S100-glia regulation of GABA transport across the nerve cell membrane

Antisecretory factor peptide derivatives specifically inhibit [3H]-gamma-amino-butyric acid/36Cl- out-->in permeation across the isolated rabbit Deiters' neuronal membrane

AIMS

Antisecretory factor (AF) is a 41-kDa protein, its main function being the regulation of intestinal ion/water transport, but it also inhibits chloride and gamma-amino-butyric acid transport across nerve cell membranes. The present experiments were designed to evaluate whether the same AF peptide sequence mediates the permeability effects seen at the nerve cell membrane and in the rat small intestine.

METHODS

Four peptides were prepared by the solid phase technique with sequences derived from positions 1-51 of the full-length antisecretory factor AF and tested on nerve cell membranes isolated from rabbit Dieter cells.

RESULTS

AF peptides containing the active 36-51 peptide exerted a blocking effect of the out-->in permeation of 36Cl- as well as of [3H]-gamma-amino-butyric acid. The minimal dose causing inhibition, however, varied between 10(-11) m (AF10) and 10(-7) m (AF13). The most potent peptides have been shown previously to be active in inhibiting experimental diarrhoea in vivo in small intestinal ligated loops in rats. The non-active sequence AF23-32 did not inhibit any of the two permeation markers in vitro, a result which supports the lack of activity found also in vivo.

CONCLUSION

The results suggest that AF, or AF derivatives, counteract intestinal hypersecretion by blocking anion permeation across large anionic pores. Such a blocking effect could also influence the generation of action potentials in enteric nerve cells controlling the intestinal water and ion transport system.

Concomitant distribution shift of glial GABA transporter and S100 calcium-binding proteins in the rat retina after kainate-induced excitotoxic injury

The goal of this study was to elucidate the involvement of neuronal and glial calcium-binding proteins in the stimulation of gamma-aminobutyric acid (GABA) transport system by kainate-induced excitotoxicity in the rat retina. We used immunohistochemical method to assess the localization of GABA reuptake and calcium-binding proteins. After systemic administration of kainate, the neuronal GABA transporter does not show an association with calbindin D-28K. However, the localization of the GAT-3 transport system in Müller glial cells is closely correlated with the S100 proteins interacting with glial fibrillary acidic protein (GFAP) in response to kainate injury. Furthermore, we demonstrate that kainate-mediated excitotoxicity induced concomitant distribution shift of glial GABA transporter, S100 proteins and GFAP in the distal processes and endfeet of glial cells during the first 48 h.

Unorthodox view of the functioning of a GABAA synapse

1. Studies about the permeation of labelled chloride and GABA across single plasma membranes microdissected from vestibular Deiters' neurons have yielded two unexpected results: (a) intracellular GABA stimulates chloride permeation in an asymmetric fashion (efflux being favoured); (b) under certain conditions GABA permeates by a diffusion mechanism in the out-->in direction across these plasma membranes. 2. These two main results have been obtained over many years together with a host of other indications about the fine mechanism of these events. Thus, a picture has emerged of their physiological meaning within the context of the functioning of the GABAA synapses between the Purkinje cells and the Deiters' neurons. 3. In short, it is proposed that at these synapses GABA accumulates into the postsynaptic neuron after its release and activation of the postsynaptic receptors. GABA accumulated in the Deiters' neurons is involved in the process of chloride extrusion to build an inward directed electrochemical gradient for chloride.

GABA and chloride permeate via the same channels across single plasma membranes microdissected from rabbit Deiters' vestibular neurones

The permeation of labelled gamma-aminobutyric acid (GABA) across single microdissected Deiters' membranes has been studied in a microchamber system. The GABA permeation is via pores which are blocked by 4,4'-diisothiocyanato stilbene-2-2'disulphonic acid (DIDS). As this substance blocks as well chloride permeation across these membranes we tested whether GABA and chloride permeate across the same pores. Membrane pre-treatment with different doses of corticotropin releasing factor (CRF), a membrane permeant cyclic AMP analogue and phalloidin parallelly block the permeation of the two substances. Thus, it is most probable that GABA and chloride pass across the same pores. These pores may be swelling activated ones, opened by the mechanical stress on the membranes in the microchamber system. The passage of GABA across these pores may be of physiological importance in the termination of GABA inhibitory action on the vestibular Deiters' neurones.

