Morphological characteristics of the motor neurons of the spinal cord in physical loading up to the limit

The experiments have been performed on 98 white rats adapted and nonadapted to the effect of physical loadings. The loadings up to the limit are reached by swimming of the rats up to fatigue. The swimming lasts for 10-15, 20-35, 40-65, 70-90 h. Under the conditions mentioned, morphological changes of the neurons are of mosaic pattern. Light optic and electron microscopic methods demonstrate swelling of neurons, endocellular and pericellular edema, vacuolization, appearance of gigantic degeneratively altered mitochondria, presence of vesicles in mitochondria, hollow mitochondria, dilated cysterns of the endoplasmic reticulum, degenerated synapses and glial reaction. These changes are considered as adaptive and compensatory reactions in the process of physiological strain of the organism, directed towards increasing stability against the effect of the extermal factor. In the animals nonadapted to any physical loadings, morphological changes in neurons of the ventral horns of the spinal cord are more deeply and widely spread in character.     

Morphofunctional changes in the long tubular bones of animals which have developed while readapting after physical loads

The investigation has been performed on 120 white male rats of Wistar line. By means of the morphometry, electron microscopy and chemical methods dynamics of readaptive changes have been studied in long tubular bones during the period, when the effect of physical loadings both of dynamic and static character and of various intensity has been stopped, up to the old periods of the animals' life. Readaptation after moderate dynamic and static loadings is occurring for a long time and steadily. The changes caused by static loadings are nearly completely restored in a year. Morphofunctional rearrangements of the long tubular bones in the readaptation process after moderate dynamic loadings is characterized by residual manifestations. Prolonged readaptation after intensive physical loadings does not result in a complete restoration of all the parameters studied concerning growth and skeletal development. An intensive dynamic loading produces more stable changes, that are not subjected to a complete correction even after a passive readaptation for a year. Readaptation morphofunctional rearrangements of the long tubular skeletal bones depend on conditions of the previous regimen of the motor activity.     

Adaptive changes in sections of the myocardium of experimental animals undergoing physical loading of a static nature

Adaptation of the parts of myocardium of 18 white rats to the physical static loadings during two months have been studied by means of morphometric and histological methods. Physical loadings cause hyperfunction and hypertrophy of all chambers of the heart with a predominant hypertrophy of the right ventricle, right auricle and dilatation of these cavities. The heterogeneous changes of the myocardium were found on the organic level.     

Ultrastructural changes of receptor endings in prolonged action of local anesthetics

Ultrastructural changes of the terminal plates of the bushy receptors in the frog urinary bladder have been studied after two hours' exposition in 0.05% novocaine solution and one hour's exposition in 0.05% dicaine and trimecaine solution. During these periods a steady block of the receptor impulse activity develops. The local anesthetics essentially change ultramicroscopic structure of the terminals. The reaction to the anesthetics investigated has both some features in common and certain peculiarities. At each effect three types of changes can be determined, characterized with various degree of rearrangement in neurilemma, neuroplasm and organelles. Each type of the changes is supposed to reflect a certain phase of the plate reactive response. Specificities of the reaction to novocaine are minimal changes of mitochondria, accumulation of glycogen granules, deformity and decreasing amount of vesicles. Under dicaine effect mitochondria do not change, amount of vesicles increases, their form does not change; under trimecaine effect mitochondria undergo most noticeable alterations. The changes of the terminal plates observed are interpreted as adaptive. The effect of the local anesthetics on the receptors is not limited with the blockade of the sodium canals of the afferent fibers, in parallel, biochemical processes, occurring in cytosol of the terminals also change; their morphological manifestations are the ultrastructural changes observed.     

