Oxygen consumption and phosphate efflux in mammalian non-myelinated nerve fibres

Energy optimisation predicts the capacity of ion buffering in the brain

Neurons store energy in the ionic concentration gradients they build across their cell membrane. The amount of energy stored, and hence the work the ions can do by mixing, can be enhanced by the presence of ion buffers in extra- and intracellular space. Buffers act as sources and sinks of ions, however, and unless the buffering capacities for different ion species obey certain relationships, a complete mixing of the ions may be impeded by the physical conditions of charge neutrality and isotonicity. From these conditions, buffering capacities were calculated that enabled each ion species to mix completely. In all valid buffer distributions, the [Formula: see text] ions were buffered most, with a capacity exceeding that of [Formula: see text] and [Formula: see text] buffering by at least an order of magnitude. The similar magnitude of the (oppositely directed) [Formula: see text] and [Formula: see text] gradients made extracellular space behave as a [Formula: see text]-[Formula: see text] exchanger. Anions such as [Formula: see text] were buffered least. The great capacity of the extra- and intracellular [Formula: see text] buffers caused a large influx of [Formula: see text] ions as is typically observed during energy deprivation. These results explain many characteristics of the physiological buffer distributions but raise the question how the brain controls the capacity of its ion buffers. It is suggested that neurons and glial cells, by their great sensitivity to gradients of charge and osmolarity, respectively, sense deviations from electro-neutral and isotonic mixing, and use these signals to tune the chemical composition, and buffering capacity, of the extra- and intracellular matrices.

Anoxia-induced changes in optimal substrate for peripheral nerve

Hyperglycemia accentuates the injury produced by anoxia both in the central and peripheral nervous system. To understand whether this is a consequence of changes in metabolic pathways produced by anoxia, the effect of the metabolic substrate used by the rat peripheral nerve on the nerve action potential (NAP) was studied in the presence and absence of anoxia. In the continuously oxygenated state, the NAP was well preserved with glucose, lactate, as well as with high concentrations of sorbitol and fructose but not β-hydroxybutyrate, acetate or galactose. With intermittent anoxia, the pattern of substrate effects on the NAP changed markedly so that low concentrations of fructose became able to support neurophysiologic activity but not high concentrations of glucose. These alterations occurred gradually with repeated episodes of anoxia as reflected by the progressive increase in the time needed for the NAP to disappear during anoxia when using glucose as substrate. This "preconditioning" effect was not seen with other substrates and an opposite effect was seen with lactate. In fact, the rate at which the NAP disappeared during anoxia was not simply related to degree of recovery after anoxia. These are distinct phenomena. For example, the NAP persisted longest during anoxia in the setting of hyperglycemia but this was the state in which the anoxic damage was most severe. Correlating the results with existing literature on the metabolic functions of Schwann cells and axons generates testable hypotheses for the mechanism of hyperglycemic damage during anoxia and lead to discussions of the role for a metabolic shuttle between Schwann cells and axons as well as a potential important role of glycogen.

Inorganic phosphate enhances phosphonucleotide concentrations in cultured fetal rat cortical neurons

Our laboratory has recently characterized saturable Na(+)-dependent P(i) import into cultured fetal rat cortical neurons and shown that a substantial fraction of the P(i) so accumulated is incorporated into ATP. We now report that the ATP, NADPH and intracellular free P(i) ([P(i)]i) concentrations of cultured fetal rat cortical neurons are dependent on the extracellular P(i) concentration ([P(i)]e). [ATP], [NADPH] and [P(i)]i display a hyperbolic dependence upon [P(i)]e, being significantly increased after incubation with [P(i)]e of > or = 10 microM, and maximal at > or = 500 microM. Increases in both [ATP] and [NADPH] are abolished in the absence of glucose. In the absence of extracellular P(i), both [ATP] and [P(i)]i decline over time. Our data suggest that in cultured fetal rat cortical neurons [P(i)]e has a direct effect on glucose utilization, stimulating both ATP and NADPH synthesis via glycolysis and the pentose phosphate pathway.