Holger Hydén's technique of preparation of single Deiters' neurons and study of permeability characteristics of their plasma membranes

The protocols described here refer to Hydén's technique of isolation and microdissection of vestibular Deiters' neurons from adult mammals. The isolation of Deiters' cells from bovine is described and an example is given of the immunocytochemical visualization of their GABA(A) receptors by monoclonal antibodies against the beta(2/3) subunit. In addition, the protocol of the method for isolation of Deiters' cells from adult rabbit brain stem, the preparation of their plasma membranes and the study of their permeability characteristics is presented. Also in this case, examples of its application to the determination of chloride permeability and its modulation by GABA are given.

GABA uptake by rabbit restiform body homogenates

Restiform body (inferior cerebellar peduncle) preparations were obtained from rabbit brain stem slices and homogenized. When challenged with labelled GABA, these homogenates took it up briskly. We have characterized pharmacologically this uptake which resulted almost equally neuronal and glial. The neuronal component of the GABA uptake might be due to the adjacent cochlear nuclei coming along in the preparations, whereas the glial component probably belongs to the restiform body proper. Another possibility is that actually both components are due to the myelinated fibers and glia which make up the restiform body.

Modulation by acute stress of chloride permeation across microdissected vestibular neurons membranes: different results in two rabbit strains and CRF involvement

Free hand isolation of adult rabbit vestibular Deiters' neurons and dissection of their single membranes allows the study of their ionic permeability characteristics in a microchambers device. In the case of hare-like rabbits, the dissection of such membranes presents evidence of a high basal permeation of labelled chloride, possibly related to mechanical disturbance of the plasma membrane-related cytoskeleton and activation of chloride channels. This did not apply to the laboratory strain of white New Zealand rabbits. However, membranes from hare-like rabbits which were stressed by being rotated on a platform before the experiment, behaved like those from the New Zealand strain. Vice versa, habituation to handling day after day of New Zealand rabbits resulted in a chloride permeation equal to that of unstressed hare-like rabbits. We propose that the stressful conditions result in the release of neurochemical messages to the vestibular Deiters' cells which influence their electrophysiological behavior. The corticotropin releasing factor (CRF), a stress-related peptide present in the climbing fibers, actually blocks the basal chloride permeation across the Deiters' membranes and this effect is partially reversed by its receptor antagonist, alpha-helical CRF [9-41].

Intracellular GABA-activated in-->out permeation of chloride across the Deiters' neuron membrane: modulation by phosphorylating activities

The modulation of intracellular GABA activated 36Cl- in-->out permeation across single Deiters' neuron membranes has been studied in a microchamber system. Addition of Mg2+/ATP on the membrane cytoplasmic side reduces strongly the GABA effect as does ATP alone. However, the greatest inhibition of the GABA effect is given by the addition of Mg2+ to the intracellular side buffer: a complete block of the stimulation by GABA of 36Cl- in-->out permeation. This is interpreted as due to the presence in this case of a constant concentration of exogenous Mg2+ acting together with endogenous ATP in the small cytoplasmic layer on the membrane inner side. The addition of ADP to Mg2+/ATP increases the inhibitory effect of the latter. This is presumably due to an extra increase of ATP, locally under the membrane, due to phosphorylation of ADP by endogenous phosphocreatine. Overall, the data confirm that phosphorylating conditions impair the intracellular GABA action on 36Cl- in-->out permeation.

Chloride permeation across the Deiters' neuron plasma membrane: activation by GABA on the membrane cytoplasmic side

Single plasma membranes were microdissected from Deiters' neurons freshly obtained from the lateral vestibular nucleus of the rabbit and their chloride permeability was studied in a microchamber system. The basal in-->out 36Cl- permeation initially found was brought to zero by Zn2+, 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid and iodide. GABA on the membrane cytoplasmic side resulted in a measurable in-->out 36Cl- passage, which was blocked by the GABA(A) antagonists bicuculline and picrotoxin. This effect peaked at 1 microM GABA on the inner side of the membrane. At higher GABA concentrations, a strong desensitization of the effect was found. Stimulation of Cl- permeability by GABA on the extracellular side of the membrane peaked at much higher GABA concentrations, 10-100 microM. This excludes an effect due to passage of the neurotransmitter from the inner to the outer compartment in our microchamber device. Moreover, this possibility is also dismissed by the fact that 1 microM GABA on the membrane outside did not evoke any 36Cl- in-->out permeation. In addition, pentobarbitone by itself could also stimulate 36Cl- in-->out permeation when added on the cytoplasmic side of Deiters' membrane. On these bases and in agreement with our previous reports, we propose that structures behaving pharmacologically as GABA(A) receptors respond to low levels of GABA on the cytoplasmic side of these neurons' membranes. We suggest that these structures are devices that, at the expense of ATP consumed in their phosphorylation, extrude Cl- after postsynaptic GABA uptake into the Deiters' neuron.

