Isoproterenol-induced myocardial ischemic injury in the rabbit: functional and ultrastructural alterations

The functional and ultrastructural changes observed during myocardial ischemic injury (MII) in the rabbit are described. MII was induced by repeated subcutaneous injections of increasing doses of isoproterenol (ISO; 0.5 mg/kg on day 1, to 15.5 mg/kg on day 15). Measurement of cardiovascular changes revealed a significant decrease in the mean arterial pressure and an increase in heart rate of the ISO-treated animals. ISO treatment also initiated a variety of atrial and ventricular arrhythmias, including ventricular fibrillation, as well as significant ST segment elevations and the appearance of Q waves. Electron-microscopic analysis of hearts from ISO-treated animals showed accumulation of lipid and depletion of glycogen. The myofibrils had poorly defined Z bands and appeared as a homogeneous mass. The most marked effects of ISO treatment were on the mitochondria, which appeared swollen and fragmented. The mitochondrial cristae were also disrupted and fragmented. A few amorphous electron-dense bodies were observed in and around the mitochondria. The changes observed in this study are qualitatively similar to those observed in the rabbit following coronary artery ligation.     

Effects of spaceflight on the spermatogonial population of rat seminiferous epithelium

Testes from rats flown on Cosmos 1887 were compared with vivarium control and synchronous control samples. The mean weights of flight testes, normalized for weight per 100 g, were 6.4% less when compared with the vivarium controls. Counts of spermatogonia from tissue sections (seminiferous tubules in maturation stage 6) from five animals in each group revealed 4% fewer spermatogonia in flight testes compared with synchronous controls and 11% fewer spermatogonia in flight samples compared with vivarium controls.     

Ultrastructure of skeletal muscle fibers in monkeys after space flight

It is known that exposure of humans and animals to microgravity causes reduction in the cross-sected area of muscle fibers and muscle atrophy. These changes also involve ultrastructural alterations in muscle fibers. Therefore primates, that are physiologically close to humans, are to be examined to help a better understanding of the nature of these ultrastructural changes is muscles and muscle fibers. Although failed to find any relevant published data on the quantitative aspects of ultrastructural changes in muscle fibers of space-flown primates we believe that it is important to examine these aspects. The postflight study of monkey's m. soleus, and m. vastus lateralis did not reveal any significant changes in volume density of the myofibrillar apparatus. Mitochondria of m. soleus showed a distinct reduction in volume density, being more obvious in the subsarcolemmal zone than in the central one. Mitochondria of m. vastus lateralis showed a decrease (P > 0.05) in volume density. Following the flight, m. soleus and m. vastus lateralis of the monkeys showed a significant increase in the mean area of myofibrils, and a trend towards a decrease in the number of myofibrils per 100 micron 2. Besides, m. soleus showed a significant increase in the mean area of mitochondria, and a trend towards a decrease in the number of mitochondria per 100 micron 2. In m. vastus lateralis of the monkeys after space flight the number opf mitochondria tended to decrease and the mean area showed differential changes. It can be postulated that these phenomena may be associated with a reduction in the diffusion surface of mitochondria resulting from the diminished myofibrillar volume.     

Correction of stress-induced disorders of the ultrastructure of hypertrophied myocardium with thyroid hormones

In the experiment performed on 25 non-inbred male rats ultrastructural changes in cardiomyocytes of the hypertrophied heart have been studied under conditions of stress caused by immobilization and possibility to correct these changes by means of thyroid hormones. The stress intensifies destructive lesions in a number of organelles++, which develop at a prolonged hypertrophy, decreases essentially the ratio mitochondria/myofibrils in section area. Small doses of the thyroid hormones protect the hypertrophied heart from the damaging effect of the stress: prevent the stress-induced+ decrease in the ratio mitochondria/myofibrils, as well as stimulate development of the regenerative-adaptive processes (increase in size and number of mitochondria and their crists, elements of the sarcoplasmic reticulum, glycogen granules, increase in section areas of their nuclei and chromatin in them). The thyroid hormones restrict essentially decrease in correlation of organelles++, resulted from hypertrophy. Thus, the stress-induced disturbances in ultrastructure of the hypertrophied heart can be prevent by means of the thyroid hormones, administered in small doses.     

