Fluid compartmentation and electrolytes of cat cerebral cortex in vitro. I. Swelling and solute distribution in mature cerebral cortex

The distribution of indicator solutes (inulin, sucrose, raffinose, thiocyanate, chloride, and isethionate) and the swelling in slices of adult cat cerebral cortex incubated in vitro have been investigated for a variety of incubation media and conditions. Where appropriate, these data have been compared with analogous data obtained on cat cerebral cortex in vivo (Bourke et al., 1965) and with data previously reported for slices of rat cerebral cortex (Pappius and Elliott , 1956; Pappius et al., 1962) and guinea pig cerebral cortex (Varon and Mc Ilwain , 1961; Keesey et al., 1965) incubated in vitro under comparable conditions. In addition to substantial agreement of present data with previously reported in vitro data, a number of new findings have been added by the present study: (a) a component of slice swelling which is K⁺-dependent; (b) the association of slice swelling with presence of a diffusible, external anion (Cl^?) and its prevention by replacement with a relatively non-diffusible anion (isethionate^?); (c) variation of the size of slice chloride spaces as a direct function of slice swelling; (d) dependence of the size of slice fluid spaces accessible to inulin and sucrose upon time, during incubation, of solute addition and upon K⁺ concentration of the incubation medium; (e) indications of the dynamic and presumably metabolically-dependent nature of indicator solute distribution; and (f) the mobility of a portion of the fluid of swelling associated with changing the K⁺ concentration but not the tonicity of the medium during incubation. At least five operationally-defined fluid compartments may be inferred from the present data : (1) interstitial or extracellular space(s) readily accessible to all solutes and of a size which can be minimally estimated from direct determinations in viuo; (2) additional fluid space(s) accessible to most solutes, including inulin and sucrose, under apparently suboptimal conditions of slice metabolism in vitro; (3) fluid space(s) prone to swell under in vitro conditions and readily accessible in vitro to chloride and thiocyanate but not to inulin or sucrose; (4) fluid space(s) which swell reversibly in the presence of added external K⁺ (or Rb⁺) and are inaccessible to all usual indicator solutes; and (5) after exclusion of the foregoing, the remaining fluid presumably comprising most of the intracellular space(s). The data have been discussed in terms of the morphological complexity of cerebral cortex, in terms of applicability to studies of cortical electrolyte distribution, and in terms of the general problem of delineating cerebral interstitial spaces.     

Taurine in the developing cat: Uptake and release in different brain areas

Taurine is an important modulator of neuronal activity in the immature brain. In kittens, taurine deficiency causes serious dysfunction in the cerebellar and cerebral visual cortex. The processes of taurine transport in vitro were now studied for the first time in different brain areas in developing and adult cats. The uptake of taurine consisted initially of two saturable components, high- and low-affinity, in synaptosomal preparations from the developing cerebral cortex and cerebellum, but the high-affinity uptake component completely disappeared during maturation. The release of both endogenous and preloaded labeled taurine from brain slices measured in a superfusion system was severalfold stimulated with a slow onset by depolarizing K⁺ (50 mM) concentrations. K⁺ stimulation released markedly more taurine from the cerebral cortex, cerebellum and brain stem in kittens than in adult cats. The responses were largest in the cerebellum. Both uptake and release of taurine are thus highly efficient in the brain of kittens and may be of significance in view of the vulnerability of cats to taurine deficiency.     

FLUID COMPARTMENTATION AND ELECTROLYTES OF CAT CEREBRAL CORTEX IN VITRO–II SODIUM, POTASSIUM AND CHLORIDE OF MATURE CEREBRAL CORTEX