Energy efficient neural codes

In 1969 Barlow introduced the phrase "economy of impulses" to express the tendency for successive neural systems to use lower and lower levels of cell firings to produce equivalent encodings. From this viewpoint, the ultimate economy of impulses is a neural code of minimal redundancy. The hypothesis motivating our research is that energy expenditures, e.g., the metabolic cost of recovering from an action potential relative to the cost of inactivity, should also be factored into the economy of impulses. In fact, coding schemes with the largest representational capacity are not, in general, optimal when energy expenditures are taken into account. We show that for both binary and analog neurons, increased energy expenditure per neuron implies a decrease in average firing rate if energy efficient information transmission is to be maintained.

Simultaneous measurement of oxygen and dopamine: coupling of oxygen consumption and neurotransmission

Fast-scan cyclic voltammetry was used to simultaneously measure increases in dopamine concentration and decreases in O2 concentration evoked by brief electrical stimulation (two pulses at 10 Hz) in slices of rat caudate nucleus. Dopamine concentration began increasing immediately after the first pulse and reached a maximum within 200 ms of stimulation. The O2 concentration began to decrease 300-700 ms after onset of stimulus. Responses for both dopamine and O2 were dependent on external Ca2+ and were Cd2+ and tetrodotoxin sensitive. Only the O2 response was sensitive to CN- (0.15 mM). At short times after exposure to 50 microM ouabain, electrically stimulated dopamine overflow was increased by 150% and electrically stimulated changes in O2 concentration were unaffected. Maximum dopamine concentration was increased 28% by sulpiride (2 microM), 78% by L-DOPA (60 microM), 105% by nomifensine (10 microM) and unaffected by nialamide (10 microM). Maximum decrease in O2 concentration was increased by 25% by sulpiride and unaffected by nialamide, L-DOPA, or nomifensine. The decreases in O2 concentration are indicative of increased O2 consumption and are a measure of oxidative energy production evoked by electrical stimulation. The increase in dopamine is due to the release of dopamine balanced by uptake and serves as an indication of neurotransmitter activity. The results indicate that increases in oxidative energy production following electrical stimulation are dependent on external Ca2+ entry through Cd(2+)-sensitive channels. Possible mechanisms for this coupling are discussed.

Inhibition of sodium-potassium-ATPase: a potentially ubiquitous mechanism contributing to central nervous system neuropathology

Direct and indirect evidence suggests that Na+/K(+)-ATPase activity is reduced or insufficient to maintain ionic balances during and immediately after episodes of ischemia, hypoglycemia, epilepsy, and after administration of excitotoxins (glutamate agonists). Recent results show that inhibition of this enzyme results in neuronal death, and thus a hypothesis is proposed that a reduction and/or inhibition of this enzyme contributes to producing the central neuropathy found in the above disorders, and identifies potential mechanisms involved. While the extent of inhibition of Na+/K(+)-ATPase during ischemia, hypoglycemia and epilepsy may be insufficient to cause neuronal death by itself, unless the inhibition is severe and prolonged, there are a number of interactions which can lead to a potentiation of the neurotoxic actions of glutamate, a prime candidate for causing part of the damage following trauma. Presynaptically, inhibition of the Na+/K(+)-ATPase destroys the sodium gradient which drives the uptake of acidic amino acids and a number of other neurotransmitters. This results in both a block of reuptake and a stimulation of the release not only of glutamate but also of other neurotransmitters which modulate the neurotoxicity of glutamate. An exocytotic release of glutamate can also occur as inhibition of the enzyme causes depolarization of the membrane, but exocytosis is only possible when ATP levels are sufficiently high. Postsynaptically, the depolarization could alleviate the magnesium block of NMDA receptors, a major mechanism for glutamate-induced neurotoxicity, while massive depolarization results in seizure activity. With less severe inhibition, the retention of sodium results in osmotic swelling and possible cellular lysis. A build-up of intracellular calcium also occurs via voltage-gated calcium channels following depolarization and as a consequence of a failure of the sodium-calcium exchange system, maintained by the sodium gradient.

