UMLS:C0027960 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: UMLS:C0027960 (mole)
21,279 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. In chick ciliary ganglia and irises, cholineacetyltransferase (ChAc) and acetylcholinesterase (AChE) activities were measured from the fifth day of incubation until 1 week after hatching. The changes in enzyme activity were correlated in time with previous electrophysiological and morphological findings of synapse formation in these tissues. 2. At Stage 26 (Hamburger & Hamilton, 1951; before synapse formation in the ganglia) low activities of ChAc (12 +/- 4 [mean +/- S.E.] p-mole of ACh synthesized/hr) were measured in the iris nerve terminals, indicating that ganglion cells are biochemically differentiated, immediately after cell migration is completed. The specific acitivities of ChAc and AChE rose during development and these increases were closely related to the onset and maturation of ganglionic and iris synaptic transmission. These increases in enzyme activities can be used in cholinergic synapses as an index of synapse formation. 3. The 200-fold specific increase of ChAc in iris nerve terminals which occurs at Stage 34 probably reflects an increase in synthesis of the enzyme in ganglion cells and suggests that the formation of the iris neuromuscular junction triggers the enzyme induction. It is implied that the cell responds to a signal ascending the axon from the terminal. 4. The initial increase of AChE specific activity in the ganglion occurs after transmission is established in all cells between Stage 30 and 34 and is mainly due to enzyme synthesis by the ganglion cells. In the iris there is a twofold increase in specific activity after the formation of neuromuscular junctions which probably reflects enzyme induction in the muscle subneural region. It is concluded that the specific induction of AChE in post-junctional cells is due to an influence of the prejunctional element. 5. During synaptic formation in the ciliary ganglion, reciprocal interactions between the neurones and their targets result in the induction of ChAc in the prejunctional elements and AChE in the post-junctional cells.
...
PMID:Induction of cholinergic enzymes in chick ciliary ganglion and iris muscle cells during synapse formation. 18 63

1. Membrane potential changes produced by adenosine and adenine nucleotides, acetylcholine, and vagus nerve stimulation were studied by intracellular recording in the sinus venosus of the frog, Rana pipiens. 2. Acetylcholine (ACh) released from the vagus nerve terminals evoked a slow hyperpolarization lasting several seconds in the cells of the sinus. Ionophoretic application of ACh from a micropipette produced a response which is similar in time course and amplitude to that evoked by vagus nerve stimulation. Bath application of ACh caused a steady hyperpolarization in quiescent preparations, or cessation of action potential generation in spontaneously active preparations. 3. Adenosine and adenine nucleotides produced hyperpolarizations when applied by addition to the bath or by ionophoresis from micropipettes. The hyperpolarization produced by ionophoresis of adenine compounds was somewhat slower than that produced by ACh. 4. Adenosine and the adenine nucleotides, 5'-AMP, 3'-AMP, 2'-AMP, and 5'-atp were virtually equipotent in their action. Adenosine was at least 1000-fold more potent than other purine and pyrimidine nucleosides or adenine. Both the ribose and adenine groups were important for agonist activity. 5. The concentrations of agonist required to produce half-maximal responses were estimated from dose--response curves as 3 x 10(-7) M for ACh and 2 x 10(-6) M for ATP. ACh is about 7 times more potent than ATP in producing a hyperpolarization. 6. Adenine compounds act directly upon the cardiac muscle fibres: bath or ionophoretically applied adenine compounds act even when transmitter release from nerve terminals is blocked with high (Mn2+) or when ACh receptors are blocked with atropine. 7. Adenine compounds act on the surface of the muscle fibre membrane. Analogues of adenosine which do not enter the cell are potent agonists of the receptor. An adenyl oligonucleotide too large to enter the cell was 2.6 times more potent per mole than adenosine in producing a hyperpolarization. Drugs such as dipyridamole and 6-(2-hydroxy 5-nitrobenzyl) thioguanosine, which are potent blockers of adenosine transport, potentiate the response of the sinus cells to adenosine. 8. Aminophylline and theophylline are competitive antagonists of adenosine action. The apparent Ki for aminophylline inhibition was 5 microM. 9. The response produced by adenine compounds is partly caused by an increase in the permeability of the membrane to K+. The maximum response to both ACh and adenine nucleotides approached the estimated level of EK or ECl. Replacing extracellular chloride with impermeant isethionate had no effect on responses to ACh or adenine nucleotides. The hyperpolarization was not produced by an activation of an ouabain-sensitive pump since 20 microM-ouabain had little effect on the response to adenosine. 10. The response to vagus nerve stimulation is completely blocked by 50 nM-atropine...
...
PMID:Adenosine receptors in frog sinus venosus: slow inhibitory potentials produced by adenine compounds and acetylcholine. 31 61

