Depolarising effect of curare on embryonic rat muscles

Expression of ALS-linked SOD1 Mutation in Motoneurons or Myotubes Induces Differential Effects on Neuromuscular Function In vitro

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease that selectively affects upper and lower motoneurons. Dismantlement of the neuromuscular junction (NMJ) is an early pathological hallmark of the disease whose cellular origin remains still debated. We developed an in vitro NMJ model to investigate the differential contribution of motoneurons and muscle cells expressing ALS-causing mutation in the superoxide dismutase 1 (SOD1) to neuromuscular dysfunction. The primary co-culture system allows the formation of functional NMJs and fosters the expression of the ALS-sensitive fast fatigable type II-b myosin heavy chain (MHC) isoform. Expression of SOD1^G93A in myotubes does not prevent the formation of a functional NMJ but leads to decreased contraction frequency and lowers the slow type I MHC isoform transcript levels. Expression of SOD1^G93A in both motoneurons and myotubes or in motoneurons alone however alters the formation of a functional NMJ. Our results strongly suggest that motoneurons are a major factor involved in the process of NMJ dismantlement in an experimental model of ALS.

Acetylcholine receptors in the equatorial region of intrafusal muscle fibres modulate mouse muscle spindle sensitivity

KEY POINTS

Acetylcholine receptors are aggregated in the central regions of intrafusal muscle fibres. Single unit muscle spindle afferent responses from isolated mouse extensor digitorum longus muscle were recorded in the absence of fusimotor input to ramp and hold stretches as well as to sinusoidal vibrations in the presence and absence of the acetylcholine receptor blockers d-tubocurarine and α-bungarotoxin. Proprioceptive afferent responses to both types of stretch were enhanced in the presence of either blocker. Blocking acetylcholine uptake and vesicular acetylcholine release by hemicholinium-3 also enhanced stretch-evoked responses. These results represent the first evidence that acetylcholine receptors negatively modulate muscle spindle responses to stretch. The data support the hypothesis that the sensory nerve terminal is able to release vesicles to fine-tune proprioceptive afferent sensitivity.

ABSTRACT

Muscle spindles are complex stretch-sensitive mechanoreceptors. They consist of specialized skeletal muscle fibres, called intrafusal fibres, which are innervated in the central (equatorial) region by afferent sensory axons and in both polar regions by efferent γ-motoneurons. Previously it was shown that acetylcholine receptors (AChR) are concentrated in the equatorial region at the contact site between the sensory neuron and the intrafusal muscle fibre. To address the function of these AChRs, single unit sensory afferents were recorded from an isolated mouse extensor digitorum longus muscle in the absence of γ-motoneuron activity. Specifically, we investigated the responses of individual sensory neurons to ramp-and-hold stretches and sinusoidal vibrations before and after the addition of the competitive and non-competitive AChR blockers d-tubocurarine and α-bungarotoxin, respectively. The presence of either drug did not affect the resting action potential discharge frequency. However, the action potential frequencies in response to stretch were increased. In particular, frequencies of the dynamic peak and dynamic index to ramp-and-hold stretches were significantly higher in the presence of either drug. Treatment of muscle spindle afferents with the high-affinity choline transporter antagonist hemicholinium-3 similarly increased muscle spindle afferent firing frequencies during stretch. Moreover, the firing rate during sinusoidal vibration stimuli at low amplitudes was higher in the presence of α-bungarotoxin compared to control spindles also indicating an increased sensitivity to stretch. Collectively these data suggest a modulation of the muscle spindle afferent response to stretch by AChRs in the central region of intrafusal fibres possibly fine-tuning muscle spindle sensitivity.

Postnatal changes in vagal control of esophageal muscle contractions in rats

AIMS

Replacement of smooth muscles by striated muscles occurs in the esophagus during the early postnatal period. The aim of this study was to clarify postnatal changes in vagal control of esophageal muscle contractions in rats.

MAIN METHODS

An isolated segment of the neonatal rat esophagus was placed in an organ bath and the contractile responses were recorded using a force transducer.

KEY FINDINGS

Electrical stimulation of the vagus trunk evoked a biphasic contractile response in the neonatal esophageal segment. The first and second components of the contractions were inhibited by α-bungarotoxin and atropine, respectively. Ganglion blockers, hexamethonium and mecamylamine, did not affect vagally mediated contractions. The first component gradually enlarged with age in days, whereas the second component declined during the first week after birth. Application of d-tubocurarine or acetylcholine caused an apparent contraction in the esophageal striated muscle at postnatal day 0, but responses to these drugs were not observed at 1 week after birth. The neonatal esophagus expressed the γ-subunit of nicotinic acetylcholine receptors. In contrast, the ε-subunit was dominantly expressed in the adult esophagus.

SIGNIFICANCE

The vagus nerves directly innervate both the esophageal striated muscles and smooth muscles in the early neonatal period. During the process of muscle rearrangement, the property of the striated muscles is altered substantially. The specific features of striated muscles in the neonatal rat esophagus might compensate for immature formation of neuromuscular junctions. Unsuccessful conversion of the striated muscle property during postnatal muscle rearrangement would be related to disorders of esophageal motility.

Interaction of benzylidene-anabaseine analogues with agonist and allosteric sites on muscle nicotinic acetylcholine receptors

BACKGROUND AND PURPOSE

Benzylidene-anabaseines (BAs) are partial agonists of the alpha7 nicotinic acetylcholine receptor (nAChR) but their mechanism(s) of action are unknown. Our study explores several possibilities, including direct interactions of BAs with the nAChR channel.

EXPERIMENTAL APPROACH

Functional and radioligand-binding assays were used to examine the interaction of two BA analogues, 3-(2,4-dimethoxybenzylidene)-anabaseine (DMXBA) and its primary metabolite 3-(4-hydroxy-2-methoxybenzylidene)-anabaseine (4OH-DMXBA) with both agonist and non-competitive antagonist (NCA)-binding sites on muscle-type nAChRs.

KEY RESULTS

Both BAs non-competitively inhibited ACh activation of human fetal muscle nAChRs and sterically inhibited the specific binding of the NCAs [piperidyl-3,4-3H(N)]-(N-(1-(2-thienyl)cyclohexyl)-3,4-piperidine ([(3)H]TCP) and [(3)H]dizocilpine to Torpedo nAChRs in the desensitized state. These compounds modulated [(3)H]tetracaine, [(14)C]amobarbital and [(3)H]TCP binding to resting nAChRs by allosteric mechanisms. Both BAs enhanced [(3)H]TCP binding when the nAChR was initially in the resting but activatable state, suggesting that both compounds desensitized the Torpedo nAChR. Although DMXBA failed to activate human fetal muscle nAChRs, 4OH-DMXBA was found to be a partial agonist. [(3)H]Nicotine competition-binding experiments confirmed that 4OH-DMXBA has higher affinity than DMXBA for the agonist sites, and that DMXBA is also a competitive antagonist.