The contents of K⁺, Na⁺ and Cl^? in various incubation media and in slices of adult cat cerebral cortex incubated in vitro under a variety of conditions have been determined in conjunction with studies on slice swelling and fluid compartmentation reported in the preceding paper (Bourke and Tower , 1966). Cortical slices incubated in media containing 16 Or 27 mm-K⁺ exhibit contents of K⁺ and Na⁺ most nearly comparable to those found in viuo. Substitution of isethionate^? For Cl^? or omission of Ca²⁺ in such media have little effect on slice cation composition. Rb⁺ can effectively substitute for K⁺, but substitution of Li⁺ or choline⁺ for most of the naf in incubation media is associated with accumulation of these cations in slices at the expense of both K⁺ and Na⁺. Compared to values in vivo for net contents and/or concentrations of electrolytes in the non-sucrose spaces of cortical slices, conditions yielding most favourable data in vitro appeared to be incubation of cortical slices in 16 mm -K⁺ medium or in 27 mm -K⁺ medium with either omission of Ca²⁺ or replacement of Cl^? by isethionate. Essentially complete inhibition of maintenance of K⁺ and extrusion of Na⁺ in slices of cat cerebral cortex occurs upon incubation with 10^?5 or 10^?4m -ouabain, with 50 per cent inhibition of cortical slice electrolyte metabolism occurring at about 8 × 10^?7m -ouabain. Cortical slices incubated in 27 mm -K⁺ medium in the presence of ⁴²K exhibited rates of exchange and turnover of slice K⁺ (in non-sucrose spaces) of 0·7 μequiv./min and 6.45 per cent respectively. In the presence of 10^?5m -ouabain, a maximal ratio of slice specific activity/medium specific activity is attained within about 5 min after ⁴²K addition, compared to >20 min for control slices. In neither case does the maximal specific activity ratio exceed about 0.85; this suggests that some 10-15 per cent of total cortical K⁺ comprises a “slowly exchangeable” fraction. In the presence of Ca²⁺ (1.3 mm ) slice oxygen consumption is markedly stimulated (39 per cent) and aerobic glycolysis is markedly depressed (54 per cent) in the presence of 10^?5m -ouabain; whereas on omission of Ca²⁺ from incubation media, both respiration and glycolysis are normally stimulated but, with 10^?5m -ouabain present, both are significantly depressed (20 per cent and 37 per cent respectively). Possible relevance of these effects to mobilization of tissue Ca²⁺ by ouabain and to effects of intracellular Ca²⁺ on mitochondrial respiratory metabolism is discussed.     

FURTHER STUDIES ON THE K+-DEPENDENT SWELLING OF PRIMATE CEREBRAL CORTEX IN VIVO: THE ENZYMATIC BASIS OF THE K+-DEPENDENT TRANSPORT OF CHLORIDE

Abstract— The swelling of intact, exposed primate cerebral cortex perfused in vioo under, isosmotic conditions was a linear function of the concentration of K⁺ in perfusate over the range 25–117 mM. The K⁺-dependent swelling was manifested throughout the depth of the cerebral cortex studied and was associated with an increased content of chloride in the swollen tissue, despite the constancy of the concentration of external chloride. The swelling of the cerebral cortex was a linear function of the temperature of the perfusate over the range 15–38°C, despite the constancy of the concentration of external K⁺. Moreover, the content of chloride in the swollen cerebral cortex was a linear function of the temperature of the overlying perfusate, despite the constancy of the external concentration of chloride. The changes in the contents of Na⁺ and K⁺ in the swollen cerebral cortex perfused with solutions containing constant concentrations of external Na⁺ and K⁺ but differing in temperature suggested that the fluid of swelling in the tissue was rich in both K⁺ and CI^-, as had been shown previously in vitro. Perfusion of the exposed, intact cerebral cortex in uiuo with K⁺-rich fluids usually involved the reciprocal reduction of the concentrations of Na+ in the perfusate to maintain isotonicity. When comparable reductions in the concentration of external Na⁺ were achieved by replacement with choline (instead of K⁺), swelling of the perfused, exposed cortex was significantly less than that attributed to isotonic, K⁺-rich but Na⁺-poor fluids. These observations suggested that it was the elevated levels of K⁺ rather than lowered concentrations of Na+ that promoted the swelling of the perfused cerebral cortex. The apparent rate of influx of ³⁶Cl from the perfusate into the underlying exposed and intact monkey cerebral cortex in vivo was a linear function of the concentration of K⁺ in perfusate over the range 25–117 mM and conformed to Michaelis-Menten kinetics when plotted according to Lineweaver and Burk. Moreover, the apparent influx of chloride from perfusate into swollen cerebral cortex was a linear function of the percentage swelling of cerebral cortex over the range 6–30 per cent. However, the apparent rate of influx of chloride from perfusate into unswollen cortex was not consistent with the linear correlation already described for swollen cerebral cortex. One reason for this discrepancy was the reduction in the size of the true (inulin) extracellular space associated with the K⁺-dependent swelling of cerebral cortex in vivo. The anatomical locus for this K⁺-dependent swelling of cerebral cortex was an expanded glial compartment, as demonstrated by electron-microscopy. The parenteral administration (50 mg/kg) or local perfusion (5 mM) of acetazolamide inhibited the K⁺-dependent swelling of cerebral cortex in vivo. Moreover, administration of acetazolamide inhibited the K⁺-dependent increase in content of C1- and the K⁺-dependent rate of influx of ³⁶Cl into swollen cerebral cortex. We have discussed the possible enzymatic basis of these K⁺-dependent alterations in content of fluid and chloride and transport of chloride in mammalian cerebral cortex in viuo.     