Curarized and non-curarized rat hemidiaphragm muscles were indirectly stimulated in vitro. 2. The fluid bathing the active curarized muscles was eluted through a dextran gel (Sephadex G-10), effecting a complete separation of ACh from curare. The acetylcholine fraction was then assayed on an isometric leech muscle preparation. 3. Prostaglandin (PGE1) in a concentration fifteen times that estimated to be released from the skeletal muscle preparation did not affect the response of leech muscle to ACh. 4. The amount of ACh released by curarized muscles (4-9 X 10(-18) mole/impulse-junction) was not significantly different from that released by non-curarized muscles (4-6 X 10(-18) mole/impulse-junction). These quantities are similar to those obtained by previous workers. It is concluded that curare in a paralytic dose does not affect the output of ACh from motor nerve terminals stimulated at low frequencies. 5. Spontaneous release of ACh from non-curarized muscles was estimated at 0-45-0-65 p-mole/min. hemidiaphragm. It is calculated that only 2% of this amount could give rise to post-synaptic electrical events, the remainder having a non-synaptic source. 6. The number of molecules of 'quantal' ACh released by stimulated muscle is calculated as 2-5 X 10(6)/impulse-junction, taking account of the non-synaptic release. The number of ACh molecules in one quantum was estimated to be 6250, an amount that could be easily accommodated in one synaptic vesicle.
...
PMID:The effect of curare on the release of acetylcholine from mammalian motor nerve terminals and an estimate of quantum content. 118 11

Tris+/Na+ permeability ratios were measured from shifts in the biionic reversal potentials of the macroscopic ACh-induced currents for 3 wild-type (WT), 1 hybrid, 2 subunit-deficient, and 25 mutant nicotinic receptors expressed in Xenopus oocytes. At two positions near the putative intracellular end of M2, 2' (alpha Thr244, beta Gly255, gamma Thr253, delta Ser258) and -1', point mutations reduced the relative Tris+ permeability of the mouse receptor as much as threefold. Comparable mutations at several other positions had no effects on relative Tris+ permeability. Mutations in delta had a greater effect on relative Tris+ permeability than did comparable mutations in gamma; omission of the mouse delta subunit (delta 0 receptor) or replacement of mouse delta with Xenopus delta dramatically reduced relative Tris+ permeability. The WT mouse muscle receptor (alpha beta gamma delta) had a higher relative permeability to Tris+ than the wild-type Torpedo receptor. Analysis of the data show that (a) changes in the Tris+/Na+ permeability ratio produced by mutations correlate better with the hydrophobicity of the amino acid residues in M2 than with their volume; and (b) the mole-fraction dependence of the reversal potential in mixed Na+/Tris+ solutions is approximately consistent with the Goldman-Hodgkin-Katz voltage equation. The results suggest that the main ion selectivity filter for large monovalent cations in the ACh receptor channel is the region delimited by positions -1' and 2' near the intracellular end of the M2 helix.
...
PMID:Tris+/Na+ permeability ratios of nicotinic acetylcholine receptors are reduced by mutations near the intracellular end of the M2 region. 159 78