The effect of starvation on the ultrastructure of the red and white myotomal muscles of the crucian carp (Carassius carassius)

Summary The effect of 16 weeks total starvation on the ultrastructure of the red and white myotomal muscles of the crucian carp (Carassius Carassius) has been investigated. In the white fibres the amount of myofibrillar material fell from 89.6% to 70.7% of the total fibre volume whilst in the red fibres the fall was from 72.2% to 70.3%. The sarcoplasmic reticulum appeared to have become swollen during starvation in both fibre types. In the white fibres the terminal cisternae of some triads seem to have fused. The volume of the red fibres occupied by mitochondria was reduced from 16.2 % to 5.9 %. The concentration of mitochondria in the white fibres was too low to detect any quantitative changes. A marked reduction in the amount of euchromatin material was observed in most white fibre nuclei and many red fibre nuclei. Many of the ultrastructural changes noted in the present study can be correlated with biochemical changes known to occur in the red and white myotomal muscles of fish during starvation. This work was supported by a grant from the Natural Environmental Research Council.     

Ultrastructure of neuromuscular synapses of 3 types of muscle fibers of the rat diaphragm in acute chlorophos poisoning

A comparative analysis of changes in ultrastructure of neuro-muscular synapses of three types has been studied in the rat diaphragmal muscle at an acute poisoning with chlorophos. A high stability to the damaging action of chlorophos in white muscle fibers has been revealed in comparison with other types. The most essential changes of the ultrastructure have taken place in slow intermediate fibers. These differences are evidently connected with certain peculiarities in morphofunctional organization of calcium-sequestring ++ components of three types of muscle fibers (sarcotubular system, mitochondria) and presence of parvalbulin.     

Changes in the structure and cell composition of the thymus as a result of dosed physical loads

By means of histological and morphometrical methods normal age involution of the thymus has been studied, as well as its changes under conditions of dosed physical loadings. The experiment has been performed in 92 non-inbred white male rats. At adaptation of the organism to the loadings, involution of the gland decelerates, and at an insufficient adaptation--accelerates. This is, probably, the cause of decreasing protective forces of the organism.     

Ultrastructural changes in the red muscle fibers of the quadriceps muscle of the rat femur during increased motor activity

Experiments on rats were made to study the effect of physical exercise running in a treadbahn on ultrastructure of skeletal muscle fibers. The biphasic mechanism of muscle contractile activity was shown. The processes of destruction occurring in red muscle fibers of the intensely working quadriceps femoris were manifested by enlargement of T system and sarcoplasmic reticulum elements, mitochondrial matrix swelling, cryst destruction, vacuolar degeneration of part of the mitochondria, and destruction of individual myofibrils. In addition to destructive changes, the muscle exhibited the recovery processes--physiological regeneration. Those processes included large accumulations of the mitochondria beneath the plasma membrane of muscle fibers, the presence of small mitochondria, division of the mitochondria, transformation of myosatellitocytes to myoblasts, the presence of centrioles in endotheliocytes, and so forth.     

Ultrastructural changes in the skeletal muscles after physical exertion in rats of various ages

The white rats of the age 1, 3 and 12 months ran in the treadmill at a speed 45 m/min for 20, 40, 60 and 90 days. There is not any linear dependence of muscular transformations and the intensity of physical loading. Changes of the material components of muscular fibers are of undulated character, depending on the age, increase in quantity of myofibrils is always accompanied with a decrease in the quantity of mitochondria. When the total share of myofibrils and mitochondria increases, the quantity of other ultrastructural elements of the muscular fibers and hyaloplasm decreases.     

Scanning electron-microscopic studies on the three-dimensional structure of mitochondria in the mammalian red,white and intermediate muscle fibers

