A histochemical and ultrastructural study of heterogeneous red fibres of pigeon pectoralis muscle

The oxidative fibres of pigeon pectoralis muscle are 'type II red' on the basis of high myofibrillar adenosine triphosphatase (ATPase) and succinate dehydrogenase (SDH). The ATPase and SDH reactions do not characterize the heterogeneity of the red fibres in the normal pigeon pectoralis. Therefore, lipid, glycogen, phosphorylase, glycogen synthetase, SDH and ATPase reactions were studied in transverse sections of the pigeon pectoralis red fibre. This study has revealed the existence of an inherent heterogeneity between these red fibres. Three sub-populations distinguished were : (1) 'red1' fibres showing low fat but high glycogen and enzymes of glycogen metabolism (EGM); (2) 'red2' fibres displaying higher fat and higher amount of glycogen and EGM; and (3) 'red3' fibres possessing higher fat but lower content of glycogen and EGM. Ultrastructurally, one category of fibres (presumably red2 and red3) showed a higher concentration of fat; these fibres presumably possess higher synthetic capacity and lower (or higher?) utilization. Other mitochondria-loaded red fibres (presumably red1) documented here for the first time, showed fewer and smaller fat droplets indicating that they are 'predominantly lipid utilizers' and are incapable of storing large quantities of lipid. Moreover, the differing histochemical-ultrastructural attributes are presumably correlated with differences in levels of energetic metabolism, heat production and motor units of the red fibres.     

"Red" fibres of pigeon pectoralis major muscle are "type II red".

On the basis of the histochemical activity of succinic dehydrogenase, only two fibre-types are distinguished in pigeon pectoralis major muscle. These are narrow "Red" and broad "White". The histochemical activity of myofibrillar ATPase was studied in these two distinct fibre-types. Both fibre-types showed high activity for the ATPase. "Red" fibres of pigeon pectoralis were not alkali-labile, at incubation pH 9.4, as were the "Type I" fibres of both avian and mammalian muscles. Again unlike "Type I" fibres, the "Red" fibres of pigeon pectoralis lacked the characteristic activation of acid-preincubated ATPase reaction. Pigeon pectoralis "Red" fibres are known to possess some characteristics of fast-twitch fibres (e.g. high fat, considerable phosphorylase, fibrillenstruktur myofibrillar arrangement, focal "en plaque" pattern of nerve endings). It is emphasized, therefore, that the pigeon pectoralis "Red" fibres are not equivalent to "Type I or slow-twitch", muscle fibres, but they are possibly "fast-twitch fatigue resistent or Type II Red" muscle fibres.     

Morphometric analysis of capillary geometry in pigeon pectoralis muscle

The objective of the study was to examine the relationship(s) between the size and the geometry of the capillary network in the flight muscle of pigeon (Columbia livia). To this end, we used morphometry to analyze the degree of anisotropy (i.e., orientation) of capillaries with respect to the axis of the muscle fibers in perfusion-fixed samples of pigeon pectoralis muscles with large difference in capillary density. Capillary number per fiber cross-sectional area (range, 1,491-5,680 mm-2) depended on fiber size (aerobic fibers, 304-782 microns 2; glycolytic, 1,785-2,444 microns 2), as well as sarcomere length (1.69-2.20 microns), and the relative sectional area of aerobic and glycolytic fibers (aerobic, 42-84% of total fiber area). The degree of tortuosity of capillaries, i.e., their bending or sinuosity relative to the muscle fiber axis, was primarily a function of sarcomere length. In spite of large differences in capillary density, capillary orientation at a given sarcomere length was remarkably similar among samples. In addition to capillaries running parallel to the muscle fiber axis, a unique arrangement of branches running perpendicular to the muscle fiber axis was found in all samples. This arrangement yielded a large circumferential distribution of capillary surface around the muscle fibers. Compared to mammalian limb muscles examined over a 10-fold range of capillary density (range, 450-4,670 mm-2), the degree of anisotropy of capillaries was greater in all samples of pigeon M. pectoralis. In the pigeon, there was no increase in the amount of capillary surface area available for exchange per microvessel as a result of a greater degree of capillary tortuosity in samples with larger capillary density (capillary number per fiber cross-sectional area greater than 4,000 mm-2), as compared to samples with a capillary density less than 4,000 mm-2.     

