Intracellular pH and Na fluxes in barnacle muscle with evidence for reversal of the ionic mechanism of intracellular pH regulation

The ion transport mechanism that regulates intracellular pH (pHi) in giant barnacle muscle fibers was studied by measuring pHi and unidirectional Na+ fluxes in internally dialyzed fibers. The overall process normally results in a net acid extrusion from the cell, presumably by a membrane transport mechanism that exchanges external Na+ and HCO-3 for internal Cl- and possibly H+. However, we found that net transport can be reversed either by lowering [HCO-3]o and pHo or by reducing [Na+]o. This reversal (acid uptake) required external Cl-, was stimulated by raising [Na+]i, and was blocked by SITS. When the transporter was operating in the net forward direction (acid extrusion), we found a unidirectional Na+ influx of approximately 60 pmol . cm-2 . s-1, which required external HCO-3 and internal Cl- and was stimulated by cyclic AMP and blocked by SITS or DIDS. These properties of the Na+ influx are all shared with the net acid extrusion process. We also found that under conditions of net forward transport, the pHi-regulating system mediated a unidirectional Na+ efflux, which was significantly smaller than the simultaneous Na+ influx. These data are consistent with a reversible transport mechanism which, even when operating in the net forward direction, mediates a small amount of reversed transport. We also found that the ouabain-sensitive Na+ efflux was sharply inhibited by acidic pHi, being totally absent at pHi values below approximately 6.8.     

Cyclic AMP-stimulated chloride fluxes in dialyzed barnacle muscle fibers

Unidirectional chloride efflux and influx were studied in giant barnacle muscle fibers that were internally dialyzed. When cyclic 3'5'- adenosine monophosphate (cAMP) was included in the dialysis fluid, both unidirectional fluxes were stimulated by about the same amount. This stimulation was not associated with measurable changes either in membrane electrical conductance or with net movements of chloride. The stimulation required the trans-side presence of chloride. The stimulated flux was inhibited by the sulfonic acid stilbene derivatives 4-acetamido-4'-isothiocyanostilbene-2',2'-disulfonate (SITS) and 4,4'- diisothiocyanostilbene-2,2'-disulfonate (DIDS) or by furosemide. When cAMP was presented in high concentrations (10-5 M), the effect on chloride fluxes was characterized by a desensitization phenomenon. This desensitization was not the result of an increased amount of phosphodiesterase activity, but may be related to ATP and/or intracellular calcium levels. These results further support the hypothesis that the barnacle sarcolemma possesses a specialized chloride transport mechanism that largely engages in Cl-Cl exchange under conditions of normal intracellular pH.     

The interaction of intracellular Mg2+ and pH on Cl- fluxes associated with intracellular pH regulation in barnacle muscle fibers

The intracellular dialysis technique was used to measure unidirectional Cl- fluxes and net acid extrusion by single muscle fibers from the giant barnacle. Decreasing pHi below normal levels of 7.35 stimulated both Cl- efflux and influx. These increases of Cl- fluxes were blocked by disulfonic acid stilbene derivatives such as SITS and DIDS. The SITS-sensitive Cl- efflux was sharply dependent upon pHi, increasing approximately 20-fold as pHi was decreased from 7.35 to 6.7. Under conditions of normal intracellular Mg2+ concentration, the apparent pKa for the activation of Cl- efflux was 7.0. We found that raising [Mg2+]i, but not [Mg2+]o, had a pronounced inhibitory effect on both SITS-sensitive unidirectional Cl- fluxes as well as on SITS-sensitive net acid extrusion. Increasing [Mg2+]i shifted the apparent pKa of Cl- efflux to a more acid value without affecting the maximal flux that could be attained. This relation between pHi and [Mg2+]i on SITS-sensitive Cl- efflux is consistent with a competition between H ions and Mg ions. We conclude that the SITS-inhibitable Cl- fluxes are mediated by the pHi-regulatory transport mechanism and that changes of intracellular Mg2+ levels can modify the activity of the pHi regulator/anion transporter.     

