Lactate dehydrogenase isoenzyme spectrum of fast and slow muscles with innervation disorders

A relative content of muscle fibers of various types and the spectrum of lactate dehydrogenase (LDH) isozymes were studied in fast-twitch (extensor digitorum longus) and slow-twitch (soleus) muscles of newborn rats, of those aged 2, 3 weeks and one month and of adult rats after neonatal sciatic denervation and application of 0.5 mM colchicine solution to the sciatic nerve. No muscle fibers of various types were found (from the level of succinate dehydrogenase activity) in one-month-old rats, whereas the control and fast-twitch muscles showed A, B and C types and the slow-twitch one B and C types. The denervation brought about an increase in the content of LDH4 and LDH5 in both the muscles, while colchicine application gave rise to an increase in LDH2 activity, diminution of LDH1 in the fast-twitch muscle and elevation of LDH4 in the slow-twitch one. The data obtained attest to the retardation of muscle differentiation under application of the colchicine-induced blockade of axoplasmic transport.     

Neural Regulation of Muscle Glucose 6-Phosphate Dehydrogenase: Effect of Batrachotoxin and Tetrodotoxin

Abstract: We tested the hypothesis that glucose 6-phosphate dehydrogenase (G6PD) activity in the rat skeletal muscle is regulated by putative axonally derived neurotrophic factors. This was accomplished by comparing the effects of nerve section and subperineural injection of batrachotoxin (BTX) or tetrodotoxin (TTX) on G6PD in rat extensor digitorum longus (EDL) muscle. BTX, an agent known to block nerve impulse conduction and axonal transport, increased G6PD activity to 155% and 163% of control by days 2 and 4 after injection. Denervation of the EDL muscle by section of the peroneal nerve 10–20 mm from its entrance to the muscle caused G6PD activity to increase to 170% of control by day 1 and to 200% and 180% of control by days 2 and 4, respectively. The increase in enzyme activity after denervation and after subperineural injection of BTX was due in part to muscle inactivity resulting from blockade of nerve impulses. This conclusion is based upon the observation that subperineural injection of TTX at an identical site in the peroneal nerve caused a small but significant (30%) increase in G6PD activity after 4 days. Choline acetyltransferase (CAT) activity was assessed as a measure of the efficacy of blockade of slow axonal transport. Decreases in CAT activity following denervation or injection of BTX or TTX were parallel to increases in G6PD activity observed under these conditions. These results argue for a role of axonal transport in neural regulation of muscle G6PD, with a small contribution by neuromuscular activity.     

Neurotrophic control of myosin synthesis in guinea pig slow muscle]

After experimental cease of neurotrophic control of skeletal muscle by denervation no changes in myosin ATP-ase histochemistry and immunohistochemical profile in slow (m. soleus) muscle of guinea pig were found. All muscle fibers in intact muscle fibers). However after colchicine blockade of axoplasmic transport in this slow muscle some muscle fibers reacting with monoclonal antibodies against fast myosin heavy chain were found. At the same time no changes in histochemical ATP-ase profile were observed. Validity of myosin ATP-ase histochemistry for muscle fibers typing as well as possible influence of nerve activity and neurotrophic control itself were discussed.     

Neurotrophic control of 16S acetylcholinesterase at the vertebrate neuromuscular junction.

