Attachment of acetylcholinesterase to structures of the motor endplate.

The kinetics of AChE solubilization from intact motor endplates of mouse diaphragm, by collagenase, papain and hyaluronidase, was studied in parallel with the ultrastructural localization of AChE in treated neuromuscular junctions. Hyaluronidase did not solubilize more AChE from isolated motor endplate regions than Ringer's solution itself. Residual AChE activity could be demonstrated histochemically in motor endplates even after the plateau of solubilization by collagenase or papain was reached. Less than 35% of junctional AChE is left after collagenase, and less than 20% after papain treatment, as estimated by the percentage of AChE activity left in the isolated endplate region of the diaphragm after protease treatment. Cytochemically, both proteases had a similar effect on postsynaptic AChE. Residual AChE activity was distributed randomly, adhering to the sarcolemma of junctional clefts. Presynaptic AChE localized in the gap between axon terminal and Schwann cell appears to be resistant to collagenase but not to papain treatment. The mode of AChE attachment or the composition of the intercellular material in this gap may differ from that of the primary and secondary clefts.     

INCREASE IN THE APPARENT AChE ACTIVITY IN THE MOUSE DIAPHRAGM INDUCED BY PROTEOLYTIC TREATMENT

Abstract— Isolated endplate regions from the mouse diaphragm were treated with different agents before or after homogenization in order to solubilize junctional AChE and study the effect of solubilization on its apparent activity. Total AChE activity (solubilized + nonsolubilized) of samples treated with collagenase or papain before homogenization was nearly twice as high as in control samples. If collagenase was added after homogenization no increase in apparent activity was observed although in both cases about 70–80% of AChE activity was solubilized. The access of ACh to the membrane-bound enzyme is probably not a limiting factor in the AChE assay as is the case in the electric organ homogenates. Both 1 m -NaCl and Triton X-100 were quite ineffective as solubilizers when applied before homogenization and had an insignificant effect on the apparent AChE activity.
The increase in apparent AChE activity cannot be explained either by a de novo synthesis or by the change in kinetic properties of different species of AChE, or by the release of AChE possibly sequestrated in the membrane vesicles. The possibility is discussed that a part of junctional AChE is inactivated at the beginning of homogenization while it can be preserved by previous solubilization, or that proteolytic treatment may activate some 'silent' AChE sites in motor endplates.
However, the mere fact that the difference does exist suggests that all AChE activity present in intact motor endplates may not be measurable after homogenization.     

Development of rat soleus endplate membrane following denervation at birth

Rat soleus endplates develop some of their characteristic features before birth and others after birth. Specializations appearing before birth include a localized cluster of acetylcholine receptors (AChRs), an accumulation of acetylcholinesterase (AChE) in the synaptic basal lamina, and a cluster of nuclei near the endplate membrane. In contrast, postsynaptic membrane folds are elaborated during the first three weeks after birth. We denervated soleus muscles on postnatal day 1, before folds had appeared, and followed the subsequent development of endplate regions with light and electron microscopy. We found that the denervated endplates initiated fold formation on schedule and maintained their accumulations of AChRs, AChE, and endplate nuclei. However, the endplates stopped fold formation prematurely and eventually lost their rudimentary folds. At about the same time, the junctional AChR clusters were joined by ectopic patches of AChRs. The former endplate regions also became unusually elongated, possibly as a consequence of the lack of membrane folds. Apparently, endplate membranes have only a limited capacity for further development in the absence of both the nerve and muscle activity.     

Comparison of changes in AChE activity in the brain of the laboratory rat after soman and tabun intoxication

The aim of this study was to compare changes in activity of acetylcholinesterase (AChE) in the brain and motor endplates of rat after administration of soman and tabun. We took brain and diaphragm from laboratory rats administered a median lethal dose (LD(50)) of soman or tabun. Enzyme activity of AChE was studied in selected structures of brain and in motor endplates in the diaphragm. Histochemical detection of AChE by Karnovski and Roots with simultaneous histochemical detection of alkaline phosphatase in case of brain sections was used. The highest activity of AChE in the control group was found in the striatum, amygdaloid nuclei, substantia nigra, superior colliculi, and motor nuclei of cranial nerves V, X a XII. LD(50) of both nerve agents dramatically decreased the activity of AChE in the structures studied--both brain and diaphragm. After intoxication by either agent, activity in above mentioned nuclei was characterized as low or focally moderate. Very low activity was seen in some structures (CA3 field of hippocampus, some nuclei of the tegmentum and cerebellar cortex). We found minimal differences in the histochemical picture of soman or tabun intoxication, apart from the striatum and the superior colliculi which showed stronger inhibition by tabun.     