Stoichiometry and ion dependencies of the intracellular-pH-regulating mechanism in squid giant axons

The ion transport system responsible for intracellular pH (pHi) regulation in squid giant axons was examined in experiments with pH- sensitive microelectrodes and isotopic fluxes of Na+ and Cl-. In one study, axons were acid-loaded and the rate of the subsequent pHi recovery was used to calculate the acid extrusion rate. There was an absolute dependence of acid extrusion on external Na+, external HCO-3 (at constant pH), and internal Cl-. Furthermore, the dependence of the acid extrusion rate on each of these three parameters was described by Michaelis-Menten kinetics. Acid extrusion was stimulated by an acid pHi, required internal ATP, and was blocked by external 4-acetamido-4'- isothiocyanostilbene-2,2'-disulfonate (SITS). Under a standard set of conditions (i.e., [HCO-3]o = 12 mM, pHo = 8.00, [Na+]o = 425 mM, [Cl-]i = 150 mM, [ATP]i = 4 mM, pHi = 6.5, and 16 degrees C), the mean acid extrusion rate was 7.5 pmol X cm-2 X s-1. In a second study under the above standard conditions, the unidirectional Na+ efflux (measured with 22Na) mediated by the pHi-regulating system was found to be approximately 0, whereas the mean influx was about 3.4 pmol X cm-2 X s- 1. This net influx required external HCO-3, internal Cl-, and acid pHi, internal ATP, and was blocked by SITS. In the final series of experiments under the above standard conditions, the unidirectional Cl- influx (measured with 36Cl) mediated by the pHi-regulating system was found to be approximately 0, whereas the mean efflux was approximately 3.9 pmol X cm-2 X s-1. This net efflux required external HCO-3, external Na+, an acid pHi, internal ATP, and was blocked by SITS. We conclude that the pHi-regulating system mediates the obligate net influx of HCO-3 (or equivalent species) and Na+ and the net efflux of Cl- in the stoichiometry of 2:1:1. The transport system is stimulated by intracellular acid loads, requires ATP, and is blocked by SITS.     

Chloride fluxes in isolated dialyzed barnacle muscle fibers

Chloride outflux and influx has been studied in single isolated muscle fibers from the giant barnacle under constant internal composition by means of a dialysis perfusion technique. Membrane potential was continually recorded. The chloride outfluxes and influxes were 143 and 144 pmoles/cm²-sec (mean resting potential: 58 mv, temperature: 22°–24°C) with internal and external chloride concentrations of 30 and 541 mM, respectively. The chloride conductance calculated from tracer measurements using constant field assumptions is about fourfold greater than that calculated from published electrical data. Replacing 97% of the external chloride ions by propionate reduces the chloride efflux by 51%. Nitrate ions applied either to the internal or external surface of the membrane slows the chloride efflux. The external pH dependence of the chloride efflux follows the external pH dependence of the membrane conductance, in the range pH 3.9–4.7, increasing with decreasing pH. In the range pH 5–9, the chloride efflux increased with increasing pH, in a manner similar to that observed in frog muscle fibers. The titration curve for internal pH changes in the range 4.0–7.0 was quantitatively much different from that for external pH change, indicating significant asymmetry in the internal and external pH dependence of the chloride efflux.     

Effect of disulfonic stilbene anion-channel blockers on the guinea-pig myocardium

The role of anions in the maintenance of tension in electrically driven left atria isolated from guinea pigs has been examined. The disulfonic stilbene anion-channel blockers SITS (4-acetamido-4'-isothiocyanostilbene 2'-disulfonate) and DIDS (4,4'-diisothiocyano-2,2'-stilbene disulfonate) decreased the contractile force developed in a time- and concentration-dependent manner. As in the red cell anion channel, DIDS was more potent than SITS, but the maximal inhibition of tension produced by N-(4-azido-2-nitrophenyl)-2-aminoethyl sulfonate (NAP-taurine) was considerably lower than the near maximal inhibition produced by SITS and DIDS. The inhibition by SITS and DIDS was irreversible, suggesting a covalent interaction, and could not be overcome by increasing the calcium concentration or the frequency of stimulation. Consistent with a requirement for chloride anion, substitution of chloride and bicarbonate by the impermeant anion gluconate did not support contraction, while only partial tension was maintained with the lipophilic anions acetate and thiocyanate. Incubation of atria with 400 microM SITS blocked both 36Cl and 45Ca uptake to a similar extent, whereas the efflux of both these ions was not affected by incubation of the atria with SITS. The blockade by disulfonic stilbene anion-channel blockers of the contraction of the guinea pig myocardium may result from impairment of excitation-contraction coupling.     