CONCLUSIONS AND IMPLICATIONS

3-(4-hydroxy-2-methoxybenzylidene)-anabaseine is a partial agonist for human fetal muscle nAChRs, whereas DMXBA only has competitive and NCA activities. The NCA-binding site for BAs overlaps both the phencyclidine- and dizocilpine-binding sites in the desensitized Torpedo nAChR ion channel. The desensitizing property of BAs suggests another possible mode of non-competitive inhibition in addition to direct channel-blocking mechanisms.

Neonatal partial denervation results in nodal but not terminal sprouting and a decrease in efficacy of remaining neuromuscular junctions in rat soleus muscle

Mature motoneurons respond to partial denervation of their target muscle by sprouting to reinnervate denervated fibers, thus maintaining muscle strength in the face of motoneuronal loss caused by injury or disease. Neonatal motoneurons, however, do not expand to innervate more muscle fibers. The present work seeks to understand this developmental change in motoneuron response to partial denervation. It has been suggested that neonatal motor units cannot increase in size because they are already at their maximum size (approximately five times larger than in adulthood). We ruled out this explanation by showing that after partial denervation on postnatal day 14 (P14), when motor units have decreased to their adult size, motoneurons still did not sprout to reinnervate as many fibers as in adulthood. Instead, we found evidence supporting an alternative explanation involving terminal Schwann cells. After partial denervation of neonatal (but not adult) muscles, terminal Schwann cells at denervated endplates undergo apoptosis. We found that terminal (but not nodal) sprouting was absent in partially denervated neonatal muscles. This finding suggests that terminal Schwann cells, previously reported to guide terminal sprouts to denervated endplates in adult muscles, are necessary for the formation and growth of terminal sprouts. Moreover, partial denervation on P14 severely weakened the remaining, uninjured synapses, suggesting that neonatal motoneurons may withdraw terminals after the denervation of nearby fibers. These findings have implications for the interpretation of previous studies on synapse elimination and offer insight into the failure of young motor units to expand after partial denervation.

Nuclear clustering in myotubes: a proposed role in acetylcholine receptor mRNA expression

We investigated the functional relationship between nuclear topology, as expressed by degree and type of nuclear aggregation, and appearance of acetylcholine receptor (AChR) subunit mRNAs. Embryonic chick muscle cell cultures treated with the muscle activity blocking agents decamethonium (DCM), d-tubocurare (TBC), and tetrodotoxin (TTX) or co-cultured with cholinergic neurons were examined for the influence of muscle activity on nuclear aggregation and its effects on AChR alpha-, gamma-, and delta-subunit message expression. mRNA was measured by in situ hybridization and nuclei were visualized by bis-benzimide DNA staining. DCM and TBC treatments, as well as neuronal co-culture, resulted in increased nuclear clustering within myotubes and a per nucleus upregulation in mRNA expression relative to control for each subunit. The pattern of nuclear aggregation was treatment dependent, with more and larger aggregates found when myotubes were co-cultured with neurons. Moreover, as nuclear aggregates became larger: (1) nearly all nuclei within active aggregates expressed mRNA and (2) local accumulation (mRNA per unit area) was elevated relative to single nuclei, while per nucleus mRNA production decreased. To determine whether mRNA expression was transient and did not result in steady-state upregulation of AChR receptor protein, we performed a double labeling of surface AChRs with 125I-alpha-bungarotoxin (125I-alpha-BTX) concomitant to the in situ hybridization for mRNA quantification on TTX treated muscle cells. Surface receptor expression tracked mRNA expression forall types of nuclear topology observed, indicating that message levels are in fact reliable indicators of receptor population on the plasma membrane surface in myotubes. We propose that nuclear clustering is an organelle-level, accessory mechanism whereby cells concentrate relatively large amounts of AChR mRNA/protein in specific myotube regions.

Pharmacology of the nicotinic acetylcholine receptor from fetal rat muscle expressed in Xenopus oocytes

The fetal rat muscle nicotinic acetylcholine receptor was expressed in Xenopus oocytes. Using the voltage-clamp technique, the response to a range of agonists was measured, listed in order of (decreasing) activity efficacy: anatoxin > or = epibatidine > acetylcholine > DMPP (1,1-dimethyl-4-phenylpiperazinium) > > cytisine > pyrantel > nicotine > coniine > tubocurare > lobeline. The agonist responses were compared with the steric and electrostatic properties of the molecules, using molecular modelling. Single-channel current were measured in outside-out patches for acetylcholine, nicotine, cytisine, anatoxin and epibatidine. The conductance of the single channels was independent of the type of agonist. The mean open times were characteristic of the agonist applied. Tubocurare, better known for its antagonist properties, was also a partial agonist. Single-channel currents were also observed for tubocurare, and for methyllycaconitine in patches with a very high density of the muscle nicotinic acetylcholine receptor, and these were blocked by alpha-bungarotoxin. The agonist properties of physostigmine, galanthamine and their methyl derivatives were also investigated. The conductance of the channels observed in outside-out patches was similar to that obtained for the classical agonists. The single-channel currents observed for physostigmine, galanthamine and their methyl derivatives were blocked by alpha-bungarotoxin, methyllycaconitine and mecamylamine, in contrast to previously reported studies on neuronal and adult muscle nicotinic acetylcholine receptors.

Characterization of d-tubocurarine binding site of Torpedo acetylcholine receptor

d-Tubocurarine (curare) is a well-characterized competitive antagonist of nicotinic acetylcholine receptors (AChRs), and it is usually assumed that curare and agonists share a common binding site. We have examined the role of several highly conserved residues of the alpha-, gamma-, and delta-subunits in the interaction of curare with the Torpedo acetylcholine receptor (AChR). Curare inhibition of wild-type receptors is consistent with curare binding to a single high-affinity binding site [inhibitor constant (Ki) = 20 nM]. Phenylalanine substitutions for two tyrosine residues implicated as being in the ligand binding site (alpha Y93F, alpha Y190F) reduce curare affinity, indicating that these residues are also important for high-affinity curare binding. Phenylalanine substitution for alpha Y198 [alpha Y198F (notation used here: subunit/amino acid in wild-type/residue number/substitution)] causes a 10-fold increase in curare affinity (Ki = 3.1 nM), and measurement of the recovery from curare inhibition indicates that this increase in affinity is due to a reduction in the rate of curare dissociation from the receptor. In addition to the alpha-subunits, portions of the ligand binding sites also reside on the gamma- and delta-subunits, and photoaffinity studies have implicated two residues (gamma W55 and delta W57) as forming part of the curare sites. The gamma W55L mutation results in an eightfold decrease in curare affinity (Ki = 170 nM), whereas the delta W57L mutation has no effect. These data support the notion that the high-affinity curare binding site is formed by segments of the alpha- and gamma-subunits.(ABSTRACT TRUNCATED AT 250 WORDS)