16 S acetylcholinesterase in endplate-free regions of developing rat diaphragm

Velocity sedimentation patterns of acetylcholinesterase (AChE, EC 3.7.1.1) in endplate-free regions of the diaphragm were studied in rats during early postnatal development. A significant amount of 16 S AChE, comprising 20% total activity, was found in endplate-free regions of the diaphragm of 8- and 19-day-old rats. By 32 days after birth, 16 S AChE accounted for less than 5% total AChE activity in endplate-free regions. 16 S AChE is, therefore, not strictly an endplate-specific molecular form. Instead, it becomes restricted to the motor endplate region of the rat diaphragm by the end of the first month of life.     

Neurotrophic control of 16S acetylcholinesterase from mammalian skeletal muscle in organ culture

The effects of rat obturator nerve extracts on total and 16S acetylcholinesterase (AChE) activity were studied in endplate regions of denervated anterior gracilis muscles maintained in organ culture for 48 hr. The decrease of total AChE activity in cultured muscles was similar to that observed in denervated muscles in vivo. This decrease in activity was partly prevented by addition of either 100 or 200 μl nerve extract (2.7 mg/ml protein) to the nutrient medium. Nerve extract treatment also decreased the release of AChE activity from the muscle into the bathing medium. Conversely, rat serum (20 μl; 90 mg/ml protein) had no effect on total AChE activity in muscle endplates, nor on release of the enzyme by the muscle. The 16S form of AChE was confined to motor endplate muscle regions and its activity was drastically decreased by denervation in both organ culture and in vivo preparations in a comparable manner. Nerve-extract supplemented cultures contained a significantly (p ? 0.001) larger amount of endplate 16S AChE activity (140–145%) than the corresponding controls (100-). Our results suggest that some nerve soluble substance, other than serum contaminants or 16S AChE itself, affects the maintenance of 16S AChE at the neuromuscular junction.     

Structural differences of pale and strongly stained motor end-plates of the rat diaphragm.

According to the staining intensities for AChE, the motor end-plates of the rat diaphragm can be classified into strong (S) and pale (P) types. About 34% of the total end-plates of the rat diaphragm are of S type and 50% of P type. The P end-plates differ from S end-plates in two aspects. First, the secondary subneural clefts of the S end-plates are well developed. They are numerous, long, closely packed and often branched. On the other hand, the secondary subneural clefts of the P end-plates are short, sparse and usually unbranched. Secondly, there seems to be a variation in AChE activity in the P end-plates. Focal negative AChE areas are found in the subneural apparatus of some P end-plates. It is concluded that the less well developed secondary subneural clefts and focal areas of negative AChE activity contribute to the paler staining of the P end-plates.     

Junctional form of acetylcholinesterase restored at nerve-free endplates.

Rat soleus muscles were ectopically innervated by implanting a foreign nerve in an endplate-free region of muscle and, 2–3 weeks later, cutting the original nerve. The junctional, 16 S form of acetylcholinesterase (AChE) and focal staining for AChE disappeared from the old endplate region within a few days after denervation. In muscles with an ectopic nerve, but not in paired control muscles, 16 S AChE and focal staining were restored in the old endplate region 1–2 weeks after denervation even though nerve fibers could not be detected in that region. These results suggest that the nerve exerts a local effect, specifying the site at which junctional AChE appears, and a nonlocal effect, perhaps mediated by muscle activity, regulating the amount of junctional AChE.     

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.     

Electronmicroscopic localization of cholinesterase at the neuromuscular junction by a quaternary carbon analogue of acetylthiocholine as substrate

Summary By means of a quaternary carbon analogue of acetylthiocholine (AThCh)' 3,3-dimethylbuthylthioacetate (DMBTA) as a substrate for cholinesterase (ChE), acethylcholinesterase (AChE) has been localized at the neuromuscular junctions of the rat diaphragm in an electron microscope histochemical investigation. AChE is associated with the pre- and postsynaptical membranes, with much greater activity at the latter. Enzymatic activity is not found within the junctional clefts, nor in association with the synaptic vesicles of the axonal end arborization. The lack of AChE in association with the vesicles is regarded as particularly important, since DMBTA due to its electroneutrality probably penetrate biological membranes more easily than charged substrates employed so far.     