Chloride and sodium influx: a coupled uptake mechanism in the squid giant axon

The squid giant axon was internally dialyzed while the unidirectional fluxes of either Cl or Na were measured. The effects of varying the internal or external concentration of either Na or Cl were studied. Chloride influx was directly proportional to the external Na concentration whereas Cl efflux was unaffected by changes of the external Na concentration between 0 and 425 mM. Neither Cl influx nor efflux were affected by changes of internal Na concentration over the range of 8-158 mM. After ouabain and TTX treatment a portion of the remaining Na influx was directly dependent on the extracellular Cl concentration. Furthermore, when the internal Cl concentration was increased from 0 to 150 mM, the influxes of Cl and Na were decreased by 14 and 11 pmol/cm2.s, respectively. The influx of both ions could be substantially reduced when the axon was depleted of ATP. The influxes of both ions were inhibited by furosemide but unaffected by ouabain. It is concluded that the squid axolemma has an ATP-dependent coupled Na-Cl co-transport uptake mechanism.     

Stimulation of cyclic nucleotides of calcium efflux in barnacle muscle fibers.

Internal application of 10⁻⁴, 10⁻⁵, 10⁻⁶ and 10⁻⁷M cGMP and cAMP caused an increase in ⁴⁵Ca efflux in barnacle muscle fibers. Stimulation by either nucleotide occurred in the absence of external calcium and could be prevented by external application of 10 mM procaine or by prior internal treatment of these fibers with EGTA. The results indicate that cyclic nucleotides increase calcium efflux by releasing calcium from internal stores.     

Chloride influx provokes lamellipodium formation in microglial cells.

Lamellipodium extension and retraction is the driving force for cell migration. Although several studies document that activation of chloride channels are essential in cell migration, little is known about their contribution in lamellipodium formation. To address this question, we characterized chloride channels and transporters by whole cell recording and RT-PCR, respectively, as well as quantified lamellipodium formation in murine primary microglial cells as well as the microglial cell-line, BV-2, using time-lapse microscopy. The repertoire of chloride conducting pathways in BV-2 cells included, swelling-activated chloride channels as well as the KCl cotransporters, KCC1, KCC2, KCC3, and KCC4. Swelling-activated chloride channels were either activated by a hypoosmotic solution or by a high KCl saline, which promotes K(+) and Cl(-) influx instead of efflux by KCCs. Conductance through swelling-activated chloride channels was completely blocked by flufenamic acid (200 microM), SITS (1 mM) and DIOA (10 microM). By exposing primary microglial cells or BV-2 cells to a high KCl saline, we observed a local swelling, which developed into a prominent lamellipodium. Blockade of chloride influx by flufenamic acid (200 microM) or DIOA (10 microM) as well as incubation of cells in a chloride-free high K(+) saline suppressed formation of a lamellipodium. We assume that local swellings, established by an increase in chloride influx, are a general principle in formation of lamellipodia in eukaryotic cells.     

Influence of insulin on sodium efflux in barnacle muscle fibers

Summary The efflux of radiosodium in single muscle fibers from the barnacleBalanus nubilus was irresponsive to internal or external application of insulin. However, this was not the case with fibers isolated from a barnacle specimen pre-exposed overnight to a large dose of insulin. External application of insulin to pre-exposed fibers caused a decrease in the rate of decline of the radiosodium efflux and stopped the decline in the fractional rate constant for Na efflux. Such kinetics were interpreted as indicating that insulin acts either by releasing sequestered Na or abolishing the process of sequestration. Internal application of saline slowed the rate of decline but failed to completely abolish the mechanism of sequestration. Only in the presence of insulin was the fractional loss of Na each second constant. Internal application of insulin caused a prompt step-up in the rate of Na efflux, followed by a reduced efflux rate constant. This meant that injected insulin caused the release of sequestered Na, leading to partial saturation of the efflux. The response of the Na efflux to injected denatured insulin, though resembling that to native insulin was much smaller in size. Internal application of lysozyme produced a transitory step-up in the rate of Na efflux but failed to produce the kinetics observed with native or denatured insulin. Overnight exposure of the barnacle to a dose of denatured insulin failed to render the fiber sensitive to external and internal application of denatured or native insulinin vitro. Experiments with ouabain-poisoned fibers showed that external or internal application of native insulin caused stimulation of the remaining Na efflux. They also showed that a 10-fold increase in the concentration of ouabain failed to further reduce the ouabaininsensitive Na efflux. Microinjection of GTP into ouabain-poisoned fibers pre-exposed to insulin resulted in a striking rise in the remaining Na efflux. The magnitude of this effect was considerably greater than that in unexposed fibers. The response which was dose-dependent could be blunted by prior injection of CaCl₂. Similarly, the response to CaCl₂ injection could be blunted by prior injection of GTP. The evidence brought forward is compatible with the view that insulin acts by abolishing the mechanism of internal Na sequestration and by increasing the activity of the guanylate cyclase system.     