Synapse elimination from the mouse neuromuscular junction in vitro: a non-Hebbian activity-dependent process

The effect of action potentials on elimination of mouse neuromuscular junctions (NMJ) was studied in a three-compartment cell culture preparation. Axons from superior cervical ganglion or ventral spinal cord neurons in two lateral compartments formed multiple neuromuscular junctions with muscle cells in a central compartment. The loss of synapses over a 2-7-day period was determined by serial electrophysiological recording and a functional assay. Electrical stimulation of axons from one side compartment during this period, using 30-Hz bursts of 2-s duration, repeated at 10-s intervals, caused a significant increase in synapse elimination compared to unstimulated cultures (p < 0.001). The extent of homosynaptic and heterosynaptic elimination was comparable, i.e., of the 226 functional synapses of each type studied, 111 (49%) of the synapses that had been stimulated were eliminated, and 87 (39%) of unstimulated synapses on the same muscle cells were eliminated. Also, simultaneous bilateral stimulation caused significantly greater elimination of synapses than unilateral stimulation (p < 0.005). These observations are contrary to the Hebbian hypothesis of synaptic plasticity. A spatial effect of stimulus-induced synapse elimination was also evident following simultaneous bilateral stimulation. Prior to stimulation, most muscle cells were innervated by axons from both side compartments, but after bilateral stimulation, muscle cells were predominantly unilaterally innervated by axons from the closer compartment. These experiments suggest that synapse elimination at the NMJ is an activity-dependent process, but it does not follow Hebbian or anti-Hebbian rules of synaptic plasticity. Rather, elimination is a consequence of postsynaptic activation and a function of location of the muscle cell relative to the neuron. An interaction between spatial and activity-dependent effects on synapse elimination could help produce optimal refinement of synaptic connections during postnatal development.

Salivatory responses to classical and nontraditional parasympatholytic agents in human subjects: critical comments

Both classical (atropine, scopolamine) and nontraditional (pirenzepine, telenzepine) cholinolytic agents themselves cause no salivation in human subjects. Ordinarily, they block salivation caused by pilocarpine. Conversely, they all stimulate intense salivatory response in the chronically denervated human parotid gland. The author presents critical comments on the concept that cholinolytic agents cause salivation by suppression of the mechanism of presynaptic autoinhibition. An alternative explanation of the initial cholinomimetic effect of cholinolytic agents is suggested.

Neuromuscular transmission to identified primary and secondary myotubes: a reevaluation of polyneuronal innervation patterns in rat embryos

The early morphogenesis of rat skeletal muscle is a biphasic process involving two sequentially generated populations of myotubes. A small population of primary myotubes appears early and is followed by a much larger population of secondary myotubes which appear progressively over a number of days. All previously published electrophysiological studies of developing muscle have failed to appreciate the relevance of biphasic myotube production. Here we reevaluate the status of early motor innervation, taking into account the wide range of sizes and levels of maturity within the two myotube populations. Evoked end-plate potentials (EPPs) were recorded from fibers of E17-20 rat sternocostalis muscles. Impaled fibers were then marked by ejection of HRP from the recording pipet, enabling ultrastructural identification of fibers from which recordings had been made. The average number of synaptic inputs per fiber increased to a peak at E19, and the rate of rise of the EPPs increased with age. The majority of impaled fibers (76%) were subsequently found to be primary myotubes, even at ages when secondary myotubes formed the majority of fibers in the muscle. Electrophysiological studies during early stages of secondary myotube development therefore sample largely from the more mature primary fibers and probably give the wrong impression of the extent and degree of polyneuronal innervation and of synaptic rearrangement within the muscle. In addition, the results show that very young secondary myotubes are distinguished by EPPs of longer latency, slower rate of rise, and smaller size than those of other types of myotubes. These results suggest that young secondary myotubes are predominantly activated by EPPs which originate in adjoining primary myotubes and propagate electronically to the secondary myotube. We propose a new model of early synaptic rearrangement which accommodates the biphasic nature of muscle development. We also suggest that secondary myotubes do not require direct neural input for the initiation of their development.

Pharmacologic evidence for NMDA, APB and kainate/quisqualate retinotectal transmission in the isolated whole tectum of goldfish

The optic tectum of goldfish with intact optic and toral marginal fiber tracts was isolated in a perfusion chamber where the effectiveness of antagonists was tested on synaptic field potential responses to stimulation of each afferent system. There were 3 main conclusions about excitatory synapses. First, monosynaptic activation of retinotectal synapses was not detectably antagonized by D-tubocurarine, implying there is no nicotinic cholinergic component to optic transmission nor strong cholinergic gating of optic terminals. Second, a significant component of retinotectal transmission was shown to be mediated by kainate and quisqualate receptors since 6,7-dinitroquinoxaline-2,3-dione and kynurenate strongly suppressed the optic field potential. In addition, activation of these synapses involves two previously undescribed N-methyl-D-aspartate (NMDA) and APB receptor subtypes since optic field potentials were partially suppressed by 2-amino-5-phosphonovalerate (APV), 2-amino-4-phosphonobutyrate (APB) and MK-801. This is the first evidence that APB receptors exist in the visual system central to the retina. Together, these results are consistent with the possibility that retinal ganglion cells use multiple glutamate receptor subtypes. Third, the optic tectum contains a population of intrinsic glutaminergic synapses activated by a non-optic input, the marginal fibers, which can be suppressed by both APV and kynurenate. The existence of tectal NMDA receptors which are not at primary optic synapses implies that APV used to interfere with rearrangement of optic fibers during development may act not only at afferent synapses but also at a more central component of the circuit.

Autoantibodies bind solubilized calcium channel-omega-conotoxin complexes from small cell lung carcinoma: a diagnostic aid for Lambert-Eaton myasthenic syndrome

Serum autoantibodies found by radioimmunoassay in 27 of 52 patients with the Lambert-Eaton myasthenic syndrome (LES) bound specifically to a soluble omega-conotoxin binding component of a voltage-gated Ca2+ channel (VGCC) complex extracted from small cell lung carcinoma (SCC). These antibodies were not found in 43 control patients with other neurologic diseases, including myasthenia gravis, peripheral neuropathies, and amyotrophic lateral sclerosis, or in 9 patients with endocrine autoimmunity, but they were found in 2 of 21 control patients with SCC without a history of LES, 1 of whom had severe autonomic neuropathy. Seropositivity was more frequent in patients with LES who had evidence of a primary lung cancer (76%) than in those with other neoplasms or without evidence of cancer (30%). Antigens extracted from SCC tumor lines derived from patients with and without LES and from a human neuroblastoma line yielded results that were highly correlated. A control extract of colonic carcinoma (derived from a patient with LES) yielded negative results. The data implicate a tumor-associated VGCC as the autoimmunizing stimulus in a subset of patients with LES and provide the first direct evidence that the VGCC complex in SCC is a target for some LES antibodies. The serologic test described should be a useful aid in diagnosing LES.