Endplate 16S acetylcholinesterase (16S-AChE) from rat anterior gracilis muscle was assessed, 6 hr to 10 days after denervation, by velocity sedimentation analysis on linear sucrose gradients. The innervating obturator nerve was transected either close (1--2 mm, short stump) or far (35--40 mm, long stump) from the muscle. In both instances, the activity of 16S-AChE gradually decreased and reached approximately the same level (10%--20% of control) by 6 days after denervation. However, enzymatic decay started considerably earlier in short stump (12--24 hr) as compared to long stump (4--5 days preparations, i.e., the time of onset of 16S-AChE loss depended on the length of nerve that remained attached to the muscle. Whether this result extended to other AChE molecular forms (10S, 4S) in muscle endplates could not be determined because, in contrast to 16S-AChE, these forms were also detected in red blood cells (4S) and plasma (10S). Only small amounts of 16S-AChE were found in intact obturator nerves (1/100 of that in gracilis endplate regions). Thus a faster depletion of enzyme from shorter nerve stumps after axotomy could not entirely account for the substantial effect of nerve stump length on 16S-AChE. Since muscle contraction ceases immediately following nerve transection, regardless of nerve stump length, the results can be ascribed to the lack of some neural influence other than nerve-evoked muscle activity. The present findings are consistent with the view that maintenance of 16SAChE at neuromuscular junctions primarily depends on regulatory substances which are conveyed by axonal transport and released from nerve terminals.     

Neurotrophic control of 16S acetylcholinesterase at the vertebrate neuromuscular junction

Endplate 16S acetylcholinesterase (16S-AChE) from rat anterior gracilis muscle was assessed, 6 hr to 10 days after denervation, by velocity sedimentation analysis on linear sucrose gradients. The innervating obturator nerve was transected either close (1-2 mm, short stump) or far (35-40 mm, long stump) from the muscle. In both instances, the activity of 16S-AChE gradually decreased and reached approximately the same level (10%-20% of control) by 6 days after denervation. However, enzymatic decay started considerably earlier in short stump (12-24 hr) as compared to long stump (4-5 days) preparations, i.e., the time of onset of 16S-AChE loss depended on the length of nerve that remained attached to the muscle. Whether this result extended to other AChE molecular forms (10S, 4S) in muscle endplates could not be determined because, in contrast to 16S-AChE, these forms were also detected in red blood cells (4S) and plasma (10S). Only small amounts of 16S-AChE were found in intact obturator nerves (1/100 of that in gracilis endplate regions). Thus a faster depletion of enzyme from shorter nerve stumps after axotomy could not entirely account for the substantial effect of nerve stump length on 16S-AChE. Since muscle contraction ceases immediately following nerve transection, regardless of nerve stump length, the results can be ascribed to the lack of some neural influence other than nerve-evoked muscle activity. The present findings are consistent with the view that maintenance of 16S-AChE at neuromuscular junctions primarily depends on regulatory substances which are conveyed by axonal transport and released from nerve terminals.     

Formation of postural asymmetry in rat hindlimbs during colchicine-induced unilateral blockade of axonal transport in cortico-lumbar projections

The possibility of the formation of spinal cord functional asymmetry by the blockade of axonal transport in corticolumbar projections with colchicine was investigated. To identify the blockade of axonal transport, the method of retrograde transport of horseradish peroxidase was used. The blockade of axonal transport led to the formation of the asymmetric functional status of the spinal cord, manifesting in postural asymmetry of the hind limbs and characteristic changes in the pattern of bioelectrical activity of the flexor muscles. An endogenous factor inducing postural asymmetry in intact recipients was detected in the cerebrospinal fluid of colchicine treated animals. Based on the experimental data the conclusion is drawn that interruption of normal axonal transport attests to the destruction of central neurons.     

EFFECT OF DENERVATION AND OF AXOPLASMIC TRANSPORT BLOCKAGE ON THE IN VITRO RELEASE OF MUSCLE ENDPLATE ACETYLCHOLINESTERASE

Abstract— Cat geniohyoid muscle samples containing endplate regions, when incubated in vitro at 37°C in phosphate buffer (pH 73, release acetylcholinesterase (AChE; EC 3.1.1.7) to the bathing medium. By treating the muscle samples with collagenase (EC 3.4.4.19), it was confirmed that most of the AChE released came from the endplates. Enzyme liberation was studied 10 days after either local injection of 10mM-cokhicine into the hypoglossal nerve or following nerve transection. Results showed that the rate of release is increased by denervation, but is not affected by axoplasmic transport blockage. It is postulated that the cellular contact between nerve and muscle—altered by denervation but not by interruption of axoplasmic transport—is an essential factor in maintaining the localization of end-plate AChE within the synaptic cleft substance. This does not invalidate the possible participation of ACh and muscle activity in such enzyme localization.     

