Modulation of Ca2+ channels by atrial natriuretic peptide in the bovine adrenal glomerulosa cell.

In the bovine adrenal glomerulosa cell, calcium influx through voltage-dependent calcium channels is critical to maintaining an aldosterone secretory response. In patch clamp, atrial natriuretic peptide (ANP) inhibits T-type calcium channel current yet stimulates L-type calcium channel current. In the present study the channel effects of ANP observed in the patch-clamp configuration were extended and related to populations of cells. We observed the following. (i) The effect of ANP on T-channel current resulted in the reduction in the open state probability. ANP decreased the mean open state duration from 14.2 to 1.8 ms/sweep. (ii) In the weakly depolarized cell stimulated by 8 mM K+, ANP reduced the level of aequorin luminescence (a measure of cytosolic calcium) and completely inhibited the stimulated rate of aldosterone secretion, returning it to prestimulation values. These effects are consistent with a decrease in net calcium channel influx and the reported inhibition of T-channel current. In contrast, the calcium channel blocker, nitrendipine, which at low dose selectively blocks L-type calcium channel flux, only slightly reduced luminescence, and partially inhibited the sustained secretory response. (iii) In the strongly depolarized cell, stimulated by 60 mM K+, ANP increased the level of aequorin luminescence consistent with an increase in net calcium channel influx and the reported stimulation of L-channel current. These results indicate that under physiological conditions the inhibition of T-type calcium channels may be involved in the inhibition of the aldosterone secretion induced by ANP.     

Effect of anaesthetics on calcium-induced luminescence of aequorin

The effect of some general and local anaesthetics on the calcium-induced luminescence of aequorin was studied in vitro using a photomultiplier tube and recording technique. Purified aequorin (0.1 microliter) was injected into a 500 micron diameter porous cellulose acetate capillary tube containing 0.5 M KC1, 20 mM phosphate (pH 7.2) and calcium-EGTA buffers. The trapped aequorin was superfused with buffer solutions which sometimes contained anaesthetic (test) solutions. The results showed that some anaesthetics, e.g. urethane, etomidate and lignocaine, increased whereas others, e.g. methohexitone, thiopentone, decreased the light output (luminescence) of aequorin in constant ionized calcium and EGTA buffers. Similar results were produced by some non-anaesthetic drugs, e.g. glycerol, TEA, caffeine, etc. Concentration-response curves for calcium-dependent and -independent luminescence of aequorin showed that anaesthetics variously affected the aequorin response. Some anaesthetics, e.g. lignocaine, increased the maximum response while others, e.g. etomidate, increased the affinity (i.e. decreased EC50s) of aequorin to calcium ions without altering the slope, which remained at about 2. It was concluded that anaesthetics can either excite or depress aequorin luminescence, the effect being dependent on the type and the concentration used.     

Effect of calcium chelators on the Ca2+-dependent luminescence of aequorin.

The luminescence of aequorin, a useful tool for studying intracellular Ca2+, was recently found to be inhibited by the free EDTA and EGTA that are present in calcium buffers. In the present study we have examined the effect of the free forms of various chelators in the calibration of [Ca2+] with aequorin. Free EDTA and EGTA in low-ionic-strength solutions strongly inhibited the Ca2+-triggered luminescence of aequorin, causing large errors in the calibration of [Ca2+] (approx. 2 pCa units), whereas in solutions containing 150mM-KCl, errors were relatively small (0.2-0.3 pCa units). Citric acid in low-ionic-strength solutions and [(carbamoylmethyl)imino]diacetic acid in high-ionic-strength solutions showed no inhibition and did not cause detectable error in the calibration of [Ca2+], indicating that they are better chelators than EDTA and EGTA for use with aequorin.     

A direct demonstration that inositol-trisphosphate induces an increase in intracellular calcium in Limulus photoreceptors

Inositol-trisphosphate was pressure-injected into Limulus ventral photoreceptors; these injections induced electrical responses that mimic several aspects of the electrical responses induced by light. Single cells were also injected with aequorin. Injections of inositol-trisphosphate into such cells induced an increase in luminescence from the intracellular aequorin, even in the absence of extracellular calcium ions. These aequorin responses show directly that inositol-trisphosphate induces an increase in ionized calcium concentration within intact and functioning cells that arises from release of calcium ions from intracellular stores.     