Curare binding and the curare-induced subconductance state of the acetylcholine receptor channel

The curare-induced subconductance state of the nicotinic acetylcholine receptor (AChR) of mouse skeletal muscle was examined using the patch-clamp technique. Two mechanisms for the generation of subconductance states were considered. One of these mechanisms entails allosteric induction of a distinct channel conformation through the binding of curare to the agonist binding site. The other mechanism entails the binding of curare to a different site on the protein. Occupation of this site would then limit the flow of ions through the channel. The voltage dependence and concentration dependence of subconductance state kinetics are consistent with curare binding to a site within the channel. The first order rate constant for binding is 1.2 X 10(6) M-1s-1 at 0 mV, and increases e-fold per 118 mV of membrane hyperpolarization. The rate of curare dissociation from this site is 1.9 X 10(2)s-1 at 0 mV, and decreases e-fold per 95 mV hyperpolarization. The equilibrium constant is 1.4 X 10(-4) M at 0 mV, and decreases e-fold per 55 mV hyperpolarization. This voltage dependence suggests that the fraction of the transmembrane potential traversed by curare in binding to this site is 0.46 or 0.23, depending on whether one assumes that one or both charges of curare sense the electric field. Successive reduction and alkylation of the AChR agonist binding sites with dithiothreitol (DTT) and N-ethyl maleimide (NEM), a treatment which results in the loss of responsiveness of the AChR to agonists, produced no change in curare-induced subconductance events, despite the fact that after this treatment most of the channel openings occurred spontaneously. Mixtures of high concentrations of carbamylcholine (CCh) with a low concentration of curare, which produce channel openings gated predominantly by CCH, resulted in subconductance state kinetics similar to those seen in curare alone at the same concentration. Thus displacement by CCh of curare from the agonist binding sites does not prevent curare from inducing subconductances. The results presented here support the hypothesis that curare induces subconductance states by binding to a site on the receptor other than the agonist binding sites, possibly within the channel pore. It is the occupation of this site by curare that limits the flow of ions through an otherwise fully opened channel.

Use of formamide increases the number of detectable inputs to polyneuronally innervated mammalian skeletal muscle

We evaluated the extent of polyneuronal innervation in neonatal rat lateral gastrocnemius muscle with intracellular recording techniques using both formamide and d-tubocurarine as paralytic agents. We detected more polyneuronal innervation during the first postnatal week using formamide than d-tubocurarine. Both the average number of inputs per muscle cell and the percentage of polyinnervated cells were greater when formamide, rather than d-tubocurarine, was used to diminish muscle contraction. The difference in the extent of polyneuronal innervation detected using the two methods declines during the first postnatal week and the number of inputs observed with formamide during the second postnatal week does not differ from that seen with d-tubocurarine.

ACTH modulation of nerve development and regeneration

(1) The availability of short amino acid sequences of the naturally occurring ACTH 1-39 molecule has made it possible to separate the corticotropic characteristics of the parent molecule from its neurotrophic effects. Potent neurotrophic fragments are ACTH 4-10, an analog of ACTH 4-9 (Org 2766), and alpha-MSH (ACTH 1-13), peptide fragments that do not evoke corticosteroid secretion, yet clearly affect both the development and regeneration of peripheral nerve. (2) Early postnatal administration of either ACTH 4-10 or Org 2766 accelerates the neuromuscular development of the immature rat, increasing the contractile strength of the EDL muscle and inducing more rapid muscle contractions. Grasping strength and motor activity are increased; these are all changes indicative of more rapid neuromuscular maturation. Prenatal peptide treatment elicits a more complex pattern of response since administration early in gestation (GD 3-12) accelerates neuromuscular development whereas later administration (GD 13-21) decelerates maturation. (3) ACTH peptides have a similar accelerating effect on the morphology of the developing neuromuscular junction. At two weeks of age, nerve arborization is conspicuously increased by postnatal administration of either ACTH 4-10 or Org 2766, as is nerve terminal branching within the endplate itself. However, this is preceded by an initial depression of nerve branching in the 7-day-old rat pup. We conclude that while the developing neuromuscular system is sensitive to ACTH peptides, this susceptibility is age-related. The crucial role of these peptides may be limited to very brief, defined periods during which the peptides may interact with trophic or growth-associated substances, each of which may have its own decisive, circumscribed time frame of influence. (4) Perinatal administration of ACTH peptides affects CNS development. One measurable indication of this is an acceleration of eye opening. Early exposure to ACTH peptides has long-lasting effects on behavior, apparent when these animals are tested as adults. Increased spontaneous motor activity, heightened states of arousal and agitation, and changes in social behavior have been reported. Certain avoidance responses and tests of visual discrimination in male rats are improved by neonatal treatment with alpha-MSH. Overall motor activity is increased and the normal period of hyperactivity is initiated earlier. Male sexual behavior is decreased and sexually dimorphic behaviors in males are eliminated. alpha-MSH may alter the development of its own dopaminergic feedback circuitry while ACTH affects serotonin levels in the preoptic nucleus.(ABSTRACT TRUNCATED AT 400 WORDS)

Sensitivity to dicholines of membranes from vertebrate and invertebrate muscles

1. The depolarizing effectiveness of azelainylcholine (AzCh, a 7-C-chain dicholine) is about 10 times higher than that of succinylcholine (SCh, a 2-C-chain dicholine) in skeletal muscles of chick, frog and fish, and in body muscles of the earthworm. 2. In the chicken anterior latissimus dorsi (ALD) muscle, AzCh is about 100 times more effective than SCh. 3. In contrast to that in mammalian muscles, the AzCh-SCh sensitivity difference is not increased by denervation in frog muscles. 4. d-Tubocurarine is equally effective in the ALD and in other chicken muscles; its effectiveness is not decreased by denervation in frog muscles. 5. Cells containing muscarinic acetylcholine receptors are weakly sensitive to dicholines or not at all.