Sedimentation and release properties of P2 fractions derived from rat cerebral cortex slices incubated with radiolabeled GABA for a short or long time period

On homogenization of rat cerebral cortex slices previously incubated with [³H] GABA or [¹⁴C]GABA for 5 or 30 min, respectively, particles were recovered in P₂ fractions which exhibited similar buoyant density, but different sedimentation velocity on linear sucrose density gradient centrifugation. The K⁺-evoked release of [³H]GABA from particles isolated from slices previously incubated for 5 min with [³H]GABA was increased in the presence of exogenous Ca²⁺. In contrast, the K⁺-evoked release from particles isolated from slices previously incubated for 30 min with [³H]GABA, was not influenced by the presence of exogenous Ca²⁺.These results suggest that, depending on the incubation time of slices, exogenously applied GABA can be detected in differnnt pools. These pools not only seem to differ in their Ca²⁺ dependency of K⁺-evoked release but also in their subcellular localization.     

Experimental alcoholism in rats. Effect of acute ethanol intoxication on the in vitro incorporation of ( 3 H)leucine into neuronal and glial proteins

Abstract— Ethanol administered in vivo or in vitro during incubation of brain slices was studied with respect to its effect on brain protein synthesis. In the in vivo series the rats were given a single intraperitoneal injection of ethanol 3 h before death. Slices of cerebral cortex and liver were incubated in isotonic saline media containing [³H]leucine. Amounts of free and protein-bound radioactivity were determined. Subcellular fractions and fractions enriched in neuronal perikarya and in glial cells were prepared from cortical slices subsequent to incubation, and the specific radioactivity determined for each cell type. The incorporation of [³H]leucine into brain proteins was inhibited while incorporation into liver proteins was stimulated in ethanol-treated rats. The levels of TCA-soluble radio-activity, however, did not differ between the ethanol group and the controls. In the fractionated material from cerebral cortex, the specific radioactivity in the neuronal fraction was unaffected by ethanol, while the radioactivity in the glial fraction was significantly depressed. In vitro administration of ethanol induced a non-linear response in both brain and liver, with depression of leucine incorporation into proteins of cerebral cortex at all concentrations used. When brain slices were exposed to ethanol in vitro, in concentrations corresponding to the in vivo experiments, a similar reduction of the leucine incorporation into the glial fraction was obtained. Incorporation of leucine into subcellular fractions from whole brain cortex was also investigated. The specific sensitivity of the glial fraction to ethanol is discussed in relation to the involvement of the different cell types with transport processes in the brain.     