Free calcium wave upon activation in Xenopus eggs

Eggs of Xenopus laevis were preloaded with aequorin and the spatial and temporal pattern of free calcium release in the egg cortex on artificial activation was determined by the aequorin luminescence emitted from the thin cortical layer of naturally opaque eggs. The aequorin luminescence was detected with a photonic microscope system consisting of a light microscope and a two-dimensional photon-counting system with an image processor. A free calcium increase was initiated around the point of prick activation. The state of increased Ca2+ propagated in the cortical cytoplasm of the egg as a wave with a velocity of about 8 micron/sec at 22 degrees C. This wave reached the antipode by 5 to 6 min of prick activation. The spatial pattern of the Ca2+ wave was similar to that of changes in brightness of the egg surface on activation, termed the "activation wave" by K. Hara and P. Tydeman (1979, Wilhelm Roux's Arch. Dev. Biol. 186, 91-94). To examine the temporal correlation between the Ca2+ wave and the activation wave, images of aequorin luminescence and those of the egg cortex taken by incident light illumination were recorded alternately in the same egg. The zone of free calcium increase corresponded to the light (relaxation) zone of the activation wave, where exocytosis of cortical granules and elongation of microvilli were taking place.     

Cell-type-specific calcium responses to drought, salt and cold in the Arabidopsis root

Little is known about the signalling processes involved in the response of roots to abiotic stresses. The Arabidopsis root is a model system of root anatomy with a simple architecture and is amenable to genetic manipulation. Although it is known that the root responds to cold, drought and salt stress with increases in cytoplasmic free calcium, there is currently no information about the role(s) of the functionally diverse cell types that comprise the root. Transgenic Arabidopsis with enhancer-trapped GAL4 expression in specific cell types was used to target the calcium reporting protein, aequorin, fused to a modified yellow fluorescent protein (YFP). The luminescence output of targeted aequorin enabled in vivo measurement of changes in cytosolic free calcium concentrations ([Ca2+]cyt) in specific cell types during acute cold, osmotic and salt stresses. In response to an acute cold stress, all cell types tested as well as plants constitutively expressing aequorin displayed rapid [Ca2+]cyt peaks. However, there were significant quantitative differences between different cell types in terms of their response to cold stress, osmotic stress (440 mM mannitol) and salt stress (220 mM NaCl), implying specific roles for certain cell types in the detection and/or response to these stimuli. In response to osmotic and salt stress, the endodermis and pericycle displayed prolonged oscillations in cytosolic calcium that were distinct from the responses of the other cell types tested. Targeted expression of aequorin circumvented the technical difficulties involved in fluorescent dye injection as well as the lack of cell specificity of constitutively expressed aequorin, and revealed a new level of complexity in root calcium signalling.     

Inositol 1,4,5 trisphosphate releases calcium from specialized sites within Limulus photoreceptors

We have investigated the subcellular distribution and identity of inositol trisphosphate (InsP3)-sensitive calcium stores in living Limulus ventral photoreceptor cells, where light and InsP3 are known to raise intracellular calcium. We injected ventral photoreceptor cells with the photoprotein aequorin and viewed its luminescence with an image intensifier. InsP3 only elicited detectable aequorin luminescence when injected into the light-sensitive rhabdomeral (R)-lobe where aequorin luminescence induced by light was also confined. Calcium stores released by light and InsP3 are therefore localized to the R-lobe. Within the R-lobe, InsP3-induced aequorin luminescence was further confined around the injection site, due to rapid dilution and/or degradation of injected InsP3. Prominent cisternae of smooth endoplasmic reticulum are uniquely localized within the cell beneath the microvillar surface of the R-lobe (Calman, B., and S. Chamberlain, 1982, J. Gen. Physiol., 80:839-862). These cisternae are the probable site of InsP3 action.     

Thermostable mutants of the photoprotein aequorin obtained by in vitro evolution

Aequorin is a photoprotein that emits light upon binding calcium. Aequorin mutants showing increased intensity or slow decay of bioluminescence were isolated by in vitro evolution combining DNA shuffling and functional screening in bacteria. Luminescence decay mutants were isolated at the first round of screening and carried mutations located in EF-hand calcium binding sites or their vicinity. During in vitro evolution, the luminescence intensity of the population of mutants increased with the frequency of effective mutations whereas the frequency of other amino acid substitutions remained roughly stable. Luminescence intensity mutations neighbored the His-16 or His-169 coelenterazine binding residues or were located in the first EF-hand. None of the selected mutants exhibited an increase in photon yield when examined in a cell-free assay. However, we observed that two mutants, Q168R and L170I, exhibited an increase of the photoprotein lifetime at 37 degrees C that may underlie their high luminescence intensity in bacteria. Further analysis of Q168R and L170I mutations showed that they increased aequorin thermostability. Conversely, examination of luminescence decay mutants revealed that the F149S substitution decreased aequorin thermostability. Finally, screening of a library of random Gln-168 and Leu-170 mutants confirmed the involvement of both positions in thermostability and indicated that optimal thermostability was conferred by Q168R and L170I mutations selected through in vitro evolution. Our results suggest that Phe-149 and Gln-168 residues participate in stabilization of the coelenterazine peroxide and the triggering of photon emission by linking the third EF-hand to Trp-129 and His-169 coelenterazine binding residues.     

