Reversible protein kinase C activation in PC12 cells: effect of NGF treatment.

Although protein kinase C (PKC) is a key enzyme in the signal transduction process, there is little information on the mechanism leading to PKC activation in living cells. Using a new fluorescence imaging method, we studied this mechanism and correlated PKC conformational changes with intracellular Ca2+ concentration. PC12 cells were simultaneously loaded with Fura-2-AM and Fim-1, two fluorescent probes, which recognize Ca2+ and PKC, respectively. KCl and carbachol (an agonist to muscarinic receptors) applications induced dose-dependent increases of fluorescence for both probes. Both Ca2+ and PKC responses were observed within seconds following KCl or carbachol application, and were reversible upon stimulus withdrawal. PKC activation kinetics was slightly more rapid than the Ca2+ response after KCl application. After nerve growth factor (NGF) treatment of the cells, the amplitude of the KCl-induced PKC responses was larger indicating an increase in the activated PKC-pool in these cells. This difference between control and NGF-treated cells was not observed following carbachol application, suggesting the involvement of different PKC pools. While the Ca2+ response uniformly occurred in the cytosol, the PKC response displayed a patch pattern with higher intensities in the peripheral zone near the plasma membrane. This heterogeneous distribution of PKC activation sites was similar to the immunocytological localization of Ca2+-dependent and independent PKC isoforms, which suggested that at least several PKC isoforms interacted with intracellular elements. Upon repeated stimulation, the PKC response rapidly desensitized.

Expression and targeting to the plasma membrane of xClC-K, a chloride channel specifically expressed in distinct tubule segments of Xenopus laevis kidney.

ClC-K channels are Cl- channels specifically expressed in vertebrate kidneys. Although their heterologous functional expression is still controversial, indirect evidence points to them as major factors involved in Cl- reabsorption in the nephron. We cloned xClC-K, an amphibian (Xenopus) homologue of mammalian ClC-K. The cDNA encodes a 77 kDa protein presenting 62% similarity with human ClC-Kb. The protein is monoglycosylated and is expressed primarily in the Xenopus kidney. It is localized in the basolateral membranes of proximal convoluted tubules of the nephron and in the apical region of the diluting segments. Heterologous expression of xClC-K in HEK-293 cells showed that the full-length protein is glycosylated and targeted to the cell membrane, but no associated Cl- current could be observed with the patch-clamp recording technique. N-glycosylation of both the native kidney channel and the recombinant protein expressed in HEK-293 conferred on them anomalous behaviour in denaturing PAGE, which is indicative of strong interactions at the extracellular side of the plasma membrane. The expression of ClC-K channels in both mesonephric and metanephric kidneys will permit further comparative physiological studies of Cl- permeabilities at the molecular level.

Polyethylenimine-mediated DNA transfection of peripheral and central neurons in primary culture: probing Ca2+ channel structure and function with antisense oligonucleotides.

To study neuronal ion channel function with antisense oligonucleotides, a reliable method is needed which allows different neuronal cell types to be transfected without artifactual disruptive effects on their electrical properties. Here we report that use of the recently introduced transfecting agent, polyethylenimine, fulfills this requirement. Four days after transfection, in both central and peripheral neurons, an antisense designed to block the synthesis of the Ca2+ channel beta subunits induced a maximal decrease of the Ca2- current amplitude and modification of their kinetics and voltage-dependence. Controls with scrambled oligonucleotides, as well as Na+ current recordings of antisense transfected neurons, confirm both that the transfecting agent does not modify the electrophysiological properties of the neurons and that the effect of the antisense is sequence specific.

Muscarinic binding sites in a catecholaminergic human neuroblastoma cell line.

Tyrosine hydroxylase (TH) a characteristic enzyme activity for the catecholaminergic clonal cell line LA-N-1 and choline acetyltransferase (ChAT) a characteristic enzyme activity for the cholinergic clonal cell line LA-N-2 were previously shown to be increased in these cells exposed to 10(-5) M retinoic acid (RA) as differentiating agent. An investigation of the receptor characteristics suggests a complementarity between the two cell lines. The binding of QNB, a muscarinic ligand, was undetectable with the LA-N-2 cells but was present in the LA-N-1 cells and possessed a kD of 1.8 nM and 2.2 nM and a Bmax of 0.56 and 0.68 for control and RA grown cells respectively. There was a gradual increase in QNB binding to LA-N-1 cells from 2 days in vitro (DIV) until 6 DIV in both control and RA grown cells. An IC50 of 2.5 x 10(-8) M and 0.9 x 10(-8) M for atropine inhibition was obtained for the control and RA grown cells respectively. The corresponding values for carbachol inhibition were 7 x 10(-2) M and 3 x 10(-2) M respectively. The inhibition by the agonist oxotremorine is comparable to that of carbachol and 1 mM pilocarpine inhibited the binding by 21%. QNB binding showed a low affinity for pirenzepine and for AF-DX-116 but was inhibited with a rather high affinity by 4-DAMP (IC50:110 microM) thus suggesting the presence of an M3 receptor. Acetylcholine (100 microM) plus eserine (50 microM) and BW284c55 (1 microM), an acetylcholinesterase inhibitor, reduced the binding of QNB by approximately 25%.(ABSTRACT TRUNCATED AT 250 WORDS)

[Lethal effect of boron neutron capture reaction on human uveal melanoma cells in culture incubated with borophenylalanine]. / Effet létal de la réaction de capture neutronique du bore sur des cellules de mélanome uvéal humain en culture incubées avec la boro-phénylalanine.