Nonquantal acetylcholine release from motor nerve endings and denervation changes in rat muscle fiber membranes after axonal transport blockade

Microelectrode experiments on the rat diaphragm showed that application of colchicine, which disturbs axonal transport, to the motor nerve leads after 5 days to a decrease in resting potential and an increase in input resistance of the electrogenic membrane, disappearance of differences of input resistance between the postsynaptic and extrasynaptic membranes, the appearance of extrasynaptic sensitivity to acetylcholine, and the appearance of anode-break action potentials resistant to tetrodotoxin. Similar changes develop in the muscle membrane after division of the motor nerve. Application of colchicine to the nerve, unlike its division, does not cause cessation of contractile activity of the muscle or disturbance of quantal and reduction of nonquantal acetylcholine secretion in motor nerve endings, as reflected in the degree of hyperpolarization of the postsynaptic membrane (H effect) in response to the action of D-tubocurarine chloride on the muscle after inhibition of acetylcholinesterase. The results confirmed the view that neurotrophic control of the mammalian muscle fiber membrane is effected mainly by means of substances carried to the muscle by axonal transport. Synaptic acetylcholine, secreted from nerve endings in nonquantal form, does not play a leading role in neurotrophic control of the muscle membrane.S. V. Kurashov Medical Institute, Ministry of Health of the RSFSR, Kazan'. Translated from Neirofiziologiya, Vol. 16, No. 2, pp. 231–238, March–April, 1984.     

Morphologic and histochemical characteristics of frog skeletal muscle following application of colchicine to a motor nerve]

Experiments with application of colchicine to the muscle motor nerve carried out; this was done for the purpose of disturbance of rapid axoplasmic transport. A reduction of the areas of transverse sections of the muscle fibers, an increase in the number of fibers with a low succinic dehydrogenase (SDH) activity a greater homogeneity of the muscle fibers by the degree of optic density in staining for detection of the SDH activity was noted. Analogous changes were revealed under conditions of section of the motor nerve. However, denervation was accompanied by the block of conductivity and by degenerative changes in the nerve endings. As to the preparations treated with colchicine, transmission of excitation in the nerve and through the synapse was retained and was recorded by the end plate miniature potentials, end plate potentials and the action potentials of the muscle fibers. A conclusion was drawn that rapid axoplasmic transport brought substances maintaining differentiated state of the muscle fibers.     

Upper airway muscle paralysis reduces reflex upper airway motor response to negative transmural pressure in rat.

The reflex upper airway (UA) motor response to UA negative pressure (UANP) is attenuated by neuromuscular blockade. We hypothesized that this is due to a reduction in the sensitivity of laryngeal mechanoreceptors to changes in UA pressure. We examined the effect of neuromuscular blockade on hypoglossal motor responses to UANP and to asphyxia in 15 anesthetized, thoracotomized, artificially ventilated rats. The activity of laryngeal mechanoreceptors is influenced by contractions of laryngeal and tongue muscles, so we studied the effect of selective denervation of these muscle groups on the UA motor response to UANP and to asphyxia, recording from the pharyngeal branch of the glossopharyngeal nerve (n = 11). We also examined the effect of tongue and laryngeal muscle denervation on superior laryngeal nerve (SLN) afferent activity at different airway transmural pressures (n = 6). Neuromuscular blockade and denervation of laryngeal and tongue muscles significantly reduced baseline UA motor nerve activity (P < 0.05), caused a small but significant attenuation of the motor response to asphyxia, and markedly attenuated the response to UANP. Motor denervation of tongue and laryngeal muscles significantly decreased SLN afferent activity and altered the response to UANP. We conclude that skeletal muscle relaxation reduces the reflex UA motor response to UANP, and this may be due to a reduction in the excitability of UA motor systems as well as a decrease of the response of SLN afferents to UANP.     