Adenosine 5'-triphosphate activates acetylcholine receptor channels in cultured Xenopus myotomal muscle cells

1. Single-channel currents activated by extracellular adenosine 5'-triphosphate (ATP-induced currents) were recorded in cultured muscle cells of Xenopus laevis using the cell-attached patch clamp technique. 2. The amplitude histogram of the ATP-induced currents had two distinct peaks, corresponding to 60 pS (high-conductance (gamma) channels currents) and 41 pS (low-gamma channel currents). The peak values of the currents were unaltered during 1-6 days in culture. 3. The mean open time of the two types of ATP-induced currents was 0.93 ms for high-gamma and 0.86 ms for low-gamma channel currents at 50 mV hyperpolarization. The reversal potential of the ATP-induced current, estimated from the I-V relationship, ranged between -5 and -15 mV. 4. The open-state probability of currents induced by 10 microM-ATP decreased in the presence of 20 microM-d-tubocurarine. 5. The frequency of ATP-induced current events depended upon the ATP concentration. The current events were first detected at 0.1 microM-ATP and occurred with increasing frequency up to 10 microM-ATP. At concentrations higher than 10 microM, the frequency of current events decreased. 6. When acetylcholine (ACh, 0.1 nM) was applied together with various concentrations of ATP, the frequency of current events increased 2- to 3-fold at the ATP concentration range between 0.1 and 10 microM. At higher concentrations of ATP the frequency decreased again. When ACh (0.1 nM) was applied without ATP, current events were rarely observed. 7. Two types of ATP-induced currents were also observed with adenylylimido 5'-diphosphate (AMP-PNP) at one-hundred micromolar concentrations. Neither AMP (adenosine 5'-monophosphate) nor ADP (adenosine 5'-diphosphate) (1-500 microM) induced channel events. 8. It is concluded that the nicotinic ACh receptor channels in cultured Xenopus skeletal muscle cells are opened by micromolar concentrations of exogenous ATP. The possible physiological significance is discussed.

Isolation and characterization of nicotinic acetylcholine receptor-like protein from fetal calf thymus

A nicotinic acetylcholine receptor-like protein (AChR-LP) was isolated from fetal calf thymus by affinity chromatography using cobrotoxin-Sepharose after alkaline extraction and solubilization with Triton X-100. The AChR-LP had a specificity of 1.61 +/- 1.12 nmol of alpha-bungarotoxin binding sites per mg of protein. The isoelectric point, sedimentation coefficient and amino acid composition of the purified AChR-LP were very similar to those of muscle and electric organ AChRs. Upon SDS-polyacrylamide gel electrophoresis purified thymus AChR-LP preparations contained up to 6 polypeptide bands of molecular weights of 40,000, 43,000, 51,000, 56,000, 58,000, and 66,000, respectively. The peptides of 40,000, 51,000, 56,000, and 66,000 dalton cross-reacted with the four subunits of Torpedo californica and fetal calf muscle AChR.

Electrical properties of motoneurons in the spinal cord of rat embryos

Electrical properties of immature motoneurons were studied in vitro using isolated segments of spinal cords of rat embryos aged 14-21 days of gestation. Stable resting potentials and evoked synaptic potentials were recorded for more than 9 hr, indicating that motoneurons remain viable for many hours. Motoneurons are electrically excitable at 14 days of gestation and from the onset of excitability the action potentials are Na+-dependent but slow rising long-duration Ca2+-dependent action potentials can be evoked if K+ conductance is reduced. Thus, during embryonic development the regenerative potential inward current is Na+-and Ca2+-dependent. During motoneurons' differentiation there are some changes in their electrical properties: resting membrane potential increases, input resistance decreases, input capacitance increases, threshold for action potential decreases, and maximum rate of rise of action potential increases. Afferent motoneuron contacts are formed at 16-18 days of gestation when excitatory synaptic potentials can first be evoked in response to dorsal root stimulation. The changes in input capacitance and threshold for action potential occur at the onset of functional afferent motoneuron contacts, but it is not known whether these changes are autonomous or are influenced by the newly formed sensory inputs.

Temperature dependence of contraction characteristics in developing rat muscles

Contractions of rat extensor digitorum longus (EDL, a fast muscle) and soleus (SOL, a slow muscle) muscles of different ages (1-4 weeks) were recorded in vitro with direct stimulation and at different temperatures (range 35-10 degrees C). Twitch tension in 4-week-old EDL muscle increased in cooling from 35 to 20 degrees C (cooling potentiation); the tension decreased in further cooling below 20 degrees C. This pattern of temperature dependence of twitch tension was seen in fast muscles of all ages (1-4 weeks). Twitch tension in 4-week-old SOL muscle decreased monotonically in cooling from 35 to 10 degrees C (cooling depression). This pattern of cooling depression was not clearly evident in younger SOL muscles. There was a marked hysteresis in the temperature dependence of twitch tension in the 1-week-old SOL muscles. Tetanic tension was depressed by low temperature in both EDL and SOL muscles at 1 week and at 4 weeks of age. Results show that the processes concerned with contractile activation are nearly fully developed in the fast muscle fibers at an early age (1 week), whereas they develop later in the slow muscle fibers.

Is atropine a pilocarpine antagonist in cases of eliminated parasympathetic innervation of the human parotid salivary gland?

1 Following denervation of the human parotid salivary gland, pilocarpine caused an intensified stimulant response on salivation and a stimulant effect of atropine on salivary secretion was revealed. However, despite its stimulant effect on salivary secretion, atropine retained its action in blocking the salivatory response to pilocarpine. 2 This dualism in the action of atropine is explained by an action on different muscarinic receptor sub-types, i.e. on some sub-types atropine behaves as an antagonist and on others as an agonist. 3 Under the particular conditions in which the studies were performed, pilocarpine neither prevented nor increased the subsequent paradoxical response to atropine. Moreover, when injected at the peak of the atropine salivatory response it caused neither addition nor synergism to the atropine response. 4 Following the simultaneous injection of both pilocarpine and atropine, atropine initially suppressed the effect of pilocarpine and then itself caused a powerful paradoxical salivation. 5 Pilocarpine injected at the end of the paradoxical secretory response to atropine caused no secretion indicating that atropine retained its antisecretory effect against pilocarpine. 6 The extent of pilocarpine secretory responses is dependent upon the presence or absence of atropine, whilst the atropine effect is independent of the presence of pilocarpine. This points to the presence of differing populations of cholinoreceptors to explain the agonist effects of pilocarpine and atropine.

Domination of a strong antagonist over a weak one in paradoxical responses to cholinolytics in a parasympathetically denervated human salivary parotid gland: atropine and metacine as agonists, and chlorosyle as partial agonist

1. Chlorosyle, a modified asymmetric and somewhat heavier cholinolytic, produces a lower, by its level, paradoxical salivary effect in the human denervated parotid gland than atropine and metacine. 2. When chlorosyle acts in combination with atropine and metacine, the former inhibits the effect of the latter two and only the chlorosyle effect dominates. 3. Using atropine and metacine, which are complete agonists, chlorosyle, in this situation, plays the role of a partial agonist.

Apparent acetylcholine receptor channel conversion at individual rat soleus end-plates in vitro

Miniature end-plate currents (m.e.p.c.s.) were recorded extracellularly from individual fibres in neonatal rat soleus muscles for 2-24 h. In agreement with previous studies, the decay phases of m.e.p.c.s at many end-plates were doubly exponential with time constants of approximately 6 ms and approximately 1.5 ms at 21 degrees C. Earlier studies have shown that doubly exponential decays are due to the combined action of embryonic-type acetylcholine (ACh) receptors (AChRs) with long channel open times and adult-type AChRs with brief open times. When individual end-plates with doubly exponential m.e.p.c.s were studied for several hours or more, the relative size of the slow decay component frequently decreased with time. There was no evidence for a corresponding decrease in total m.e.p.c. amplitude. The time constants of the fast and slow components did not change. M.e.p.c. decays were stable at end-plates that were either very mature (small slow decay component) or very immature (small fast decay component). In these cases, the decay phases were virtually singly exponential and the time constant did not change. These data indicate that at end-plates with a mixture of adult-type and embryonic-type channels, the fraction of adult-type AChRs increases with time. This is similar to what occurs at end-plates developing in vivo. The results of ACh noise analysis experiments support this interpretation.