Control of canine kidney cortex slice volume and ion distribution at hypothermia by impermeable anions

Hypothermia induces swelling of dog kidney cortex slices. Swelling of cells during hypothermia is related to a number of factors including the permeability of Cl⁻. By substituting lactobionate for Cl⁻, while maintaining isoosmotic conditions, swelling is prevented. Lactobionate is an impermeable anion and its presence in the suspending fluid prevents swelling of dog kidney cortex slices in salts of Na⁺, K⁺ or combinations of Na⁺ and K⁺ even in the presence of metabolic inhibitors. By maintaining a ratio of 80 mM lactobionate: 60 mM chloride and an appropriate ratio of Na⁺:K⁺ (80 mM:60 mM), both the total tissue H₂O and ratio of intracellular K⁺/Na⁺ are kept within normal ranges during hypothermic incubation of tissue slices. Kidney cortex slices suspended in this medium at 30 °C respire at a rate 30–40% slower than that of control slices suspended in saline. A similar result is obtained by adding ouabain to slices suspended in saline. This suggests that the Na⁺-pump activity is suppressed under these conditions and results in a reduced energy demand on the cell. These results are discussed in relation to utilizing this type of solution for long-term perfusion preservation of kidneys for transplantation.     

THE MECHANISM OF THE EXCLUSION OF SODIUM IONS AND THE CONCENTRATION OF POTASSIUM IONS BY GUINEA-PIG CEREBRAL CORTEX SLICES

—Guinea pig cerebral slices were incubated in oxygenated Krebs-Ringer bicarbonate glucose saline for periods of 1 s to 60 min, and their swelling and Na⁺ and K⁺ cone were measured. The swelling was at the rate of 8 per cent for the 1st min, and 0·8 per cent for the next 29 min; it fell significantly during the subsequent 30 min (P= 0·05). The Na⁺ and K⁺ concn in the tissue fluctuated during the 1st min of incubation, but the Na⁺ concn had risen to a mean of 108 mm after 1 min incubation and the K⁺ concn had fallen to a mean of 52 mm by 3 min. The concentrations of these cations did not change significantly after these times. Cerebral slices were also incubated for 30 min in isotonic media modified such that Na⁺, + K⁺, Na⁺+ choline⁺, or K⁺+ choline⁺ always added up to 150 mm . It was found that about half of the swelling (20-25 per cent) was independent of the Na⁺ or K⁺ concn and a further 20-25 per cent of the swelling varied with the cations only if Na⁺ and K⁺ were both present and was a function of the K⁺ concn in the medium (0·15 per cent m-mol). The Na⁺ concn in the tissue was a mean 8·4 mm after incubation in a Na⁺-free medium and 7·1 mm in K⁺ after incubation in a K⁺-free medium. Cerebral slices in the presence of Na⁺+ K⁺ excluded one molecule of Na⁺ for every four molecules in the incubating medium; they accumulated K⁺ from the medium until the concn in the medium exceeded 130 mm .     

CATIONIC COMPOSITION OF RAT CEREBRAL CORTEX SLICES. COMPARATIVE STUDY DURING DEVELOPMENT

Abstract—

• 1 Slices of cerebral cortex isolated from 20-day-old rats, when incubated in an appropriate oxygenated saline, show only a slight increase in weight (± 0.4 per cent of initial fresh wt.). At 30 days, under the same conditions, this increase in weight is 12.4 per cent. This is similar to the value observed in adult animals (13.6 per cent).
• 2 Modifications of the cationic content of slices in the case of 20-day-old animals are very slight while in 30-day-old animals they are greater and similar to those observed with adults.
• 3 The inulin space of 20- and 30-day-old rats are the same. The swelling exhibited by the slices isolated from 30-day-old animals may reasonably be attributed to a cellular uptake of extracellular fluid. This is accompanied by an increase of the Naf concentration and by a decrease of the K⁺ concentration. The values observed are similar to those observed with adult rats.
• 4 Comparing our results with previous histological and histochemical data, it may be suggested that the modifications of cationic content, as well as the swelling of slices isolated from 30-day-old rats or adult animals, are solely attributable to changes affecting glial cells and more specifically the astrocytes.

     

Incorporation of [6-3H] glucose into lipid, protein, RNA and DNA of slices of differentiating rat cerebral cortex

Abstract— An assay in vitro utilizing [6^?3H)glucose as precursor for synthesis of lipids, proteins, RNA and DNA was developed for incubated slices of rat cerebral cortex. The developmental changes in synthesis of macromolecules were followed during differentiation of rat cerebral cortex. The incorporation of glucose into lipids and proteins decreased 10-fold in incubated slices of cerebral cortex during progression from foetal to adult ages. In contrast, the specific radioactivities of RNA and DNA in incubated slices increased from the values at 3 days prepartum to peaks at 2–4 weeks postpartum.     