Chicks injected with antisera to either S-100 alpha or S-100 beta protein develop amnesia for a passive avoidance task

The cellular expression of S-100 beta protein is upregulated in Alzheimer's disease and in Down's syndrome, and this protein has been implicated in memory-related processes in laboratory animals. However, the possibility that the alpha subunit of S-100 is also involved in memory has not yet been examined. In the present study, day-old black Australorp white Leghorn cockerel chicks (Gallus domesticus) received injections of monoclonal antisera to S-100 alpha (1:50) or S-100 beta (1:500) into each hemisphere immediately after training on a one-trial passive avoidance task. The chicks displayed significantly lower retention levels than control birds that had been injected with antisera to carbonic anhydrase, or with saline (p < .01). S-100 alpha antisera had an amnestic effect when injected between 0 and 20 min after training, with memory deficits occurring from 30 min post-learning, at the point of transition between the A and the B phases of the Gibbs-Ng intermediate memory stage. By contrast, the S-100 beta antisera needed to be injected either 5 min before or immediately after training and produced amnesia 10 min earlier, at the start of the A phase of the intermediate memory stage. We conclude that the two subunits of the S-100 protein are required at different points in the sequence of events leading to the consolidation of passive avoidance memory.

Further evidence for the presence of gamma-aminobutyric acidA (GABAA) receptors on the cytoplasmic side of Deiters' membrane

1. The permeation of labeled Cl- across single nerve membranes microdissected from rabbit Deiters' neurons was studied in a microchamber system. The in----out permeation of the ions was evaluated under control conditions and in the presence of either 10(-6) M GABA or 10(-6) M GABA plus 10(-5) M bicuculline methiodide (BMI) on the membrane cytoplasmic side. 2. In 32 experiments, involving one animal each, at least two membranes served as controls and at least two others were studied with the addition of GABA. Within each experiment all the membranes were obtained from the same animal. 3. In an additional 10 experiments, involving one animal each, at least two membranes served as controls and at least two others were studied in the presence of GABA plus bicuculline methiodide on the membrane cytoplasmic side. 4. The data show that 10(-6) M GABA on the Deiters' membrane cytoplasmic side stimulates Cl- permeation in----out by 42% (P = 0.0000001). When 10(-5) M BMI was present together with GABA, no stimulation of Cl- in----out permeation occurred.

Can Cl- ions be extruded from a gamma-aminobutyric (GABA)-acceptive nerve cell via GABAA receptors on the plasma membrane cytoplasmic side?

1. In this commentary we discuss results obtained by a micromethod for the study of Cl- permeability across single nerve membranes from rabbit Deiters' neurons. 2. These results showed the presence of GABAA receptors on the nerve cell membrane cytoplasmic side. 3. We could show that these receptor complexes have a higher affinity for GABA than their extracellularly facing counterparts. Moreover, they present a phenomenon of desensitization. Another distinct property is that upon activation by GABA, they expose positive charges at their cytoplasmic mouths. 4. We propose that these receptor complexes could function in situ as a device for extruding Cl- anions from the nerve cell interior. This phenomenon would create an electrochemical gradient for Cl- penetration into the cell upon the action of extracellular GABA, after its presynaptic release.