The features of mitochondria of cardiomyocytes from rats with chronic heart failure

Electron-microscopy study of rat myocardium 2 weeks after a heart attack revealed significant alterations in the ultrastructure of cardiomyocytes than for the control. The location of myofibrils was less regular than for normal cells. The population of interfibrillar mitochondria decreased. Mitochondrial cristae were located less densely and formed cellated structures. Swollen mitochondria were observed in the periinfarction and intact areas, indicating the development of ischemia in the myocardium as a whole. Six months after the occlusion of coronary vessels alterations in the location of myofibrils and mitochondria were mainly observed in the peri-infarction area. Mitochondria also formed cellated structures. A 30% decrease in the density of the arrangement of the inner membranes of mitochondria on an area unit was found in the periinfarction zone. The ratio between the relative volumes of mitochondria and myofibrils in the cardiomyocytes of the peri-infarction area was increased by 20%. The area of mitochondria in the intact zone of the left ventricle was 30% greater than for the control. A study of isolated living cardiomyocytes revealed that the mitochondrial- membrane potential in the rats subjected to myocardial infarction half a year ago previously was significantly lower than for the mitochondrial-membrane potential in the control rats. Thus, cardiomyocytes that were similar to healthy cardiomyocytes in their morphology exhibited lower total mitochondrial-membrane potential, indicating their decreased energy state.     

Reduction in myotendinous junction surface area of rats subjected to 4-day spaceflight.

The surface area of myotendinous junctions (MTJs), expressed relative to the cross-sectional area of myofibrils attached to them, was determined using established morphometric techniques in which the digitlike processes of the cell at MTJs are modeled as circular paraboloids. The relative area, called the folding factor, was measured for six rats after a 4-day spaceflight and six control rats maintained in a vivarium under otherwise identical conditions. Spaceflight resulted in a significant reduction in relative MTJ surface area, from 19.7 +/- 2.3 (SD) in control animals to 13.3 +/- 2.5 for animals after spaceflight. Furthermore, space animals displayed increased numbers of fibroblasts enriched in rough endoplasmic reticulum near the MTJ, a greater number of ribosomes and mitochondria within muscle at the MTJ, and increased occurrence of lesions in the connective tissue near the MTJ. The results indicate that spaceflight, possibly through the removal of gravity-associated loading from muscle, causes a modification in MTJ structure and may result in injuries at MTJs after return to normal loading.     

Effects of space flight on bone formation and resorption.

Samples of femurs and tibiae of male Wistar rats subjected to a 13 day space-flight on the biosatellite Cosmos 1887--were investigated and compared with vivarium and synchronous controls or immobilized rats, using histological and histomorphometric methods. 1. After flight in the metaphysis of bones the density and volume of the spongious trabeculae diminished significantly indicated by the Sv and Vv histomorphometric values and histological data comparing to the controls. In the diaphysis, the density of trabeculae decreased too. 2. In the flight group significant suppression of bone formation was determined by histological and histomorphometric (decrease of the OS, OB and OBI values) methods. 3. In the flight group according to the histological pictures the signs of bone resorption (increase of Hoswship's lacunae, osteoclastic activity, structural rarefication of spongious and cortical bones, osteon disintegration, osteocytic osteolysis) were revealed, which was substantiated by the histomorphometric results (increase of osteoclastic index: OCI). 4. Significant differences between flight and immobilized groups were not determined, except the osteoid value, which was increased in the case of immobilization. 5. Some histomorphometric values related to bone formation of synchronous control group showed close relationship rather to the flight group than to the vivarium control group.     

Skeletal muscle adaptation in rats flown on Cosmos 1667

Seven male Wistar rats were subjected to 7 days of weightlessness on the Soviet biosatellite Cosmos 1667. Muscle histomorphometry and biochemical analyses were performed on the soleus (SOL) and extensor digitorum longus (EDL) of flight rats (group F) and compared with data from three groups of terrestrial controls: one subjected to conditions similar to group F in space except for the state of weightlessness (group S) and the others living free in a vivarium (V1, V2). Relative to group V2 (its age and weight-matched control group), group F showed a greater decrease of muscle mass in SOL (23%) than in EDL (11%). In SOL a decrease in the percentage of type I fibers was counterbalanced by a simultaneous increase in type IIa fibers. The cross-sectional area of type I fiber was reduced by 24%. No statistically significant difference in capillarization and enzymatic activities was observed between the groups. In EDL a reduction in type I fiber distribution and 3-hydroxyacyl-CoA-dehydrogenase activity (27%) occurred after the flight. The small histochemical and biochemical changes reported suggest the interest in studying muscular adaptation during a flight of longer duration.     

