Extraocular muscles in the lamprey, Lampetra fluviatilis L. I. Muscle fibres

Six extraocular muscles of the river lamprey, Lampetra fluviatilis L., were studied with the light and electron microscope. On the basis of morphology and histochemistry three types of muscle fibres were distinguished: thin, thick mitochondria-rich and thick multifibrillar fibres. In the thin fibres, 2.8-22.4 microns in diameter, myofibrils are distributed peripherally and show strong ATPase activity. The mitochondria are located paraxially. In the thick mitochondria-rich fibres, 19.4-31.0 microns in diameter, myofibrils are also located peripherally, whereas the central part of the fibre is densely packed with very numerous mitochondria possessing tubular cristae. Thick multifibrillar fibres, with a diameter similar to that of the former type, contain thin myofibrils scattered over the entire cross-section of the fibre. The activity of myofibrillar ATPase is lower in both types of thick fibres than in the thin ones. The tubules of the T system were observed frequently only in the thick multifibrillar fibres. The extraocular muscles of the lamprey are composed of large quantities of muscle fibres. Thin and thick fibres do not form separate layers, but are more or less uniformly distributed throughout the muscle. Many muscle fibres show structural features suggesting their degeneration.     

Morphometry of muscle fibre types in the carp (Cyprinus carpio L.)

Summary Ultrastructural parameters of muscle fibre types of the carp (Cyprinus carpio L.) were measured and compared with their contractile properties. In red fibres, which are slower than pink fibres, the relative length of the junction between the T system and the sarcoplasmic reticulum (T-SR junction) is smaller and the Z lines are thicker than in pink fibres. Pink fibres have a smaller relative length of T-SR junction than white fibres from the axial muscles. The two types of red fibres present in carp muscle also differ in their relative lengths of T-SR junction. Significant differences in the relative areas of the SR were not found.The relative volume of myofibrils in red fibres is two-thirds that in pink fibres, a difference that is not reflected in the maximal isometric tetanic tensions of these types. Red fibres, which are less easily fatigued than pink fibres, have larger relative volumes of subsarcolemmal and intermyofibrillar mitochondria. Small pink fibres have a larger relative volume of subsarcolemmal mitochondria than large pink fibres, but have a similar relative volume of intermyofibrillar mitochondria. Small and large pink fibres differ in the relative volumes of their membrane systems, but have similar relative lengths of T-SR junction.     

The fine structure of muscle fibres of roach, Rutilus rutilus (L.), and chub, Leuciscus cephalus (L.), Cyprinidae, Teleostei: interspecific differences and effects of habitat and season

Red and white axial muscle fibres from roach and chub were investigated by electron microscopy. Fish from three different localities were compared. Qualitative and quantitative analysis of myofibrils, mitochondria, lipid and subsarcolemmal cytoplasm with regard to muscle fibre type, species, season and habitat were made. Muscle fibre types differ significantly with the exception of the subsarcolemmal cytoplasm in roach. Within-species lipid content of red fibres differs between seasons. However, the most marked effect on red muscle fibres within species and season as regards volume density of lipid and mitochondria can be attributed to the different localities. The results are discussed in relation to mode of life and differences in habitat.     

The ultrastructure of myotomal muscles of the golomianka, Cormephorus baikalensis Pallas

An ultrastructural study of the myotomal muscles in the golomianka, Comephorus baikalensis Pallas, revealed two main and distinct muscle regions: superficial and white. They were distinguished on the basis of histological and ultrastructural organization. Only the superficial fibre region shows homogeneous organization. The principal new finding is the unique ultrastructural organization of the superficial muscle fibres. Their myofibrils occur in the form of ribbons surrounded by large mitochondria.     