Summary The three-dimensional structure and arrangement of mitochondria in the red, white and intermediate striated muscle fibers of the rat were examined under a field-emission type scanning electron microscope after removal of cytoplasmic matrices by means of the Osmium-DMSO-Osmium procedure.Beneath the sarcolemma, spherical or ovoid subsarcolemmal mitochondria show accumulations. The mitochondria are numerous and large in size in the red fibers, intermediate in the intermediate fibers, and few and small in the white fibers. Paired, slender I-band-limited mitochondria were located on both sides of the Z-line and partly embraced the myofibrils at the I-band level; they occurred in all three types of fibers. In the intermyofibrillar spaces, numerous mitochondria formed mitochondrial columns. These columns were classified into two types: 1) thick mitochondrial columns, formed by multiple mitochondria each with an intermyofibrillar space corresponding to one sarcomere in length, and 2) thin mitochondrial columns, established by single mitochondria corresponding to one sarcomere in length. In the red fibers mitochondrial columns were abundant and the ratio of the thick and thin columns was almost the same, while in the intermediate fibers most of the columns belonged to the thin type. The white fibers displayed rare, very thin columns.     

Ultrastructural changes in the receptor portion of the vestibular apparatus in response to noise

The experiments have been performed on 24 guinea pigs (48 labyrinthes), 6 of them--control and 18 have been subjected to noise (one octava) with the average geometrical in diaposone of 2,000 Hz, at intensity level 100 dB. Six animals are subjected to a single effect for 6 h and 12--to repeated effect during 6 days running, 4-6 h daily. Isolation of both the vestibular and the cochlear parts of the membranous labyrinth is performed simultaneously. This gives a possibility to study all the receptors of the internal ear as a whole. Certain ultrastructural changes in all the vestibular receptors both at a single and repeated effects are revealed. Dilatation of the granular endoplasmic reticulum is observed, situating mainly in the basal part of the cell; swelling of mitochondria is accompanied with a sharp clearance of their matrix. In some mitochondria there is a local destruction of their external and internal membranes. Moreover, in cytoplasm of the receptory cells sharply osmiophilic fibrillar structures are revealed, they resemble crists and are arranged in bundles. In some cells they are not numerous and localize mainly in mitochondria, in others--their number is greater, and they localize not only in mitochondria, but in the surrounding cytoplasm, too. Similar structures are observed in some preganglionic myelin fibers. These phenomena can be considered as development of calcification processes. The changes described, evidently, form the basis of the vestibular disorders under the noise effect.     

Reaction of striated fibers of human skeletal muscles to long-term anti-orthostatic hypokinesia

Eight men have been kept under a strict bed rest. The lower end of the bed has been elevated by 6 degrees. During the whole effect of the antiorthostatic hypokinesia (AOH) in biopsy of the skeletal muscle tissue no gross morphological changes and essential changes in relation of the muscle fiber (MF) types have been found. On the 120th day of AOH without application of any physical loading concentration of RNA, protein metabolism, glycogen, activity of the energetic metabolism enzymes, MF size decrease. Both contractile and energetic apparatus suffers essentially. This demonstrates certain atrophic processes in both types of the MF. Physical loading against the background of AOH, on the 120th day, prevents development of the atrophic processes in MF. This is demonstrated as maintenance of certain metabolic level and less pronounced changes of ultrastructure. On the 360th day of the experiment in the group without any loading, an essential atrophy of MF, a noticeable++ decrease in metabolism are observed. In the test group against the background of AOH the changes in the biopsy fibers are less pronounced and not so uniform. Application of physical loadings contributes to the development of certain adaptive reactions; their positive effect to the skeletal muscle fiber morphology depends on the structural background, against which it acts and their intensity. The earlier the load begins to act and the higher its intensity, the more pronounced is the delay in development of profound atrophic changes.     

Features of the ultrastructural organization of the muscles of skaters in relation to their sport specialization and muscle fiber composition

An electron microscopical and histochemical investigation of bioptates obtained from the external broad femoral muscle of 74 sportsmen-skaters has been performed. Structural adaptation of the muscles to speed loadings and to endurance loadings has been analysed taking into consideration contents of muscle fibers (MF) of various type. Peculiarities in ultrastructural organization of the skeletal MF in the sprinter- and stayer-skaters, who undergo training according to a special program, are described; the character of the muscle changes is also followed in the sportsmen who undergo training according to the program that does not correspond to the contents of their MF. Lesions in the latter up to the necrotic ones are mostly found in the muscles of the stayer-skaters, as well as in the sprinters trained according to the stayer program. Presence of essential destructive alterations of the muscles in the skaters, especially in those whose contents of slow muscles do not correspond to their specialization, demonstrates, evidently, the fact that the given physical loading is not adequate to the functional or potential possibilities of the organism.     