Effect of acute exercise stress in cardiac hypertrophy: I. correlation of regional blood flow and qualitative ultrastructural changes.

Ultrastructural myocardial cell changes were determined in eight miniswine after the development of pressure-overload hypertrophy induced by supra-valvular aortic constriction. Four miniswine served as control animals. Regional myocardial blood flows were measured at rest and during exercise stress with radioactive microspheres after two days and one month of aortic constriction. Exercise stress, causing the heart rate to increase to 85 percent of its maximum, was imposed twice weekly for 7 minutes on four pressure-overloaded animals and the four control animals to elicit differences between the control and experimental groups that might not occur at rest. After one month of pressure overload the swine were killed and myocardial samples were processed for electron microscopy. Ultrastructural changes similar to those in hypertrophied hearts were present throughout the left ventricular walls of the pressure-overloaded animals. Other changes consistent with ischemic injury were present in the subendocardial regions of pressure-overloaded animals subjected to exercise stress. These changes included disorganization of myofibrils, disintegration and broadening of Z-bands, swelling and aggregation of mitochondria, electron-dense deposits in mitochondria, decreased cristal density and vacuolization of mitochondria, intracellular edema, margination and clumping of nuclear chromatin, and a decrease of glycogen granules. Regional ischemia in the subendocardium of these animals was confirmed by functional studies which showed decreased regional myocardial blood flow to the subendocardium during exercise and S-T segment elevation for the first 2-10 days after inducing pressure overload. The ischemia, as shown by flow studies, during exercise stress persisted in the compensatory stage of hypertrophy although S-T segments returned to normal. Thus, the combined effect of pressure overload and exercise stress can produce focal subendocardial ischemia in the compensated, hypertrophied heart.     

Myocardial cell lesions caused by an anabolic hormone

Summary Early changes in the composition of heart muscle cells of the rat caused by an anabolic hormone were investigated by electron microscopy. Mitochondria and myofibrils showed changes similar to those observed in early heart failure: The mitochondria were swollen and elongated. Their matrix was sparse and the cristae were few in number. The myofibrils showed either disintegration and widened and twisted Z-bands or a complete dissolution of the sarcomeric units.This work is supported by the Deutsche Forschungsgemeinschaft (Be 742/1)     

Effect of acute exercise stress in cardiac hypertrophy. II. Quantitative ultrastructural changes in the myocardial cell

Stereological techniques were used to determine quantitatively the changes in subcellular organelles in the hypertrophied swine heart. Hypertrophy was induced by aortic stenosis. In addition, the animals were stressed by exercising twice weekly on the treadmill for 30 days. The controls were normal animals which were neither exercised nor had aortic stenosis. Tissue samples from the left ventricle and interventricular septum were processed for electron microscopy. Relative volumes of myofibrils, mitochondria, transverse tubular system (T-system) sarcoplasmic reticulum (SR), and clear intracellular space (ICS) were measured. Significant differences in the volumes of all the components except the T-system were found between experimental and control animals in the epicardial and endocardial regions of the left ventricle and interventricular septum. Mitochondria and myofibrils were significantly decreased in the exercise stressed hypertrophied hearts as reported in ischemia, while SR and ICS were significantly increased. These findings suggest that ischemic injury occurs in all regions of the hypertrophied heart wall subjected to acute exercise stress, not solely the endocardial region as previous qualitative studies suggested.     

Mitochondrial membrane fluidity, potential, and calcium transients in the myocardium from acute diabetic rats

In this study, we report for the first time concurrent measurements of membrane potential and dynamics and respiratory chain activities in rat heart mitochondria, as well as calcium transients in the hearts of rats in an early phase of streptozotocin diabetes, not yet accompanied with diabetes-induced complications. Quantitative relationships among these variables were assessed. The mitochondria from diabetic rats exhibited decreased fluorescence anisotropy values of diphenylhexatriene. This indicates that hydrophobic core of the membranes was more fluid compared with controls (p<0.05). We discuss the changes in fluidity as having been associated with augmented energy transduction through the diabetic membranes. Reduced ratio of JC-1 fluorescence (aggregates to monomers) in the mitochondria from diabetic hearts reflected descendent transmembrane potential. A significant negative association between membrane fluidity and potential in the diabetic group was found (p<0.05; r=0.67). Further, we observed an increase in calcium transient amplitude (CTA) in the diabetic cardiomyocytes (p=0.048). We conclude that some of the calcium-induced regulatory events that dictate fuel selection and capacity for ATP production in diabetic heart occur at the membrane level. Our findings offer new insight into acute diabetes-induced changes in cardiac mitochondria.     