Mechanism of anoxic conduction block in mammalian nerve

The mechanism by which anoxia blocks impulse conduction was studied in isolated sciatic nerves from the rat. The desheathed nerve was mounted in a recording chamber, and the compound action potential (CAP) was measured at controlled temperature (23 and 37 degrees C). When the nerve was irrigated with nitrogenated Ringer's solution compound action potential decreased to 50% in 10 min at 37 degrees C and in 35 min at 23 degrees C, whereas in oxygenated solution compound action potential decreased less than 5% in 60 min. A Na-free nitrogenated solution similarly caused anoxic block, that is the effect was independent of impulse activity. Ouabain (1 mM) decreased compound action potential by only ca. 4% in 30 min, and the effect of anoxia was delayed in presence of ouabain. Dinitrophenol (0.05 mM) reduced compound action potential to 50% in 5 min. These findings indicated that the anoxic block was not related to changes in axonal concentration of Na or K following impulse activity or inhibition of Na-K-ATPase. Instead the findings imply that the anoxic block is due to inactivation of Na-channels as a consequence of inhibition of another ATP-dependent process in the axon.

Calcium-dependent and ouabain-resistant oxygen consumption in the rat neurohypophysis

To analyze rapid changes in energy metabolism in the neurohypophysis, pO2 was measured in the tissue in vitro with a miniature O2 electrode (tip diameter less than 100 microns, 90% response time less than 3 s). Electrical stimulation (20 Hz, 5 s) evoked immediate pO2 decreases by 93.4 +/- 10.5 mm Hg (mean +/- S.E.M., n = 12) which lasted for about 1 min and were blocked by tetrodotoxin (1 microM) or sodium cyanide (1 mM). Replacement of Ca2+ in the perifusing medium with Mn2+ reduced the pO2 decreases to 23.1 +/- 4.9% (n = 5) of the value before the replacement. In normal medium, ouabain application (1 mM, 3 min) suppressed the electrically evoked pO2 decreases only slightly to 82.6 +/- 6.5% (n = 5). In the Mn2+ medium, the same ouabain application suppressed the pO2 changes to 28.8 +/- 1.4%. High K+ (70 mM) evoked pO2 decreases by 175.8 +/- 14.9 mm Hg (n = 5) within 1-2 min. These pO2 changes were reduced to 35.6 +/- 3.8% in an Mn2+ medium. Veratridine (100 microM) evoked pO2 decreases by 204.8 +/- 36.3 mm Hg (n = 5). During the pO2 decreases, the effects of electrical or high K+ stimulation on pO2 were blocked. These results indicate that O2 consumption was evoked by electrical stimulation, and probably that high K+ or veratridine application in the neurohypophysis is mainly dependent on extracellular calcium and resistant to ouabain. The relationship between O2 consumption and exocytotic release is discussed.

Firing rate may be a determinant of nerve fibre vulnerability in axonopathies

Analysis of the discharge characteristics and conduction velocities of single vagal nerve fibres innervating slowly adapting mechanoreceptors in the oesophagus and lungs of acrylamide affected dogs has demonstrated that a group of fibres, the fastest conducting fibres to each organ, fail to conduct. The two failed groups have conduction velocities which are grossly different and yet they have a common receptor type, they have a similar fibre length and they have the same central nervous system destination. Amongst the oesophageal fibres, the failed group with conduction velocities in the upper third of the control range had firing rates which were normally higher than those of the surviving slower conducting fibres (P less than 0.01). The same observation applied to the respiratory fibres (P less than 0.05). It is possible that firing rate is also a factor in predicting the vulnerability of axons in axonopathies.

