Development of the myoneural junction in the rat

Summary The structure of the myoneural junction in the striated muscle of rat embryos and postnatal rats was studied by electron microscopy in order to assess at ultrastructural level the roles of neuronal and muscular elements and the sequence of events resulting in the formation of a functionally mature synaptic organization.From the observations it is concluded that the axon terminals enveloped by Schwann cells contain vesicles prior to apposition of the prospective synaptic membranes. Subsequently, subsarcolemmal thickening of the postsynaptic membrane takes place after the synaptic gap has been formed by disappearance of the teloglial cell from between the synaptic membranes but before the primary synaptic cleft in the strict sense is formed. Secondary synaptic clefts are formed later, when the primary synaptic cleft is regular in width, by local finger-like invaginations of the postsynaptic membrane, which thereafter expand basally, in a plane transverse to the axis of the axon terminal, to resemble flattened flasks. The junction is formed between multinucleated muscle cells and multiple axons, which at first lie side by side and later, when formation of adult-type secondary synaptic clefts is in progress, become separated by folds of the sarcoplasm and the teloglia. In extraocular muscles of adult rats the sarcoplasmic reticulum is closely associated with the postjunctional sarcoplasm.In the light of earlier observations on the development of contractibility after nerve stimulation, cholinesterase histochemistry and muscle fibre physiology, these observations are interpreted to indicate that functional differentiation of the myoneural synapse results from induction by the motor axon and that the association of the sarcoplasmic reticulum with the postjunctional sarcoplasm in adult extraocular muscles is related to modified fibre physiology.The author wishes to thank Prof. Antti Telkkä, M.D., Head of the Electron Microscope Laboratory, University of Helsinki, for placing the electron microscopic facilities at his disposal.     

Localization of acetylcholinesterase in the rat myoneural junction

Summary The distribution of myoneural acetylcholinesterase (AChE; EC. 3.1.1.7) was studied electron microscopically with the copper ferricyanide method at pH 6.0, using acetylthiocholine iodide as substrate and iso-OMPA to exclude other cholinesterase activity.It was observed that the results obtained with this method are affected by changes in the reaction temperature, inhibitor concentration and fixation time. Changes which retard the rate of hydrolysis of AChE were observed to transfer the localization of the reaction endproduct in intact junctions from the extracellular side of the postsynaptic membrane to the intracellular side of the postsynaptic membrane. From the results it is concluded that the site of most intense AChE corresponds to the region of increased subsarcolemmal electron density of the postsynaptic membrane.     

Electron microscopic localization of cholinesterases in the rat myoneural junction

Summary The distribution of acetylcholinesterase (E.C. 3.1.1.7.) and other cholinesterases (E.C. 3.1.1.8.) in the fine structure of the myoneural junction of the rat diaphragma was studied, using acetylthiocholine and butyrylthiocholine as substrates. p]Acetylcholinesterase was located in the muscle sarcoplasm closely related to the postsynaptic membrane. Other cholinesterases are observed in the primary and secondary synaptic clefts and between the axon and the teloglial cells.     

Effects of colchicine and vinblastine on neurotubules of the sciatic nerve and cholinesterases in the developing myoneural junction of the rat

Summary Colchicine (0.1 M) or vinblastine (0.01 M) was locally applied on the sciatic nerves of newborn rats. Both colchicine and vinblastine caused reversible disappearance of axonal neurotubules and appearance of increased amounts of neurofilaments at the site of application. Subsequent morphogenesis of myoneural junctions in the tibialis anterior muscle was studied after histochemical demonstration of acetylcholinesterase (AChE; E.C. 3.1.1.7) and non-specific cholinesterase (Ns. ChE; E.C. 3.1.1.8) activity in the myoneural area.Development of the postsynaptic muscle plasma membrane of the myoneural junction was arrested in the ipsilateral, but not in the contralateral control side, for a period of about three weeks following treatment with the test substances. After this delay the myoneural morphogenesis continued normally and neurotubules were seen in the axoplasm.Since disruption of neurotubules is likely to cause blockage of the intratubular axoplasmic transport system, it seems possible that the neurotrophic influence responsible for the development of the postsynaptic muscle membrane is mediated through a secretory product transported along axons intratubularly to the nerve endings.     