Asymmetry in the mechanism for anion exchange in human red blood cell membranes. Evidence for reciprocating sites that react with one transported anion at a time

The kinetics of chloride and bromide transport were examined in intact human red blood cells and resealed ghosts. Because the influx and efflux of halide ions are almost equal (less than 0.01% difference), the stimulation of the exchange flux by external halides could be determined by measuring 36Cl or 82Br efflux. When the external halide concentration was increased by replacement of isoionic, isotonic solutions of sucrose and the nontransported anion citrate, the stimulation of the exchange flux was hyperbolic and was maximum at 20 mM halide externally. The K 1/2-out, the external concentration of chloride or bromide which stimulated the efflux to half of its maximum value, was 3 and 1 mM respectively, 15-fold smaller than K 1/2-in which we found to be about equal to the K 1/2 of halide self-exchange with nearly equal internal and external concentrations. Thus, the transport mechanism behaves asymmetrically with respect to these transported halides. Bromide flux was two-fold greater in bromide-chloride heteroexchange than in bromide-bromide self-exchange but it was still much smaller than the chloride self-exchange flux. The maximum influx and efflux of bromide in exchange for chloride were roughly eqal. Thus, since the maximum transport rates in the two directions are nearly equal, the kinetics of bromide equilibrium exchange with equal concentrations on the two sides are controlled on the inside where K 1/2 is greatest. The K 1/2-out Cl was a hyperbolic function of internal chloride concentration and was proportional to the maximum flux at each internal chloride concentration. These results are evaluated in terms of two broad categories of models. We conclude that, in contrast to other ion transport systems which have been shown to have kinetics of a sequential mechanism, anion exchange is compatible with a ping-pong mechanism in which a single site reciprocates between inside- and outside-facing orientations with asymmetric K 1/2 values.     

Chloride and potassium movements from frog's sartorius muscle in the presence of aromatic anions

Summary The efflux of³⁶Cl and⁴²K from frog's sartorius muscles equilibrated in Ringer's fluid with added KCl were measured in the absence and presence of salicylate, benzoate, and acetylsalicylate. The transmembrane potential and resistance were also measured in sartorii under similar conditions. Although the rate coefficient for loss of⁴²K remained reasonably constant over extended experimental periods for untreated muscles, the rate coefficient for loss of³⁶Cl fluctuated in many muscles giving rise to minima and maxima. The aromatic anions mentioned increased the efflux of chloride while having no detectable effect on the potassium efflux. The aromatic anion-stimulated chloride efflux was insensitive to alterations of external pH and was markedly reduced when nitrate replaced external chloride. No detectable changes in transmembrane potential or resistance were produced by salicylate, the most extensively studied aromatic anion. The results suggest that salicylate and the other aromatic anions stimulate an exchange diffusion mechanism for chloride.     

Evidence for the presence of protein kinase C in barnacle muscle fibers

1. The efflux of 22Na from single barnacle muscle fibers poisoned with ouabain (strophanthin G) is found to be very sensitive to the tumor-promoting agent, phorbol dibutyrate (PDBu). 2. Injection or external application of PDBu leads to stimulation of the ouabain-insensitive component of the Na efflux. This response is dose-dependent, the minimal effective concentration being about 10(-8)M. 3. The observed stimulatory response is completely dependent on the presence of external Ca2+. 4. Biochemical studies including immunoblot analysis reveal the presence in barnacle muscle of a protein kinase C with a mol. wt of 80,000, the activity of which is dependent on phosphatidylserine and Ca2+. 5. Taken together, these results support the view that barnacle muscle fibers possess protein kinase C. They also raise the possibility that protein kinase C plays a role in modulating the ouabain-insensitive component of the Na efflux.     