Morphofunctional characteristics of enzyme activity of the muscles in ontogenesis and after physical load

By means of histochemical methods using cytospectrophotometer in femoral muscles of white rats 1-, 3- and 12-month-old enzymatic activity of anaerobic and aerobic cycles has been estimated. The greatest changes occur after 20 days of physical load in 1- and 12-month-old animals. The semitendinous muscle (ventral origin), consisting mainly of red muscle fibers, works chiefly in aerobic regime and possesses a more manifested succinate dehydrogenase activity, and the quadriceps muscle (dorsal origin) consists principally of white fibers and its lactate dehydrogenase activity changes more noticeably.     

8-Oxoguanosine and uracil repair of nuclear and mitochondrial DNA in red and white skeletal muscle of exercise-trained old rats.

Oxoguanine DNA glycosylase (OGG1) and uracil DNA glycosylase (UDG) are two of the most important repair enzymes that are involved in the base excision repair processes to eliminate oxidative damage from mammalian DNA, which accumulates with aging. Red and white skeletal muscle fibers have very different antioxidant enzyme activities and resistance to oxidative stress. In this paper, we demonstrate that the activity of OGG1 is significantly higher in the red type of skeletal muscle compared with white fibers from old rats. Exercise training resulted in increased OGG1 activity in the nuclei of red fibers and decreased activity in nuclei of white fibers and in the mitochondria of both red and white fibers. The activities of UDG were similar in both red and white muscle fibers. Exercise training appears to increase the activity of UDG in the nuclei and mitochondria. However, exercise training affects the activity of OGG1 in nuclei and mitochondria differently, suggesting different regulation of the enzymes. In contrast, UDG showed similar activities in nuclei and mitochondrial extracts of exercise-trained animals. These data provide evidence for differential regulation of UDG and OGG1 in maintaining fidelity of DNA in oxidatively stressed cells.     

Age-related alterations of mitochondria from muscle tissue

The ultrastructure of mitochondria of cross-striated muscles during aging was studied by electron microscopy. Mitochondrial ultrastructure was analyzed in the flight muscle of D. melanogaster (1- and 36-day-old) and in the cardiomyocytes and skeletal muscle of young and senile Wistar and OXYS rats (3- and 25-month-old). The mitochondria in the flight muscle samples of senile D. melanogaster flies were shown to have several types of peculiar age-related mitochondrial abnormalities corresponding to those described previously. Previously unknown changes were revealed in the ultrastructure of cardiomyocyte mitochondria in senile rats (both Wistar and OXYS). Substantial changes in the ultrastructure of subsarcolemmal mitochondria were found in the fibers of red skeletal muscle of senile OXYS rats. It has been shown that the subsarcolemmal mitochondria of red muscle fibers are a peculiar population of mitochondria with atypical ultrastructure. Initial changes in the ultrastructure of subsarcolemmal mitochondria were revealed even in 3-month-old OXYS rats. At the same time, the skeletal muscle mitochondria of senile Wistar rats maintain their morphological characteristics, and their ultrastructure corresponds to that of skeletal muscle mitochondria in 3-month-old Wistar rats.     