Quantitative fine structural diversification of red and white muscle fibres in cyprinids

Synopsis Based on the results of investigations into the fine structure of red and white muscle of roach, Rutilus rutilus, and chub, Leuciscus cephalus (Sänger et al. 1990), analysis of axial muscle has been extended to include nine other cyprinid species. Quantitative comparisons were made of myofibrils, mitochondria, lipid and sub-sarcolemmal cytoplasm in relation to muscle fibre type and species. A comparison of these variables between the species shows that for red fibres there are significant differences in all measured variables in at least some cases. The most striking difference is in lipid content, with Danube bleak, Chalcalburnus chalcoides mento, having the highest amount. For white fibres, there were significant differences only in intermyofibrillar mitochondria and myofibrils, which were most significant in Danube bleak. As a preliminary study, intermediate, fibres have been examined qualitatively and compared with the other two fibre types using the above mentioned variables. The results allow cyprinids to be arranged according to their scores from the different measurements. These groupings are discussed in relation to the different life-styles of the fish.     

Three muscle fibre types in the axial muscle of axolotl (Ambystoma mexicanum Shaw) A quantitative lightand electron microscopic study

Morphometric analysis by light microscopy of p-phenylene-diamine stained semithin sections of axolotl tail muscle revealed differences in the cross-sectional area of the fibres and in the number of mitochondria and of lipid inclusions per fibre, and indicated the presence of three distinct types of fibres. The tripartition was found to be statistically highly significant. Representative fibres from each group established by light microscopic morphometry were subjected to an ultrastructural morphometric analysis. The volume content of mitochondria amounted to 9.8% of the fibre volume for red, 4.0% for intermediate and 0.8% for white fibres. The myofibrils composed 60%, 70% and 83% in the same fibres. The volume of the sarcotubular system (t-tubuli and sarcoplasmic reticulum) was 2.5% in red, 4.5% in intermediate and 11.7% in white fibres. The three fibre types also demonstrated differences in myofibrillar cross-striation pattern and number of triads. The reliability of the light microscopic morphometry was tested by correlation with EM montages of the representative fibres.     

Diameter changes of muscle fiber types of the inferior oblique muscle of the rabbit following denervation]

Changes in fibre diameters of extraocular muscles of the rabbit were studied at different times after denervation. The whole inferior oblique muscle hypertrophied, while some of the muscle fibres hypertrophied and others showed atrophy, depending on the fibre type. Fibre types have been determined by their histochemical enzyme profile. In the central layer of the muscle the phasic muscle fibres, which are rich in mitochondria, exhibited a transient hypertrophy being maximal 4-5 weeks after denervation and afterwards they atrophied; other phasic muscle fibres, which are poor in mitochondria, atrophied without having shown any sign of hypertrophy. Special, putatively slow tonic muscle fibres, which have low enzyme activities, underwent small long-lasting increases of their diameters. In the superficial layer of extraocular muscle there are two types of extremely thin muscle fibres rich in mitochondira. Both these fibre types hypertrophied to the greatest degree and for a very long time. Comparable changes in fibre diameters as described here for the muscle fibre types of an extraocular muscle are known from special muscle fibres in other vertebrate     

Temperature acclimation in crucian carp, Carassius carassius L., morphometric analyses of muscle fibre ultrastructure

Carp show a partial compensation in metabolic rate and activity following temperature acclimation. In the present study crucian carp, Carassius carassius , were acclimated for eight weeks to either 2deg; C or 28deg; C. The effects of temperature acclimation on muscle fibre ultrastructure has been investigated. The fractional volume (%) of each fibre type occupied by mitochondria and myofibrils was determined using a point counting morphometric method. Mitochondrial density was found to be higher in the muscles of cold (red fibres 25%; pink fibres 20% and white fibres 4%) than in those of warm acclimated fish (red fibres 14%, pink fibres 11%, white fibres 1%). The proportion of subsarcolemmal to intra-myofibrillar mitochondria was significantly lower in the red fibres of cold acclimated fish. Metabolic compensation to low temperatures are therefore associated with an increase in the number of mitochondria per cell. In contrast, the fractional volume occupied by myofibrils actually decreased following cold acclimation. Evidence is reviewed that temperature compensation of contractile activity results from qualitative rather than quantitative changes in myofibrillar proteins.     

