Acetylcholine receptors in normal and denervated rat diaphragm muscle. I. Purification and interaction with [125I]-alpha-bungarotoxin.

Acetylcholine receptors have been purified from junctional regions of normal rat diaphragm muscle and from extrajunctional regions of denervated diaphragm. The reaction of purified receptors with [122I]-alpha-bungarotoxin has been investigated by kinetic methods. The toxin-receptor complexes dissociated in a biphasic manner at 35 degrees with a rapidly dissociating component (t1/2 = 4 hr) and a slowly dissociating component (t1/2 is greater than or equal to 100 hr). The association reaction between toxin and receptor did not obey simple second-order kinetics but could be analyzed in terms of two classes of binding sites corresponding to the two rates of dissociation. This treatment of the data allowed derivation of association rate constants for the two sites. Value obtained for the dissociation constants were 3.7 times 10(-10) and less than or equal to 0.4 times 10(-10) M for the junctional receptor and 1.7 times 10(-10) and is less than or equal to 0.2 times 10(-10) M for the extrajunctional receptor. In each case it is the more tightly binding component that associates and dissociates more slowly. Receptors present in crude preparations were comparable to purified receptors in their reaction with [125I-alpha-bungarotoxin. The validity of the two site model is discussed in relation to the kinetic studies.     

Subunit structure and peptide mapping of junctional and extrajunctional acetylcholine receptors from rat muscle.

We have purified the junctional acetylcholine receptor from normal rat skeletal muscle and compared its structure with that of the extrajunctional receptor from denervated muscle. The two receptors from leg muscle were distinguished by isoelectric focusing and by reaction with sera from patients with myasthenia gravis. The junctional form of the acetylcholine receptor was purified from normal leg muscle by affinity chromatography on concanavalin A/Sepharose and cobrotoxin/Sepharose followed by sucrose gradient centrifugation. Analysis of radioiodinated receptor by polyacrylamide gel electrophoresis in sodium dodecyl sulfate indicated that the subunit structure of the junctional receptor was similar to that previously determined for the extra-junctional form (Froehner, S. C., et al. (1977) J. Biol. Chem. 252, 8589-8596), with major polypeptides, whose apparent molecular weights in 9% polyacrylamide gels were 45 000 and 51 000. In addition, several minor polypeptides were found. When the two receptors were labeled with different isotopes of iodine and run together on a sodium dodecyl sulfate gel, the subunits of one receptor could not be resolved from those of the other. As seen earlier with the extrajunctional form, the affinity alkylating reagent [3H]MBTA labeled the 45 000- and 49 000-dalton polypeptides of the junctional receptor. Peptide mapping showed that the two MBTA binding subunits are structurally related, although they are unrelated to the other polypeptides, and that the 45 000- and 51 000-dalton polypeptides of the junctional receptor were indistinguishable from those of the extrajunctional receptor. In addition, peptide mapping of the four subunits of acetylcholine receptor isolated from Torpedo californica electric organ showed that these four polypeptides appear to be structurally unrelated.     

Acetylcholine Receptors : Distribution and extrajunctional density in rat diaphragm after denervation correlated with acetylcholine sensitivity

Using ¹²⁵iodine-labeled α-bungarotoxin (α-BGT-¹²⁵I) and quantitative radioautography, we have studied the time-course of the change in acetylcholine (ACh) receptor distribution and density occurring in rat diaphragm after denervation. In innervated fibers, ACh receptors are localized at the neuromuscular junction and the extrajunctional receptor density is less than five receptors per square micrometer. The extrajunctional receptor density begins to increase between 2 and 3 days after denervation and increases approximately linearly to 1695 receptors/µm² at 14 days, subsequently decreasing to 529 receptors/µm² at 45 days. We have isolated plasma membranes from rat leg muscles at various times after denervation and find that the change in concentration of ACh receptors in the membranes measured by α-BGT-¹²⁵I binding and scintillation counting follows a time-course similar to the change in ACh receptor density measured radioautographically. Furthermore, we have correlated extrajunctional ACh receptor density measured by radioautography with extrajunctional ACh sensitivity measured by iontophoretic application of ACh and intracellular recording and find that the log of ACh receptor density is related to 0.53 times the log of ACh sensitivity. These results are discussed in terms of the electrophysiological experiments on the ACh receptor and the recent, more biochemical approaches to the study of ACh receptor control and function.     