The volume and ionic composition of cells in incubated slices of rat renal cortex, medulla and papilla

The apparent extracellular space in incubated slices of rat renal cortex, medulla and papilla has been measured using three differently sized marker molecules, mannitol, sucrose and inulin. Cellular volumes have been estimated by following the efflux of from equilibrated slices. Sucrose appears to be the most accurate extracellular marker in each of the regions examined, in that the sum of its volume of distribution plus cellular volume approximates most closely to the total slice fluid volume. Inulin has the same volume of distribution as sucrose in cortical slices, but under-penetrates medullary and papillary tissue. Mannitol overestimates the extracellular space in all three regions, although its larger volume of distribution, relative to that of sucrose, was not statistically significant in papillary slices. When cell volume and composition are estimated (a) using sucrose as extracellular marker and (b) making appropriate allowance for the presence of bound tissue electrolytes, it is found that cells in each region have low Na⁺ and high K⁺ concentrations and contents. When papillary slices are incubated in medium of very high osmolality (NaCl plus urea, 2000 mosmol/kg H₂O) there is a moderate (approx. 23%) decrease in cell volume and an increase in cell fluid Na⁺ and Cl⁻ concentrations equal to approx. 50% of the increase in the extracellular concentrations. Cell K⁺ concentrations remain unchanged. The results show that cells in renal slices are able to maintain high K⁺-to-Na⁺ ratios when incubated in isosmotic (cortex) or moderately hyperosmotic media (medulla and papilla), and suggest that regulation of papillary cell volume following hyperosmotic shock can only partly be ascribed to uptake of extracellular electrolytes.     

Cold resistance of the brain during hibernation: I. K+ transport in cerebral cortex slices

The brains of the hibernating hamsters and 13-lined ground squirrels maintain Na⁺ and K⁺ at the same concentrations as in the awake state. The ability of slices of the cerebral cortex when incubated in vitro to accumulate or retain K⁺ is similar in the awake hamster and rat at both 38 and 5 ° C. On the other hand, slices of cerebral cortex from the hibernating hamster retained slightly more K⁺ at 5 °C than did those of awake hamster or rat. It was concluded that the cerebral cortex of the awake hamster is probably not cold resistant with respect to the maintenance of cation balance. Further, the cold resistance that exists in the cerebral cortex of the hibernating hamster is largely destroyed when the brain is disrupted by slicing.     

RELEASE OF [3H]GABA FROM IN VITRO PREPARATIONS: COMPARISON OF THE EFFECT OF DABA AND β-ALANINE ON THE K+ AND PROTOVERATRINE STIMULATED RELEASE OF [3H]GABA FROM BRAIN SLICES AND SYNAPTOSOMES1

It has been proposed that the major portion of [³H]GABA released from rat cortical slices upon exposure to high K⁺ comes from a neuronal pool. Using carrier mediated exchange diffusion of DABA or β-alanine in the superfusion medium for GABA in the slice as a technique for manipulating neuronal and glial pools of GABA, it was found that DABA but not β-alanine substantially reduced the K⁺ stimulated release of [³H]GABA. The present study using synaptosomes as an in vitro model of the nerve ending was undertaken to ascertain whether this neuronal pool of releasable [³H]GABA was associated with a specific transmitter pool in nerve endings. A continuous superfusion system employing a Ca²⁺ pulse to produce a calcium coupled release (Levy et al, 1973) was used to study the effect of two concentrations (20 μm , 1 mm ) of DABA and β-alanine on the release of [³H]GABA from synaptosomes. In contrast to the results in slices, DABA at both concentrations had no effect on the release of [³H]GABA from synaptosomes in spite of evidence that exchange diffusion was occurring. With protoveratrine as the releasing agent there was no effect of DABA on the release of [³H]GABA from either slices or synaptosomes. The results suggest that the major portion of [³H]GABA released from cortical slices by high K⁺ comes from a non-transmitter pool in the neuron. Use of K⁺ stimulated release of amino acids from cortical slices as a criterion for neurotransmitter function must be viewed with caution.     