On stages of postdenervational disturbances in functioning of the human salivary parotid gland (a concise report)

The author presents an original classification of the muscarinic cholinoreceptor subpopulations in the human salivary parotid gland in normal condition or following parasympathetic denervation. The criteria characterizing each stage of the postdenervational syndrome and the general scheme of their occurrence and restoration both reflect the stages of evolutionary transformations in cholinergic receptors. Assessment of salivation rate and volume, observed as the effect of vegetotropic agents, and of electrolyte contents in saliva provide the above scheme of 3 stages of the postdenervational syndrome.

Acetylcholine receptor inhibition by d-tubocurarine involves both a competitive and a noncompetitive binding site as determined by stopped-flow measurements of receptor-controlled ion flux in membrane vesicles

The issue of whether d-tubocurarine, the classical acetylcholine receptor inhibitor, inhibits the receptor by a competitive or noncompetitive mechanism has long been controversial. d-Tubocurarine, in this study, has been found to be both a competitive (KC = 120 nM) and a noncompetitive (KNC = 4 microM) inhibitor of receptor-mediated ion flux at zero transmembrane voltage in membrane vesicles prepared from Electrophorus electricus electroplax. A spectrophotometric stopped-flow method, based on fluorescence quenching of entrapped anthracene-1,5-disulfonic acid by Cs+, was used to measure both the rate coefficient of ion flux prior to receptor inactivation (desensitization) and the rate coefficient of the rapid inactivation process. Inhibition by d-tubocurarine of the initial rate of ion flux decreased with increasing acetylcholine concentration, consistent with competitive inhibition, but the inhibition by micromolar concentrations of d-tubocurarine could not be overcome with saturating concentrations of acetylcholine, consistent with noncompetitive inhibition. A minimum mechanism is proposed in which d-tubocurarine competes for one of the two acetylcholine activating sites and also binds to a noncompetitive site. The present data do not distinguish between one or two competitive sites, although one successfully accounts for all of the data. By variation of the acetylcholine concentration, the two types of sites could be studied in isolation. Binding of d-tubocurarine to the noncompetitive site does not change the rate of rapid receptor inactivation, whereas binding of d-tubocurarine to the competitive site decreases the rate of rapid inactivation by displacing acetylcholine, in agreement with the observation that d-tubocurarine does not inactivate (desensitize) the E. electricus receptor by itself.(ABSTRACT TRUNCATED AT 250 WORDS)

Acetylcholine sensitivity in myotubes of nerve-muscle co-culture cultured with anti-muscle antibodies, alpha-bungarotoxin and D-tubocurarine

The effects of alpha-bungarotoxin (alpha-BuTX), D-tubocurarine (D-TC) and antibodies against muscle extract on acetylcholine (ACh) sensitivity were investigated in developing mouse myotubes in a nerve-muscle co-culture. Antibodies clearly suppressed the ACh potential amplitude in adult mouse diaphragm muscle, but antibodies in muscle pre-treated with D-TC (1 microgram/ml) weakly suppressed it. The addition of D-TC to muscle extract dose-dependently inhibited the formation of the immunoprecipitation lines. The exposure of developing myotubes to antibodies for 10 days in culture suppressed both resting potential and ACh potential, whereas co-existence of alpha-BuTX (1 microgram/ml) or D-TC (0.1 mg/ml) with antibodies suppressed ACh potential but did not affect resting potential compared with antibodies alone. The ACh potentials in myotubes cultured with alpha-BuTX and D-TC alone were also suppressed. The appearance (day 8 in culture) of this suppressive effect by alpha-BuTX was faster than that (day 11 in culture) of D-TC. These different effects depending on the time in culture may account for the conformational change of developing ACh receptors to alpha-BuTX and D-TC.

Acetylcholine receptor activation by a site-selective ligand: nature of brief open and closed states in BC3H-1 cells

Single-channel currents were recorded through acetylcholine receptor channels of clonal BC3H-1 muscle cells activated by the curare-like compound, DMT binds selectively to the two alpha-neurotoxin-binding sites on these receptors, with apparent dissociation constants differing by about 1000-fold (Sine & Taylor, 1981). Receptor channels do not open with DMT bound only to the high-affinity site, but only at DMT concentrations at which both high- and low-affinity sites are occupied. Open-duration histograms are not single exponentials, but are described by the sums of two (or three) exponentials. Both brief- and long-duration openings are observed in the presence of 3 microM-DMT, and are seen at the same relative frequency up to 80 microM-DMT. Long-duration openings are interrupted by brief closures with a mean duration of 50 microseconds and which occur at a frequency of 50-60 per second of open time. These temporal characteristics closely parallel those of the brief closures observed with the full agonists, acetylcholine, carbamylcholine, and suberyldicholine. Raised concentrations of DMT apparently block open channels in a voltage-dependent fashion. It is concluded that both brief- and long-duration openings arise from receptors with two molecules of DMT bound. Furthermore, brief closures in general do not appear to reflect receptor activation processes. Instead, they seem to arise through entry to a closed state with properties independent of the agonist, but characteristic of open channels.

Ca2+-dependent phosphorylation of tyrosine hydroxylase in PC12 cells

Ca2+-dependent protein phosphorylation has been detected in numerous tissues and may mediate some of the effects of hormones and other extracellular stimuli on cell function. In this paper we demonstrate that a Ca2+/calmodulin-dependent protein kinase similar to the enzyme previously purified and characterized from rat brain is present in PC12, a rat pheochromocytoma cell line. We show that Ca2+ influx elicited by various forms of cell stimulation leads to increased 32P incorporation into tyrosine hydroxylase (TH), a major phosphoprotein in these cells. Several other unidentified proteins are either phosphorylated or dephosphorylated as a result of Ca2+ influx. Acetylcholine stimulates TH phosphorylation by activation of nicotinic receptors. K+-induced depolarization stimulates TH phosphorylation in a Ca2+-dependent manner, presumably by opening voltage-dependent Ca2+ channels. Ca2+ influx that results from the direct effects of the ionophore A23187 also leads to TH phosphorylation. Phosphorylation of TH is accompanied by an activation of the enzyme. These Ca2+-dependent effects are independent of cyclic AMP and thus implicate a Ca2+-dependent protein kinase as a mediator of both hormonal and electrical stimulation of PC12 cells.