1. In order to determine the stoichiometry of K+ uptake and ATP consumption by Na+, K(+)-ATPase in the isolated, perfused mandibular gland of the rat, oxygen consumption and net K+ uptake from the vascular side were measured during the recovery period following K+ depletion by stimulation with acetylcholine in combination with ouabain. 2. Acetylcholine (10(-6) M) induced fluid secretion and an initial, transient release of K+ from the gland. Addition of ouabain suppressed salivary fluid secretion and caused an additional, dose-dependent, transient release of K+. 3. With acetylcholine (10(-6) M), the oxygen consumption of the gland increased to 62.4 +/- 4.2 microliters/(g min) from a resting value of 12.9 +/- 1.2 microliters/(g min). The increased oxygen consumption was suppressed by ouabain, in a dose-dependent fashion. 4. Withdrawal of acetylcholine and ouabain induced a net uptake of K+ and, simultaneously, an increase in oxygen consumption. The cumulative K+ uptake and the increment of oxygen consumption during the recovery period were dependent on the concentration of used ouabain. 5. The rates of K+ uptake and ATP hydrolysis were compared during recovery, assuming that six moles of ATP were hydrolysed for each mole of oxygen consumed. The data obtained during the later phase of the recovery lay on a single straight line with a slope of 1.8 for each of the various concentrations of ouabain, suggesting that the relationship between K+ uptake and energy consumption was linear. 6. Assuming the K+:ATP stoichiometry of the Na+, K(+)-ATPase to be 2:1, K+ would appear to be transported with ca 90% efficiency by Na+, K(+)-ATPase in the rat mandibular gland. Using 1.8-2.0 as a K+/ATP stoichiometry, the rate of primary active K+ uptake and the corresponding passive K+ efflux during secretion were estimated to be 20-22 mumol/(g min) from the oxygen consumption and the net K+ flux. 7. The passive K+ efflux was estimated, from the initial rate of K+ release caused by addition of 10(-3) M-ouabain, to be 30 mumol/g min). The discrepancy between the estimated active K+ uptake and passive K+ release (8-10 mumol/(g min] could be attributed to a secondary active K+ uptake process such as Na(+)-K(+)-2Cl-symport.
...
PMID:Oxygen consumption for K+ uptake during post-stimulatory activation of Na+, K(+)-ATPase in perfused rat mandibular gland. 217 14

1. Segments of rat diaphragms were kept in choline-free media for 4 hr and were then exposed to a physiological concentration of [(14)C]-choline (30 muM) at 37 degrees C. The synthesis, storage and subsequent release of [(14)C]acetylcholine by the muscles was assessed by isotopic- and bio-assays after isolation of the transmitter by paper electrophoresis.2. Replacement of endogenous acetylcholine (0.92 mu-mole/kg) with labelled acetylcholine proceeded slowly at rest, but rapidly during nerve stimulation. [(14)C]Acetylcholine accumulated most rapidly when hydrolysis of the released transmitter, and thus the re-use of endogenous choline, was prevented by an esterase inhibitor. Fully replaced stores were maintained during nerve stimulation by synthesis rates sufficient to replenish at least 35% of the store size in 5 min.3 In the presence of hemicholinium-3, which inhibits choline uptake, acetylcholine stores declined rapidly during stimulation, and residual synthesis was slight, indicating little intraneural choline. Net choline uptake into nerve terminals was estimated from the highest observed synthesis rate and from previous measurements of the number and size of terminals, as 3-6 p-mole/cm(2) sec.4. Transmitter synthesis was localized in the region of end-plates, and was reduced to a few per cent of normal 6 weeks after phrenic nerve section. Release experiments suggested that at least half of the acetylcholine in phrenic nerves is in their terminals; from this content and the morphology of the terminals, the average concentration of transmitter in the whole endings would appear to be about 50 m-mole/l. Homogenization of the muscles freed choline acetyltransferase into solution, but left some [(14)C]acetylcholine associated with small particles, presumably synaptic vesicles.5. Resting transmitter release was about 0.013% of stores/sec. With 360 nerve impulses at 1-20/sec, release increased up to 0.43% of stores/sec, and amounted to 3.5-7 x 10(-18) moles per end-plate per impulse. The release rate was unaffected by the doubling of store size which occurred with eserine, but the extra transmitter did help to maintain releasable stores during prolonged stimulation. Experiments with fractional store labelling indicated that newly synthesized acetylcholine was preferentially released.6. Preformed [(3)H]acetylcholine was not taken up and retained by muscle or nerve cells in the absence of an esterase inhibitor. With eserine present, labelled acetylcholine was taken up uniformly by muscle segments; when eserine was then removed, radioactive acetylcholine remained only near neuromuscular junctions.
...
PMID:Synthesis, storage and release of [14C]acetylcholine in isolated rat diaphragm muscles. 549 53