High -resolution scanning electron-microscopic studies on the three-dimensional structure of mitochondria and sarcoplasmic reticulum in the different twitch muscle fibers of the frog

Summary The three-dimensional structure of the mitochondria and sarcoplasmic reticulum (SR) in the three types of twitch fibers, i.e., the red, white and intermediate skeletal muscle fibers, of the vastus lateralis muscle of the Japanese meadow frog (Rana nigromaculata nigromaculata Hallowell) was examined by high resolution scanning electron microscopy, after removal of the cytoplasmic matrices.The small red fibers have numerous mitochondrial columns of large diameter, while the large white fibers have a small number of mitochondrial columns of small diameter. In the medium-size intermediate fibers, the number and diameter of the mitochondrial columns are intermediate between those of the red and white fibers.In all three types of fibers, the terminal cisternae and transverse tubules form triads at the level of each Z-line. The thick terminal cisternae continue into much thinner flat intermediate cisternae, through a transitional part where a row of tiny indentations can be observed. Numerous slender longitudinal tubules originating from the intermediate cisternae, extend longitudinally or obliquely and form elongated oval networks of various sizes in front of the A-band, then fuse to form the H-band collar (fenestrated collar) around the myofibrils. On the surface of the H-band collar, small fenestrations as well as tiny hollows are seen. The three-dimensional structure of SR is basically the same in all three muscle fiber-types. However, the SR is sparse on the surface of mitochondria, so the mitochondria-rich red fiber has a smaller total volume of SR than the mitochondria-poor white fiber. The volume of SR of the intermediate fiber is intermediate between other the two.     

Structural reaction of skeletal muscle mitochondria to deep hypothermia in the experiment

The reaction of locomotor muscle mitochondria was studied in white rats during different periods of deep hypothermia. An acute exposure to cold produced substantial changes of the muscle cellular mitochondrial apparatus, such as matrix swelling, crysts destruction with a significant decrease in mitochondrial profiles on the periphery of muscle fibers. Destructive and degenerative mitochondrial lesions were greater in prolonged hypothermia and subsequent warming. Such structural reaction of locomotor muscle mitochondria could reveal a substantial insufficiency of the muscle cellular energy apparatus during experimental hypothermia.     

Ultrastructure of the smooth muscle cells of the femoral artery in rats exposed to vibration

Electron microscopic study of femoral arteries of white rats exposed to prolonged general vibration at a frequency of 100 Hz with an amplitude of 0.5-0.7 mm has been performed. Light and dark smooth muscle cells, as well as unchanged cells have been found in the vascular media of experimental animals. Light cells are swollen with destroyed myofilaments and great number of microtubules in cytoplasm. Dark cells are characterized by coagulation necrosis and melting of myofilaments. Vibration was shown to cause marked structural changes in smooth muscle cells mitochondria: destruction of internal and external membranes, increasing matrix osmophilia or swelling of mitochondria accompanied by crista fragmentation, as well as matrix clarification and disappearance. Morphometric analysis indicates a considerably decreased energy production by smooth muscle cell mitochondria. It has been concluded that vibrations have a damaging effect on medial smooth muscle cells of the femoral artery in the experimental animals.     

Intermembrane inclusions induced by anoxia in heart and skeletal muscle mitochondria.

Heart and skeletal muscle from rats of different ages were incubated in vitro in an oxygen-free medium supplied with substrates in order to investigate the effect of anoxia on muscle fine structure, particulary on the mitochondria. In skeletal muscle fibers anoxia has been found to induce changes similar to those previously described in ischemic muscles in vivo namely giant mitochondria, apparently derived by mitochondrial fusion, and intermembrane inclusions with a paracrystalline structure. The plate-like inclusions are mostly located in the intracristal spaces and are closely associated to cristal membranes even in markedly swollen mitochondria. Identical inclusions have been observed in cardiac muscle cells following anoxic injury, whereas they are never found in non-muscle cells such as endothelia, fibroblasts and nerve fibers. Cardiac and skeletal muscle fibers from newborn rats maintained in an oxygen-free medium show mitochondrial swelling but no intermembrane inclusions. The different response of mitochondria from developing vs adult striated muscle to anoxia may be due to changes during postnatal development in the quality or quantity of the protein component(s) involved in paracrystal formation.