A comparative study of myosin and its subunits in adult and neonatal-rat hearts and in rat heart cells from young and old cultures.

A possible explanation for the decrease in myosin Ca2+-dependent ATPase activity as rat heart cells age in culture is presented. The subunit structure and enzyme kinetics of myosin from adult and neonatal rat hearts and from rat heart cells of young and old cultures are compared. These studies indicate that the loss in Ca-ATPase activity of myosin from older cultures was an intrinsic property of the myosin itself. Myofibrillar fractions from the indicated four sources showed no qualitative or quantitative differences in electrophoretic patterns. Myosin from older cultures was more sensitive to alkaline denaturation than was myosin from younger cultures, as indicated by its more accelerated loss of K+(EDTA)-dependent ATPase activity after 10 min of incubation at pH 10. Furthermore, myosin from older cultures was more temperature-sensitive, as indicted by a more rapid loss of Ca-ATPase with decrease in assay temperature. It is suggested that there is either a change in conformation of myosin molecules at or near the active site of the enzyme or alternatively there is a change in light chain 1-light chain 2 and/or light-chain-heavy-chain interaction(s) in the myosin molecules under study.     

Role of cell division in the cytodifferentiation of rat heart cells in culture

BrdU and irradiation with visible light eliminates dividing cells from rat heart cell cultures. The lethal effect of light on the cultures is dependent upon the prior integration of BrdU into the DNA. Elimination of dividing cells is shown by the decreased uptake of ³H TdR in the remaining cells. Cultures in which the dividing cells were eliminated displayed a loss in myosin ATPase activity and a decrease in the rate of myosin ATPase activity increase, normally seen in control cultures. These results are consistent with the existence of cells at three stages of development; premyoblasts, which divide and contain no myosin; myoblasts which divide and contain myosin; and myocytes, which cannot divide and contain myosin. The results also indicate that the increase in myosin ATPase activity normally seen in heart cell cultures is a result of an increase in myosin in fully developed cells and in the increase in the number of cells capable of synthesizing myosin.     

The relation between ATPASE activity and light chains of myosin in developing, adult and denervated muscles of several animals species.

Ca2+ATPase activity and light chains of myosin, fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, in developing, adult and denervated fast, slow and cardiac muscles of the rat, guinea-pig, cat, rabbit and chick were studied. It has been shown that in normal adult muscles the electrophoretic pattern of light chains of myosin reflects the myosin ATPase activity only when muscles from the same animal species are compared. In homologous muscles from adult animals differing in size, the size-dependent difference in myosin ATPase activity is not revealed in the electrophoretic pattern. Both in developing and in denervated muscle, changes in myosin ATPase activity are either connected with changes in the pattern of light chains of myosin or this pattern does not change. This relation is different in fast and slow muscles and also differs in chick and rabbit muscles. There are several possibilities of explaining the relation between ATPase activity of myosin and the pattern of light chains of myosin. The observation that myosin from the soleus muscle of 1-month-old rabbit contains light chains corresponding to both fast and slow type of myosin, indicates that the change in myosin ATPase activity during development is due to changes in the ratio between the fast and slow type of myosin.     

Identification of a novel type 2 fiber population in mammalian skeletal muscle by combined use of histochemical myosin ATPase and anti-myosin monoclonal antibodies

A novel type of myosin heavy chain (MHC), called 2X, has been recently identified in type 2 fibers of rat skeletal muscles using an immunochemical approach. In the present study, the same panel of anti-MHC monoclonal antibodies was used in immunohistochemistry combined with enzyme histochemistry to identify and compare type 2X fibers in hindlimb skeletal muscles of rat, mouse, and guinea pig. Immunohistochemistry shows that 2X MHC is localized in a large subset of type 2 fibers and is co-expressed with 2A or 2B MHC in a small number of fibers. Enzyme histochemistry shows that type 2X fibers display low myosin ATPase activity after pre-incubation at pH 4.3 and high activity after paraformaldehyde pre-incubation at pH 10.4. After pre-incubation at pH 4.6, myosin ATPase shows intermediate and high activity in rat and mouse 2X fibers, respectively, whereas it is low in guinea pig 2X fibers. Succinate dehydrogenase displays moderate to high activity in 2X fibers of all species. Taken together, these staining patterns allow this novel fiber population to be distinguished from the other type 2 fibers using only enzyme histochemistry. Nevertheless, the combined use of immuno- and enzyme histochemistry prevents incorrect fiber typing due to the interspecies variability of myosin ATPase activity among the correspondent fiber types, and completely modifies the presently used classification of mouse type 2 fibers.     