Effects of External Potassium and Strophanthidin on Sodium Fluxes in Frog Striated Muscle

Unidirectional Na fluxes in isolated fibers from the frog''s semitendinosus muscle were measured in the presence of strophanthidin and increased external potassium ion concentrations. Strophanthidin at a concentration of 10^-5 M inhibited about 80 per cent of the resting Na efflux without having any detectable effect on the resting Na influx. From this it is concluded that the major portion of the resting Na efflux is caused by active transport processes. External potassium concentrations from 2.5 to 7.5 mM had little effect on resting Na efflux. Above 7.5 mM and up to 15 mM external K, the Na efflux was markedly stimulated; with 15 mM K the Na influx was 250 to 300 per cent greater than normal. On the other hand, Na influx was unchanged with 15 mM K. The stimulated Na efflux with the higher concentrations was not appreciably reduced when choline or Li was substituted for external Na, but was completely inhibited by 10^-5 M strophanthidin. From these findings it is concluded that the active transport of Na is stimulated by the higher concentrations of K. It is postulated that this effect on the Na "pump" is produced as a result of the depolarization of the muscle membranes and is related to the increased metabolism and heat production found under conditions of high external K.     

Sensitivity of the sodium efflux in barnacle muscle fibers to the microinjection of ATP

Sodium efflux in barnacle muscle fibers is promptly stimulated by internal application of ATP. This response is markedly augmented by pretreatment of the barnacle fiber with ouabain. ArP is found to be considerably less effective than ATP. It is suggested that the stimulatory response of the ouabain-insensitive Na efflux to the microinjection of ATP may be due to a significant rise in the sarcoplasmic cAMP concentration caused by the catalytic action of an adenyl cyclase system.     

Proton pump activity is required for active uptake of chloride in isolated amphibian skin exposed to freshwater

Net proton secretion and unidirectional chloride fluxes were measured in isolated skin of toads ( Bufo bufo) and frogs ( Rana esculenta) mounted in an Ussing chamber and exposed to a Ringer's solution on the serosal side and a freshwater-like solution (1-3 mM Cl(-)) on the external side. Active proton secretion was 34.2+/-2.0 pmol.cm(-2).s(-1) ( n=18) in frog skin, and 16.7+/-1.7 pmol.cm(-2).s(-1) ( n=10) in toad skin. Proton secretion by toad skin was dependent on the transepithelial potential ( V(T)), and an amiloride-insensitive short-circuit current was stimulated by exogenous CO(2)/HCO(3)(-), indicating the presence of a rheogenic proton pump. Cl(-) influx was 37.4+/-7.5 pmol.cm(-2).s(-1) ( n=14) in frog skin and 19.5+/-3.5 pmol.cm(-2).s(-1) ( n=11) in toad skin. In toad skin, the mean Cl(-) flux ratio was larger than expected for simple electro-diffusion. In 8 of 11 sets of paired skins, influx was greater than the efflux indicating active uptake of Cl(-). Cl(-) influx in toad skin was unaffected by large perturbations (100-150 mV) of V(T), which was accomplished by adding amiloride to the outer bath under open circuit conditions. A component of the Cl(-) efflux seemed to be dependent on V(T). 4,4'-Diisothiocyanato-stilbene-2,2'-disulfonic acid (DIDS; 0.3 mM or 1.3 mM) inhibited Cl(-) influx and, surprisingly, increased Cl(-) efflux in toad skin. Influx and efflux of Cl(-) in toad skin were highly dependent on the external [Cl(-)] in the freshwater range (0.1-4 mM). (36)Cl(-) influx decreased whereas the total Cl(-) efflux increased as a function of external [Cl(-)]. These data indicate the presence of a DIDS-sensitive, electroneutral carrier mechanism with an external binding site for Cl(-). Ethoxzolamide (100 micro M), an inhibitor of carbonic anhydrase, reduced proton secretion and Cl(-) influx in frog skin. Concanamycin A (0.1-10 micro M), a specific vacuolar-type proton pump (V-ATPase) inhibitor, significantly reduced proton secretion in frog skin. In addition, concanamycin A (1 micro M) significantly reduced Cl(-) influx in frog skin. We suggest that the active proton secretion and Cl(-) influx are coupled. We hypothesise that an apical V-ATPase is capable of energising active Cl(-) uptake in fresh water by creating a favourable gradient for an apical HCO(3)(-) exit in exchange for external Cl(-). The data also suggest that a carbonic anhydrase activity provides H(+) and HCO(3)(-) for apically co-expressed proton pumps and Cl(-)/HCO(3)(-) exchangers.     