Net fluxes of orthophosphate across the plasma membrane in human red cells following alteration of pH and extracellular Pi concentration

Even though net fluxes of Pi (orthophosphate) across the cell membrane may be important in clinical disorders involving the abnormal extracellular Pi concentration, in acid-base disturbances, and in the responses of some cells to hormones, relatively few studies have been made of these fluxes, owing to the complexities of interpretation. Here we have studied net fluxes in response to changes in extracellular pH and Pi concentration in the simple case of the human red cell. The permeability of the cell membrane to net Pi fluxes was described in terms of a first-order rate constant, epsilon. By means of a mathematical model, it was possible to discriminate between transmembrane Pi movement, net intracellular generation or consumption of Pi by organic phosphates, and extracellular generation of Pi from the cells lysing during the experiment. We show that net Pi influx into the cell during experimental alkalosis was probably driven by net consumption of Pi by organic phosphates, and that this was reversed during acidosis. Inhibition of net Pi influx by 4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonate (SITS) suggests that, like Pi self-exchange, net influx is at least partly mediated by the band 3 transport protein. Unexpectedly, epsilon increased from 2 h-1 at extracellular pH 7.4 to approx. 7 h-1 at pH 7.8. From the value of epsilon at pH 7.4, we conclude that the apparent buffering or regulation of steady-state Pi concentrations, previously reported in red cells in vitro, was not an artifact of intracellular generation of Pi from organic phosphates.

Elevated regional sciatic nerve blood flow in hypothermic anesthetized rats

The effect of corporal hypothermia on regional blood flow in peripheral nerve is unknown. We compared blood flow in resting sciatic nerves of anesthetized, normothermic rats with that of rats whose rectal temperatures had been acutely lowered to 28 to 30 degrees C. Peripheral nerve regional blood flow in normothermic rats in which one hind limb was cooled was also measured, as were simultaneous flow changes in biceps femoris muscle and thigh skin. Flows were quantitated by the fractional distribution of [14C]butanol. Hypothermia was associated with increased peripheral nerve blood flow and a simultaneous decrease in muscle and skin blood flow. Nerve vascular resistance was not consistently altered in hypothermia, but muscle and skin vascular resistances were elevated. Topical cooling of one limb did not affect the tissue blood flows in either limb. The regulation of resting nerve blood flow in hypothermic rats differs appreciably from that in biceps femoris muscle and skin. Nerve blood flow did not increase with local cooling in normothermic rats. Central, neurally mediated mechanisms may be responsible for the increased regional nerve blood flow in hypothermic rats.

The production and absorption of heat associated with electrical activity in nerve and electric organ

All living cells require a supply of energy from appropriate metabolic pathways in order in fulfill their physiological functions. A special function common to peripheral nerve fibres and the electroplates of the electric organ is the generation of electrical potentials and a consequent flow of current. A large fraction of their metabolism is therefore devoted basically to maintenance of the unequal distribution of sodium and potassium ions across the cell membranes on which their electrical excitability depends, and involves a consumption of ATP by the membrane-bound Na, K—ATPase system known as the sodium pump.

A note on the mechanism of resistance to anoxia and ischaemia in pathophysiological mammalian myelinated nerve

Computer simulation of the action potential in myelinated nerve fibres show that the metabolic cost of conduction of an impulse is less than normal in a slightly depolarised fibre. This would account, at least in part, for the greater resistance to ischaemia and anoxia of nerves from diabetics and other pathophysiological conditions.