Proteolytic stimulation and solubilization of membrane-bound acetylcholinesterase from muscle sarcotubular system

Incubation of membranes derived from sarcotubular system of rabbit skeletal muscle with increasing concentrations of Triton X-100 produced both stimulation of the AChE activity and solubilization of this enzyme. Mild proteolytic treatment of microsomal membranes produced a several fold activation of the still membrane-bound acetylcholinesterase (AChE) activity. Attempts were made to solubilize AChE from microsomal membranes by proteolytic treatment. About 30–40% of the total enzyme activity could be solubilized by means of trypsin or papain. Short trypsin treatment of the microsomal membranes produced first an activation of the membrane-bound enzyme followed by solubilization. Incubation of muscle microsomes for a short time with papain yielded a significant portion of soluble enzyme. Membrane-bound enzyme activation was measured after a prolonged incubation period. These results are compared with those of solubilization obtained by treatment of membranes with progressive concentrations of Triton X-100. The occurrence of molecular forms in protease-solubilized AChE was investigated by means of centrifugation analysis and slab gel electrophoresis. Centrifugation on sucrose gradients revealed two main components of 4.4S and 10–11S in either trypsin or papain-solubilized AChE. These components behaved as hydrophilic species whereas the Triton solubilized AChE showed an amphipatic character. Application of slab gel electrophoresis showed the occurrence of forms with molecular weights of 350,000; 175,000; 165,000; 85,000 and 76,000. The stimulation of membrane-bound AChE by detergents or proteases would indicate that most of the enzyme molecules or their active sites are sequestered into the lipid bilayer through lipid-protein or protein-protein interactions and these are broken by proteolytic digestion of the muscle microsomes.     

QUANTITATIVE STUDIES ON ENZYMES IN STRUCTURES IN STRIATED MUSCLES BY LABELED INHIBITOR METHODS : I. The Number of Acetylcholinesterase Molecules and of Other DFP-Reactive Sites at Motor Endplates, Measured by Radioautography

Di-isopropylfluorophosphate (DFP) labeled with phosphorus-32 was applied to fragments of the diaphragm and sternomastoid muscles of the mouse, in conditions in which it saturated all available sites at the motor endplates. After adequate washing and exchange with unlabeled DFP, single endplates were obtained by microdissection and their radioactivity was found by beta track radioautography. The number of sites phosphorylated by DFP-³²P per endplate was relatively constant for each muscle: in the sternomastoid, about 9 x 10⁷ sites per endplate, in the diaphragm, about 3 x 10⁷. Reaction with DFP-³²P was abolished by prior treatment with unlabeled DFP. Labeling was unaffected by prior fixation in formaldehyde, but was inversely proportional to the time of incubation in the Koelle staining medium, when this preceded labeling. The contribution of acetylcholinesterase (AChase) to this total number of DFP-reactive sites was determined by three methods. The first involved reactivation of the phosphorylated AChase by pyridine-2-aldoxime methiodide (2-PAM), in conditions in which the reactivation of other enzymes would be insignificant. The other two methods involved protection of the active centers of AChase from phosphorylation by labeled DFP by use of 284C51, an inhibitor highly specific for this enzyme, or by use of eserine. Each of these methods indicated that about 35% of the DFP-reactive sites at endplates of the sternomastoid and diaphragm are AChase. The mean number of AChase molecules was thus found to be 3.1 x 10⁷ and 1.1 x 10⁷per endplate in sternomastoid and diaphragm, respectively. No significant reaction of labeled DFP with muscle and nerve was observed. Mast cells in the muscle had a concentration of DFP-reactive sites far higher than the endplates.     

Association of tailed acetylcholinesterase to lipidic membranes in mammalian skeletal muscle

Tailed acetylcholinesterase (AChE) was studied in three subcellular membrane fractions of mouse skeletal muscle: a fraction enriched in isolated motor endplates (C), an extrasynaptic membrane fraction (A) and a microsomal fraction (S). In the (C) fraction, tailed asymmetric 16S AChE required high salt conditions to be extracted, while in (A) and (S) microsomal membranes, a collagenase sensitive 16S form, was extracted by detergent alone. This apparent “hydrophobic” property suggests that there is a pool of 16S AChE which is probably bound to lipidic membranes. The detergent extractable (DE) 16S AChE was not concentrated in motor endplate-rich regions and differential inhibition of external and internal AChE demonstrated that it could have both intra- and extracellular locations in the adult differentiated muscle fibres.     