Cyclic AMP stabilizes the degradation of original junctional acetylcholine receptors in denervated muscle.

We used mouse diaphragm muscle in organ culture to study the stabilization of acetylcholine receptor (AChR) degradation at denervated neuromuscular junctions. After denervation, the degradation rate of the AChRs present prior to denervation (slowly degrading, or Rs, AChRs) accelerates from the predenervation degradation half-life (t1/2) of approximately 8-10 days to a t1/2 of approximately 2-3 days. We report that addition to the organ culture medium of pharmacological agents that elevate cytoplasmic cAMP levels (forskolin, dibutyryl cAMP, and 8-bromo-cAMP) reversed the change in t1/2 caused by denervation, whereas addition of 1,9-dideoxyforskolin, a forskolin analog that does not elevate cytoplasmic cAMP levels, did not reverse the effect of denervation. The degradation rate of AChRs in primary myotube cultures and that of the newly synthesized AChRs in denervated muscle were little affected by forskolin or dibutyryl cAMP. The possibility is raised that the modulation of Rs AChR degradation by innervation may be mediated by cAMP.     

Autoradiographic visualization of beta-adrenergic receptors in normal and denervated skeletal muscle.

Autoradiographic localization of beta-adrenergic receptors in rat skeletal muscle in vivo was achieved utilizing [125I]-iodohydroxybenzylpindolol, a potent beta-adrenergic blocker with high affinity and specificity for those receptors. In normal muscle the beta-adrenergic receptors were localized mainly to blood vessels, arterioles greater than venules, with much less concentration of grains over the fascicles of muscle fibers. One week after denervation there was an increase in binding both to blood vessels and muscle fibers, more so in soleus and gactrocnemius than in extensor digitorum longus. While these results parallel in vitro biochemical studies, they dictate caution when inferring cellular localization of beta-adrenergic receptors (and other molecules) solely on the basis of biochemical techniques applied to subcellular fractions of whole-organ homogenates.     

Characteristics of sarcoplasmic reticulum from normal and denervated rat skeletal muscle.

Denervation of rat skeletal muscle produces after 14 days a decrease in Ca2+ uptake of a heterogeneous population of sarcoplasmic-reticulum vesicles, when measured in the presence of oxalate. The Mg2+-dependent ATPase (Ca2+-independent) activity increased after the same period and the Ca2+ + Mg2+-dependent ATPase activity decreased. Concomitant with these changes, there was an increase in vesicle size and calcium content. The observations are discussed in terms of changes in altered membrane structure, manifested in the shift of the equilibrium of the ATPase from an enzyme involved in calcium transport to a phosphoenzyme giving rise to an increase in the Mg2+-dependent ATPase activity.     

Cell accumulation in the junctional region of denervated muscle

If skeletal muscles are denervated, the number of mononucleated cells in the connective tissue between muscle fibers increases. Since interstitial cells might remodel extracellular matrix, and since extracellular matrix in nerve and muscle plays a direct role in reinnervation of the sites of the original neuromuscular junctions, we sought to determine whether interstitial cell accumulation differs between junctional and extrajunctional regions of denervated muscle. We found in muscles from frog and rat that the increase in interstitial cell number was severalfold (14-fold for frog, sevenfold for rat) greater in the vicinity of junctional sites than in extrajunctional regions. Characteristics of the response at the junctional sites of frog muscles are as follows. During chronic denervation, the accumulation of interstitial cells begins within 1 wk and it is maximal by 3 wk. Reinnervation 1-2 wk after nerve damage prevents the maximal accumulation. Processes of the cells form a multilayered veil around muscle fibers but make little, if any, contact with the muscle cell or its basal lamina sheath. The results of additional experiments indicate that the accumulated cells do not originate from terminal Schwann cells or from muscle satellite cells. Most likely the cells are derived from fibroblasts that normally occupy the space between muscle fibers and are known to make and degrade extracellular matrix components.     

Satellite cells on isolated myofibers from normal and denervated adult rat muscle.