Localization of the ruthenium red-positive substance in the myoneural junction of rat.

Ruthenium red staining of myoneural junctions was examined in the flexor digitorum brevis muscle of the rat. Ruthenium red-positive electron dense substance was observed to emerge from the outer layer of the presynaptic axolemma and post-synaptic sarcolemma towards the synaptic cleft. Also the cleft substance was intensely stained, usually consisting of a medium dense layer between pre- and postsynaptic membranes. The probable function of acid mucopolysaccharides in the neuromuscular transmission is discussed.     

Action of inhibitors at the myoneural junction

1. A study is presented of the actions of certain inhibitors on the frog rectus abdominis muscle stimulated by acetylcholine. 2. A type of analysis has been developed which provides a reliable criterion for judging whether an inhibitor is competing with acetylcholine for receptors at the myoneural junction or whether acting by a different mechanism. 3. The "curares" are shown to act by competitive inhibition at the myoneural junction, confirming earlier work of others on the mode of action of curare. 4. Atropine acts as an inhibitor at the myoneural junction. The inhibition may be non-competitive or it may be complicated by an additional effect at some point other than the myoneural junction. 5. A possible mechanism for anomalous inhibitor effects is the action of a single compound at more than one locus in the Ach mechanism. Eserine exerts such a dual effect at the end-plate. 6. Some of the available electrical and chemical data have been correlated to make possible a partial explanation of the role of Ach in transmission at the myoneural junction.     

Effect of oculomotor and trigeminal nerve section on the ultrastructure of different myoneural junctions in the rat extraocular muscles

Summary The intramuscular nerves and myoneural junctions in the rat rectus superior, medialis and inferior muscles from 10 hours to about 10 days after section of the trigeminal and oculomotor nerves were studied with the electron microscope. Two different kinds of myoneural junctions are to be observed; one type derives from myelinated nerves and is similar to the ordinary myoneural junctions (motor end plates) of other striated skeletal muscles, while the other type derives from unmyelinated nerves, is smaller in size and has many myoneural synapses distributed along a single extrafusal muscle fibre.Section of the trigeminal nerve caused no changes in the myoneural synapses. After section of the oculomotor nerve degenerative changes occur in both the myelinated and unmyelinated nerves and in both types of myoneural junctions. In the axon terminals of both the myelinated and unmyelinated nerves the earliest changes are to be observed 10 to 15 hours after section of the nerve. First, swelling of the axoplasm, fragmentation of microtubules and microfilaments and swelling of mitochondria takes place, somewhat later agglutination of the axonal vesicles and mitochondria. The axon terminals are separated from the postsynaptic muscle membrane by hypertrophied teloglial cells about 24 hours after section of the nerve. The debris of the axon terminals is usually digested by the teloglial cells within 42 to 48 hours in both types of myoneural junction.Changes in the postsynaptic membrane are observed in the myoneural junctions of the unmyelinated nerves as disappearance of the already earlier irregular infoldings, whereas no changes take place in the infoldings of the motor end plates. The postsynaptic sarcoplasm and its ribosomal content increase somewhat.The earliest changes occur along unmyelinated axons 10 to 15 hours and along myelinated axons 15 to 24 hours after nerve section. The unmyelinated axons are usually totally digested within 48 hours, whereas the myelinated axons took between 48 hours and 4 days to disappear. The degeneration, fragmentation and digestion of the myelin sheath begin between 24 and 42 hours and still continues 10 days after the operation.The results demonstrate that in the three muscles studied structures underlying the physiologically well known double innervation of the extraoccular muscles are all part of the oculomotor system.We are grateful to Professor Antti Telkkä, M. D. Head of the Electron Microscope Laboratory, University of Helsinki, for permission to use the facilities of the laboratory.     