Enhanced oxygen consumption in adrenal medulla on stimulation with acetylcholine

When perfused cortex-free ox adrenal medulla was stimulated to secrete catecholamine by infusion of 0.1 mM acetylcholine for 4 min, the oxygen consumption increased to a value which was 0.15 +/- 0.07 mumole O2/min/g wet weight (+/- S.D., N = 12) above the pre-stimulation value of 0.49 +/- 0.15 (P less than 0.001). 1.4 +/- 0.9 (+/- S.D., N = 12) mole of catecholamine was secreted per mole of enhanced O2 consumption in the 16 min following the start of the stimulation. The rate of ATP hydrolysis by the proton-translocating Mg-ATPase of the chromaffin granule may increase on fusing with the plasma membrane of the chromaffin cell during exocytosis. However, from the amount of catecholamine secreted, this was estimated to account for less than 17% of the oxygen consumption increase. The amount of catecholamine secreted by 4 min 0.1 mM acetylcholine stimulations correlated with the enhancement of oxygen consumption (r = 0.82, P less than 0.001) but, on stimulation with 60 microM veratridine for 4 min, O2 consumption enhancement was anomalously low. This dependence on mode of stimulation suggests that ATP consumption in exocytosis itself is an inadequate explanation. Ouabain-sensitive oxygen consumption rose from undetectable levels to 18 +/- 8% (+/- S.D., N = 4) of the basal respiration during prolonged 0.1 mM acetylcholine stimulation in the absence of Ca, indicating that Na,K-ATPase was not responsible for all of the oxygen consumption enhancement.

Release of adenosine, inosine and hypoxanthine from rabbit non-myelinated nerve fibres at rest and during activity

The composition of the efflux from desheathed rabbit vagus nerve, loaded with radioactivity by incubation in [3H]adenosine, was studied at rest and during electrical activity and after application of inhibitors of ecto-enzymes and modifications of intermediary metabolism. In addition, the degradation of externally applied ATP and adenosine was examined. [3H]ATP applied to the incubation medium was degraded to ADP, AMP, adenosine and inosine. The hydrolysis to nucleosides was inhibited by alpha, beta-methylene ADP; the appearance of AMP and nucleosides was slowed by beta, gamma-methylene ATP. Deamination of [3H]adenosine was blocked by 2-deoxycoformycin. The effluent from resting and stimulated preparations showed the presence of large amounts of inosine and hypoxanthine, smaller amounts of adenosine and adenine and traces of nucleotides. The composition of the effluent was not significantly altered by addition of alpha, beta-methylene ADP; beta, gamma-methylene ATP or 2-deoxycoformycin. Application of glucose-free solutions caused a large release of adenosine instead of inosine and hypoxanthine and a small increase in resting and stimulated efflux of 3H. Addition of 2-deoxyglucose produced a large increase in resting efflux and increased liberation of adenosine. Cyanide, 2,4-dinitrophenol, arsenate or salicylate increased the resting efflux of adenosine, inosine and hypoxanthine, and the effect of activity. It is concluded that electrical activity leads to release of adenosine, inosine and hypoxanthine, in various proportions depending on metabolic state, and that there is practically no liberation of nucleotides from nerve axons.

Involvement of intracellular calcium in the phosphate efflux from mammalian nonmyelinated nerve fibers

Phosphate efflux was measured as the fractional rate of loss of radioactivity from desheathed rabbit vagus nerves after loading with radiophosphate . The effects of strategies designed to increase intracellular calcium were investigated. At the same time, the exchangeable calcium content was measured using 45Ca. Application of calcium ionophore A23187 increased phosphate efflux in the presence of external calcium in parallel with an increase in calcium content. In the absence of external calcium, there was only a late, small increase in phosphate efflux. For nerves already treated with the calcium ionophore, the phosphate efflux was sensitive to small changes in external calcium, in the range 0.2 to 2 mM calcium, whereas similar increases in calcium in absence of ionophore gave much smaller increases in phosphate efflux. Removal of external sodium (choline substitution) produced an initial increase in phosphate efflux followed by a fall. The initial increase in phosphate efflux was much larger in the presence of calcium, than in its absence. The difference was again paralleled by an increase in calcium content of the preparation, thought to be due to inhibition of Na/Ca exchange by removal of external sodium. Measurements of ATP content and ATP, ADP, phosphate and creatine phosphate ratios did not indicate significant metabolic changes when the calcium content was increased. Stimulation of phosphate efflux by an increase in intracellular calcium may be due to stimulation of phospholipid metabolism. Alternatively, it is suggested that stimulation of phosphate efflux is associated with the stimulation of calcium efflux, possibly by cotransport of calcium and phosphate.