Bone biochemistry in rat femoral diaphysis after space flight

The aim of this experiment was to identify the location of the biochemical changes associated with depressed mineralization during space flight. We carried out biochemical analysis of 4 sections of the femoral diaphyses from 107 day old male rats flown aboard Cosmos 2044 Biosatellite for 16 days. Control femurs were preflight, vivarium, synchronous for feed, cage and temperature exposure, and a flight simulation model. Distal sections in both the flight and synchronous femurs showed mineral deficits associated with reduced levels of the reducible cross-link product of type I collagen, dehydro-dihydroxylysinonorleucine (deH-DHLNL) (p<.05). Unloaded bones in the ground based flight simulation model showed changes in cross-links similar to flight and synchronous controls, but were not associated with the mineral deficit. Mean values of elements measured in each section of all groups revealed significant associations (p<.005) between the non-collagenous protein, osteocalcin and calcium (r=0.774), phosphorus (r=-.624) and deH-DHLNL/deH-HLNL (r=.883). The ratio of the nonreducible cross-link, pyridinoline, to its lysl analogue, deoxypyridinoline, was consistently lower in the distal than proximal sections of the groups tested. None of the changes during space flight were unique to flight bone. The most significant and extensive changes in bone composition, i.e. mineral deficits associated with changes in both osteocalcin and reducible cross-links, were located in the distal section of the diaphysis of the femur.     

Stereological analysis of the ultrastructural organization of the cardiomyocytes in the red-cheeked suslik in different seasons of the year

The myocardium of red-cheeked sousliks was studied at different seasons with the use of stereological analysis. The volume and surface densities of the myofibrils, mitochondria, T system, sarcoplasmic reticulum as well as the surface-volume ratios of the main organelles were measured. Pronounced seasonal changes in physiological activity of the heterothermal animals were accompanied by marked reorganization of the spatial ultrastructure of the cardiomyocytes. The seasonal regression of the heart weight and diminution of the cardiomyocyte diameter were recorded during hibernation. The authors believe that the increased volume ratio of the cytoplasmic organelles to the myofibrils forms the basis for a rapid adaptive reaction of the heart during hibernation and waking up.     

An ultrastructural stereological analysis of the myocardium in homoiothermal animals during cooling]

By methods of electron microscopy and stereology the ultrastructural cardiomyocyte reorganization of rats exposed to influence of low temperatures (exposure during 16 days at -7 degrees C) was studied. It was shown, that with this regime of cooling the disturbance of intracellular regeneration in cardiomyocytes occurred and the complex of morphological changes typical for the syndrome of regenerative-plastic deficiency was developed. The most essential changes were seen in myofibrils and mitochondria. According to the stereologic data a change in spatial reorganization of cardiomyocytes was connected largely with these organelles. With the increase in cooling duration an increase in the volume density of myofibrils and a decrease in this parameter for mitochondria were marked. As a result of these changes the mitochondria/myofibrils volume ratio was essentially decreased. As a whole, ultrastructural reorganization of cardiomyocytes under the influence of low temperatures on rats was characterized by a decrease in the ratio of the organelle volume to myofibrillar volume. The same quantitative reorganization was revealed in atrophied cardiomyocytes under the conditions of the decreased inflow of plastic substances to cells.     

Adaptive morphology of the heart of Southern‐Fur‐Seal (Arctocephalus australis – Zimmermamm, 1783)

The Southern‐fur‐seal belongs to the order Carnivora, suborder Pinnipedia, and Otariidae family. This species inhabits aquatic and terrestrial environments, thus presenting important morphophysiological adaptive changes, especially in the cardiac system. For this purpose, Southern‐fur‐seal (Arctocephalus australis) hearts were used from animals that died from natural causes. Gross morphology observations were supported by light, scanning and transmission electron microscopy. The heart was long and flat; it was lined by pericardium and partly covered by lungs. Structurally, atrium and ventricle muscle fibers exhibit typical features of cardiac fibers revealing myofibrils bundles, mitochondria, plate‐shaped junctions, anastomosis between myofibrils bundles, and electron‐dense granule natriuretic around the nucleus and mitochondria of atrium muscle cells. The Southern‐fur‐seal heart was structurally similar to other mammals; however, it presented morphological changes that assist in their adaptation to their environment.     