Interpretation of the cross sectional structure of skeletal muscle fibers. 2. Light and electron microscopic studies of m. rectus abdominis in Rana esculenta]

In both longitudinal and cross sections of rectus abdominis muscle of Rana esculenta three types of muscle fibres are identified by means of light and electron microscopy. A comparison is made between these fibre types in homologous muscles of frog and mammals (rat and mouse). In longitudinal sections of mammalian and frog muscle the Z-line can be used for discrimination of the fibre types A, B and C because that line is of different thickness in each type. The proportions of the thickness in frog and mammalian muscles are relatively the same, but the absolute values are different. In cross sections there are no differences between frog and mammalian muscle fibres concerning the typical form of myofibrils in type A- and B-fibres, whereas in type C-fibres the arrangement of the filaments in the Z- and H-layer is different in the members of both animal classes. The amount of mitochondria and lipid droplets is different as well. In the species examined the distribution of A-, B- and C-fibres changes within the whole muscle. In frog, this pattern depends on the level in which the muscle has been sectioned. This is not true for mammalian muscle. On the other hand both ends of the rectus abdominis muscle in frog, rat and mouse show an accumulation of B- and C-type fibres.     

The so-called tonic muscle fibre type in cyprinid axial muscle: their morphology and response to endurance exercise training

The morphology and the effect of an endurance training programme on tonic muscle fibres were studied in chub Leuciscus cephalus , by means of histochemistry and immunohistochemistry, electronmicroscopy and morphometry/stereology. Location and distribution, SDH- and mATPase-activity, reaction to an anti-tonic myosin antibody and ultrastructural features of the fibre type were investigated. With regard to training conditions, fibre size was not significantly affected. However, an increase in the volume densities of mitochondria, lipid and myofibrils can be observed, suggesting a training influence on the aerobic capacity of the so-called tonic muscle fibres. Based on the quantitative findings, the fine structure and the response to training, similarities with intermediate muscle fibres and the functional role of these so-called tonic muscle fibres are discussed.     

Structure and distribution of fibre types in the external eye muscles of the rat

Rat extraocular muscles are composed of two layers differing in muscle fibre diameter. In both layers multiply innervated fibres are found besides focally innervated ones. Significant differences in internal structure thus demand further subtyping. The global layer (predominantly larger fibres) contains 10" 'clear' fibres (multiple innervation, medium size) and a spectrum of focally innervated fibres, from small 'dark' fibres (30%, abundant mitochondria) over 'intermediate' fibres (30%) to large 'pale' fibres (30 %, few mitochondria). The orbital layer (exclusively small fibres) contains 80% focally innervated 'dark' fibres and 20% extremely small 'clear' fibres with multiple innervation. An ultrastructural characterization of the fibre types is given and possible functional implications are discussed.     

Atypical ‘fibrillar’ flight muscle in strepsiptera

The fine structure of the principal and ancillary metathoracic flight muscle fibres in the adult male of a strepsipteran, Elenchus tenuicornis, is described. Power-producing dorsal longitudinal and dorso-ventral flight muscles show features consistent with myoneural asynchrony: myofibrils are large and discrete and are separated by large closely packed mitochondria; the sarcoplasmic reticulum is very reduced but engages with T-system membranes in dyads at the mid-sarcomere H-band level. With respect to other asynchronous insect flight muscles, the fibres of Elenchus are anomalous (i) in the small fibre diameter, (ii) in the variable contour of the myofibrils and (iii) in the absence of tracheolar invagination. The functional significance of these structural features is discussed. Ancillary metathoracic muscles are structurally comparable with other synchronous fibres in possessing an extensive SR compartment. Structural evidence for asynchrony in the flight mechanism of Strepsiptera is considered in the context of the evolution of this mechanism throughout the insect Orders.     

Skeletal muscle characteristics of reindeer (Rangifer tarandus L.)