Imaging calcium dynamics in living plants using semi-synthetic recombinant aequorins

The genetic transformation of the higher plant Nicotiana plumbaginifolia to express the protein apoaequorin has recently been used as a method to measure cytosolic free calcium ([Ca2+]i) changes within intact living plants (Knight, M. R., A. K. Campbell, S. M. Smith, and A. J. Trewavas. 1991. Nature (Lond.). 352:524-526; Knight, M. R., S. M. Smith, and A. J. Trewavas. 1992. Proc. Natl. Acad. Sci. USA. 89:4967-4971). After treatment with the luminophore coelenterazine the calcium-activated photoprotein aequorin is formed within the cytosol of the cells of the transformed plants. Aequorin emits blue light in a dose-dependent manner upon binding free calcium (Ca2+). Thus the quantification of light emission from coelenterazine-treated transgenic plant cells provides a direct measurement of [Ca2+]i. In this paper, by using a highly sensitive photon-counting camera connected to a light microscope, we have for the first time imaged changes in [Ca2+]i in response to cold-shock, touch and wounding in different tissues of transgenic Nicotiana plants. Using this approach we have been able to observe tissue-specific [Ca2+]i responses. We also demonstrate how this method can be tailored by the use of different coelenterazine analogues which endow the resultant aequorin (termed semi-synthetic recombinant aeqorin) with different properties. By using h-coelenterazine, which renders the recombinant aequorin reporter more sensitive to Ca2+, we have been able to image relatively small changes in [Ca2+]i in response to touch and wounding: changes not detectable when standard coelenterazine is used. Reconstitution of recombinant aequorin with another coelenterazine analogue (e-coelenterazine) produces a semi-synthetic recombinant aequorin with a bimodal spectrum of luminescence emission. The ratio of luminescence at two wavelengths (421 and 477 nm) provides a simpler method for quantification of [Ca2+]i in vivo than was previously available. This approach has the benefit that no information is needed on the amount of expression, reconstitution or consumption of aequorin which is normally required for calibration with aequorin.     

The effect of physiologically occurring cations upon aequorin light emission. Determination of the binding constants.

1. The effect of K+, Na+, Mg2+ and pH upon the rate of aequorin utilization has been investigated in the presence of Ca2+. 2. The aequorin light emission in a medium simulating the in vivo cationic conditions for barnacle muscle fibres indicates that two Ca2+ are apparently involved in this process for free calcium concentrations higher than approx. 10(-5) M. However, for free calcium concentrations lower than 10(-6) M, the intensity of light emitted by aequorin shows a steeper dependency upon [Ca2+] than the square low relationship, indicating that a third Ca2+ should be involved in the process of aequorin light emission, as it has been previously predicted (Moisescu, D.G., Ashley, C.C. and Campbell, A.K. (1975) Biochim. Biophys. Acta. 396, 133-140). 3. The inhibitory effect of physiologically occurring cations upon the aequorin light emission can be explained by the cooperative action of two cations, competing with Ca2+ for the reactive sites on aequorin. 4. At a given concentration, Na2+ was found to have a stronger inhibitory effect upon the aequoring light emission than K+. 5. The experiments indicate a strong interaction between Na+ and K+ in this inhibitory process, since for a given total concentration of monovalent cations, a mixture containing both Na+ and K+ has a larger inhibitory effect on the aequorin light response than solutions containing either Na+ or K+ alone. 6. All other interactions between K+, Na+, H+ and Mg2+ appear to be weak. 7. The reaction schemes used for the explanation of these and other published results on aequorin (Moisescu, D.G., Ashley, C.C. and Campbell, A.K. (1975) Biochim. Biophys, Acta 396, 133-140 and Blinks, J.R. (1973) Eur. J. Cardiol. 1, 135-142) are described, and the 'absolute' binding constants of all physiologically occurring cations for aequorin have been determined. 8. Based on these parameters one can make accurate quantitative predictions for the aequoring light response under a variety of ionic conditions, and this suggests that it is possible to determine absolute free calcium concentrations providing that the ionic composition of the solutions is known, and that the relative rate of aequorin utilization is higher than 0.005.     