Stimulation of 36Cl- permeation in the in----out direction across the Dieters' neuron membrane by GABA on its cytoplasmic side: effect of different ionic conditions

The permeation of labelled Cl- ions across single plasma membranes microdissected from rabbit Deiters' neuron was studied in a microchamber system. In particular, we studied 36Cl- in----out permeation and its stimulation by 10(-6) M GABA on the cytoplasmic side under different ionic conditions on both sides of the membrane. Three main results were found: a) The GABA effect turns up at a cytoplasmic side [Cl-], 21 mM, in the range of the normal steady state intracellular Cl- concentration. It disappears both at tracer level of Cl- on the cytoplasmic side and when [Cl-] is high there (140 mM). b) The increase in ionic strength due to the equinormal substitution of monovalent anions (Cl- and acetate) with the trivalent impermeant anion citrate on both sides of the membrane erases the GABA effect even if Cl- is at the optimal cytoplasmic side concentration, 21 mM. c) Citrate ions reduce to the limit of significance the GABA effect even when they are only on the membrane extracellular side and [Cl-] is at the optimal level on the other side. These results confirm that GABA stimulated Cl- permeation in the in----out direction is via Cl- channels exposing positive charges at their cytoplasmic mouth. In addition, they point out that such GABA activated channels are endowed with a partial electrical positivity at their extracellular exit.

Effect of phosphatidylserine on the basal and GABA-activated Cl- permeation across single nerve membranes from rabbit Deiters' neurons

The permeation of labeled Cl- ions across single plasma membranes from Deiters' neurons has been studied in the presence of various concentrations of phosphatidylserine (PS) on their extracellular side. PS reduces significantly basal Cl- permeation only at 10(-5) M on the membrane exterior. No effect was found at other concentrations. GABA activable 36Cl- permeation is heavily reduced and almost abolished at 10(-11) - 10(-5) M phosphatidylserine. This exogenous phosphatidylserine effect is difficult to interpret in relation to the function of the endogenous phospholipid. However, it may be involved in the epileptogenic effect in vivo of exogenous phosphatidylserine administration to rats.

"Intracellular" GABA affects the equilibrium distribution of Cl- across the plasma membrane of a GABA acceptive neuron

The permeability of Cl- ions through single microdissected plasma membrane from Deiters' neurons was studied by a microtechnique. In particular, the time course of the passage of 36Cl- ions from a microchamber, M1, to another one, M2, across the membrane was followed. This study was performed with or without gamma-amino-butyric acid (GABA) in the two microchambers. The results suggest that in basal conditions the high intracellular concentration normally present in these neurons, 3.3 mM (1), causes a higher permeability of Cl- in the direction inside----outside in the respect of the plasma membrane. "Extracellular" GABA, 0.1 mM, is able to abolish this imbalance in Cl- permeability in the two opposite directions. This event appears to be the basis for GABA induced hyperpolarization of these neurons.

Effect of anti-S-100 serum on 36Cl- ion permeability across the Deiters' neuron plasma membrane

1. A microtechnique allowing the study of single plasma membranes from the gamma-aminobutyric acid (GABA)-acceptive Deiters' neuron has been utilized in order to assess the effect of both S-100 protein and its antiserum on 36Cl- permeability through such membranes. 2. The results show that both S-100 (in the Ca2+ form) incorporation onto the external side of the membranes and their preincubation with anti-S-100 serum stimulate 36Cl- permeability. 3. These effects are not additive with that of GABA, indicating that both S-100 and anti-S-100 act via the GABAA receptor complexes on Deiters' membranes. 4. When the membranes were incubated first with S-100/Ca2+ and then with anti-S-100, the second treatment resulted in the disappearance of the S-100 effect. However, the anti-S-100 effect was fully displayed.

The effect of antisecretory factor on the permeability of nerve cell membrane to chloride ion

The antisecretory factor (ASF) is a hormone-like protein (m.w. 60,000) that most effectively counteracts hypersecretion in vivo in the small intestine of pigs and rats. The present report demonstrate that 10(-13) moles of ASF inhibits significantly the 36Cl- permeation through the isolated neuronal plasma membrane of Deiters' cells in rabbits. This effect was enhanced by 0.2 mM gamma-aminobutyric acid (GABA), and quenched by the addition of anti-ASF immunoglobulins; pretreatment of the neuronal membrane with nipecotic acid (10(-6) M) or with bicuculline (10(-3) M) abolished the ASF action whilst picrotoxin (10(-4) M) pretreatment left the inhibitory effect of ASF unaffected. The results suggest that ASF blocks chloride channels in neuronal membranes, including those channels activated by GABA.

