uniformly increased muscle tension development but which had contrasting effects on sodium influx. Protein synthesis increased in the presence of Na+ influx enhancers, monensin or veratridine; however, protein synthesis decreased in the presence of amiloride, a sodium influx inhibitor. Thus, myocardial protein synthesis varied directly with sodium influx despite the positive inotropic effect observed with each of these agents. In addition, inhibition of protein synthesis by ouabain demonstrated that activation of the Na+ pump is required for the anabolic effect of load. This study, therefore, identifies deformation-dependent sodium influx as an early signal in the transduction of load into growth in adult mammalian myocardium.

Hemodynamic versus adrenergic control of cat right ventricular hypertrophy.

The purpose of this study was to determine whether cardiac hypertrophy in response to hemodynamic overloading is a primary result of the increased load or is instead a secondary result of such other factors as concurrent sympathetic activation. To make this distinction, four experiments were done; the major experimental result, cardiac hypertrophy, was assessed in terms of ventricular mass and cardiocyte cross-sectional area. In the first experiment, the cat right ventricle was loaded differentially by pressure overloading the ventricle, while unloading a constituent papillary muscle; this model was used to ask whether any endogenous or exogenous substance caused uniform hypertrophy, or whether locally appropriate load responses caused ventricular hypertrophy with papillary muscle atrophy. The latter result obtained, both when each aspect of differential loading was simultaneous and when a previously hypertrophied papillary muscle was unloaded in a pressure overloaded right ventricle. In the second experiment, epicardial denervation and then pressure overloading was used to assess the role of local neurogenic catecholamines in the genesis of hypertrophy. The degree of hypertrophy caused by these procedures was the same as that caused by pressure overloading alone. In the third and fourth experiments, beta-adrenoceptor or alpha-adrenoceptor blockade was produced before and maintained during pressure overloading. The hypertrophic response did not differ in either case from that caused by pressure overloading without adrenoceptor blockade. These experiments demonstrate the following: first, cardiac hypertrophy is a local response to increased load, so that any factor serving as a mediator of this response must be either locally generated or selectively active only in those cardiocytes in which stress and/or strain are increased; second, catecholamines are not that mediator, in that adrenergic activation is neither necessary for nor importantly modifies the cardiac hypertrophic response to an increased hemodynamic load.

Load regulation of the properties of adult feline cardiocytes. The role of substrate adhesion.

We have recently described rapid and reversible changes in cardiac structure, function, and composition in response to surgical load alteration in vivo. In the present study, weused a simple, well- defined in vitro experimental model system, consisting of terminally differentiated quiescent adult cat ventricular cardiocytes maintained in serum-free culture medium, to assess more definitively the role of loading conditions in regulating these same biological properties of heart muscle. Cardiocytes considered to be externally loaded were adherent throughout their length to a protein substrate, such that the tendency for the ends of the cells to retract was prevented. Cardiocytes considered to be unloaded were not adherent to a substrate and, thus, were free to assume a spherical shape. Cardiocyte structure and surface area were assessed, in initially identified cells, both by serial light microscopy and by terminal electron microscopy. Cardiocyte function was assessed in terms of the ability to exclude trypan blue, to remain quiescent with relaxed sarcomeres containing I-bands, and to shorten in response to electrical stimulation. Cardiocyte composition was first assessed by quantitative gel electrophoresis of proteins and then by microfluorimetric measurement of ribonucleic acid, protein, and deoxyribonucleic acid. In addition, cardiocyte incorporation of [3H]thymidine into deoxyribonucleic acid and [3H]uridine into ribonucleic acid were measured. Loading via substrate adhesion was found to be very effective in terms of each of these measurements in retaining the differentiated features of adult cardiocytes for up to 2 weeks in culture; unattached and thus unloaded cardiocytes quickly dedifferentiated. Conditions thought to stimulate cardiac growth, including catecholamine stimulation, were found to be ineffective. These experiments demonstrate that external load has a primary role in the maintenance of the basic differentiated properties of adult mammalian cardiocytes.

Atrophy reversal and cardiocyte redifferentiation in reloaded cat myocardium.