Significance of tissue myo-inositol concentrations in metabolic regulation in nerve

Approximately 25 percent of resting energy utilization in isolated nerve endoneurium is inhibited by medium containing defatted albumin and selectively restored by arachidonic acid but is unaffected by indomethacin or nordihydroguaiaretic acid. The same component of energy utilization is inhibited by small decreases in endoneurial myo-inositol, which decrease incorporation of carbon-14-labeled arachidonic acid into phosphatidylinositol. The fraction of the resting oxygen uptake inhibited by ouabain is decreased 40 to 50 percent by a reduced tissue myo-inositol concentration or by defatted albumin. Metabolic regulation by rapid, basal phosphatidylinositol turnover is dependent on the maintenance of normal tissue myoinositol concentrations.

Effects of calcium and lanthanum on phosphate efflux from nonmyelinated nerve fibers

Phosphate efflux was measured as the fractional rate of loss of radioactivity from rabbit vagus loaded with radiophosphate. The effects of changes in extracellular calcium and of lanthanum have been investigated. In Locke solution with normal, 0.9 mM, calcium and without phosphate, the fractional rate of loss was 1.62 X 10(-3) min-1 at 120 min after the beginning of the washing period and fell slowly (9% hr-1) during washing from 2 to 6 hr. Addition of calcium to the Locke solution produced a transient increase followed by a reversible maintained increase in phosphate efflux. The latter was 40 and 75% above efflux in normal calcium for 20 and 50 mM calcium, respectively. Removal of calcium, with or without addition of EGTA, produced only a transient increase in phosphate efflux, with no subsequent maintained change. Addition of low concentrations of lanthanum produced a reversible inhibition of phosphate efflux. Half-maximal inhibition was at 3.5 micro M lanthanum and appeared to be due to binding of lanthanum to more than one, probably two, sites. Measurements of inhibition by lanthanum at different calcium concentrations did not indicate any competition between calcium and lanthanum. It is suggested that a least a part of phosphate efflux depends on internal calcium and that lanthanum acts by preventing release of phosphate from the phosphate transport mechanism.

Uptake of adenosine and release of adenine derivatives in mammalian non-myelinated nerve fibres at rest and during activity

1. Influx of adenosine into rabbit non-myelinated nerve fibres was measured using [2-(3)H]adenosine. The uptake of radioactivity increased linearly with duration of incubation for up to 60 min and adenosine concentration up to 200 mum. The uptake at different adenosine concentrations showed a saturable component with a half-maximal activation at 17.1 mum and a linear part.2. The radioactivity taken up was rapidly incorporated into AMP, ADP and ATP. Isotopic equilibrium between the nucleotides was achieved within 15 min.3. The uptake of (3)H from 0.2 mum-adenosine was almost completely inhibited by addition of 200 mum-adenosine and to a similar extent by 200 mum-tubercidin and AMP; a 70% inhibition was found with ATP and ADP; alpha, beta methylene-ADP had no effect.4. ATP, ADP and AMP added to the extracellular medium of a desheathed vagus were slowly hydrolysed.5. In preparations loaded with [2-(3)H]adenosine and then washed with adenosine and label-free solution there was a steady efflux of radioactivity amounting to 0.18 x 10(-3)/min. Addition of adenosine or tubercidin transiently increased the efflux.6. Electrical stimulation caused an extra release of radioactivity. The extra fractional loss was 21.8 x 10(-6)/impulse in preparations that had rested for several hours; it decreased to 2.3 x 10(-6)/impulse when stimulation was applied after a 30 min rest.7. The radioactivity of the resting efflux and of the extra efflux after stimulation was found mostly in inosine and hypoxanthine; adenosine and adenine accounted for only 3%, and the nucleotides for less than 1% of the efflux.8. Adenosine added to the external medium of a desheathed nerve was slowly deaminated.9. It is concluded that inosine and hypoxanthine found in the effluent from desheathed vagus nerve trunk result from release of these compounds from nerve fibres and not from extracellular breakdown of released ATP or adenosine.10. Electrical activity in non-myelinated nerve fibres of the nerve trunk thus causes the release of metabolites (inosine and hypoxanthine) together with small amounts of adenosine and adenine, while release of ATP and other nucleotides is almost completely absent.