Effect of physico-chemical factors on anion-sensitive ATPase activity

Effects of temperature, pH and anions on the ATPase activity of submitochondrial particles of rat liver, rat heart, mouse liver, of red blood cell membranes, and of soluble enzyme of rat liver, mouse liver mitochondria were studied. The temperature relationships of membrane-bound and soluble ATPases have the breaks at 18-21 degrees C and 30-32 degrees C. These breaks were not shifted by sulfite, thiocyanate, methanol, glycerol and GTP. The pH changes from 6.0 to 8.5 produced no effect on the temperature relationships of ATPase activities but, strongly influenced the rate of ATPase reaction. The conformity between the obtained data and earlier proposed mechanism of anion control over anion-sensitive ATPase activity was discussed.     

Myogenic and neurogenic contributions to the development of fast and slow twitch muscles in rat.

The histochemical ATPase activity and the myosin light chains of a rat fast muscle (extensor digitorum longus, EDL) and a rat slow muscle (soleus) during development have been investigated. Both muscles initially synthesize fast myosin light chains and show the intense histochemical ATPase activity characteristic of adult fast muscle fibers. After birth, the soleus begins to accumulate slow fibers with their characteristic low histochemical ATPase activity, and slow myosin light chains begin to appear. Sciatic neurectomy prevents the development of slow fibers and the synthesis of slow myosin light chains in the soleus, while the EDL is unaffected. Similarly, cordotomy of an adult rat results, in the soleus, in the appearance of fibers with more intense staining for ATPase and an increase in fast myosin light chains. The EDL is unchanged by cordotomy. As a result, we suggest that slow muscle development, but not fast muscle development, is dependent upon the functional activity of the nervous system.     

The relation between myosin Ca2+ - and K+ -adenosine triphosphatase activity of heart muscles in mammals of different size

1. The influence of KCl and CaCl2 on ATPase activity of ventricular myosin of the mouse, rat, rabbit and cow, the temperature dependence of ATPase and the effect of pCMB treatment and tryptic digestion on ATPase activity of these myosins were studied. 2. Ca2+ - and K+ -ATPase activities of myosins were inversely related to body size of the animal species; when K+ -ATPase activities were measured in the absence of EDTA, the body size/ATPase dependence was only slightly apparent. 3. The influence of temperature, the effect of pCMB and the influence of tryptic digestion on Ca2+ - ATPase activity distinguished the compared myosins. 4. There was a marked alteration of the effect of myosin treatment with pCMB or trypsin on K+ -ATPase activity of these myosins and in this case differences in K+ -ATPase activities were less pronounced.     

Measurement of myosin adenosinetriphosphatase and myosin content in cultured heart cells

An assay specific for myosin ATPase in whole-cell extracts of cultured heart cells has been developed. Myosin ATPase is measured by the production of Pi from ATP in the presence of high ionic strength (0.5 M KCl) at pH 9.1. Enzyme activity is maximal with 10 mM CaCl2 and completely inhibited with 5 mM MgCl2. Spontaneously beating myocytes grown in the presence of 10% newborn calf serum and 0.1 mM 5-bromo-2'-deoxyuridine show a significant rise in myosin ATPase between Days 1 and 4 in culture. The measurement of myosin ATPase allows for the quantitation of cellular myosin content, and can be used to assess changes in myosin content that occur during growth, development, and cellular repair.     