The depolarization-induced release of cholecystokinin C-terminal octapeptide (CCK-8) from rat synaptosomes and brain slices

Studies on the subcellular distribution of immunoreactive cholecystokinin (CCK) in homogenates of rat cerebral cortex showed that approximately 95% was associated with particulate fractions, including presynaptic terminals (synaptosomes). Chromatography of extracts of tissue and medium from incubated synaptosomes revealed that this material was almost exclusively in the form of COOH-terminal octapeptide (CCK-8), very little CCK-33 being present. There was a wide range of CCK-8 concentrations in synaptosomes from different brain regions (cortex > striatum ? hypothalamus > brain stem). Cerebral cortex synaptosomes were incubated in vitro and showed a complex pattern of CCK-8 release with varying concentrations of tissue: amounts in the medium rose rapidly with increasing synaptosome concentrations, then fell to a plateau at higher tissue values. A mechanism for the rapid disposal of extracellular CCK-8 was associated with synaptosomal fractions. Depolarization-induced (high K⁺) release of CCK-8 was observed with cortex and corpus striatum synaptosomes. A rapid and reversible enhancement of CCK-8 release from cortex slices was observed in response to elevated K⁺. Veratrine also released CCK-8 from cortex slices, although this was not reversible. Stimulus-induced release of CCK-8 from synaptosomes and slices required extracellular Ca²⁺. The storage, release and degradation of CCK-8 by nerve-endings suggest a synaptic function for this peptide.     

UPTAKE AND RELEASE OF EXOGENOUS [1-14C]ACETYLCHOLINE BY BRAIN CORTEX SLICES FROM THE RAT

Abstract— Radioactive acetylcholine ([¹⁴C]ACh) that is taken up by rat cerebral cortex slices, incubated aerobically in a physiological saline-glucose paraoxon-[¹⁴C]ACh medium, apparently by a passive diffusion process at concentrations > 1 mm consists essentially of two forms, a readily exchangeable and releaseable or mobile form, and a bound or retained form, poorly (or not) exchangeable. The quantity of retained ACh consists of a considerable fraction of that taken up amounting to 54% with external 0.1 mm -[¹⁴C]ACh and about constant, 27%, for the range 5-50mm -[¹⁴C]ACh. All its ACh is released on homogenization with 0.1 n -perchloric acid or on tissue disintegration in distilled water. The cerebral uptake of ACh differs basically from that of urea as there is no retention of the latter following its uptake. Cerebral cortex slices are superior to those of cerebellar cortex, subcortical white matter, kidney cortex, liver and spleen in taking up and retaining [¹⁴C]ACh. Deprivation in the incubation media of glucose or Na⁺ or Ca²⁺. or the presence of dinitrophenol, whilst causing little change in ACh uptake, induces considerable changes in swelling and ACh retention; the greater the amount of swelling the smaller is that of retention. It seems that the latter is segregated in compartments characterized by a low permeability to exogenous ACh. About half of it is independent of changes in incubation conditions whilst the other half enters the compartment by an Na⁺, Ca²⁺ and energy-dependent process. At least part of the retention is neuronal as it is diminished by protovera-trine, the diminution being blocked by tetrodotoxin. Mobile ACh (i.e. total uptake minus retained ACh) is largely unaffected by protoveratrine, ouabain, etc. It seems that the retained ACh is directly proportional to the amount of mobile ACh minus the amount that enters with swelling. If the latter is largely glial in location, then the retained ACh is simply proportional to the mobile neuronal ACh. Suggestions are made as to the location of the retained ACh in the brain cells and to the processes involved in its segregation there. Release of retained ACh occurs on change of the Na⁺ gradient. Atropine and d-tubocurarine also diminish the amount of retained ACh but the percentage diminution falls with increase of the concentration of exogenous ACh.     