Fibre type composition, fibre areas, capillaries, enzyme activities and intramuscular substrates were analysed on skeletal muscle samples from reindeer. The muscles contained 10-20% Type I fibres and a higher percentage of Type IIB (40-60%) than Type IIA fibres (20-40%). All fibre types revealed medium or dark staining intensity for oxidative capacity. Glycolytic capacity was greatest in Type IIB fibres. All fibres stained for glycogen, while Type I and IIA fibres stained for lipids. The mean number of capillaries in contact with fibres of each type, relative to fibre type area was high in all muscle types. The metabolic profile of reindeer muscle indicates that energy, to a great extent, is produced through oxidative pathways.     

Ultrastructural transformation of fast chicken muscle fibres induced by nerve cross-union

Summary The fast posterior latissimus dorsi (PLD) muscle of newly hatched chickens was transposed and cross-innervated by the slow-type nerve originally innervating the anterior latissimus dorsi (ALD) muscle. The innervation and the ultrastructure of the cross-innervated posterior latissimus dorsi (PLD-X) muscle was investigated from one week up to 18 months after the operation and compared with that of the control fast (PLD-C) and control slow (ALD-C) muscles. All nerve terminals in the PLD-X muscle were of the slow type. Yet the degree of ultrastructural transformation differed from fibre to fibre. Only about 30% of PLD-X fibres had transformed ultrastructure closely resembling the control slow fibres. In this group of maximally altered fibres, the myofibrils had large diameters, wide Z lines and indistinct M lines as the control slow fibres. The amount of mitochondria was increased to levels found in control slow fibres. The mean percentage of triads was also comparable to that of control slow fibres, being approximately by two thirds lower than in control fast fibres.The differences in the degree of ultrastructural transformation are presumably due to different plasticity of muscle cells at the time of cross-innervation. In the transposed PLD-X muscles large areas undergo degeneration and regeneration. It is suggested that an almost complete changeover of the fibre type is only brought about after cross-innervation of newly differentiating muscle cells, whereas partial alteration occurs after reinnervation of young myofibres.The skillful technical assistance of Dr. Z. Liková, Mrs. M. Sobotková, Ing. M. Doubek and Mr. H. Kunz is gratefully acknowledged.     

Fibre types in locomotory muscles of the cartilaginous fish Chimaera monstrosa

The cartilaginous fish Chimaera monstrosa swims slowly by means of pectoral fin movements, and fast by undulations of the tail. In order to compare the fibres in the corresponding muscles, they were studied by histochemistry and electron microscopy. Three fibre types were identified by microphotometry and morphometry. Most of the axial muscles are white fibres, containing little mitochondria and glycogen. Red fibres, with glycogen and about 5 % mitochondria constitute a thin sheet in the axial muscles, composed of one fibre layer only. Pink fibres, with intermediate amounts of glycogen and mitochondria are situated between these two types, but are often not covered by red fibres. Pectoral muscles contain numerous red and intermediate fibres, partially mixed, superficially, and white fibres deeper. Pectoral muscle red fibres contain about 25 % mitochondria, half of which are situated in subsarcolemmal accummulations. The sarcotubular system has T-tubules at the Z discs, and the terminal cisternae are partially divided by regularly spaced clefts.     

The ultrastructure and vascular supply of the different fibre types in the axial muscle of the sturgeon Acipenser stellatus,Pallas

Summary The ultrastructure and vascular supply of the different fibre types in the lateral muscles of the sturgeon Acipenser stellatus were studied by light- and electron microscopy and morphometry. Three fibre types form separate layers without intermingling. The red fibres are superficial, the white fibres deep and the intermediate fibres between them. From morphometric analyses, the mitochondrial volume fraction in red fibres is 30%, in intermediate fibres 3.7% and in white fibres 0.7%. Z lines are most fuzzy in the red fibres. Triads of the sarcotubular system are always situated at the level of the Z discs. In red fibres the three elements are arranged in a series along the myofibrils, whereas in white fibres they are arranged transversely and in the intermediate fibres they are aligned obliquely. The number of capillaries surrounding each fibre is 2.3, 0.9 and 0.2 for the red, intermediate and white fibres, respectively. In red fibres 16% of the surface is directly covered by capillaries. The corresponding percentages for intermediate and white fibres are 5 and 1, respectively. Per unit volume of the fibre, the directly vascularised fibre surface in red fibres is about ten times larger than that of white fibres.The degree of vascularisation of the fibre types is directly related to the volume fraction of mitochondria, and thus to their aerobic capacities.     

