Sodium efflux in Myxicola giant axons

Direct inhibitory action of EGTA-Ca complex on reverse-mode Na/Ca exchange in Myxicola giant axons

Giant axons from the marine annelid Myxicola infundibulum were internally dialyzed with solutions containing 22Na ions as tracers of Na efflux. In experiments performed in Li-substituted seawater, Na efflux that is dependent on external Ca ion concentration, [Ca2+]o, was measured using dialysis to maintain [Na+]i at 100 mM, which enhances the [Ca2+]o-dependent Na efflux component, (i.e., reverse-mode Na/Ca exchange). When dialysis fluid contained EGTA (1 mM) to buffer the internal Ca concentration, [Ca2+]i, to desired levels, Na efflux lost its normal sensitivity to external calcium. The inhibition was not simply due to the Ca-chelating action of EGTA to produce insufficient [Ca2+]i to activate Na/Ca exchange. The addition of EGTA inhibited Cao-dependent Na efflux even when a large enough excess of [Ca2+]i was present to saturate the EGTA and still produce elevated values of [Ca2+]i. Control experiments showed that these high values of [Ca2+]i resulted in normal Na/Ca exchange in the absence of EGTA. It is concluded that the presence of EGTA itself interferes with the manifestation of reverse-mode Na/Ca exchange in Myxicola giant axons.

Anomalous influence of reduced internal ATP levels on sodium efflux in Myxicola giant axons

Giant axons from the marine annelid, Myxicola infundibulum, were internally dialyzed with ATP-free media and with media with lower than normal ATP levels in an attempt to determine quantitatively the ATP requirement of the Na pump in these cells. This was accomplished by using 22Na ions to measure Na efflux. When [ATP]i in dialysis fluid fell to values within the range of 20-40 microM, a marked stimulation of Na efflux was observed even though an essentially normal ouabain sensitivity of Na efflux persisted; when axons were dialyzed with ATP-free solutions with ouabain present in the external medium throughout the dialysis period, the stimulation of Na efflux still occurred. The stimulation of Na efflux produced by low [ATP]i levels could be reversed by reintroducing normal ATP levels into the dialysis medium. Reversibility was complete provided axons were not depleted of ATP for periods longer than about 1 hr. Longer periods of ATP depletion led to larger and ultimately irreversible increases in Na efflux. The increases in Na efflux occasioned by ATP depletion either prevented or obscured the decrease in Na efflux expected to occur from unfueling the Na pump. Since [ATP]i levels required to significantly unfuel the Na pump lie below the levels at which the Na efflux stimulation occurred, it is problematic to quantitatively assess the influence of [ATP]i levels on Na pump rate by measurements of Na efflux in this preparation. Substitutes for ATP failed to prevent increases in Na efflux. The large increases in Na efflux observed at low [ATP]i occurred with no important changes in the resting membrane potential, and also occurred in Na-free and Ca-free external media. At least part of the increased Na efflux under these conditions may be due to a Na/Na exchange component, as a significant dependence of Na efflux on [Na]o appropriate for this kind of exchange was observed in the ATP-depleted axons. Whether the highly reproducible anomalous effect on Na efflux in Myxicola axons has some fundamental significance in its own right is a matter for future investigation. A few possible explanations of the anomalous effect of reduced ATP levels are discussed.

Amino acid transport in Myxicola giant axon: stability of the amino acid pool, taurine efflux, and trans effect of sodium