An investigation of the ionic calcium assay based on the jellyfish protein aequorin

The ionic calcium assay based on the luminescence of the jellyfish protein aequorin was studied. A rapid mixing device was found to be necessary for good reproducibility. The accuracy of the procedure described could depend on the association constants of the calcium chelating agents involved in the test solutions.     

Expression of apo-aequorin during embryonic development; how much is needed for calcium imaging?

Aequorin is a bioluminescent calcium indicator consisting of a 21 kDa protein (apo-aequorin) that is covalently linked to a lipophilic cofactor (coelenterazine). The aequorin gene can be expressed in a variety of cell lines and tissues, allowing non-invasive calcium imaging of specific cell types. In the present paper, we describe the possibilities and limitations of calcium imaging with genetically introduced apo-aequorin during embryonic development. By injecting aequorin into sea urchin, Drosophila and zebrafish eggs, we found that higher aequorin concentrations are needed in smaller eggs. Our results suggest that for measuring resting levels of free cytosolic calcium, one needs aequorin concentrations of at least 40 μM in sea urchin eggs, 2 μM in Drosophila eggs, and only 0.11 μM in zebrafish eggs. A simple assay was used to determine the absolute concentrations of expressed apo-aequorin and the percentage of aequorin formation in vivo. The use of this assay is illustrated by expression of the aequorin gene in Drosophila oocytes. These oocytes form up to 1 μM apo-aequorin. In our hands, only 0.3% of this apo-aequorin combined with coelenterazine entering from the medium to form aequorin, which was not enough for calcium imaging of the oocytes, but did allow in vivo imaging of the ovaries. From these studies, we conclude that coelenterazine entry into the cell is the rate limiting step in aequorin formation. Based on the rate of coelenterazine uptake in Drosophila, we estimate that complete conversion of 1 μM apo-aequorin would take 50 days in zebrafish eggs, 19 days in Drosophila eggs, 7 days in sea urchin eggs or 18 h in a 10 gm tissue culture cell. Our results suggest that work based on genetically introduced apo-aequorin will be most successful when large amounts of small cells can be incubated in coelenterazine. During embryonic development this would involve introducing coelenterazine into the circulatory system of late stage embryos. Calcium imaging in early stage embryos may be best done by injecting aequorin, which circumvents the slow process of coelenterazine entry.     

Changes in Intracellular Free Calcium Concentration during Illumination of Invertebrate Photoreceptors : Detection with Aequorin

Aequorin, which luminesces in the presence of calcium, was injected into photoreceptor cells of Limulus ventral eye. A bright light stimulus elicited a large increase in aequorin luminescence, the aequorin response, indicating a rise of intracellular calcium ion concentration, Ca_i. The aequorin response reached a maximum after the peak of the electrical response of the photoreceptor, decayed during a prolonged stimulus, and returned to an undetectable level in the dark. Reduction of Ca_o reduced the amplitude of the aequorin response by a factor no greater than 3. Raising Ca_o increased the amplitude of the aequorin response. The aequorin response became smaller when membrane voltage was clamped to successively more positive values. These results indicate that the stimulus-induced rise of Ca_i may be due in part to a light-induced influx of Ca and in part to release of Ca from an intracellular store. Our findings are consistent with the hypothesis that a rise in Ca_i is a step in the sequence of events underlying light-adaptation in Limulus ventral photoreceptors. Aequorin was also injected into photoreceptors of Balanus. The aequorin responses were similar to those recorded from Limulus cells in all but two ways: (a) A large sustained aequorin luminescence was measured during a prolonged stimulus, and (b) removal of extracellular calcium reduced the aequorin response to an undetectable level.     