Effect of scorpion venom, tityustoxin, on the release of acetylcholine from incubated slices of rat brain

Abstract— Purified tityustoxin (TsTX) from the venom of the scorpion, Tityus serrulatus, when incubated in vitro with slices of rat cerebral cortex, increased the amount of free ace-tylcholine (ACh) in the incubation medium and, simultaneously, reduced the amount of bound ACh in the slices. The effect was optimal at pH 7.4 and was dependent upon time of incubation, an energy source and the concentration of toxin. Tityustoxin increased the synthesis of ACh, but this effect seemed to be related to an increase in the release of ACh. The effect of the TsTX was independent of the concentration of K⁺ ion but was dependent on the presence of Na⁺ and Ca²⁺ in the incubation medium. Hexamethonium and hemicholinium reduced the effect of tityustoxin, but cocaine had no effect on the release of ACh stimulated by the TsTX. Tetrodotoxin blocked completely the stimulation caused by the tityustoxin. We suggest that probably both tityustoxin and tetrodotoxin exert different and antagonistic effects competing in the Na⁺ channels.     

Effects of ammonium ions on spontaneous action potentials and on contents of sodium, potassium, ammonium and chloride ions in brain in vitro

The effects of ammonium ions on the frequency of spontaneous action potentials in guinea-pig cerebellar slices, recorded with an extracellular microelectrode, and on the contents of sodium, potassium and chloride ions in incubated guinea-pig cerebellar, and rat brain cortex, slices have been investigated. The frequencies of the spontaneous action potentials are partially suppressed by concentrations of NH₄Cl less than 2 mm and completely abolished by concentrations exceeding 2 mm . The amplitudes of the spike discharges are unaffected. A lag period of at least 15 s precedes the inhibition. The suppressing action of NH on the spike frequency is reversible, as shown by complete recovery on removal of NH after short time intervals. Deficiency of Cl^? in the superfusion medium causes conversion of inhibition by NH to excitation. Reduction of [K⁺], or of [Na⁺], causes increase of inhibition by NH in a normal [Cl¹], and reduction of excitation in a low [Cl¹], medium. The inhibitory effects of NH on spike frequency are unaffected by picrotoxin or strychnine. NH₄Cl, even at 1 or 2 mm , causes a significant increase of aerobic glycolysis. It is suggested that the lag period preceding the suppression of the frequency of spike discharges by NH is partly due to a metabolic change induced by NH, perhaps a transient lowering of pH in the responsible neurons, causing changed permeability to Cl^? and possibly to K⁺ and Na⁺, NH promotes, in guinea-pig cerebellar slices, an inward flow of Na⁺ and an outward flow of K⁺, the latter being greater than that due to exchange of K⁺ for NH. NH₄Cl at 1 or 2 mm causes an outward flow of K⁺ and an inward flow of Cl^? in rat brain cortex slices. The movement of Cl^? is biphasic, the first phase, seen with low [NH], consisting of an increase of tissue content of Cl^? with little or no fluid uptake and a second phase, seen with high (> 5 mm ) concentrations of NH, in which the uptake of Cl^? is directly proportional to the fluid uptake. It is suggested that the first phase is largely neuronal in location whilst the second is largely glial. In infant rat brain cortex slices, there seems to be predominantly an equal exchange of NH for K^+. There is little evidence of energy assisted concentrative uptake of NH by brain slices and this is thought to be due largely to the rapid diffusion of undissociated NH₃ across cell membranes. It is suggested that some NH (amounting to about 2 mequiv/1) may be bound in the brain. It is concluded that changes in ionic permeabilities, particularly that of Cl^?, partly due to a metabolic action, may be responsible for some of the acute cerebral effects of NH administration.     