Effects of training on biochemical and functional properties of rodent neonatal heart

This study was undertaken to determine biochemical and functional (in vivo) adaptations of the rodent neonatal heart in response to a training program of endurance running. Ten day-old rats were progressively trained on a treadmill (final intensity, 21 m/min, 30% grade, 1 h/day) until 75 days of age. The training program induced 14, 57, and 24% increases in relative heart mass, skeletal muscle citrate synthase activity, and whole-body maximal O2 uptake, respectively (P less than 0.05). Cardiac myosin (ATPase) and Ca2+-regulated myofibril ATPase were both reduced by approximately 15% in trained vs. sedentary animals (P less than 0.05). In the majority of trained hearts examined, the myosin isozyme profile reflected an estimated 14 +/- 3% shift toward the V3 or low ATPase isozyme. Left ventricular functional indices during submaximal exercise, derived from a fluid-filled indwelling cannula, indicated that the trained animals maintained similar left ventricular (LV) systolic pressure, LV + the time derivative of pressure, and systemic arterial mean blood pressure compared with their sedentary counterparts. These functional parameters were maintained even though the trained animals performed with lower submaximal exercise heart rate. These findings suggest that maximal exercise capacity can be enhanced in neonatal rats even though the biochemical potential for ATP degradation in the cardiac contractile system is lowered. We speculate that the trend to maintain the myosin isozyme pattern further in the direction of the V3 isozyme in the trained neonatal rat heart may reflect a means to economize cross-bridge cycling while maintaining normal levels of ventricle performance at a given submaximal work load.     

Effects of mercury on myosin ATPase in the ventricular myocardium of the rat

Mercury reduces twitch and tetanic force development in isolated rat papillary muscles, and a putative toxic effect on the contractile machinery has been suggested. Based on that, the actions of HgCl2 on the myosin ATPase activity of the left ventricular myocardium were investigated. Samples for assay of myosin ATPase activity were obtained from rats' left ventricles. Increasing concentrations of HgCl2 reduced dose-dependently the activity of the myosin ATPase. This reduction was observed even at very small concentrations, 50 nM HgCl2. This effect was dependent on the presence of SH groups in the myosin molecule since DTT and glutathione protected the myosin ATPase against toxic effects of mercury; full activity being restored by using 500 nM DTT or 500 nM glutathione. Results also suggested that the metal acts as an uncompetitive inhibitor with a Ki of 200 nM HgCl2. Our results suggest that mercury reduces the activity of the myosin ATPase by an uncompetitive mechanism at a very low dose that does not depress force. DTT and glutathione are effective for protection against the actions of mercury suggesting that SH groups might be the sites of action of the metal on the myosin molecule.     

In vitro studies of beating heart cells in culture. XVI. The effect of a heart stable serum fraction on the level of myosin adenosinetriphosphatase

A heat stable serum factor of low molecular weight maintains the myosin ATPase activity of cultured rat heart cells. Its action is directly on the heart cells and it does not act by selection of heart muscle cells. It has no effect on heart muscle creatine phosphokinase or lactic dehydrogenase nor on myosin in skeletal muscle cultures.     

Decrease in rat cardiac myosin ATPase with aortic constriction: prevention by thyroxine treatment.

Severe aortic constriction in rats produced cardiac hypertrophy and a chronic decrease in cardiac actomyosin ATPase activity during a six week postoperative period. Two weeks following aortic constriction, Ca²⁺ stimulated cardiac myosin ATPase activity was also depressed; the K_m and V_max were decreased by 86.2% (p < 0.0025) and 84.4% (p < 0.0025), respectively, when compared to sham operated controls. Administration of thyroxine (100 μg/kg/day for 14 days), which was initiated on the same day as aortic constriction, prevented, to a large extent, the decrease in cardiac myosin ATPase activity. The K_m and V_max of myosin from animals with aortic constriction showed substantially smaller decreases as a result of concomitant thyroxine administration (p < 0.0025 for the change from aortic constriction without thyroxine treatment). Thyroxine treatment in rats with aortic stenosis resulted in an additional increment of cardiomegaly when compared to animals with aortic constriction alone. The results of this study indicate that thyroxine, which normally has no effect on Ca²⁺ activated cardiac myosin ATPase in the rat, can prevent the decrease in myosin ATPase activity which results from severe aortic stenosis.     

Thyroxine-induced cardiomegaly: assessment of nucleic acid, protein content and myosin ATPase of rat heart.