Ultrastructural morphometry of the myocardium of Thunnus alalunga

The common ventricle in the heart of the Thunnus alalunga was studied. The ventricular myocardium consists of an outer compact layer and a thick inner spongy layer. The compact layer has slightly larger cells (4-6 microns diameter) than the spongy layer (2.5-5 microns diameter). Ultrastructurally the myocardium displays normal arrangements of myofibrils and mitochondria. The sarcoplasmic reticulum is poorly developed. The intercalated discs are simple with the fascia adherens being the most frequent junctional type observed; occasionally a desmosome was seen. Nexus type junctions are present but are unassociated with the intercalated discs. There are no t-tubules evident but the plasmalemma exhibits numerous caveolae which rarely form couplings with the sarcoplasmic reticulum. A morphometric analysis of the volume percent of mitochondria and myofibrils showed that the myocardial cells in the spongy layer of the heart have a significantly greater volume percentage of mitochondria than the compact layer. No significant differences were found between myocardial regions when the volume percentages of myofibrils were compared. The physiological studies revealed that the albacore tuna has heart rates (120 bpm) and ventricular blood pressures (100 mmHg) that are among the highest reported for fish.     

Myocardial lysosomes in pressure-overload hypertrophy

Summary Combined electron microscopic and cytochemical studies were used to investigate the effects of chronic-pressure overload hypertrophy on myocardial lysosomes, mitochondria, and myofibrils in the left ventricle of the cat. Myocardial hypertrophy was induced by an 84% banding constriction of the ascending aorta. After one month of aortic constriction the experimental animals demonstrated a 51% increase in left ventricular mass. No qualitative ultrastructural differences were noted between the myocardial tissues of the hypertrophy and normal group. However, the cytochemical reaction product to acid phosphatase appeared more frequently in the myocardium of the hypertrophy group compared to that of the normal group. By use of quantitative morphometry the percentage of mitochondria, myofibrils and lysosomes per myocardial cell was determined in both hypertrophy and normal groups of animals. Despite significant increases in the left ventricular mass of hypertrophy animals, a normal balance of mitochondria and myofibrils was maintained within the myocardium. Further analysis indicated an enhanced lysosomal population in the hypertrophy group compared to the normal group.This research was supported by a grant from the California Affiliate of the American Heart Association     

Genetic models in applied physiology: selected contribution: effects of spaceflight on immunity in the C57BL/6 mouse. II. Activation, cytokines, erythrocytes, and platelets.

This portion of the study quantified the effects of a 12-day space shuttle mission (Space Transport System-108/UF-1) on body and lymphoid organ masses, activation marker expression, cytokine secretion, and erythrocyte and thrombocyte characteristics in C57BL/6 mice. Animals in flight (Flt group) had 10-12% lower body mass compared with ground controls housed either in animal enclosure modules or under standard vivarium conditions (P < 0.001) and the smallest thymus and spleen masses. Percentages of CD25(+) lymphocytes, CD3(+)/CD25(+) T cells, and NK1.1(+)/CD25(+) natural killer cells from Flt mice were higher compared with both controls (P < 0.05). In contrast, CD71 expression was depressed in the Flt and animal enclosure module control mice compared with vivarium control animals (P < 0.001). Secretion of interferon-gamma, IL-2, and IL-4, but not tumor necrosis factor-alpha and IL-5, by splenocytes from Flt mice was decreased relative to either one or both ground controls (P < 0.05). Flt mice also had high red blood cell and thrombocyte counts compared with both sets of controls; low red blood cell volume and distribution width, percentage of reticulocytes, and platelet volume were also noted (P < 0.05) and were consistent with dehydration. These data indicate that relatively short exposure to the spaceflight environment can induce profound changes that may become significant during long-term space missions.     

Fine structural changes in embryonic chick heart ventricle induced by lead poisoning.

The embryonic chick heart ventricle of day 11 was studied electron microscopically to learn the structural changes that develop in lead poisoning. The chick embryos were administered with 0.015 mg/egg of lead acetate at day 2. The most pronounced changes observed in the ventricle were: malformed mitochondria, disorganized, short and scanty myofibrils and abundance of swollen vacuoles. The ultrastructure of the ventricle from the control chick embryos was normal. The most frequent change noted in the ventricular tissue was an alteration in the myofibrils. This study indicates that electron microscopic changes can be induced in the embryonic chick heart ventricle by lead poisoning.