1. A study has been made of the oxygen consumption of non-myelinated nerve fibres of rabbit desheathed cervical vagus nerves at rest and during activity.2. The average resting oxygen consumption (Q(r)) was 0.0924 mumole/g. min at 21 degrees C. Stimulation for 1-3 min at 3/sec caused an extra oxygen consumption (Q(s)) of 816 p-mole/g.shock.3. When the frequency of stimulation was increased, to 10/sec and 30/sec, Q(s) fell. When the frequency was decreased, to 1/sec and 0.3/sec, Q(s) increased slightly.4. When the temperature was decreased, Q(r) fell; when the temperature was increased, Q(s) also increased. Temperature similarly affected Q(s) with high frequencies of stimulation, but had relatively little effect on Q(s) at low frequencies of stimulation.5. An isolated single shock seemed to produce an increase in oxygen consumption of about 1200 p-mole/g, and this value was largely independent of temperature.6. When part of the sodium in the Locke solution was replaced by barium, Q(r) decreased (by 12%) whereas Q(s) increased (by 87%).7. Veratrine (1 mug/ml.) increased both Q(r) (by 142%) and Q(s) (by 361%).8. Acetylcholine (1.7 mM) increased Q(r) (by 32%).9. When nerves were transferred to potassium-free solutions there was little change in Q(r), and Q(s) fell slightly (by 8%).10. When the potassium concentration in the Locke solution was increased 4-fold, Q(r) increased (by 27%).11. Salicylate (1-10 mM) increased Q(r) (by 24%) and abolished Q(s).12. When the sodium of Locke solution was replaced by lithium, Q(r) decreased (by 19%) and Q(s) was abolished.13. In sodium-Locke solution ouabain (100 muM) decreased Q(r) (by 26%) and abolished Q(s). In lithium-Locke solution ouabain also decreased Q(r) (by 28%).14. All or nearly all of the oxygen consumed at rest or during activity seemed to be used to pump potassium ions into, and sodium ions out of, the axoplasm.15. The K/O(2) ratio during pumping was about 5.0.
...
PMID:The oxygen consumption of mammalian non-myelinated nerve fibres at rest and during activity. 603 3

1. Noradrenaline release and radioligand binding studies were carried out in the cat hypogastric nerve ligated in vito 2 cm distal to the inferior mesenteric ganglion for different time periods, and in different effector organs.2. Large quantities of noradrenaline and dopamine beta-hydroxylase (DBH) accumulated in the segments of nerve immediately proximal (P(1)) and distal (D(1)) to the ligation, with rates of about 100 and 25 mm/24 hr for the orthograde and retrograde transport, respectively.3. Nicotine evoked the release of noradrenaline from P(1) and atrial slices; the secretory response to nicotine was completely antagonized by mecamylamine. [(3)H]alpha-bungarotoxin biding to membranes from P(1) allowed the estimation of a K(D) of 2.97 nm and a B(max) of 1639 f-mole/mg protein.4. Acetylcholine inhibited the release of endogenous noradrenaline evoked by high K(+) stimulation in atrial slices, but not in P(1) segments. Similarly, carbachol decreased [(3)H]noradrenaline release induced by electrical stimulation (twenty-six shocks, 2 Hz, 5 msec) in the atrium but not in P(1).5. [(3)H]Quinuclydinilbenzylate ([(3)H]QNB) specifically binds to membranes from P(1) and vas deferens, following a saturation curve. In the case of P(1) segments taken 48 hr after ligation a K(D) of 0.35 nm and a B(max) of 129 f-mole/mg protein were found.6. The fact that the B(max) in P(1) and D(1) increased with the time of ligation suggests that orthograde and retrograde axonal transports of muscarinic binding sites exist in this nerve, with approximate rates of transport of 15 and 8 mm/24 hr, respectively.7. As far as adrenoceptors are concerned, we observed that yohimbine or phentholamine did not modify transmitter release from P(1), evoked by high K(+) or electrical stimulation. However, yohimbine enhanced the release of [(3)H]noradrenaline induced by electrical stimulation from splenic slices of the same animals.8. [(3)H]Clonidine, [(3)H]dihydroergocryptine or [(3)H]dihydroalprenolol ([(3)H]DHA) did not specifically bind to membranes from P(1), in spite of the fact that they showed typical saturation curves for specific binding in cortex and atrial membranes from the same cats.9. In conclusion, these data (a) further show that the ligated hypogastric nerve is a good model of noradrenergic nerve terminal free of effector cell; (b) provide direct evidence for the neural location of nicotinic receptors whose activation trigger noradrenaline release from noradrenergic neurones; (c) demonstrate the neural location and axonal transport of muscarinic receptor sites, but leave certain doubts about its functional role in this noradrenergic neurone; and (d) do not support the hypothesis that alpha and beta-adrenoceptors which modulate noradrenaline release from peripheral noradrenergic nerve terminals are neurally (or prejunctionally) located.
...
PMID:Presence and axonal transport of cholinoceptor, but not adrenoceptor sites on a cat noradrenergic neurone. 618 90