GABAA receptor complexes are present on both sides of a GABA-acceptive neuronal membrane

A micromethod allowing the study of the characteristics of single GABA-acceptive membranes microdissected from Deiters' neurones was used in order to assess the effects of both "extra"- and "intra"-cellular GABA on Cl- permeability. The results indicate that GABA can activate Cl- permeability in the in----out direction when it is present on the cytoplasmic side of the membrane. Moreover, as already described, it can activate Cl- permeability in the opposite direction when present on the "extracellular" side of the membrane. Both these phenomena are blocked by GABAA receptor inhibitors, bicuculline and picrotoxin. The presence of GABAA receptors on both sides of the membrane is discussed as the possible basis for synaptically released GABA hyperpolarising action on these neurones.

Effect of sodium butyrate on S-100 protein levels and the cAMP response

Sodium butyrate (NaB), when added to cell cultures, produces a variety of morphological and biochemical changes. We examined its effects, in nM concentrations, on the expression of two glioma cell-associated proteins, glial fibrillary acidic protein (GFAP) and S-100 protein in human glioma-derived cell line (RF), and of S-100 protein in the C6 rat glioma cell line. GFAP levels decreased by about 50% in the RF cell line, and S-100 protein levels decreased protein levels decreased by about 40% after treatment with 1 mM NaB for 48 h. In the C6 rat glioma cell line, isoproterenol with theophylline was found to increase S-100 levels by two-fold over basal levels. NaB was found to inhibit the induction of S-100 protein but exhibited no effect on the basal levels of the protein. Other short chain fatty acids, including sodium propionate and sodium isobutyrate, exhibited partial inhibitory activity. NaB, at an EC50 of 1 mM, was also found to inhibit both the beta-adrenergic and the forskolin-mediated increase in cAMP levels in these cells. This suggests that NaB may inhibit cells from expressing S-100 protein by attenuating cAMP levels.

Increase in chloride ion permeability across the nerve cell membrane after the endogenous antigen S-100 incorporation

36Cl fluxes through microdissected Deiters' neuronal membranes have been studied in a microchamber device simulating the extra- and intracellular compartments. GABA stimulates Cl- permeability through the membranes by 24%. Also, S-100/Ca2+ incorporation into the Deiters' membrane increases 36Cl- permeation to a similar extent. The two effects do not appear to be additive. This circumstance is interpreted as indicating that S-100/Ca2+ exerts its effects via postsynaptic GABAA receptor complexes.

Calcium ions in the presence of exogenous phosphatidylserine interfere with GABA diffusion through the Deiters' neuron membrane

Diffusion of GABA through the plasma membrane of GABA-acceptive neurons might be a mechanism of importance for the termination of its synaptic action. In the present investigation we studied the effects of phosphatidylserine (PS) (10(-4)-10(-3) M), Ca2+ 2 mM and PS + 2 mM Ca2+ on such a process. The method involved the use of single microdissected Deiters' membranes which were put between two small microchambers in order to study the passage of GABA across the membrane. The results show that whereas PS and Ca2+ by themselves have no effect on such a process, PS + 2 mM CaCl2 give a significant, although slight, inhibition. The hypothesis that Calcium ion + PS effect is due to a disturbance of the interaction between GABA and endogenous PS molecules of the membrane is discussed.

gamma-Aminobutyric acid stimulates chloride permeability across microdissected Deiters' neuronal membrane

Fluxes of 36Cl- across freshly prepared Deiters' neuronal membranes have been studied in a two-compartment microchamber simulating the extra- and the intracellular space. The rate of 36Cl- influx was enhanced by gamma-aminobutyric acid (GABA) (10(-4) M), the effect being reversed by picrotoxin (10(-4) M) and by bicuculline (10(-5) M). Diazepam (10(-8)-10(-7) M) did not potentiate the response to GABA and rather depressed it. However, a barbiturate site is most probably present in the GABA receptor complexes since pentobarbitone (10(-4) M) was able to stimulate 36Cl- permeability to the same extent as GABA itself.