The voltage-dependent sodium channel is co-localized with the acetylcholine receptor at the vertebrate neuromuscular junction

Isolated motor endplates from mouse intercostal muscles can be obtained after subcellular fractionation. On these motor endplates, localization of the nicotinic receptor and of the voltage-dependent Na+ channel coincides as demonstrated by double labeling with rhodamine alpha-bungarotoxin and a specific anti-Na+ channel monoclonal antibody. High density of Na+ channel at the motor endplate is confirmed by the enrichment in TTX binding sites as compared to the crude homogenate. In contrast isolated motor endplates are almost completely devoid of Ca2+ channel antagonist binding sites.     

Atypical endplate miniature potentials in the frog neuromuscular junction after modification of the intercellular matrix and osmotic exposures]

In frog cutaneous-pectoris muscles the frequency of slowly rising atypical miniature endplate potentials (MEPPs) was significantly enhanced after collagenase (0.1%) treatment. Treatment with trypsin, hyaluronidase, hyper- and hypoosmotic solutions caused no changes in slowly rising MEPP (frequency in muscle fibers with intact acetylcholinesterase (AChE). Inhibition of AChE caused appearance of giant MEPPs. Acceleration of acetylcholine diffusion from synaptic cleft after treatment with hyaluronidase decreased giant MEPP frequency demonstrating their dependence upon nonhydrolyzed acetylcholine in synaptic cleft. The relation between slowly rising MEPPs and activity of synaptic Schwann cells in discussed.     

THE FINE STRUCTURE OF MOTOR ENDPLATE MORPHOGENESIS

The fine structure of the developing neuromuscular junction of rat intercostal muscle has been studied from 16 days in utero to 10 days postpartum. At 16 days, neuromuscular relations consist of close membrane apposition between clusters of axons and groups of myotubes. Focal electron-opaque membrane specializations more intimately connect axon and myotube membranes to each other. What relation these focal contacts bear to future motor endplates is undetermined. The presence of a group of axons lying within a depression in a myotube wall and local thickening of myotube membranes with some overlying basal lamina indicates primitive motor endplate differentiation. At 18 days, large myotubes surrounded by new generations of small muscle cells occur in groups. Clusters of terminal axon sprouts mutually innervate large myotubes and adjacent small muscle cells within the groups. Nerve is separated from muscle plasma membranes by synaptic gaps partially filled by basal lamina. The plasma membranes of large myotubes, where innervated, simulate postsynaptic membranes. At birth, intercostal muscle is composed of separate myofibers. Soleplate nuclei arise coincident with the peripheral migration of myofiber nuclei. A possible source of soleplate nuclei from lateral fusion of small cells' neighboring areas of innervation is suspected but not proven. Adjacent large and small myofibers are mutually innervated by terminal axon networks contained within single Schwann cells. Primary and secondary synaptic clefts are rudimentary. By 10 days, some differentiating motor endplates simulate endplates of mature muscle. Processes of Schwann cells cover primary synaptic clefts. Axon sprouts lie within the primary clefts and are separated from each other. Specific neural control over individual myofibers may occur after neural processes are segregated in this manner.     

Activity and Distribution of Tissue Transglutaminase in Association with Nerve-Muscle Synapses

Abstract: We have measured, characterized, and localized calcium-dependent protein cross-linking activity in rat skeletal muscle, and in myotubes cultured independently or In coculture with spinal neurones, catalyzed by the enzyme tissue transglutaminase (tTG). The enzyme activity was present in both motor endplate and endplate-free zones of rat diaphragm muscle. tTG in the endplate zone was more tightly associated with the tissue. This form of association was absent in extracts of peripheral nerve. Cross-linking of endogenous proteins, as measured by the content of ɛ-(γ-glutamyl)lysine isppeptide, was higher in the endplate than in the nonendplate zone. Cytosolic (C) and paniculate (B) forms of tTG were separated by ion-exchange chromatography from both regions of the muscle. In the motor endplate zone, a higher proportion of tightly bound tTG was recovered as a separate (B₁) particulate form. K _m values for calcium activation of the three forms of tTG were in the range of 5–15 μM. Immunocytochemistry with polyclonal and monoclonal antibodies revealed the enzyme at motor endplates and at contacts between neurites of rat embryo spinal neurones and myotubes in primary cocultures. Appearance of the B₁ transglutaminase could be induced by coculturing myotubes of the mouse C2C12 cell line with neurones. The results suggest that tTG is most concentrated and active at the motor endplate.     