1. The giant axon of Myxicola infundibulum was assessed for its suitability as a model preparation for study of amino acid transport mechanisms.2. The amino acid composition of axoplasm was measured and compared with those of coelomic fluid, muscle and axon sheath. The axoplasmic composition is unique. Axoplasm/coelomic fluid concentration ratios are all much larger than 1. The axoplasmic amino acid concentrations are (mmol/kg plasm): cysteic acid (104), aspartic acid (75), glutamic acid (10), taurine (64), serine (5), glycine (191) and alanine (5). Other amino acids or primary amines, if present, must have concentrations of less than 1 mm.3. The size of the sheath amino acid pool is 12% or less of the axoplasmic pool.4. The amino acid pool of axons soaked in sea water for up to 24 h is stable. Removal of Na from sea water causes a large increase of net efflux and net production of amino acids.5. Net amino acid production can not be detected in sheath. Metabolic production occurs in axoplasm with little accumulation. Time scales for production and net efflux are therefore similar.6. The Myxicola axon has a vigorous amino acid metabolism and transport systems capable of relatively large fluxes. Homeostasis is strongly linked to Na and may involve Na-coupled co-transport. Conservation of transmembrane amino acid gradients could be promoted in part by trans inhibition of efflux by external Na.7. Taurine is a useful model substrate because it is not catabolized in Myxicola and its net efflux is sensitive to Na. [(3)H]taurine efflux was measured from injected axons. Fluxes and internally recorded action potentials are stable for up to 6 h.8. Axon sheaths take up [(3)H]taurine from 10 mm-taurine sea water with an apparent half-time of 5 h. [(3)H]taurine washout from the apparent extracellular space has a half-time of 5 min. Washout from sheath cells has a half-time of 2-3 h. Sheath is not an important parallel compartment for taurine fluxes in the axon.9. Taurine efflux has a Q(10) of 1.8.10. Taurine efflux is insensitive to external taurine concentrations up to 10 mm.11. Taurine efflux is sensitive to external Na, but only if internal Na is high.12. Taurine is transported by a low-affinity Na-dependent system in Myxicola axon. Results could be explained by a carrier which is more mobile in the empty state than in the substrate-loaded state. Trans inhibition of taurine efflux by external Na is an important property of the system, and contributes to conservation of axoplasmic taurine.

Calcium efflux from Myxicola giant axons: effects of extracellular calcium and intracellular EGTA

1. (45)Ca efflux was examined in Myxicola giant axons injected with (45)CaCl(2) or various concentrations of (45)Ca/EGTA buffers. In axons injected with (45)CaCl(2), the Ca(o)-dependent Ca efflux in 1 mM-Ca(o) was about half that in 10 mM-Ca(o).2. Axons injected with (45)Ca/EGTA buffers consistently showed two types of results: in one type (B type), K((1/2)) for Ca(o) activation was less than 1 mM-Ca(o). In the other type of result (A type), there was an additional Ca activation of Ca efflux. This additional efflux exhibited a linear dependence on Ca(o) when the Ca(o) values ranged between 1 mM-Ca(o) and 10 mM-Ca(o).3. The B-type result remained unchanged when the injected Ca/EGTA concentrations were varied. The A type result, however, changed as a function of Ca/EGTA(i) in the following way: (a) at a constant ratio of Ca/EGTA(i) = 8/10, the megnitude of the linear component of the Ca(o)-activated Ca efflux was reduced by increasing the intracellular concentration of (Ca/EGTA) buffer; and (b) at a ratio Ca/EGTA = 1/10, the linear component of the Ca(o)-activated Ca efflux appeared to acquire a slower time response to changes in Ca(o).4. Na(o) acts synergistically with Ca(o) to produce the linear component of the Ca-activated Ca efflux seen in the A type result.5. With axons containing (45)Ca/EGTA buffers (total EGTA(i) = 1 mM), changing the Ca/EGTA ratio by repetitive injections of CaCl(2) did not increase (45)Ca efflux by as great an amount as would be predicted if Ca(i) (2+) were controlled by the EGTA buffer alone.6. Ca(i) (2+) (measured by arsenazo III absorbance) is influenced by Ca(o) irrespective of the presence of 1 mM-EGTA buffer inside the axon. There was a variability in the sensitivity of Ca(i) to Ca(o) that resembled the variability found in (45)Ca efflux measurements.7. (45)Ca influx is not affected by the concentration of Ca/EGTA buffer injected into the cell and appears to be only slightly, if at all, affected by increasing ionized Ca(i) (2+) from 0.016 to 0.56 muM in the injection medium.8. These results are consistent with the interpretation that the Ca efflux system of the Myxicola giant axon, or something controlling it, can exist in more than one state. One of these states, which exhibited a large Ca(o)-dependent Ca efflux, may represent axons in which Ca(i) is poorly controlled by the natural endogenous Ca buffers.

Sodium and potassium fluxes across the dialyzed giant axon of Myxicola

Resting and stimulated fluxes of sodium and potassium across the giant axon of the marine annelid, Myxicola infundibulum, have been characterized using the technique of internal dialysis. In most respects the ion movements were found to be similar to those in squid axons. Sodium efflux and potassium influx were found to be active, cardiac glycoside-sensitive fluxes, with a variable coupling ratio. However, when [ATP]i was lowered to less than 20 microM by treatment with cyanide and continuous dialysis, or to less than 2 microM by dialysis with glucose following injection of hexokinase, Na efflux and K influx were unaltered. The maintained fluxes were not accounted for by an increased passive permeability of the axolemma, although 30-60% of the Na efflux appeared to be due to Na-Na exchange. An altered form of Na pump operation at low [ATP]i is a more likely explanation than an alternate energy source, or an ATP source proximate to the axolemma. The transient response of 22Na efflux to a change in [22Na]i was found to be much slower than in squid, tau = 360 sec. The efflux delay could only be accounted for by an extra-axonal diffusion barrier, which is probably the basement membrane surrounding the ventral nerve cord.