1 mg/kg L-thyroxine was administered to rats for 14 days to evaluate the potential of the hyperthyroid state to induce heart hypertrophy and its effect on myosin adenosine-triphosphatase (ATPase) activity. Evidence of hyperthyroidism such as weight loss, elevation of rectal temperature, increased heart rate and oxygen consumption, was observed in all treated rats. Cardiac enlargement was determined by comparison of wet and dry ventricle weights, myocardial RNA, DNA and protein content. Wet and dry ventricle weights and the level of cardiac RNA and protein were augmented by thyroxine treatment. ATPase activity of cardiac myosin was stimulated as the Ca2+ concentration in the incubation medium increased. No difference was found in Ca2+-activation, salt sensitivity or ATPase activity of unreacted and sulphydrylmodified cardiac myosins from euthyroid or hyperthyroid groups. The results showed that in hyperthyroid rats, in contrast to some other species, the biochemical mechanism responsible for the enhancement of cardiac contractility is not an increased myosin ATPase.     

Myosin from fast and slow skeletal and cardiac muscles of mammals of different size.

The ATPase activity of myosin and contraction time in extensor digitorum longus muscle, soleus muscle and cardiac muscle was compared in mammals differing in size. It was shown that the myosin ATPase activity of homologous muscles decreases and contraction time increases with increasing size of animals. The rate of tryptic digestion of myosin, the electrophoretic pattern of light chains of myosin and the effect of p-chloromercuribenzoate on ATPase activity of myosin were also studied. All these three myosin properties are very characteristic when the myosin from a fast muscle is compared with the myosin from a slow muscle of the same animal, but no relationship between these three myosin properties and ATPase activity of myosin was found, when homologous muscles of various mammals were compared.     

Atrial and ventricular myosin during development and senescence of the rat

Myosin was isolated from rat atrial and ventricular myocardium and examined during post-natal development and senescence. The post-natal increase of Ca2+-ATPase activity of myosin from rat atria did not run in parallel with changes of ATPase activity of myosin from the ventricles. Ca2+-ATPase of both atrial and ventricular myosin was activated at pH 9.5, when compared with the assay performed at pH 7.5. The myosin light-chain subunits in the ventricles were different from the light-chain subunits in the atria, when characterized by SDS-polyacrylamide gel electrophoresis and the pattern remained practically unchanged during development, with the exception of atrial myosin from new-born and very old rats which contained an additional protein of low molecular weight.     

Identification of myosin-like proteins included in chromatin

A myosin-like protein was purified 40-fold from rat liver chromatin (as determined by the K+-EDTA-ATPase activity equal to 0.013 and 0.442 M PPi/mg.min for chromatin and purified protein, respectively). Electrophoresis performed under non-denaturating conditions revealed that the overall ATPase activity of the sample is associated with one component whose migration is very similar to that of skeletal muscle myosin. The myosin components isolated from the nuclei and cytoplasm of rat cardiac muscle differ by their electrophoretic mobilities; those from nuclei of different tissues, i.e., liver and heart, have similar mobilities.     

Relation of fast and slow skeletal, and atrial and ventricular myosin in various mammals

Myosin was isolated from adult mouse, rat, rabbit and cat atrial and ventricular myocardium and fast and slow skeletal muscles and examined by measuring Ca2+-ATPase activity and by electrophoretic fractionation of chymotryptic peptides and MLCs. The myosin from mouse atrial and ventricular myocardium were very similar. The properties of cat soleus muscle myosin and ventricular myocardium were also very similar (ATPase activity and electrophoretic pattern of chymotryptic peptides of myosin). The electrophoretic pattern of MLCs, however, was distinct when comparing mouse and feline muscles. These observations are consistent with the idea that atrial and ventricular alpha MHCs are closely related and that beta MHCs from ventricular myocardium and slow skeletal muscle fibres are also closely related.     

Histochemical profiles of rat soleus intrafusal fibres after chronic exercise.