Satellite cells (SCs) in normal adult muscle are quiescent. They can enter the mitotic program when stimulated with growth factors such as basic FGF. Short-term denervation stimulates SC to enter the mitotic cycle in vivo, whereas long-term denervation depletes the SC pool. The molecular basis for the neural influence on SCs has not been established. We studied the phenotype and the proliferative capacity of SCs from muscle that had been denervated before being cultured in vitro. The expression of PCNA, myogenin, and muscle (M)-cadherin in SCs of normal and denervated muscle fibers was examined at the single-cell level by immunolabeling in a culture system of isolated rat muscle fibers with attached SCs. Immediately after plating (Day 0), neither PCNA nor myogenin was present on normal muscle fibers, but we detected an average of 0.5 M-cadherin(+) SCs per muscle fiber. The number of these M-cadherin(+) cells (which are negative for PCNA and myogenin) increased over the time course examined. A larger fraction of cells negative for M-cadherin underwent mitosis and expressed PCNA, followed by myogenin. The kinetics of SCs from muscle fibers denervated for 4 days before culturing were similar to those of normal controls. Denervation from 1 to 32 weeks before plating, however, suppressed PCNA and myogenin expression almost completely. The fraction of M-cadherin(+) (PCNA(-)/myogenin(-)) SCs was decreased after 1 week of denervation, increased above normal after denervation for 4 or 8 weeks, and decreased again after denervation for 16 or 32 weeks. We suggest that the M-cadherin(+) cells are nondividing SCs because they co-express neither PCNA or myogenin, whereas the cells positive for PCNA or myogenin (and negative for M-cadherin) have entered the mitotic cycle. SCs from denervated muscle were different from normal controls when denervated for 1 week or longer. The effect of denervation on the phenotypic modulation of SCs includes resistance to recruitment into the mitotic cycle under the conditions studied here and a robust extension of the nonproliferative compartment. These characteristics of SCs deprived of neural influence may account for the failure of denervated muscle to fully regenerate. (J Histochem Cytochem 47:1375-1383, 1999)     

Evidence for active chloride accumulation in normal and denervated rat lumbrical muscle

Intracellular Cl- activity (aiCl) was measured with Cl(-)-sensitive microelectrodes in normal and denervated rat lumbrical muscle. In normal muscle bathed in normal Krebs solution, aiCl lay close to that predicted by the Nernst equation. The addition of 9-anthracene carboxylic acid, which blocks Cl- conductance, caused aiCl to increase far above that predicted by a passive distribution. Furosemide (10 microM) reversibly blocked this accumulation. After muscle denervation, aiCl progressively increased for 1-2 wk. The rise occurred in two stages. The initial stage (1-3 d after denervation) reflected passive Cl- accumulation owing to membrane depolarization. At later times, aiCl continued to increase, with no further change in membrane potential, which suggests an active uptake mechanism. This rise approximately coincided with the natural reduction in membrane conductance to Cl- that occurs several days after denervation. Na+ replacement, K+ replacement, and furosemide each reversibly blocked the active Cl- accumulation in denervated muscle. Quantitative estimates suggested that there was little difference between Cl- flux rates in normal and denervated muscles. The results can be explained by assuming that, in normal muscle, an active accumulation mechanism operates, but that Cl- lies close to equilibrium owing to the high membrane conductance to Cl-. The rise in aiCl after denervation can be accounted for by the membrane depolarization, the reduction in membrane Cl- conductance, and the nearly unaltered action of an inwardly directed Cl- "pump."     

Acetylcholine receptors of rat lymphocytes

The conditions of the binding of acetylcholine have been studied in lymphocytes isolated from rat peripheral lymph nodes. Acetylcholine appeared to penetrate the lymphocyte membrane. We have confirmed the presence of muscarinic receptors, which, however, are not involved in transport of acetylcholine through the membrane. The receptors of the nicotine type on lymphocytes are demonstrated by the decrease of acetylcholine binding in the presence of a specific antagonist, tubocurarine. These nicotinic receptors may be involved in acetylcholine transport into the cells.     

Comparison of some metabolic parameters in the perfused and the incubated rat diaphragm muscle with diaphragm muscle in vivo

1. A method is described for perfusing the rat diaphragm muscle. 2. The following parameters were compared in both perfused and non-perfused incubated preparations: water content, sorbitol space, rate of lactate production, and the concentrations of tissue glucose, pyruvate, lactate, hexose phosphate intermediates, ATP and AMP. No significant differences were found. 3. Significant differences, however, were found on comparison of the tissue kept in vitro with the tissue in vivo. Immediately after removal of the tissue from the animal, the concentrations of the hexose phosphates and ATP were found to be much higher than after incubation or perfusion, and the concentrations of free glucose and of AMP were much lower, possibly indicating that the capacity for oxidative phosphorylation of glucose is impaired in vitro because of hypoxia.