On the heterogeneity of capillaries of pigeon pectoralis muscle: a histoenzymatic and ultrastructural study

Synopsis Earlier studies had failed to show the presence of capillaries between the white fibres of pigeon pectoralis muscle. In this paper, data are reported for the first time documenting that these capillaries occur in both intra- and inter-fasicular areas of the muscle. Fresh frozen sections of pigeon pectoralis major muscle were incubated for alkaline ATPase reaction following pretreatment with different EDTA solutions (4.3 mM, pH 4.3). The results showed the existence of an inherent heterogeneity of capillaries. The capillaries of white fibres stained intensely for K^–/Mg^2–-EDTA or Mg²⁺-EDTA pre-incubated ATPase; the capillaries of red fibres stained poorly. Both white fibre and red fibre capillaries were examined ultrastructurally in the non-perfused pigeon pectoralis muscle. It is suggested that a possible correlation exists between the distinctive metabolic and mechanical characteristics of the Type II white, glycolytic, fast-twitch fast-fatigue muscle fibres and the high ATPase activity of their capillaries.     

The radial distribution of succinate dehydrogenase activity in porcine muscle fibres

Summary A microscope photometer with a computer-controlled scanning stage was used to map the distribution of succinate dehydrogenase (SDH) activity in transverse sections of skeletal muscle fibres of pigs from 9 to 29 weeks of age. Absorbance due to SDH activity was measured in successive concentric zones that converged on the central axis of the muscle fibre. In all fibres, there was less SDH activity in the axis of the fibre than in the periphery of the fibre. In fibres with strong adenosine triphosphatase (ATPase) activity and weak overall SDH activity, the radial gradient of SDH activity remained constant as fibres grew in cross-sectional area. However, in fibres with weak ATPase and strong SDH and in fibres with strong ATPase and strong SDH, the radial gradient of SDH activity increased as fibres grew larger. Changes in radial gradients were due to both decreased SDH activity in the axis and to increased SDH activity in the periphery. In all three fibre types, the overall SDH activity per fibre increased with age.     

Quantitative histochemical determination of succinic dehydrogenase activity in skeletal muscle fibres

Summary A histochemical technique was developed for the quantitative determination of succinic dehydrogenase (SDH) activity in muscle cross-sections using 1-methoxyphenazine methosulphate (mPMS) as the exogenous electron carrier, and azide as an inhibitor of cytochrome oxidase. The optimal composition of the incubation medium for the SDH reaction was determined. This histochemical procedure was compared to one using phenazine methosulphate (PMS) instead of mPMS and cyanide instead of azide. The substitution of mPMS and azide resulted in a substantial decrease in the non-specific reduction of nitroblue tetrazolium (NBT; the reaction indicator), i.e., nothing dehydrogenase activity. With mPMS and azide in the reaction medium, the production of NBT formazan was linear for at least 9 min during the enzymic reaction. This compared to a non-linear reduction of NBT during the initial stages of the reactions (SDH and nothing dehydrogenase) when using PMS and cyanide. The use of both mPMS and azide also eliminated the production of NBT monoformazan which occurred with PMS and cyanide. This procedure was shown to meet various criteria established for the quantification of histochemical reactions.     

Neuromuscular organization and regional EMG activity of the pectoralis in the pigeon

In order to improve our understanding of the neuromuscular control of the most massive avian flight muscle, we studied the innervation pattern of the pigeon pectoralis. Nine primary branches from the rostral trunk and nine to ten branches from the caudal trunk of the pectoral nerve were identified by microdissection in ten pigeons. The region of muscle that each branch innervates was delineated by nerve stimulation studies (ten pigeons) and six regions were confirmed by glycogen depletion (ten pigeons). In pigeons, branches from the rostral nerve innervate the anterior 3/5 of the sternobrachialis (SB) head of the pectoralis and branches from the caudal trunk innervate the posterior 1/2 of the SB and all of the throacobrachials (TB). In the SB, individual branches of the rostral pectoral nerve innervate wedge-shaped muscle regions (each approximately 1.3 cm wide), collectively forming a fan shaped arrangement along the sternal carina. Adjacent muscle regions partially overlap at their boundaries. Within the thoracobrachialis (TB) head of the pectrolis, muscle regions are wider. There is a region in mid-SB-where the innervation territories of the rostral and caudal nerves oferlap. Electromyographic (EMG) activity patterns were recorded within ten of the identified muscle regions during take-off, level flapping flight, and landing. Onset of EMG activity and EMG intensity within various muscle regions exhibits significant differences both within a wingbeat cycle and among different modes of flight. The innervation pattern of the pectoralis presents the anatomical substrate for neuromuscular compartmentalization and differential EMG activity within the pectoralis may reflect sensory-motor partitioning. The extent to which the neuromuscular compartmentalization of the pectoralis corresponds to its ability to produce an array of force vectors to the wing awaits further more detailed biomechanical studies. © 1993 Wiley-Liss, Inc.     