The form of sodium-calcium competition at the frog myoneural junction

The times required for a steady rate of miniature end-plate potential discharge to be reached in response to changes in extracellular [K⁺], [Na⁺], and [Ca⁺⁺] have been measured. In the presence of 15 mM KCl, Ca⁺⁺ raises and Na⁺ lowers the steady-state mepp frequency; but the depressive effect on Na⁺ is not specific: Li⁺ can replace Na⁺ to a large extent. Mepp frequency has been found to depend on the ratio of [Ca_o ⁺⁺]/[Na_o ⁺]. It is assumed that in the steady state, intracellular sodium will change when extracellular sodium is changed. Because both intracellular and extracellular sodium at motor nerve endings affect acetylcholine release, it is proposed that mepp frequency depends on the ratio [Ca_o] [Na_i]²·/[Na_o]² Two models are proposed. Firstly, to account for the action of sodium and calcium a carrier is postulated for which Ca⁺⁺ and Na⁺ compete. The carrier determines a maximum level of intracellular Ca⁺⁺ far lower than predicted by the Nernst equation for Ca. Secondly, to account for activation of acetylcholine release by a small influx of Ca⁺⁺, the ions are presumed to enter the nerve ending in a two stage process through a small intermediate compartment and to act on the acetylcholine release site in this region rather than after entering directly into the cell.     

Immunohistochemical identification of serotonin and noradrenalin containing structures within the nerve plexuses of rat ileum

The distribution of 5-hydroxytryptamine (= serotonin = 5-HT) and noradrenalin (NA) in the enteric plexuses of the rat ileum was studied using immunocytochemical techniques. 5-HT-like immunoreactive fibers were observed only in the myenteric plexus, surrounding the ganglionic cells, which are all unreactive. NA-like immunoreactive fibers were present in all layers of the ileum: in the myenteric plexus, they were localized in the nodes, forming a network all round the neuronal perikarya; in the Meissner plexus, positive axons were arranged in a delicate network; submucosal blood vessels were often provided by NA-immunopositive nerve plexus. In the inner circular muscle layer the immunoreactive NA-positive fibers run within nerve bundles mainly parallel with the smooth muscle cells. The 5-HT immunoreactive material was depleted by treatment with reserpine; depletion of NA by 6-hydroxy-dopamine was also observed; on the contrary, no depletion of 5-HT by 5,7-dihydroxytryptamine was obtained. To confirm the validity of these results, specific antibodies to tyrosine hydroxylase (TH) and aromatic 1-aminoacid-decarboxylase (AADC), two enzymes involved in the synthesis of catecholamines, were used. In conclusion these experiments indicate that 5-HT is present, probably as a transmitter, in certain fibres of the rat myenteric plexus, distributed in a way similar to that of NA-containing fibers. However, at variance with NA fibers, 5-HT fibers are not present in other regions of the intestine wall.     

A comparative study of physiological and structural changes at the myoneural junction in two species of frog after transection of the motor nerve

Summary Structural and functional behaviour of motor end-plates after transection of the motor nerve has been studied in two species of frog: Rana esculenta and Rana temporaria. The physiological results show that in both species there is a transient cessation of spontaneous activity followed by a resumption of miniature end-plate potentials (min. e.p.p.s.) after denervation. The characteristics of these potentials (frequency, distribution of amplitudes, time-course) are similar in the two species. However, some differences have been observed: Firstly, the period of silence lasts for 2–4 days in the case of Rana temporaria whereas it is prolonged to about 15 days in Rana esculenta. Secondly, the resumption of min. e.p.p.s. is gradual and after the 10th day of denervation remains constant in Rana temporaria. It is inconstant independent of the period of denervation in Rana esculenta. The morphological results show that the Schwann cell is constantly in contact with the post-synaptic membrane after about 6 days of denervation in both species. It is suggested that either the Schwann cell is capable of functioning for a limited period of time in Rana esculenta or is activated to produce min. e.p.p.s. only in certain cases.     

Embryonic cholinesterase activity during morphogenesis of the mouse genital tract

Summary In the genital tract of male and female mouse embryos cholinesterase activity is described that is independent from innervation. The enzyme activity is localized in the mesenchyme at the junction of Wolffian and Müllerian ducts with the urogenital sinus. During male development prostate buds and vesicular glands grow out into the cholinesterase-active mesenchyme. During female development the active mesenchyme participates in the downgrowth of the vaginal anlage. Ultrastructurally the cholinesterase activity is localized in the perinuclear cisterna and in smooth endoplasmic reticulum of the mesenchymal cells. The enzyme activity disappears with definitive differentiation of the tissue. The embryonic cholinesterase is a component of a primitive muscarinic system. Its relation to the morphogenetic action of testosterone and its possible general functions are discussed.