Asymmetric diffusion into the postsynaptic neuron: an extremely efficient mechanism for removing excess GABA from synaptic clefts on the Deiters' neurone plasma membrane

Microdissected Deiters' neuron plasma membranes have been used for studying the passage of GABA through the membrane both in the inward and outward direction. Working with 0.2 mM GABA in the compartment simulating the outside of the neurone and with 2.0 mM GABA in the one simulating the inside we found a net transport of GABA towards the inside. This mechanism does not require a Na+ ion gradient across the membrane. The nature of the transport process involved was studied by determining the rate of [3H]-GABA inward passage as a function of GABA concentration (1 nM - 800 microM) on the outward side of the membrane. The results have shown that until 50 microM a diffusion process (v = D1 X C, where D1 = 3.1 X 10(-11) 1/micron 2 X sec) is the sole mechanism involved. Above 50 microM a second diffusion process is activated v = D2 X (C - 50 X 10(-6), where D2 = 2.8 X 10(-11) 1/micron 2 X sec. Taking in account both inward and outward directed diffusion, one can calculate 16 microM as the equilibrium concentration of GABA on the outward side of the membrane. From a kinetic point of view, these diffusion processes are able to reduce GABA concentration in a synaptic cleft from 3 mM to 20 microM within 3 mu sec. These diffusion systems are discussed as extremely efficient in removing the excess of released GABA in the synaptic cleft.

gamma-Aminobutyric acid (GABA) removal from the synaptic cleft: a postsynaptic event?

In the present commentary we discuss the adequacy of Na+ transport-coupled presynaptic gamma-aminobutyric acid (GABA) uptake systems for the removal of GABA from the synaptic cleft. This discussion is based on the accepted stoichiometry for GABA presynaptic internalization, GABAout + 3Na+out + K+in in equilibrium GABAin + 3Na+in + K+out, on the parameters reported in the literature for typical synaptosomal preparations, and on the assumption that GABA removal must be a quick event (less than or equal to 2 msec), as derived from electrophysiological studies. On these bases, we have developed a calculation in order to evaluate the time course of synaptic cleft GABA removal by presynaptic systems and ended up with an overall value (t approximately 0.3 sec) which does not fit with the data derived from electrophysiological recordings. Moreover, we calculated that if such systems had the function of removing GABA within 2 msec, as it should be, a large depolarization would be brought about in GABAergic boutons, resulting ultimately in further GABA release. These considerations together with biochemical and pharmacological experimental results seem to exclude that presynaptic uptake systems have the function of removing GABA from the synaptic cleft. Our experimental data on the ability of a GABA-acceptive postsynaptic membrane (Deiters' neuron membrane) to transport GABA indicate that this system may have the correct characteristics for removing the neurotransmitter. This refers to both the kinetics and the electrophysiological consequences of the phenomenon.

An inhibitory protein of intestinal fluid secretion reverses neuronal GABA transport

Intestinal challenge with cholera toxin induces the synthesis of a hormone-like protein which counteracts intestinal hypersecretion. This study shows that the protein also inhibits GABA transport across the plasma membrane of Deiters' cells in rabbits. The inhibitory action of the protein was dose dependent, and 10(3) times more potent than met 5-enkephalin, hitherto the most effective known inhibitor of GABA transport in vitro. The influence of the protein on the plasma membrane was reversible, and did not affect either postsynaptic binding or uptake of GABA.

S-100 protein in normal, osteoarthrotic, and arthritic cartilage

The occurrence of the S-100 protein was studied in normal and pathological cartilage from patients with osteoarthrosis and rheumatoid arthritis. In normal cartilage all cells of the different zones exhibit immunoreactivity for this protein. An identical distribution is observed in cases of osteoarthrosis and rheumatoid arthritis. Cellular pannus tissue usually is devoid of the S-100 protein. However, if chondroid metaplasia occurs in this tissue the cells become positive for the S-100 protein. From these results it is concluded that a chondroid metaplasia not only leads to a matrix comparable to cartilage but also contains cells that gain further characteristics of original chondrocytes.

Inhibition by sodium valproate of the transport of GABA through the Deiters' neurone plasma membrane

The transport of GABA through the microdissected plasma membrane Deiters' neurone reflects the physiological event of postsynaptic uptake of GABA by its uptake carrier. Sodium valproate at concentrations greater than or equal to 2.4 mM was able to decrease markedly (57%) such a transport. This effect, which reduces the efficiency of the GABA postsynaptic inactivation process, might be a mechanism for the potentiation by valproate of the synaptic action of GABA.