Neuromuscular organization of avian flight muscle: architecture of single muscle fibres in muscle units of the pectoralis (pars thoracicus) of pigeon (Columba livia)

The M. pectoralis (pars thoracicus) of pigeons (Columba livia) is comprised of short muscle fibres that do not extend from muscle origin to insertion but overlap ''in-series''. Individual pectoralis motor units are limited in territory to a portion of muscle length and are comprised of either fast twitch, oxidative and glycolytic fibres (FOG) or fast twitch and glycolytic fibres (FG). FOG fibres make up 88 to 90% of the total muscle population and have a mean diameter one-half of that of the relatively large FG fibres. Here we report on the organization of individual fibres identified in six muscle units depleted of glycogen, three comprised of FOG fibres and three comprised of FG fibres. For each motor unit, fibre counts revealed unequal numbers of depleted fibres in different unit cross-sections. We traced individual fibres in one unit comprised of FOG fibres and a second comprised of FG fibres. Six fibres from a FOG unit (total length 15.45 mm) ranged from 10.11 to 11.82 mm in length and averaged (± s.d.) 10.74 ± 0.79 mm. All originated bluntly (en mass) from a fascicle near the proximal end of the muscle unit and all terminated intramuscularly. Five of these ended in a taper and one ended bluntly. Fibres coursed on average for 70% of the muscle unit length. Six fibres from a FG unit (total length 34.76 mm) ranged from 8.97 to 18.38 mm in length and averaged 15.32 ± 3.75 mm. All originated bluntly and terminated intramuscularly; one of these ended in a taper and five ended bluntly. Fibres coursed on average for 44% of the muscle unit length. Because fibres of individual muscle units do not extend the whole muscle unit territory, the effective cross-sectional area changes along the motor unit length. These non-uniformities in the distribution of fibres within a muscle unit emphasize that the functional interactions within and between motor units are complex.     

Biochemical verification of quantitative histochemical analysis of succinate dehydrogenase activity in skeletal muscle fibres

Summary The purpose of this investigation was to examine critically the validity of a computerized quantitative microphotometric histochemical technique for the determination of succinate dehydrogenase (SDH) activity in skeletal muscle fibres. Sections from the anterior costal diaphragm were removed from Fischer-344 rats (n = 12) and assayed histochemically to determine SDH activity. The SDH activity in individual muscle fibres was computed using a computerized microphotometric histochemical technique which involves measurement of the optical density of deposited diformazan derived from nitroblue tetrazolium within the fibres. To validate the histochemical technique, whole muscle SDH activities were calculated from the histochemical procedure and were compared to SDH activities determined from whole muscle homogenates via a standard quantitative biochemical assay. The mean within-day variability of the computerized microphotometric histochemical technique of determining SDH activity was 6% (range = 0.5–10.9%) for an area containing ~50 fibres and 6.1% (range = 1.05–14.9%) for an individual muscle fibre. Similarly, the mean between-day variability of the microphotometric histochemical technique of determining SDH activity was 5.9% (range = 2.6–13.9%) for an area containing ~50 fibres and 6.6% (range = 2.2–13.9%) for an individual muscle fibre. The inter-class correlation coefficient between biochemically determined SDH activity and histochemically determined SDH activity was r = 0.83 (p < 0.05). Collectively, these data demonstrate that the quantitative histochemical technique of Blanco et al. (1988) is both valid and reliable in the determination of SDH activity in skeletal muscle fibres.     

On T-tubule openings at the sarcolemma of white fast-twitch muscle fibres in fish and frog

Summary In white muscle fibres of a teleost fish T-tubule openings may occur regularly at all Z-disc levels between adjacent peripheral myofibrils, the T-tubule openings thus occurring at a density of ca. 0.9 m^-2.In frog white fibres, T-tubule openings are infrequently seen in material fixed like the fish material. In material prepared according to the albumin method of Gray (1975, 1976 a, b) which renders the muscle fibres swollen, straight tubules or sometimes chains of vesicles instead are seen opening at the sarcolemmal surface. Such tubules occur at a higher density than expected from experiments with local activation of contraction. Lability and dynamics within the T-system normally and during fixation are discussed.     