Simultaneous studies on the secretory response of amylase and the neurotransmitter receptors of rat parotid gland, after brief treatment with agonists, showed selective alteration in beta-adrenoceptors with specific change in amylase secretion, suggesting a regulatory role of the receptors in the secretory response. The beta-adrenergic agonist (+/-)-isoprenaline (IPR) stimulated amylase secretion from rat parotid tissues much more than did the same concentration of an alpha-adrenergic or cholinergic agonist. The stimulatory effects of IPR were studied by pre-treating rat parotid tissues with IPR for 10 min and then incubating the tissue in fresh medium for 10 min. Pre-treatment with 10 microM-IPR for 10 min resulted in increased amylase secretion during further incubation with IPR and also in a lower EC50 value of amylase secretion for IPR. This treatment also resulted in selective changes in the number and affinity of beta-adrenoceptors, assessed by measuring binding of [3H]dihydroalprenolol (DHA): the maximal binding sites increased from 286/357 f-mole to mg protein and the IC50 value (the concentration for 50% inhibition of specific [3H]DHA binding) of beta-agonists, not antagonists, decreased significantly. An increase in the period of pre-treatment with IPR to 30 min resulted in a decrease in the maximal binding sites of beta-adrenoceptors and a decrease in amylase secretion during further incubation with IPR. Experiments with other agonists showed that supersensitivity of the secretory response was induced specifically by beta-agonists. Binding studies with [3H]WB-4101 and [3H]quinuclidinyl benzilate showed that alpha-adrenoceptors and muscarinic ACh receptors in rat parotid did not change under the conditions tested. The alteration in beta-adrenoceptors was parallel with a change in amylase secretion after IPR pre-treatment, but not with a change in cyclic AMP content.
...
PMID:beta-Adrenoceptor alterations coupled with secretory response in rat parotid tissue. 619 86

Acetylcholine receptors of fish electric organs and mammalian skeletal muscle comprise four structurally homologous glycoprotein subunits in the mole ratio alpha 2 beta gamma delta (refs 1-4). All four subunits have leader sequences and are exposed on both sides of the membrane. From amino acid sequencing, three groups have predicted that each subunit has four hydrophobic alpha-helical transmembranous domains. Because the N-terminus of each subunit is thought to remain on the extracellular surface after cleavage of the leader sequence, this model predicts that the N- and C- termini are both on the extracellular side. An alternative model proposed by two other groups predicts that there is, in addition, a fifth amphipathic transmembranous domain which would place the C-terminus on the cytoplasmic side. Here, using anti-subunit sera and monoclonal antibodies and their reaction with synthetic subunit peptides, we demonstrate that the C-terminus is in fact on the cytoplasmic surface. We also show that, contrary to other predictions, the most hydrophilic sequence on the extracellular domain of alpha-subunits is not the main immunogenic region.
...
PMID:Immunochemical tests of acetylcholine receptor subunit models. 620 39

1 2 Next >>