Increased binding of GABA to its post-synaptic carrier sites on the plasma membrane of Deiters' neurons after a learning experiment in rats

A new micromethod for studying the interaction of gamma-aminobutyric acid (GABA) with its post-synaptic uptake in a defined type of nerve cell is described. The method involves the isolation by free hand microdissection of Deiters' nerve cells from the rabbit lateral vestibular nucleus and their incubation with tritiated GABA in the presence of 100 mM Na+ at 4 degrees C. From the binding data a Kd was calculated for this interaction of 104 nM and a BMax of 8.4 X 10(5) sites/neuron. The method was applied to the study of the modifications of the binding of GABA to Deiters' neurons from control rats and rats trained to balance on a steel wire in order to reach food. This performance is a powerful stimulation to the vestibular system. The results show that, in the binding experiment with 100 nM [3H]GABA, the amount of GABA which specifically binds to the Deiters' neurons is increased by 38% in the trained rats. Analogously, when the incubation with GABA was performed at 37 degrees C, involving an intake of GABA into the neurons, the amount of GABA taken up increases by 50% in the trained group. No GABA-binding or uptake increase was found when animals were subjected to intense vestibular stimulation for a short period without learning. These results indicate that when rats learn a behavioral test which involves an improved vestibular control, there is a specific neurochemical modification in the neurons of the lateral vestibular nucleus. This modification seems to be of importance for the physiology of the neuronal circuits controlling the vestibular function in the rat.

Novel clonal strains from adult rat anterior pituitary producing S-100 protein

S-100 protein, one of the unique proteins found in the nervous system, has recently been discovered unexpectedly in the rat anterior pituitary. Immunocytochemistry reveals that stellate, follicular and folliculostellate cells, and marginal cells of the rat anterior pituitary contain this protein; however, as far as we know, there are no reports on the physiological role of this protein in the anterior pituitary. In the study reported here, three S-100 protein-producing clonal strains (JH-S3, JH-S8 and JH-S12) from adult rat anterior pituitaries were established by using the single cell-plating feeder layer method. These new clonal strains reveal that the S-100 protein-producing cell is an independent cell type of the anterior pituitary. Both cultures and grafts of the JH-S3 cells stain immunocytochemically with anti-S100 protein IgG fraction. Moreover, the S-100 protein and conditioned medium of JH-S3 clonal cells both stimulate release of prolactin from prolactin-secreting clonal cells (1G4) in vitro.

Distribution of S-100 protein outside the central nervous system

The distribution of S-100 outside the central nervous system in humans and rats was explored using antiserum to S-100 and the peroxidase anti-peroxidase method of Sternberger. In peripheral nerves the Schwann cells and the outermost part of the myelin sheaths were stained; axons were not. In dorsal root ganglia and ganglia of the autonomic nervous system only satellite cells were stained. In the adrenal medulla a considerable number of cells were stained. In all other organs studied Schwann cells and satellite cells of ganglia were the only elements that were stained. We conclude that S-100 could serve as a marker for Schwann cells in situ.

The effect of S100 protein on the plasma membrane function of neurons

The protein S100 markedly increases the net intake of GABA across the plasma membrane of Deiters' neurons which have GABA receptors on their surfaces. This membrane function of S100 was found by using a new microtechnique. Plasma membranes of such cells have been freshly prepared by freehand microsurgery and are tightly fixed over a 30-micrometers phi hole between two compartments of a microchamber containing 2.0 mM GABA in 7.5 microliters and 0.2 mM GABA in 75 microliters, respectively. The transport of GABA has been determined after incubation of the membrane for from 30 sec to 10 min at 29 degrees C. GABA is transported at a rate of 145 ng in 3 min over a 700-micrometers2 membrane area. S100 in its calcium form reacts with the membrane and increases GABA transport by 20% which is ATP dependent and inhibited by ouabain and ruthenium red. The kinetics of the transport furthermore prove that GABA transport across the plasma membrane is an active process.

On the presence of met 5-enkephalin receptors on the plasma membrane of Deiters' neurons and their modulation of GABA transport

Met 5-enkephalin blocks the active transport of GABA across plasma membranes of rabbit Deiters' neurons prepared by microdissection. Such an effect is receptor-mediated, being reversed by the antagonist Naloxone. This result shows that Deiters' neurons bear enkephalin receptors, and suggests a hypothesis on the mechanism of enkephalin-mediated neuronal inhibition.