Avian muscular dystrophy: Thyroidal influence on pectoralis muscle growth and glucose-6-phosphate dehydrogenase activity

The pectoralis muscles of dystrophic chickens (line 413) were hypertrophic on the basis of fresh weight and fat-free dry weight. They also had greater DNA content and greater glucose-6-phosphate dehydrogenase (G6PD) and 6-phosphogluconate dehydrogenase (6PGD) activities. Of the parameters measured, the largest differences between pectoralis muscles from dystrophic and normal (line 412) chickens were for DNA content and G6PD activity. These parameters were 4.3- and 6.7-fold, respectively, the values for control pectoralis at 5 wk of age. The average number of nuclei per unit length of isolated muscle fiber was also greater (approximately 3-fold) for the dystrophic pectoralis. Body weight and pectoralis fresh weight, fat-free dry weight, DNA content, G6PD activity and 6PGD activity were reduced significantly in propylthiouracil (PTU)-treated normal and dystrophic chickens. Moreover, the effects of PTU were more pronounced in the dystrophic strain. Thyroid deprivation significantly improved the righting ability of the dystrophic chickens, in addition to its influence on muscle hypertrophy and body growth. Thyroxine (T₄) replacement reversed the PTU effects in both strains. Of all the variables measured, total G6PD activity was the most affected by PTU treatment of dystrophic chickens and was only 16% of the control dystrophic value.In addition to the effects of thyroid deprivation on the expression of avian muscular dystrophy, we observed significant differences in thyroid-related variables in the two strains. The average thyroid weight at 4 wk and serum triiodothyronine level at 5 wk for dystrophic chickens were 65 and 76%, respectively, of the normal values. The results that we report here indicate that altered thyroid function affects the expression of avian muscular dystrophy.     

Inhibition of pigeon breast muscle alpha-ketoglutarate dehydrogenase by phosphonate analogues of alpha-ketoglutarate.

Succinylphosphonate (SP) is a powerful inhibitor of alpha-ketoglutarate dehydrogenase (KGD). Methylation of the phosphonate reduces its inhibitory effect. The complex of KGD with SP undergoes a kinetically slow transition similar to the process observed during catalysis. alpha-Ketoglutarate binds to the enzyme-inhibitor complex, preventing its isomerisation.     

The substrate-mediated inactivation of the pyruvate dehydrogenase component of the pigeon breast muscle pyruvate dehydrogenase complex

Incubation of the pyruvate dehydrogenase component isolated from the pigeon breast muscle pyruvate dehydrogenase complex with Mg2+, thiamine pyrophosphate and low concentrations of pyruvic acid in the absence of electron acceptors results in irreversible time-dependent inactivation of the enzyme. The rate of the enzyme inactivation is markedly decreased in the presence of high concentrations of pyruvate; in this case acetoin and acetolactate are detected in the reaction mixture. The enzyme activity is stabilized when the artificial electron acceptor, 2,6-dichlorophenolindophenol, is present in the reaction mixture. The substrate-mediated inactivation of the enzyme is accompanied by incorporation of the 2-[14C]-substrate fragment and labelled thiamine pyrophosphate into the protein fraction. The enzyme reactivation by neutral hydroxylamine and the protective effect of dithiothreitol suggest that the SH-group(s) may be involved in the substrate-mediated inactivation of pyruvate dehydrogenase.     

Cooperative interaction of pyruvate dehydrogenase from pigeon breast muscle]

Cooperative interaction of pyruvate with the pyruvate dehydrogenase (PD) complex from pigeon breast muscle was shown. The sigmoidal dependence of the reaction rate on pyruvate concentration was observed for the PD complex. The Hill coefficient is equal to 1,5; no inhibition by the substrate (up to 2.2.10(-3) M) was found. The kinetic behaviour of the isolated pyruvate dehydrogenase component (PDH) analyzed under similar conditions, is more complex; this may be probably due to the presence of oligomeric forms with different molecular weights and specific activities. The competitive inhibitor of the PD complex--an amide of pyruvic acid (PA) (Ki=6.3-10(-6) M) activates the enzyme at low concentrations (less than 2,10(-6) M). When PA is present, the dependence of the reaction rate on pyruvate concentration gives a usual hyperbolic curve, v of [S]o. It is concluded that pyruvate may have a regulatory effect on the activity of muscle PD complex.