Ultrastructural alterations in extrinsic eye muscles induced by vincristine.

A comparative morphological analysis of the effects of vincristine on particular types of muscle fibres of the eye and selected trunk muscles of the mouse was performed. Great resistance of the mouse organism to the action of sublethal doses of vincristine has been found. Degenerative changes of great intensity (atrophy of myofibrils, disturbances of the Z line) and the appearance of new changes, not mentioned hitherto among the vincristine myopathies (megamitochondria, intermembranous inclusions, glycogen in mitochondria and very large vacuoles) were observed in the trunk muscles of mice. The eye muscles are seem to be more resistant to the action of vincristine. The intensity of changes in the eye muscles was connected with the types of muscle fibres. Red fibres, rich in mitochondria, underwent relatively greatest changes, whereas the smallest changes were found in tonic fibres, poor in mitochondria and sarcotubular system, i.e. these structures from which spheromembranous bodies, most characteristic of the pathogenic effects of vincristine arise.     

Relationship among fibre type, myosin ATPase activity and contractile properties

Summary At least two types of skeletal muscle myosin have been described which differ in ATPase activity and stability in alkaline or acidic media. Differences in ATPase characteristics distinguish Type I and Type II fibres histochemically. In this study, ATPase activity of myosin from muscles of several species with known histochemical and contractile properties has been determined to test the hypothesis that (1) myosin ATPase activity, (2) histochemical determination of fibre types and (3) maximum shortening velocity, all provide equivalent estimates of contractile properties in muscles of mixed fibre types. Maximum shortening velocity appears to be proportional to ATPase activity as expected from previous reports by Barany. However, both myosin ATPase and the maximum shortening velocity exhibit curvilinear relationships to the fraction of cross-sectional area occupied by Type II fibres. Therefore, we reject the hypothesis and conclude that histochemically determined myofibrillar ATPase does not accurately reflect the intrinsic ATPase activity or shortening velocity in muscles of mixed fibre types. Our data are consistent with the presence of more than two myosin isozymes or with a mixture of isozymes within single muscle fibres.     

Immunohistochemical analysis of the human psoas major muscle with regards to the body side and aging

The aim of our study was to explore the age related changes of the fibre type composition of the human psoas major muscle. Moreover, we wanted to compare the fibre type composition of the left and right muscle. Muscle samples were collected from 15 young and 15 old males. Type I, IIA and IIX muscle fibres were typed using myosin heavy chain identification. The serial transverse sections were analysed using a light microscope. Results of our study showed that the age-related atrophy affected all three fibre types. Type IIA fibres were affected most profoundly while type I fibres were affected most weakly. The percentage of the different fibre types did not change during aging. There were no differences in the fibre type composition between the left and right muscle. Human psoas major muscle undergoes normal aging changes with the atrophy of all three fibre types, whereas atrophy most profoundly affects type IIA fibres. No differences in the fibre type composition between the left and right muscle point to the equal engagement of both legs in normal everyday activities of human.     