Heterogeneity of neuromuscular junctions in striated muscle of human esophagus demonstrated by triple staining for the vesicular acetylcholine transporter, α-bungarotoxin, and acetylcholinesterase

During studies on enteric co-innervation in the human esophagus, we found that not all acetylcholinesterase (AChE)-positive motor endplates stained for α-bungarotoxin (α-BT) and the vesicular acetylcholine transporter (VAChT), respectively. Therefore, we probed for differences in neuromuscular junctions in human esophagus by using triple staining for VAChT, α-BT, and AChE followed by qualitative and quantitative analysis. To exclude that the results were caused by processing artifacts, we additionally examined the influence of a number of factors including post-mortem changes and the type and duration of fixation on the staining results. Four types of neuromuscular junction could be distinguished in human esophagus: type I with VAChT-positive and type II with VAChT-negative nerve terminals on a α-BT-positive and AChE-positive endplate area, type III with VAChT-positive nerve terminals on a α-BT-negative but AChE-positive endplate area, and type IV with VAChT-negative nerve terminals on a α-BT-negative but AChE-positive endplate area. On average, 32% of evaluated AChE-positive motor endplates were type I, 6% type II, 24% type III, and 38% type IV. Based on these results, we suggest that, in human esophagus, (1) the most reliable method for staining motor endplates is presently AChE histochemistry, (2) α-BT-sensitive and α-BT-resistant nicotinic acetylcholine receptors exist in neuromuscular junctions, and (3) different types of VAChT or transport mechanisms for acetylcholine probably exist in neuromuscular junctions.This study was supported by the “Johannes und Frieda Marohn-Stiftung”, Erlangen.     

Selective Increase of Tetrameric (G4) Acetylcholinesterase Activity in Rat Hindlimb Skeletal Muscle Term Denervation

Acetylcholinesterase (AChE; EC 3.1.1.7) isoenzymes in gracilis muscles from adult Sprague-Dawley rats were studied 24-96 h after obturator nerve transection. Results show a selective denervation-induced increase in the globular G4 isoform, which is predominantly associated with the plasmalemma. This enzymatic increase was (a) transient (occurring between 24 and 60 h) and accompanied by declines in all other identifiable AChE isoforms; (b) observed after concurrent denervation and inactivation of the enzyme with diisopropylfluorophosphate, but not following treatment with cycloheximide; and (c) more prominent in the extracellular compartment of muscle endplate regions. Aside from this transient change, G4 activity did not fall below control levels, indicating that at least the short-term maintenance of G4 AChE (i.e., at both normal and temporarily elevated levels) does not critically depend on the presence of the motor nerve. In addition, this isoform's activity increases in response to perturbations of the neuromuscular system that are known to produce elevated levels of acetylcholine (ACh), such as short-term denervation and exercise-induced enhancement of motor activity. The present study is consistent with the hypothesis that individual AChE isoforms in gracilis muscle are subject to distinct modes of neural regulation and suggests a role for ACh in modulating the activity of G4 AChE at the motor endplate.     

Influence of testosterone on the development of the ischiocavernosus muscle of the rat

The mean area of the neuromuscular endplates and the acetylcholinesterase (AChE) activity at the myotendinous junction of the ischiocavernosus muscle were studied in normal, castrated and testosterone-treated castrated Wistar rats by the Koelle method. The mean endplate area was found to be smaller in castrated rats, compared to normal ones (p less than 0.001), while testosterone treatment restored its normal size (0.8 greater than p greater than 0.7). The terminal AChE activity in castrated rats was as strong and spread as in juvenile ones, while it was almost absent in normal and in testosterone-treated castrated rats. The same parameters were examined in the tibialis anterior muscle of the same rats, chosen as a specimen of 'nonhormone-dependent' muscle, without finding any difference among the single groups.