Potential types of response of the parasympathetic denervated human parotid gland to cholinergic ligands

Investigation of functioning of human parotid salivatory glands, both normal and postdenervated, has demonstrated the presence of 5 main types of salivatory responses to cholinergic agonists and antagonists. Existence of various types of response has indicated the presence of different subpopulations of M-cholinergic structures that interact differently with the agents of cholinergic induction and blockade. Two subtypes function in the norm and they are conditioned by the presence of a double regulation; nervous and humeral. Three additional potential subtypes of response have been revealed only under conditions produced by various degrees of the gland's denervation. The data obtained relate to the nature of multireceptors or receptor states within the M-cholinergic system.

Curare-induced transformation of myosin pattern in developing skeletal muscle fibers

The effects of neuromuscular block on the pattern of distribution of myosin isozymes in developing skeletal muscle fibers was examined by immunocytochemistry. The homogeneous population of fibers in the anterior latissimus dorsi (ALD) of the 18-day chick embryo was converted by curare to a mosaic of at least two categories of fibers. Normally all fibers in this slow muscle reacted with antibodies against slow myosin (anti-ALD). They also reacted with an antibody specific for the alkali 1 light chain (anti-delta 1) but not the alkali 2 light chain (anti-delta 2) of fast myosin. After treatment with curare, which inhibits neuronal cell death and increases the number of axonal endings, ALD muscle fibers continued to react with anti-delta 1, but many now reacted with anti-delta 2 as well. The same fibers failed to react with anti-ALD. From this it can be concluded that the myosin in this population was converted to a type not normally present. The changes, therefore, are not merely a result of the preferential loss of a slow type of fiber, nor are they a result of delayed maturation. In contrast, curare had no apparent effect on the fast posterior latissimus dorsi (PLD). As in the normal muscle at 18 days, all fibers reacted strongly with anti-delta 1 and to variable degrees with anti-delta 2, and very few fibers reacted with anti-ALD. Our observations suggest that the dual response to antibodies against fast and slow myosin during development is not a necessary consequence of multiple axon terminals. We present evidence that curare induces the expression of a different myosin in the embryonic ALD, and we suggest that the selective transformation of the fiber population may be a manifestation of a change in composition of the motoneuron pool.

Acetylcholinesterase is functional in embryonic rat muscle before its accumulation at the sites of nerve-muscle contact

We have examined the expression, the location, and the physiological activity of acetylcholinesterase (AChE) in developing intercostal muscles in the rat. Although focal accumulations of AChE at developing end plates do not appear until Embryonic Day (ED) 16-17, 16 S AChE is present at ED 14. Experiments with permeable and impermeable inhibitors established that prior to focal accumulation most of the 16 S enzyme is on the surface of muscle fibers, where it constitutes the major species. Intracellular recording from developing muscle fibers showed that as early as ED 14, AChE inhibitors prolonged evoked end-plate potentials. We conclude that prior to its focal accumulation, AChE is present on the surface of muscle fibers and is physiologically active. Histochemical staining of the focally accumulated enzyme demonstrated that the enzyme is concentrated both intracellularly and extracellularly at the sites of developing nerve-muscle contacts.

Ligand-induced variations in the reactivity of thio groups of the alpha-subunit of the acetylcholine receptor from Torpedo californica

We have studied alkylation of the acetylcholine receptor by N-[3H]ethylmaleimide ([3H]NEM) under various conditions. The radiolabeled preparations were submitted to sodium dodecyl sulfate-polyacrylamide gel electrophoresis to separate the receptor complex into subunits, and the incorporation of 3H into each type of chain was determined. We found the following: (i) When cysteines of native receptor in intact membranes were reacted with [3H]NEM, only the beta-subunit was labeled; the extent of alkylation did not change significantly if cholinergic effectors were present during this reaction. (ii) When the disulfide bonds of the receptor were reduced with dithiothreitol (DTT), the alpha- and beta-chains were labeled with [3H]NEM. The presence of receptor agonists and competitive antagonists during alkylation significantly altered the labeling patterns. Gallamine and hexamethonium markedly enhanced, while carbamylcholine and decamethonium markedly lessened, labeling of the alpha-subunit. Choline, d-tubocurarine, and alpha-neurotoxin induced small, but significant decreases in alkylation of the alpha-subunit, while procaine had no effect. (iii) When the same ligands were present during the reduction step, subsequent labeling with [3H]NEM produced patterns similar to those described in (ii). We also investigated the effects of gallamine and hexamethonium on reduction of the disulfide bond located near the acetylcholine binding site by using the affinity alkylating reagent (bromoacetyl)choline (BAC). Gallamine (0.1 mM) was able to increase the rate of reduction of this particular disulfide bond 3-fold in comparison to the control. In these experiments, alkylation by BAC blocked 50% of the toxin binding sites. Hexamethonium (1 mM) had a similar effect.(ABSTRACT TRUNCATED AT 250 WORDS)

A patch-clamp study of the partial agonist actions of tubocurarine on rat myotubes

Single channels activated by (+)-tubocurarine (curare) were recorded from rat myotubes using the patch-clamp technique. The agonist-like action of curare does not result from a contaminant molecule, as the same effects were observed with curare purified by high-performance liquid chromatography. A curare-activated channel can adopt two levels of conductance: full (F) or partial (P). The F state has a slope conductance of 40 pS (identical to that of the acetylcholine (ACh)-activated channel) and the P state has a conductance of 13 pS. At low concentrations of agonist (ACh or curare), the distribution of channel open times is biphasic. The briefer channels may result from the binding of a single agonist molecule whereas the longer-lived channels probably occur following the binding of two agonist molecules. The mean open time of the F state decreases with increasing curare concentration. It is shown that band-width limitations are likely to account for only a very small part of this observed reduction. In contrast, the mean open time of the P state is independent of the concentration of curare. A simple interpretation is that the F state is susceptible to channel blockade by curare, whereas the P state is not. The P state preceded the F state almost as often as it followed the F state; it can also be observed separately from the F state. The fraction of events including a P state increases from about 4% in the presence of 1 microM-curare to 30% at 100 microM-curare. This fraction is also increased by hyperpolarization. When the curare concentration is increased, the F-state frequency first increases and then decreases at higher concentration. This frequency is also decreased by hyperpolarization. The decrease in F-state frequency is probably related to channel blockade by curare; it cannot be wholly accounted for by problems associated with limited time resolution. A synthetic analogue of curare, (+)- tubocurine dimethiodide presents an agonist activity similar to that of curare but with a faster closing rate for both F and P states. The various actions of curare are summarized in two possible models where the P state is interpreted as either a partially open channel or a channel which is partially blocked.