On the cellular regulation of growth and development in skeletal muscle

1. Fibres of skeletal muscle in different mammalian species vary more in number and in their rates of growth than in their ultimate breadth, and they grow more slowly in cattle and man than in rats and mice. Cells of large mammalian species probably divide comparatively slowly in pre-natal life but do so for longer, and thus they attain greater numbers than do their counterparts in smaller mammals. Such cells include the precursors of muscle, and common mechanisms may therefore limit rates of growth before and after muscles form. If some metabolic processes are slower in mammals destined to be large, corresponding trends in age-related cellular changes which ultimately suppress mitotic activity may cause differences between species in the overall size of muscles and in that of other tissues. This is probably an oversimplification. 2. It is difficult to decide how far the rate of growth and the final diameters of muscle fibres reflect the number of myoblasts which initially fuse into myotubes and the number of myoblasts which are subsequently incorporated into individual fibres. New nuclei are probably added with age along the length of a fibre, but it is uncertain whether they then synthesize ribosomes which produce contractile protein. It seems likely that fibres elongate to different extents by adding myoblasts terminally. 3. There is some evidence that myofibrils grow throughout the depth of a fibre by adding new myofilaments to their surface, but there is none that is convincing to the effect that myofibrils form de novo at a fibre's periphery. Ribosome-like structures distributed in the sarcoplasm between myofibrils have been described, and their numbers decline in comparison with those of the myofibrils during growth. Thus, fibres possibly attain their maximum breadth when the loss of superficial filaments from myofibrils exceeds the capacity of ribosomes to replace them. The evidence is inconclusive as to whether myofitrillar protein is broken down and replaced at rates which vary within a muscle or between muscles differing in physiological properties. Sarcoplasmic proteins appear to be replaced more rapidly than those in myofibrils. It is also speculated that muscle proteins are synthesized and degraded more slowly in species which take longer to develop. 4. Observations, with the microscope suggest that new ribosomes appear in cells which are becoming myoblasts. Whether the ribosomes subsequently break down is not established. The evidence that I-somes occur in muscle is inconclusive, as is that for the existence of messenger RNA and its selective synthesis when muscle is forming in the embryo. 5. A decline in the synthesis of RNA occurs as myotubes appear and contractile protein begins to accumulate. The significance of this phenomenon is not known, and in more mature muscle some RNA also appears to fluctuate in a fashion which is unrelated to rates of controlling protein synthesis. Such RNA may occur at the periphery of fibres or in satellite cells. In some instances it may be formed by cells of the connective tissue and capillaries. There are indications that the growth of muscle does not require the continued transport of new RNA and ribosomes into the body of a fibre. 6. As regards the existence of polyribosomes in muscle and the activity of muscle ribosomes in zlitro, most relevant phenomena can be explained if the ribosomes are aggregated, inter ah, by newly completed protein and if observed variations in activity are some function of the residual amounts of nascent protein which remain on the ribosomes. The morphological appearance of ribosomes in myoblasts is difficult to reconcile with the notion of ribosomes linked by messenger RNA. There is also some rather inconclusive evidence that the sarcoplasm varies in the effectiveness with which it supports protein synthesis by ribosomes. 7. Muscle fibres differ markedly in the number of mitochondria which they exhibit in histological sections and in the rate at which the homogenized fibres catalyse the processes of aerobic respiration which occur in mitochondria. It is uncertain how far such variation is determined by the properties of myoblasts and myotubes, by the nature of subsequent contractile activity and by dilution of the mitochondria as myofibrillar protein accumulates. In part, the tendency of fibres richest in mitochondria to be comparatively small may reflect the diversion of energy sources and oxidizable precursors of protein into energy-generating pathways. However, such fibres perhaps also possess fewer nuclei and fewer functional ribosomes. 8. Within a given animal, variation between fibres in the activity of sarcoplasmic enzymes becomes most pronounced after the myoblast stage. Assuming that these sarcoplasmic proteins are increasing by dissimilar amounts, genes in different fibres are perhaps varying in activity, but this has not been studied. It may be that the intermittent and increasingly forceful contractions of developing fast-phasic fibres simply cause them to accumulate increased amounts of amino acids in the pool from which protein is synthesized, so that a generalized stimulation of protein synthesis follows. Sarcoplasmic protein should then accumulate more than myofibrillar protein relative to starting quantities. This is a consequence of sarcoplasmic protein turning over faster. However, in addition, one must postulate that sarcoplasmic enzymes vary in stability between fibre types. It also remains to assess whether such differences reflect the presence of different molecular forms of each enzyme and whether the latter possess dissimilarities of amino-acid sequence or of molecular configuration. Similar unsolved problems arise regarding the ATPase activity of myosin in developing muscles and its variation between fibres.