Catecholamine-stimulated ion transport in duck red cells. Gradient effects in electrically neutral [Na + K + 2Cl] Co-transport

The transient increase in cation permeability observed in duck red cells incubated with norepinephrine has been shown to be a linked, bidirectional, co-transport of sodium plus potassium. This pathway, sensitive to loop diuretics such as furosemide, was found to have a [Na + K] stoichiometry of 1:1 under all conditions tested. Net sodium efflux was inhibited by increasing external potassium, and net potassium efflux was inhibited by increasing external sodium. Thus, the movement of either cation is coupled to, and can be driven by, the gradient of its co-ion. There is no evidence of trans stimulation of co- transport by either cation. The system also has a specific anion requirement satisfied only by chloride or bromide. Shifting the membrane potential by varying either external chloride (at constant internal chloride) or external potassium (at constant internal potassium in the presence of valinomycin and DIDs [4,4'-diisothiocyano- 2,2'-disulfonic acid stilbene]), has no effect on nor-epinephrine- stimulated net sodium transport. Thus, this co-transport system is unaffected by membrane potential and is therefore electrically neutral. Finally, under the latter conditions-when Em was held constant near EK and chloride was not at equilibrium-net sodium extrusion against a substantial electrochemical gradient could be produced by lowering external chloride at high internal concentrations, thereby demonstrating that the anion gradient can also drive co-transport. We conclude, therefore, that chloride participates directly in the co- transport of [Na + K + 2Cl].     

Kinetics of Cl-dependent K fluxes in hyposmotically swollen low K sheep erythrocytes

A detailed kinetic study of K:Cl cotransport in hyposmotically swollen low K sheep red blood cells was carried out to characterize the nature of the outwardly poised carrier. The kinetic parameters were determined from the rate of K efflux and influx under zero-K-trans conditions in red cells with cellular K altered by the nystatin method and with different extracellular K or Rb concentrations. Although apparent affinities for efflux and influx were quite similar, the maximal velocity for K efflux was approximately two times greater than for influx. Furthermore, at thermodynamic equilibrium (i.e., when the ion product of K and Cl within the cell was equal to that outside) a temperature-dependent net K efflux was observed, approaching zero only when the external product reached approximately two times the internal product. The binding order of the ions to the transporter was asymmetric, being ordered outside (Cl binding first, followed by K) and random inside. K efflux but not influx was trans-inhibited by KCl. Trans inhibition of K efflux was used to verify the order of binding outside: trans inhibition by external Cl occurred in the absence of external K, but not vice versa. Thus K:Cl cotransport is kinetically asymmetric in hyposmotically swollen low K sheep red cells.     

Sensitivity of the sodium efflux in barnacle muscle fibers to the microinjection of monensin

Sodium efflux in barnacle muscle fibers is stimulated by internal application of monensin. Pretreatment of fibers with ouabain leads to marked enhancement of the response of the Na efflux to monensin. This response though independent of the Ca²⁺ gradient can be augmented by protonation of a bathing medium free of HCO₃^?.     

Chloride currents from the transverse tubular system in adult mammalian skeletal muscle fibers

Chloride fluxes are the main contributors to the resting conductance of mammalian skeletal muscle fibers. ClC-1, the most abundant chloride channel isoform in this preparation, is believed to be responsible for this conductance. However, the actual distribution of ClC-1 channels between the surface and transverse tubular system (TTS) membranes has not been assessed in intact muscle fibers. To investigate this issue, we voltageclamped enzymatically dissociated short fibers using a two-microelectrode configuration and simultaneously recorded chloride currents (I(Cl)) and di-8-ANEPPS fluorescence signals to assess membrane potential changes in the TTS. Experiments were conducted in conditions that blocked all but the chloride conductance. Fibers were equilibrated with 40 or 70 mM intracellular chloride to enhance the magnitude of inward I(Cl), and the specific ClC-1 blocker 9-ACA was used to eliminate these currents whenever necessary. Voltage-dependent di-8-ANEPPS signals and I(Cl) acquired before (control) and after the addition of 9-ACA were comparatively assessed. Early after the onset of stimulus pulses, di-8-ANEPPS signals under control conditions were smaller than those recorded in the presence of 9-ACA. We defined as attenuation the normalized time-dependent difference between these signals. Attenuation was discovered to be I(Cl) dependent since its magnitude varied in close correlation with the amplitude and time course of I(Cl). While the properties of I(Cl), and those of the attenuation seen in optical records, could be simultaneously predicted by model simulations when the chloride permeability (P(Cl)) at the surface and TTS membranes were approximately equal, the model failed to explain the optical data if P(Cl) was precluded from the TTS membranes. Since the ratio between the areas of TTS membranes and the sarcolemma is large in mammalian muscle fibers, our results demonstrate that a significant fraction of the experimentally recorded I(Cl) arises from TTS contributions.