LDH and LDH Isoenzymes of Synovial Fluid in the Horse

LDH is an intracellular enzyme, which when cells degenerate is released to the extracellular spaces and body fluids. Cells and organs in the mammalian body differ from each other with respect to their LDH isoenzyme patterns. These circumstances have led to the use of LDH isoenzyme determinations in laboratory diagnostic work. In the present investigation total LDH activity and LDH isoenzyme distribution in equine synovial fluid from healthy joints, joints with serous arthritis, osteochondrosis dissecans and arthrosis, were determined. The fluids from the diseased joints differed from normal synovial fluid with respect to total LDH activity, and the different joint diseases each seemed to give rise to a characteristic isoenzyme pattern. In order to examine possible sources of the increased LDH activity and altered isoenzyme patterns, blood plasma, red and white blood cells, synovial membrane and articular cartilage were also studied. It was found that LDH4 and LDH5 were present in high amounts in articular cartilage, and an increase in these isoenzymes was the most characteristic feature in synovial fluid from joints with arthrosis. The results were discussed in view of possible diagnostic value of isoenzyme determinations on synovial fluid.     

Modification of motoneuron size after partial denervation in neonatal rats

Our previous studies have shown that partial denervation of extensor digitorum longus muscle (EDL) in the rat at 3 days of age causes an increase in the activity of the intact motoneurons. The originally phasic pattern of activity of EDL became tonic after partial denervation. These modifications of motoneuron activity were associated with the change in the phenotype of the muscle from fast to slow contracting and with a conversion of the muscle fibres from a fast to a slow type. The present study investigates whether the size of the cell body of the active EDL motoneurons change in parallel with the altered muscular activity. The study involved partial denervation of rat EDL muscle by section of the L4 spinal nerve at 3 days of age. Then the remaining motoneurons from L5 spinal nerve supplying the EDL muscle were retrogradly labelled with horseradish peroxidase two months later. The results show a reduction in motoneuron size in parallel with an increase in activity of the motoneurons after partial denervation of EDL muscle.     

Axonal transport involvement in long-lasting synaptic modifications in Blatta orientalis

To determine whether axonal transport plays a role in the establishment of long-lasting changes in synaptic transmission, the effects of colchicine on transport and on synaptic modifications induced by hyperactivity were studied in the nerve cord of the cockroach Blatta orientalis. Application of a lead weight on the insect's dorsum, and the consequent exaggerated use of antigravity reflexes, facilitated synaptic transmission along a particular nervous pathway in the metathoracic ganglion. Application of colchicine in the prothoracic ganglion reversibly blocked such synaptic facilitation and temporarily interfered with the transport of proteins along the cord. Five components of axonal transport, moving at 2, 10, 25, 75, and 150 mm/day, were altered by colchicine treatment with a temporal course that coincided with the reversible inhibition of synaptic facilitation. These results were brought about by colchicine acting directly on axonal transport at the level of the prothoracic ganglion, rather than on synaptic transmission measured at the metathoracic ganglion. The temporal correlation observed between the effects of colchicine on axonal transport and on synaptic facilitation strongly suggest that the transport process is essential for long-lasting synaptic modifications to take place.     