Amino acid sequence of the calcium-dependent photoprotein aequorin

The Ca(II)-dependent photoprotein aequorin produces the luminescence of the marine coelenterate Aequorea victoria. The complete amino acid sequence of aequorin has been determined. A complete set of nonoverlapping peptides was produced by cyanogen bromide cleavage. These peptides were aligned by using the amino-terminal sequence of the intact protein and the sequences of selected arginyl and lysyl cleavage products. Although the aequorin preparations employed in these studies were homogeneous by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the presence of a minimum of 3 isotypes was demonstrated by the location of 17 sites of sequence microheterogeneity. Two amino acid variants were observed at each of 16 positions while 1 position had 3 different replacements. The protein as isolated has 189 amino acids with an unblocked amino terminus. According to the sequence reported here, the molecular weight of the apoprotein is 21 459 while that of the holoprotein is 21 914. The molecule possesses three internally homologous domains which were judged to be EF-hand Ca(II) binding domains by several different criteria. Aequorin is homologous to troponin C and to calmodulin. These findings demonstrate that aequorin is a member of the Ca(II) binding protein superfamily.     

Comparative study of the effect of aliphatic alcohols on energy-dependent accumulation of Ca2+ in intracellular membranes of smooth muscle cells

The effects of ethanol and other aliphatic alcohols on energy-dependent Ca2+ transport in endoplasmic reticulum and mitochondria were studied in digitonin-treated myometrium cells. The Ca2+ uptake in mitochondria increased (on 15-20%) with increasing methanol, ethanol and propanol concentrations in medium, whereas further rise of concentration inhibited this process. Treatments of myometrial cells with short-chain alcohols caused an inhibition of calcium uptake in endoplasmic reticulum. Butanol inhibited both calcium uptake in mitochondria and endoplasmic reticulum. Ca2+ accumulation in intracellular pools is inhibited by aliphatic alcohols in the following order of potency: butanol > propanol > ethanol > methanol. It is concluded that modifying effect of aliphatic alcohols on energy dependent calcium accumulation in intracellular membrane structures is defined as on origin of Ca(2+)-transporting system and (or) properties of these membrane structures so on properties of alcohols.     

The mechanism of increase in the ATPase activity of sarcoplasmic reticulum vesicles treated with n-alcohols.

Treatment of sarcoplasmic reticulum vesicles with aqueous n-alcohols caused inhibition of calcium uptake and enhancement of ATPase activity. With increasing alcohol concentration, the ATPase activity reached a maximum (in the case of n-butanol, at about 350 mM) and then decreased. The effect of n-butanol was extensively studied. The purified ATPase enzyme and leaky vesicles treated with Triton X-100 or phospholipase A showed high ATPase activity in the absence of n-butanol. With increasing n-butanol concentration, their atpase activities began to decrease above about 250 mM n-butanol, without any enhancement. In the presence of ATP, the turnover rate of calcium after calcium accumulation had reached a steady level was the same as that at the initial uptake. n-Butanol did not affect these rates. Kinetic analyses of these experiments were carried out. The mechanisms of calcium transport and of increase of ATPase activity in the presence of alcohol were interpreted as follows. After calcium accumulation had reached a steady level, fast influx and efflux continued; the influx was coupled with phosphorylated enzyme (E-P) formation and most of the efflux was coupled with rephosphorylation of ATP from ADP and E-P. The observed ATPase activity is the difference between these two reactions. If alcohol molecules make the vesicles leaky, calcium ions will flow out without ATP synthesis and the apparent ATPase activity will increase. The effect of alcohols on sarcoplasmic reticulum vesicles was separated into two actions. The enhancement of ATPase activity was attributed to a leakage of calcium ions from the vesicles, while the decrease of ATPase activity at higher concentrations of alcohols was attributed to denaturation of the ATPase enzyme itself. The two effects were interpreted in terms of equilibrium binding of alcohol molecules to two different sites of the vesicles; leakage and denaturation sites. Similar analysis was carried out for various n-alcohols from methanol to n-heptanol. The apparent free energies of binding of the methylene groups of n-alcohols were evaluated to be -863 cal/mol for the leakage site, and -732 cal/mol for the denaturation site.     

Comparative aspects of the calcium-sensitive photoproteins aequorin and obelin.

1. The calcium-dependency of the process of light emission has been investigated for the photoproteins aequorin and obelin. 2. The experimental curves of light production, expressed as a percentage of the maximal rate of utilisation, versus pCa are accurately predicted by the cooperative action of at least 2Ca-2+ for aequorin and at least 3Ca-2+ for obelin. 3. At low total monovalent cation concentrations, a pH change from 6.8 to 7.1 shifts the light production vs pCa curve by approx. 0.2 pCa units to the right for aequorin, while that for obelin is shifted by some 0.37 pCa units. 4. Other monovalent cations, such as Na+ are able to compete with Ca-2+ for the active sites of aequorin and also shift the light production vs pCa curve to the right. There is no apparent change in the calcium stoichiometry for light production under these conditions. 5. The same calcium stoichiometry for light emission was also obtained for aequorin or obelin in the presence of either unbuffered Ca-2+ solutions or of calcium/EGTA buffers.     