Intrafusal fibres from the rat soleus were investigated for representative histochemical profiles in sedentary animals and animals chronically exercised for 17 weeks on a treadmill. The pattern of myosin adenosine triphosphatase (ATPase) activity in the polar region revealed three intrafusal fibre types: (1) myosin ATPase-dark (MD) fibres, alkali- and acid-stabile; (2) myosin ATPase-light (ML) fibres, alkali- and acid-labile; and (3) myosin ATPase-reversible (MR) fibres, alkali-stabile and acid-labile. The three fibre types were correlated with the level of reduced NADH diaphorase activity, with MR, ML and MD fibres staining dark, moderate and light, respectively. In the equatorial region the morphological features of representative ML and MD fibres revealed that they were nuclear bag fibres, while representative MR fibres were identified as nuclear chain fibres. The MR fibres in the exercised animals had higher levels of myosin ATPase alkaline stability and acid lability than MR fibres in the sedentary animals, suggesting the MR fibre profiles are selectively influenced by chronic exercise. The mean cross-sectional area of MR fibres from the exercised animals was significantly less than the MR fibres from the sedentary animals. In contrast to the effect of endurance training on NADH diaphorase activity in extrafusal muscle fibres, there was evidence of less activity in the MD fibres of the exercised animals.     

Effects of systolic overload and swim training on cardiac mechanics and biochemistry in rats

We have previously shown that swim conditioning corrects the depressed mechanical function and myosin adenosinetriphosphatase (ATPase) activities associated with renovascular hypertension (HTN) in the rat. The present study was designed to assess the effects of swim conditioning on another form of systolic overload, subdiaphragmatic suprarenal aortic stenosis. Cardiac mechanics in an isolated working heart apparatus and myosin enzymology were studied in four groups of rats: controls (C), animals with chronic systolic overload secondary to aortic constriction (St), swim-conditioning animals (Sw), and animals exposed to a combined load (St-Sw). Heart weight was increased by 23% in St, 27% in Sw, and 36% in St-Sw. In contrast to HTN, cardiac pump and muscle function were not depressed in St. Sw was associated with improved cardiac output, stroke work, and velocity of circumferential fiber shortening. St-Sw showed improved mechanical cardiac performance relative to both C and St. The percent of ventricular myosin of the V1 type and Ca2+-activated myosin ATPase activity relative to C was unchanged in Sw but was depressed in St and St-Sw. These data demonstrate that the salutory mechanical effects of Sw can be superimposed on the systolic overload of St. However, the dissociation between mechanics and myosin enzymology suggests that factors in excitation-contraction coupling other than myosin isoenzyme shifts are responsible for this finding.     

Diabetes-induced abnormalities in the myocardium

One of the leading causes of mortality in diabetics is myocardial disease. In the past few years this subject has generated a significant amount of interest with the result that myocardial problems associated with diabetes are far better understood. Though originally thought to occur as a result of atherosclerosis, various studies have shown that heart disease can occur in the absence of atherosclerosis, suggesting a diabetic cardiomyopathy. Using diabetic animals, it has been possible to characterize diabetes-induced myocardial abnormalities. Diabetic rat hearts do not respond to conditions of high stress as well as controls. The functional depression is accompanied by altered cardiac enzyme systems. A decrease in myosin ATPase activity which appears to be a result of diabetes-induced hypothyroidism is seen. Also, a depression of sarcoplasmic reticular calcium ATPase, along with a depression of calcium uptake by the SR, is seen in diabetic rat hearts. Na+, K+ ATPase activity has also been shown to be depressed and the depression appears to correlate with depressed atrial contractility. High levels of circulating fats in diabetics may alter the integrity of membranes leading to altered enzyme activities. Insulin treatment has been relatively successful at reversing or preventing myocardial changes in the diabetic rat. Other treatments that have been studied include thyroid hormone treatment, since the depression of myosin ATPase can be corrected by such treatment; and carnitine treatment, as the elevation of long chain acyl carnitines (LCAC) and the resulting depression of calcium uptake in the SR can be so normalized. These treatments have not been successful at normalizing cardiac function. A combination of the two treatments normalized function only partially, suggesting that factors besides myosin ATPase and SR calcium uptake are involved. Other treatments that have been tried include vanadate, methyl palmoxirate, and choline and methionine. Vanadate treatment has proved to be encouraging in that it normalizes both function and hyperglycemia. Methyl palmoxirate, a fatty acid analog, normalized only the elevation of LCAC but did not affect function. Methionine and choline were only partially successful in preventing the functional alterations of diabetic rat hearts. The purpose of the present article is to review our understanding of diabetes-induced myocardial problems and their possible causes. Findings from our laboratory and others are described in which attempts have been made to normalize cardiac function.