Dopamine, noradrenaline and isoprenaline: secretory and electrophysiological effects in vitro on mouse pancreas.
(12/18)
The amylase release from mouse pancreatic fragments was studied after dopamine (DA), and alpha- or beta-sympathomimetic agonist application. The electrical parameters of the acinar cell membrane were also monitored. Both DA (from 5 X 10(-6) to 10(-4) M) and beta-stimulants (isoprenaline from 5 X 10(-6) to 5 X 10(-5) M; noradrenaline from 3 X 10(-4) to 10(-3) M) evoked an increase in amylase release, while noradrenaline in alpha-receptor stimulating doses failed to have any effect. The stimulatory effect of DA was blocked by ganglion blockers (Arfonad 10(-5) M; pentamethonium 3 X 10(-5) M) in a competitive manner and a dual antagonism was observed with atropine (10(-7) M, 10(-9) M). An alpha-receptor antagonist (phentolamine 10(-5) M) and a beta-receptor antagonist (propranolol 10(-5) M) had no influence on the dopamine response. Moreover, the DA-induced stimulation was dependent on the presence of extracellular calcium. Perfusion with 10(-4) and 10(-3) M-DA or local application (from 77 micrograms to 4.3 mg), resulted in marked membrane depolarization with diminution of the input resistance. This effect was blocked by atropine (10(-5) M) and pentamethonium (10(-4) M), but not by propranolol (10(-5) M) or phentolamine (10(-5) M). The isoprenaline- (IP) and noradrenaline- (NA) induced increase in amylase release was competitively blocked by propranolol (10(-5) M) but not by phentolamine (10(-5) M). Atropine caused a dose-dependent (10(-7) M, 10(-6) M) decrease in the maximal response (non-competitive antagonism), while the ganglion blocker pentamethonium (10(-4) M) was without effect. NA caused membrane depolarization accompanied by a decrease in the input resistance after local application (from 77 micrograms to 1.6 mg). This effect persisted in the presence of 10(-5) M-phentolamine but was abolished by 10(-5) M-propranolol. IP perfusion (10(-4) and 10(-3) M) or local application (0.3 M; from 32 to 130 micrograms) caused the same electrical changes as those induced by NA and DA. The effect of IP persisted in the presence of 10(-5) M-phentolamine, 10(-4) M-pentamethonium and 10(-4) M-domperidone, but was abolished by propranolol (10(-5) M) and tetrodotoxin (5 X 10(-6) M) and markedly diminished by atropine (10(-5) M).(ABSTRACT TRUNCATED AT 400 WORDS) (+info)
Transmembrane electrical potential and transmembrane pH gradient in the acidophile Thiobacillus ferro-oxidans.
(13/18)
Thiobacillus ferro-oxidans is capable of using the oxidation of Fe2+ by O2 at pH 2.0 as the sole source of energy for growth and CO2 fixation. The bacterium maintains an intracellular pH of 6.5 over a range of external pH from 1.0 to 8.0, as measured by [14C]acetate and [3H]methylamine distribution. The membrane potential was estimated by the distribution of the lipid-soluble cation dibenzyldimethylammonium and the anion SCN-. At pH 2.0 (the pH of growth) during Fe2+ oxidation the transmembrane pH gradient is 4.5 units with an opposing membrane potential of -10mV, giving a proton electrochemical gradient of +256mV. This gradient is actively maintained. (+info)
Some properties of an SH group essential for choline transport in human erythrocytes.
(14/18)
1. The choline transport system in human erythrocytes is inhibited by N-ethylmaleimide (NEM), cystamine and p-chloromercuribenzene sulphonic acid (PCMBS).2. External choline increases the rate of inhibition by NEM and cystamine but decreases the rate of inhibition by PCMBS. Intracellular choline has the opposite effect.3. Competitive inhibitors of choline transport that are not themselves transported protect the carrier against all three thiol reagents.4. Some thiol reagents with a very low lipid solubility do not inhibit choline transport.5. The transport inhibition by cystamine is reversed by various reducing agents.6. Cystamine protects the transport system against NEM and PCMBS.7. It is suggested that NEM and cystamine react with an SH group of the transport system and that this SH group is more reactive when the carrier is facing inside. PCMBS penetrates erythrocytes only very slowly and is assumed to react preferentially with the outward facing carrier.8. The reactive SH group seems to be located in a lipophilic environment. (+info)
The channel-blocking action of methonium compounds on rat submandibular ganglion cells.