We have recently described rapid cardiac atrophy in response to decreased load. The present study was designed to determine whether this atrophy is solely a degenerative response of damaged myocardium or is, instead, an adaptive response of viable myocardium. A discrete portion of cat myocardium was unloaded by severing the chordae tendinae of a single right ventricular papillary muscle. One week later, the muscle was reloaded by attachment of its apex to the ventricular free wall. This allowed the load to be removed and restored without altering the blood supply, innervation, or frequency of contraction of the tissue. In myocardium unloaded for 1 week, the cardiocyte cross-sectional area and the volume densities of mitochondria and myofibrils decreased significantly. Large areas of cytoplasm were devoid of organelles, and the few remaining myofilaments were oriented in a variety of directions rather than longitudinally within the cell. Upon reloading for 1 week, the cardiocyte cross-sectional area, volume density of mitochondria, and ultrastructural organization all returned to normal. The volume density of the myofibrils increased toward control, and they reoriented with respect to the long axis of the cardiocyte. The contractile function of the papillary muscles, which was depressed as early as 1 day after unloading and almost absent at times later than 3 days after unloading, returned to normal after 2 weeks of reloading. This study demonstrates that adult mammalian myocardium responds to unloading with a marked loss of cellular differentiation, organization, and function which is fully reversible with reloading. This plasticity in response to load may well be the basic mechanism responsible for the development and maintenance of normal cardiac structure and function.

Biochemical and structural correlates in unloaded and reloaded cat myocardium

Cardiocytes of unloaded myocardium rapidly lose structural and functional integrity through a combined loss of myofibrils and contractile activity; both changes are reversible with load restoration. The present study correlates the biochemical composition of unloaded and reloaded myocardium with these alterations in structure and function. Cardiac muscle was unloaded by transecting the chordae tendineae of a cat right ventricular papillary muscle and was reloaded by suturing these same chordae tendineae to the ventricular wall at the base of the valve; an adjacent intact muscle served as the control. Muscles unloaded for 1 to 14 days were assayed for DNA, protein, total creatine and hydroxyproline content. The ratios of wet weight/DNA and creatine/DNA decreased by 30 and 22% respectively, in parallel with a 38% reduction in cardiocyte cross-sectional area. Protein/unit wet weight was decreased by 50% after 14 days of unloading, so that both protein/DNA and protein/creatine were markedly reduced. Reloading of the muscle restored cardiocyte size, protein per unit wet weight and protein/DNA to normal. Parallel reductions in both contractile filaments and contractile proteins after unloading and parallel increases in each following load restoration were demonstrated by morphometric analysis of electron micrographs and analysis of actin and myosin by gel electrophoresis. In summary, the myocardium undergoes marked, parallel changes in structure, function and biochemical composition in response to the removal and restoration of load.

Signals for cardiac muscle hypertrophy in hypertension

Hypertension is associated with a rise in arterial pressure and a compensatory increase in cardiac mass, which if not treated effectively, progresses to decompensated congestive heart failure. This decompensation of an initially compensatory hypertrophy has intensified interest in the factors that initiate and maintain the development of cardiac hypertrophy. The potential signals that induce the development of cardiac hypertrophy are grouped as hemodynamic, growth-promoting hormonal, vasoconstriction-promoting hormonal, and genetic factors. Growth-promoting hormones such as insulin and thyroxine appear to play a permissive, but essential, role in the development and maintenance of cardiac hypertrophy. However, changes in cardiac load, both above and below normal, result in parallel changes in cardiac mass, which will return to normal when a normal load is restored. This adaptive response of the myocardium in direct response to elevated and depressed loads demonstrates that cardiac structure, composition, and function are not fixed postneonatal cardiac properties, but instead are regulated dynamically by the cardiocyte loading environment. This adaptive response is subject to modulation by vasoconstriction-promoting hormones and genetic factors. The current thrust in this research area is to elucidate the cellular signals that transduce the physical stimulus for hypertrophy into biochemical events underlying hypertrophic cardiac growth. To remove complex systemic interactions in vivo from the experimental paradigm, several in vitro models have been used to examine three general, but distinct, cellular pathways involving protein kinase C activation, cyclic AMP formation, and increased ion fluxes. Each pathway demonstrated a stimulatory effect on general protein synthesis, which is necessary for growth in all cells.(ABSTRACT TRUNCATED AT 250 WORDS)

An index for comparing the inhibitory action of vasodilators

An index for comparing the inhibitory effects of vasodilators was developed to gain insight into their mechanism of action on vascular smooth muscle. Rat aortic strips were bathed in Krebs bicarbonate solution and were initially contracted to a stable tension by either phenylephrine or barium chloride. A vasodilator was then added and the remaining tension was noted; this was repeated for cumulative concentrations of vasodilator. At each concentration of vasodilator, the percent reduction in phenylephrine-induced tension (Phe) was compared to the percent reduction in barium-induced tension (Ba) and was expressed as a ratio (Phe/Ba). This ratio clearly separated verapamil and nifedipine (ratio less than 1), which block calcium influx, from papaverine (ratio = 1) which promotes calcium sequestration regardless of the source of calcium, and from dantrolene (ratio greater than 1) which interferes with intracellular calcium mobilization. This index provides a method for comparing the action of those agents presently classified as non-receptor specific vasodilators which act directly on vascular smooth muscle.