Observations on the mechanism for the active extrusion of lithium in mammalian non-myelinated nerve fibres

1. A study has been made of the O2 consumption, and the corresponding efflux of labelled phosphate, from the non-myelinated fibres of the desheathed rabbit vagus nerve at 37 degrees C in Locke solutions in which various ions were substituted for Na, and also in the presence of ouabain. 2. Switching from Na-Locke solution to Li-Locke solution produced a small transient decrease in the resting O2 consumption (of 14%), which rapidly recovered to its original value. This was accompanied by an initial brief rise followed by a maintained fall in the resting phosphate efflux. 3. In Li-Locke solution, ouabain (100 microM) produced a fall in the resting O2 consumption of 40%, i.e. similar to that produced in Na-Locke solution. Any depression of the resting phosphate efflux was absent or small. 4. In choline-Locke solution, in Tris-Locke solution, in K-Locke solution or in sucrose-Locke solution the resting O2 consumption, which fell by 30-40%, was insensitive to the addition of ouabain (100 microM). 5. Addition of either Na ions or of Li ions partially restored respiration in choline-Locke solution, Li being an order of magnitude less effective than Na. 6. In choline-Locke solution the internal K content was not affected by ouabain. However, if Li (77 mM) was present in the bathing solution ouabain (100 microM) produced a 30% fall in the internal K content. 7. It is concluded that these effects of Li, and their alteration by ouabain, reflect the activity of a mechanism for the active extrusion of Li ions. It is suggested that the mechanism for the active extrusion of Li is the same as that for Na. 8. There also seems to be a site for Li that controls the phosphate efflux and which is half-maximally activated with external Li concentrations of about 2-4 mM.

Release of inorganic phosphate during activity in mammalian non-myelinated nerve fibres

1. The efflux of labelled phosphate was measured in desheathed rabbit vagus nerve at rest and during activity.2. In solutions with 2 mM-phosphate and 1 mM-K the rate constant of the resting efflux was 2.7 x 10(-3) min(-1); stimulation caused an extra fractional loss of 2.8 x 10(-6) impulse(-1).3. Lowering the phosphate concentration decreased the resting and the stimulated efflux; with 0.2 mM-phosphate the corresponding values were 1.9 x 10(-3) min(-1) and 1.8 x 10(-6) impulse(-1), respectively.4. Increasing the K to 5.6 mM decreased both resting and stimulated efflux.5. Lowering the temperature decreased the resting efflux with a Q(10) of 2.9 and the stimulated efflux with a Q(10) of 8.1.6. Chromatography of the effluent showed that at rest and during activity at least 96% of the radiophosphate was in the orthophosphate fraction.7. Replacing the Na of the solution by Li lowered the rate constant of the resting efflux to 0.8 x 10(-3) min(-1) and abolished the extra release during activity, without reduction of the action potential.8. The presence of ouabain did not affect the resting efflux, except at 100 muM, when a transient reduction was found. The extra fractional loss was not affected with 0.001 muM; with 0.01-0.5 muM, it was reduced without much change in the action potential, and abolished at higher concentrations.9. The results agree with the hypothesis that the extra release results from an increase in internal inorganic phosphate caused by increased break-down of ATP during recovery.10. Comparison with the O(2) consumption shows that about 1% of the inorganic phosphate liberated at the inside of the axons escapes to the outside.