Calcium movement in nerve fibres

Given the existence of a difference in electrical potential between the interior of a nerve cell and the media surrounding it, where the cytoplasm is some 70 mV negative (Hodgkin, 1958), it must be expected that any positively charged ion to which the cell membrane is permeable is more concentrated in the cell interior. For monovalent cations such as Na and divalent cations such as Ca and Mg this is not the case in the majority of the cells such as the squid giant axon. In other words, nerve cells maintain a lower intracellular concentration of these ions, as compared with their concentration in the extracellular fluid. For Mg, Ca and Na ions, this lower internal concentration must, in the steady state, be effected by some membrane based mechanism which consumes energy.

Changes in the intracellular sodium activity of sheep heart Purkinje fibres produced by calcium and other divalent cations

1. The intracellular Na activity of sheep heart Purkinje fibres was recorded with Na+-sensitive glass micro-electrodes. The effects of various external divalent cations on the intracellular Na activity were investigated. 2. Raising the external concentration of divalent cations (Ca, Mg, Mn, Sr or Ba) from 3 to 16 mM resulted in a decrease in the intracellular Na activity of 10-50%. 3. Raising the external concentration of Ca, Sr or Ba could produce a decrease in the intracellular Na activity even when the Na-K pump was inhibited (with strophanthidin, 10(-5) M); but raising the external concentration of Mg or Mn could not. 4. Mn inhibited the decrease in the intracellular Na activity produced by raising external Ca while the Na-K pump was inhibited. 5. Raising external Ca or adding Mn reduced the rate of rise of the intracellular Na activity on inhibition of the Na-K pump. 6. The removal of external K resulted in an increase in the intracellular Na activity. This increase could be stopped and even reversed by raising external Ca. 7. Removal of divalent cations from the external solution produced an increase in the intracellular Na activity. However, replacing external Ca and Mg by another divalent cation, e.g. Mn, did not result in a rise in the intracellular Na activity, except when the Na-K pump was inhibited. 8. The intracellular Na activity decreased by approximately 50% for a tenfold increase in the external Ca concentration. 9. The extent of the decrease in internal Na activity produced by raising external Ca was directly proportional to the internal Na activity before external Ca was raised. 10. We conclude that external Ca influences the intracellular Na activity in two ways: (a) by changing the passive Na influx: the resultant change in the intracellular Na depends on the activity of the Na-K pump; and (b) by a process where internal Na ions are exchanged for external Ca ions.

The influence of external cations and membrane potential on Ca-activated Na efflux in Myxicola giant axons

In microinjected Myxicola giant axons with elevated [Na]i, Na efflux was sensitive to Cao under some conditions. In Li seawater, sensitivity to Cao was high whereas in Na seawater, sensitivity to Cao was observed only upon elevation of [Ca]o above the normal value. In choline seawater, the sensitivity of Na efflux to Cao was less than that observed in Li seawater whereas Mg seawater failed to support any detectable Cao-sensitive Na efflux. Addition of Na to Li seawater was inhibitory to Cao-sensitive Na efflux, the extent of inhibition increasing with rising values of [Na]o. The presence of 20 mM K in Li seawater resulted in about a threefold increase in the Cao-activated Na efflux. Experiments in which the membrane potential, Vm, was varied or held constant when [K]o was changed showed that the augmentation of Ca-activated Na efflux by Ko was not due to changes in Vm but resulted from a direct action of K on activation by Ca. The same experimental conditions that favored a large component of Cao-activated Na efflux also caused a large increase in Ca influx. Measurements of Ca influx in the presence of 20 mM K and comparison with values of Ca-activated Na efflux suggest that the Na:Ca coupling ratio may be altered by increasing external [K]o. Overall, the results suggest that the Cao-activated Na efflux in Myxicola giant axons requires the presence of an external monovalent cation and that the order of effectiveness at a total monovalent cation concentration of 430 mM is K + Li greater than Li greater than Choline greater than Na.