The composition of the incubation medium influences the sensitivity of mitochondrial permeability transition to cyclosporin A

The aim of this work was to study permeability transition, and the influence of the composition of the incubation medium, on the inhibitory action of cyclosporin A. It was found that cyclosporin inhibited the opening of a nonspecific pore, as induced by the uncoupler carbonyl cyanide m-chlorophenylhydrazone, provided K⁺ was present in the incubation medium, but failed to do so if mitochondria are incubated in sucrose or Na⁺-based medium. It was also found that the sensitivity of mitochondria to the uncoupler depended on the incubation mixture, being more sensitive when sucrose was the osmotic support. Matrix Ca²⁺ release, large amplitude swelling, and drop in transmembrane electric gradient revealed permeability transition. The titration of membrane thiol groups shows them to be increased in mitochondria incubated in sucrose medium, in comparison with the values found in mitochondria incubated in KCl or NaCl medium. Our proposal is that the incubation in sucrose medium propitiated a conformational change of membrane proteins in such a way that cyclosporin was unable to bind to its target site.     

l-serine and GABA uptake by synaptosomes during postnatal development of rat

Postnatal development changes in mechanisms of synaptosomal amino acid transport have been studied in rat cerebral cortex. Specific uptake of radiolabeled l-serine was examined and compared with that of radiolabeled GABA using synaptosomes-enriched fractions freshly prepared from cerebral cortex at different postnatal days from the birth to young adulthood. The preparations were incubated with 10 nM of [³H]l-serine and 10 nM of [³H]-GABA in either the presence or absence of NaCl, KCl or choline chloride, at 2 and 30 °C, for different periods up to 30 min. The uptake of [³H]l-serine was temperature dependent in synaptosomal fractions prepared from cerebral cortex of rats in postnatal days 5, 7, 13 and 21, but stronger dependence was observed in adult brain, irrespective of the presence of Na⁺, K⁺ or choline ions. At all postnatal ages studied, [³H]-GABA uptake showed a high activity in the presence of Na⁺ ions and at 30 °C. The values of K_m were 90–489 μM in l-serine uptake. However, in the uptake of GABA the values of K_m were 80–150 μM. The highest values of V_max were obtained at 5 and 21 postnatal days for both transport systems. These results indicate that the uptake of l-serine and GABA are regulated differentially during postnatal development.     

Use of low temperature and high K+ incubation media for in vitro tissue preparation for X-ray microanalysis

Incubation of tissue slices in physiological buffers gives rise to significant changes in the intracellular ion concentrations, which may disturb subsequent X-ray microanalysis. In the present study it was attempted to design incubation conditions that retain the in vivo conditions better. The following variables were investigated: (1) exchange of Na⁺ in the incubation medium for K⁺, and exchange of Cl^–for the less permeable gluconate anion; (2) incubation at 4°C rather than at 37°C; and (3) addition of dextran to the incubation medium. Brief exposure (a few seconds) of liver slices to a buffer causes changes in the intracellular Na, Cl and K concentrations, depending on the ionic composition of the buffer. Incubation in a normal physiological (high NaCl) buffer at 37°C results in a further increase of Na and Cl and a further decrease in K in liver cells. The changes reach a maximum at 30 min and the concentrations then remain stable throughout a 2-h incubation. Incubation in sodium gluconate medium or addition of dextran to the physiological buffer somewhat reduces the changes in the intracellular ion composition (compared to the standard physiological incubation medium). Incubation in potassium gluconate medium results in a decrease in cellular Na and an increase in K. Quantitative morphological studies show that tissue oedema is observed to the same extent in hepatocytes incubated in sodium gluconate, potassium gluconate and physiological buffer containing 10% dextran. However, these buffers cause significantly less cell oedema than the physiological (high NaCl) buffer. Incubation of liver, cerebral cortex or submandibular gland slices in physiological (high NaCl) solutions at 4°C for 4 h caused a more extensive increase in Na⁺ and decrease in K⁺ than incubation at 37°C for 2 h. This suggests inhibition of the Na⁺, K⁺-ATPase under these conditions. As compared to incubation at 37°C for 2 h, tissues incubated in potassium gluconate buffer at 4°C for 4 h have a cellular K concentration closer to the in situ value. Cholinergic stimulation of tissue slices from cerebral cortex and submandibular gland at room temperature for 1 min shows the best physiological response in tissue slices preincubated at 4°C for 4 h in high KCl, potassium gluconate and high NaCl, in this order. The response can, however, only be seen, when cholinergic stimulation is carried out in a standard physiological buffer with a high NaCl concentration. It is concluded that in vitro storage of tissue for X-ray microanalysis is best carried out at 4°C in a solution with a high K⁺ concentration.