Peptide-containing neurons intrinsic to the gut wall

Summary Nerve fibers containing substance P, VIP, enkephalin or somatostatin are numerous in the porcine gut wall. They are particularly numerous in the submucosal and myenteric plexuses where peptide-containing cell bodies are also observed. Peptide-containing nerve fibers occur also in the vagus nerves, suggesting that the gut receives an extrinsic supply of peptidergic nerves. The extrinsic contribution to the peptide-containing nerve supply of the gut wall has not yet been quantitatively assessed. In an attempt to clarify this question pigs were subjected to bilateral subdiaphragmatic vagotomy. Another group of animals was subjected to complete extrinsic denervation by autotransplantation of a jejunal segment. The pigs were killed at various time intervals after the operations; the longest time interval studied was four months. Following vagotomy the innervation pattern of the jejunum appeared completely unaffected. Following complete extrinsic denervation the adrenergic nerve fibers disappeared, while peptide-containing and acetylcholinesterase-positive nerve fibers remained apparently unaltered. This was confirmed chemically in the case of substance P.The motor activity of smooth muscle from the jejunum was studied in vitro. At low stimulation frequencies the smooth muscle from control jejunum responded by relaxation; upon cessation of stimulation a contraction occurred. With increasing stimulation frequencies the duration of the relaxation decreased; at high frequency stimulation only a contraction was recorded. In the autotransplant low frequency stimulation induced no or only a weak relaxation; high frequency stimulation induced contraction. After cholinergic and adrenergic blockade, the muscle responded with relaxation at all frequencies; the response was similar in innervated and denervated specimens. On the whole, the effects of extrinsic denervation on the motor activity of smooth muscle from porcine jejunum were minor, possibly reflecting the high degree of autonomy of the gut.     

Electrical and acetylcholine-receptive properties of the muscle fiber membrane after axoplasmic transport blockade by colchicine

Electrical properties of the membrane and sensitivity of the fibers to acetylcholine were investigated in the frog sartorius muscle after denervation and a single application of colchicine to the nerve. After both types of procedure the electrical properties showed similar changes and extrasynaptic sensitivity to acetylcholine appeared. No such changes took place in the fibers of the contralateral muscle. Injection of colchicine into the lymphatic sac did not affect the electrical properties of the membrane, but widened the zone of sensitivity to acetylcholine. The results are regarded as further evidence in support of the view that denervation-like changes after application of colchicine to the motor nerve, when the transmission of excitation of nerve to muscle is preserved, are the result of a disturbance of the supply of neurotrophic substances along the axon by means of axoplasmic transport.Kazan' Medical Institute. I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 12, No. 5, pp. 550–557, September–October, 1980.     

The pattern of innervation in serially duplicated axolotl limbs: further evidence for the existence of local pathway cues?

The innervation of the biceps muscle was examined in regenerated and vitamin A-induced serially duplicated axolotl forelimbs using retrograde transport of horseradish peroxidase. The regenerated biceps muscle becomes innervated by motor neurones in the same position in the spinal cord as the normal biceps motor pool. In previous experiments in which the innervation of a second copy of a proximal limb muscle was examined in serially duplicated limbs (Stephens, Holder & Maden, 1985), the duplicate muscle was found to become innervated by motor neurones that would normally have innervated distal muscles. In the present study, the innervation of the second copy of biceps was examined under conditions designed to encourage nerve sprouting from 'correct' biceps axons. Following either partial limb denervation or denervation coupled with removal of the proximal biceps, the second copy of the muscle was still innervated by inappropriate motor neurones, which again would normally innervate distal limb muscles. These results are interpreted as evidence for the necessity for an appropriate local environment for axonal growth to allow reformation of a correct pattern of motor innervation in the regenerated limb.     

Nonquantum release of acetylcholine in frog neuromuscular junction after blocking of axoplasmic transport with colchicine

Standard microelectrode techniques were used to evaluate the effect of d-tubocurarine chloride on membrane potential of junctional and extrajunctional areas of muscle fibers in a potassium-free Ringer solution. The experiments were made on frogs after inactivation of acetylcholinesterase. d-Tubocurarine chloride hyperpolarized the membrane of muscle fibers only in the junctional area. Blockade of axoplasmic transport with colchicine did not affect the magnitude of the hyperpolarization response of the membrane end plate to the presence of d-tubocurarine chloride, but at the same time it significantly reduced the membrane rest potential of muscle fibers, and gave rise to the appearance of extrajunctional sensitivity to acetylcholine. It is concluded that the blockade of axoplasmic transport does not affect the pattern of non-quantum acetylcholine release from nerve terminals. Therefore, this is unlikely to cause denervation-like changes in the muscle under the conditions described.