Effects of halothane, enflurane, and isoflurane on measurements of Ca(2+) by calcium electrode and aequorin luminescence

We assessed the possible effects of the volatile halogenated anesthetics halothane, enflurane, and isoflurane on Ca(2+) electrode measurements and on the Ca(2+) sensitivity of the bioluminescent protein aequorin. In Ca(2+)-EGTA buffers of different pCa values (7. 870, 6.726, 6.033, 4.974, 4.038, and 2.995) and in serial Ca(2+) dilutions (10(-4), 10(-3), and 10(-2) M), halothane, enflurane, and isoflurane each caused a concentration-dependent and reversible increase in the absolute value of the negative electrode potential. Isoflurane and enflurane had larger effects than halothane. Neither of these anesthetics changed aequorin luminescence at any pCa tested in the range 2-8. There was no potentiation or inactivation of aequorin luminescence over a period of up to 2 h. These results suggest that (1) halothane, enflurane, and isoflurane interfere with Ca(2+) electrode measurements, most likely by changing the physicochemical properties of the membrane; (2) these anesthetics do not inactivate or otherwise modify the characteristics of the reaction of Ca(2+) with aequorin; and (3) these anesthetics do not change the apparent affinity of EGTA for Ca(2+).     

Effects of ryanodine on intracellular Ca2+ transients in mammalian cardiac muscle

We observed the effects of ryanodine on the aequorin luminescence, membrane potential, and contraction of canine cardiac Purkinje fibers and ferret ventricular muscle. In canine Purkinje fibers, ryanodine (10 nM to 1 microM) abolished the spontaneous spatiotemporal fluctuations in [Ca2+] that occur as a result of Ca2+-induced Ca2+ release from the sarcoplasmic reticulum (SR) during exposure to low-Na+ solutions. Ryanodine strongly reduced the twitch and both components of the intracellular aequorin luminescence signal (L1 and L2), which normally accompanies contraction. The small luminescence signals that remained in ryanodine could be abolished by a Ca2+ channel blocker (nitrendipine, 10 microM). The plateau phase of the action potential was reduced by nitrendipine in the presence of ryanodine, which suggests that Ca2+ current was not blocked by ryanodine. In ferret ventricular tissue, ryanodine (1 microM) prolonged the action potential and reduced the peak amplitudes of both the aequorin transient and the twitch, while greatly prolonging the time-to-peak of both signals. Increases in extracellular [Ca2+] restored the peak amplitudes of the twitch and the aequorin luminescence, but did not restore the normal time-to-peak. The results show that in both tissues, the negative inotropic effect of ryanodine is due to the reduction of the intracellular [Ca2+] transient. Inasmuch as neither Ca2+ entry via surface membrane Ca2+ channels nor Na+-Ca2+ exchange appears to be blocked by ryanodine, the most probable cause of reduction of the [Ca2+] transient is an inhibition of Ca2+ release by the SR.     

Triphasic effects of short chain n-alcohols on synaptic membrane transport of choline and of gamma-aminobutyric acid

n-Alcohols, when added in increasing concentrations, had an unusual triphasic effect on the uptake of choline and of gamma-aminobutyric acid by isolated synaptosomes. There was slight inhibition of these uptakes at low n-alcohol concentrations, followed by a sharp peak of uptake enhancement, and then greater inhibition. The n-alcohol concentrations required for these effects were proportional to published n-alcohol membrane/buffer partition coefficients, with the peaks of uptake enhancement occurring at 60 mM n-propanol, 20 mM n-butanol and 7.5 mM n-pentanol. Synaptosomal membrane potential, as estimated from synaptosomal accumulation of the permeant cation [3H]tetraphenylphosphonium, was not affected by n-alcohols in the concentrations used in this study, suggesting that neither the inhibitory or enhancing effects of these n-alcohols were attributable to changes in trans-synaptosomal membrane ion gradients. The inhibiting and enhancing effects of n-alcohols could be reproduced in determinations of gamma-aminobutyric acid uptake by isolated synaptic plasma membranes, suggesting that the observed effects are due to a direct action of the n-alcohols on the synaptosomal plasma membrane. These effects may be attributable to a change in membrane binding of these alcohols from the membrane core to the membrane surface as alcohol concentration is increased.