(15/18)
The effects of drugs of the polymethylene bis-trimethylammonium (methonium) series on the characteristics of the synaptic currents (e.s.cs) recorded from voltage-clamped rat submandibular ganglion cells have been studied. The drugs studied were from C4 to C10 (decamethonium). All of the drugs except C4 shortened the initial decay phase of the e.s.c.; C9 and C10 produced an additional slowly decaying component. These effects were interpreted in terms of an open channel block mechanism, the calculated rate constants for association with the open channel at -80 mV being fairly similar (5.9 X 10(6) to 18.1 X 10(6)M-1S-1) for all of the compounds except C4, which had no effect on the e.s.c. decay. All of the compounds produced use-dependent block when tested with short trains of stimuli at 10 Hz, or with trains of ionophoretic pulses of acetylcholine, consistent with their channel blocking property. Tubocurarine had a similar effect, but not trimetaphan or mecamylamine. Recovery from use-dependent block with short chain methonium compounds, up to C8, was very slow in the absence of agonist, being incomplete even after several minutes. With C9 or C10 or tubocurarine, recovery from use-dependent block was complete within a few seconds. With C6 recovery in the absence of agonist was unaffected by membrane potential, but could be accelerated by applying acetylcholine with the cell depolarized to -40 mV. This persistent block was ascribed to the ability of the blocking molecule to become trapped by closure of the channel. With C9 and C10 it is assumed that their presence inhibits channel closure, so they can escape without the help of agonist. When use-dependent block is avoided by leaving the ganglion unstimulated during equilibration with the blocking drug, the first e.s.c. elicited shows no appreciable reduction of amplitude, though with C6, C7 or C8 subsequent responses elicited at 0.1 Hz become progressively more blocked. Even at 1 mM, C6 does not prevent acetylcholine from opening ionic channels. It is concluded that all of the effects on e.s.c. amplitude can be interpreted in terms of channel block, there being no evidence of any receptor blocking action. (+info)
Bis-quaternary ammonium blockers as structural probes of the sarcoplasmic reticulum K+ channel.
(16/18)
A series of n-alkyl-bis-alpha,omega-trimethylammonium (bisQn) compounds was synthesized, and their ability to block K+ currents through a K+ channel from sarcoplasmic reticulum was studied. K+ channels were inserted into planar phospholipid membranes, and single-channel K+ currents were measured in the presence of the blocking cations. These bisQn compounds block K+ currents only from the side of the membrane opposite to the addition of SR vesicles (the trans side). The block is dependent on transmembrane voltage, and the effective valence of the block (a measure of this voltage dependence) varies with the methylene chain length. For short chains (bisQ2-bisQ5), the effective valence decreases with chain length from 1.1 to 0.65; it then remains constant at approximately 0.65 for bisQ5 to bisQ8; the effective valence abruptly increases to 1.2-1.3 for chains of nine carbons and longer. For the compounds of nine carbons and longer, the discrete nature of the block can be observed directly as 'flickering noise" on the open channel. The kinetics of the block were studied for these long-chain blockers. Both blocking and unblocking rates of the blockers vary with chain length, with the blocking rate showing the strongest variation--an increase of 2.8-fold per added methylene group. All of the voltage dependence of the binding equilibrium resides in the blocking rate, and none in the unblocking rate. The results imply that 65% of the voltage drop within the channel occurs over a distance of 6-7A, and that the short-chain blockers bind in a bent-over conformation with both charges deeply inside the channel. (+info)