Time-resolved photolabeling by the noncompetitive blocker chlorpromazine of the acetylcholine receptor in its transiently open and closed ion channel conformations

A rapid-mixing photolabeling apparatus is developed to resolve the kinetics of association of the noncompetitive channel blocker [3H]chlorpromazine (CPZ) with the membrane-bound acetylcholine (AcCho) receptor from Torpedo marmorata and to photolabel its subunits in the 100-milli-seconds to seconds time range. Rapid mixing of AcCho and [3H]CPZ with the receptor followed by brief (less than 20 msec) UV irradiation results in the selective labeling of the four chains of the AcCho receptor, according to a rapid bimolecular association process close to diffusion-controlled. Rapid association is not observed with the competitive antagonists d-tubocurarine or flaxedil or the snake venom alpha-toxins. Its initial rate increases with agonist concentration, with maxima of 0.6 for carbamoylcholine and 0.2 for phenyltrimethylammonium taking 1 for AcCho, with apparent dissociation constants of 30 microM, 400 microM, and 300 microM for AcCho, carbamoylcholine, and phenyltrimethylammonium, respectively, and with sigmoid shape (Hill coefficients of 1.1-1.3). Under conditions in which the receptor "desensitizes" and the ionic channel closes (preincubation with AcCho), rapid [3H]CPZ association decreases in parallel. It is concluded that the agonist-dependent rapid association of [3H]CPZ takes place at the level of a site common to all five subunits, which lies within the ion channel and becomes accessible when the channel opens.

Chemically activated channels in muscle and spinal cord

The patch clamp can be used to record single chemically activated channel currents in a variety of cell culture preparations. In the case of the gamma-aminobutyric acid (GABA) response in spinal cord cell culture, the channel is Cl - selective. Cl- can be made to flow into or out of a cell by changing the direction of the electrochemical driving force for Cl-; as a result, positive or negative channel currents are produced. Channel currents generated by GABA and the GABA agonists muscimol and pentobarbital have the same amplitude. The kinetics of channel gating are studied by analyzing distributions of dwell times in conducting and nonconducting states. Such analyses of the GABA-activated channel and the acetylcholine-activated channel reveal that gating is complex. More elaborate procedures of data analysis have been used in an attempt to elucidate detailed molecular gating mechanisms.

The appearance and development of chemosensitivity in Rohon-Beard neurones of the Xenopus spinal cord

1. We have examined the onset and subsequent development of chemosensitivity in Rohon-Beard neurones from the Xenopus spinal cord. These cells become sensitive to bath-applied gamma-aminobutyric acid (GABA) around stage 25 (early tailbud, about 1 d old), and remain so at least until stage 49 (9 d old). In contrast, a number of other neurotransmitter candidates tested caused no potential or conductance change during the same period.2. We examined ionophoretic dose-response relations of the cells at stage 26, a couple of hours after the first acquisition of GABA sensitivity. Sensitivities as high as 450 mV/nC were recorded. Comparable sensitivities were recorded between stages 46-49 (5-9 d old).3. Measurements of ionophoretic sensitivities and input resistances during several periods from stage 26 to maturity show that the underlying conductance change for a given GABA dose is likely to increase steadily during this time. A ;sensitivity index' (ionophoretic sensitivity/input resistance) was calculated, which is low at stage 26, higher at intermediate stages (stages 31-42), and highest for mature cells (stages 46-49; 5-9 d of development).4. The reversal potential of the ionophoretic GABA response is the same at stage 26 (-30 mV) as it is in mature cells. Ion substitution experiments show that Na(+) and K(+), but not Cl(-) or Ca(2+), are involved in the response.5. GABA responses at stage 26 are pharmacologically similar to those of mature cells. The responses are blocked by 10 muM-picrotoxin or curare, and muscimol is an agonist in concentrations as low as 1 muM.6. GABA responses at stage 26 desensitize in a manner similar to that seen for mature cells, either with prolonged bath application of GABA or with repetitive ionophoretic application.7. Nearly half of the cells tested at stage 26 respond to glycine, in concentrations as low as 5 muM. This sensitivity is absent by 3(1/2) d of development.8. The responses of Rohon-Beard neurones to GABA are similar to those of other cells in that they involve a conductance increase, are mimicked by muscimol, and are blocked by picrotoxin. These responses are different in that they do not involve Cl(-) and are blocked by low concentrations of curare.9. Many of the characteristics of GABA receptors, i.e. the reversal potential, desensitization, and pharmacology, are constant during development. However, the sensitivity of the cells to GABA and the spectrum of transmitters to which they are sensitive appear to change.

Curare can open and block ionic channels associated with cholinergic receptors

Curare has long been regarded as a typical competitive antagonist of acetylcholine (ACh) at the vertebrate neuromuscular junction. Recently, however, it has been shown that curare can also block the channels opened by ACh at the frog neuromuscular junction as well as on rat and Aplysia neurones; moreover, curare is able to depolarize rat myotubes and thus behaves as an agonist for the cholinergic receptor of this preparation (see ref. 6). Using the single channel recording technique, we have now found that, on rat myotubes, curare can both open and block in the same cell the channels controlled by the cholinergic receptor.

Elimination of polyneuronal innervation in proximal and distal leg muscles of chick embryos

In chick embryo leg muscles, elimination of polyneuronal innervation takes place one to 1.5 days earlier in the thigh muscle m. ambiens than in the foot muscle m. flexor hallucis brevis. Initial formation of synapses takes place 2-3 days earlier in the proximal than the distal muscle, so the length of time synapses have been active may be a factor in the control of elimination of polyneuronal innervation during development.

Development of ganglion cells and their axons in organized cultures of fetal mouse retinal explants

Retinas from 13-15 day fetal mice were explanted alone, with adjacent eyeball tissue, or with nearby superior colliculus explants. The organotypic structure of the retina developed in situ, including photoreceptors, interneurons, plexiform layers, ganglion cells, and an optic fibre layer. Electrophysiologic recordings demonstrated that functional synaptic networks developed resembling bioelectric response patterns seen in situ. Within half-retinas, arrays of optic fibers converged to the optic nerve head; in co-cultures with tectum they could become myelinated. Large bundles of long, naked neurites--1 degree primary retinal fibers--emerged from the explant in the first few days in vitro; these could often be traced back to the optic nerve head and a detailed survey of their properties using horseradish peroxidase (HRP) tracing methods identified tham as ganglion cell axons. When growing upon collagen substrata, 1 degree fibers began to disintegrate during the second week in vitro; however, many 1 degree fibers that grew into superior colliculus explants were maintained for at least 5 weeks in vitro, where they formed elaborate, functional terminal arborizations. In a few cases, 1 degree fibers grew across skeletal muscle fibers and appeared to induce them to contract. A second type of neuritic outgrowth pattern appeared after the first week in vitro: 2 degrees retinal fibers. This was composed of a mixed population of interneuronal neurites; a small percentage was catecholaminergic. Our characterization of the morphologic properties of retinal ganglion cells and their axons in organotypic cultures provides the necessary background to interpret electrophysiologic mapping and neural-specificity analyses of retino-CNS co-cultures. This in vitro model system may have biological relevance to understanding the cues that control the development of the retinotectal projection in situ.