Cell cultures obtained from human uveal tumours have been used as experimental model to study the lethal effect consecutive to the neutron capture reaction on boron incorporated into cells as borophenylalanine. An irradiation with a neutron fluence of 6 x 10(9) n cm-2 reduced the number of viable cells by about 30%.

Acetylcholine synthesis by a sympathetic ganglion in the presence of 2-(4-phenylpiperidino)cyclohexanol (AH5183) and picrylsulfonic acid.

The present experiments measured the release and the synthesis of acetylcholine (ACh) by cat sympathetic ganglia in the presence of 2-(4-phenylpiperidino)cyclohexanol (AH5183 or vesamicol) and/or picrylsulfonic acid (TNBS), two compounds known to have the ability to block the uptake of ACh by cholinergic synaptic vesicles in vitro. We confirmed that, in stimulated (5 Hz) perfused (30 min) ganglia, AH5183 depressed ACh release and ACh tissue content increased by 86 +/- 6% compared to contralateral ganglia used as controls. Preganglionic activity increased ACh release by a similar amount in the presence (19.9 +/- 1.0 pmol/min) or absence (20.5 +/- 2.4 pmol/min) of TNBS. The final tissue ACh content was also similar in the presence (1,668 +/- 166 pmol) or absence (1,680 +/- 56 pmol) of TNBS. However, the AH5183-induced increase of tissue ACh content (86 +/- 6%) was abolished completely when AH5183 was perfused with 1.5 mM TNBS (-3.0 +/- 1.0%). This inhibition of ACh synthesis, observed in TNBS-AH5183-perfused ganglia, was not dependent upon further inhibition of ACh release beyond that caused by AH5183 alone, because 14.0 +/- 1.9% of the transmitter store was released by preganglionic nerve stimulation in the presence of TNBS plus AH5183 and this was similar in the presence of AH5183 without TNBS (14.0 +/- 0.6%). Moreover, when ganglia were first treated with TNBS and then stimulated in the presence of AH5183, an increase of 64 +/- 6% of the ganglionic ACh content occurred, and this increase was not statistically different from the increase measured with AH5183 alone (86 +/- 6%).(ABSTRACT TRUNCATED AT 250 WORDS)

Arachidonic acid inhibits choline uptake and depletes acetylcholine content in rat cerebral cortical synaptosomes.

The effects of arachidonic acid on [3H]choline uptake, on [3H]acetylcholine accumulation, and on endogenous acetylcholine content and release in rat cerebral cortical synaptosomes were investigated. Arachidonic acid (10-150 microM) produced a dose-dependent inhibition of high-affinity [3H]choline uptake. Low-affinity [3H]choline uptake was also inhibited by arachidonic acid. Fatty acids inhibited high-affinity [3H]choline uptake with the following order of potency: arachidonic greater than palmitoleic greater than oleic greater than lauric; stearic acid (up to 150 microM) had no effect. Inhibition of [3H]choline uptake by arachidonic acid was reversed by bovine serum albumin. In the presence of arachidonic acid, there was an increased accumulation of choline in the medium, but this did not account for the inhibition of [3H]choline uptake produced by the fatty acid. Arachidonic acid inhibited the synthesis of [3H]acetylcholine from [3H]choline, and this inhibition was equal in magnitude to the inhibition of high-affinity [3H]choline uptake produced by the fatty acid. A K+-stimulated increase in [3H]acetylcholine synthesis was inhibited completely by arachidonic acid. Arachidonic acid also depleted endogenous acetylcholine stores. Concentrations of arachidonic acid and hemicholinium-3 that produced equivalent inhibition of [3H]choline uptake also produced equivalent depletion of acetylcholine content. In the presence of eserine, arachidonic acid had no effect on acetylcholine release. The results suggest that arachidonic acid may deplete acetylcholine content by inhibiting high-affinity choline uptake and subsequent acetylcholine synthesis. This raises the possibility that arachidonic acid may play a role in the impairment of cholinergic transmission seen in cerebral ischemia and other conditions in which large amounts of the free fatty acid are released in brain.

Effect of external high potassium and pH on the uptake of choline in glial and neuronal cells in culture.

The Vmax of the uptake of choline was increased in nerve cell cultures by lowering (from 7.4 to 6.5) or increasing (from 7.4 to 8.1) the pH. In neurons no effect was observed on the value of the Km's of the uptake of either the apparent high or low affinity components. In glial cells only a low affinity component was measured at pH 6.5 and diffusion was observed at pH 8.1. An excess of K+ ions in the incubation medium reproduced the increase in Vmax observed with changes in pH suggesting a possible dependence of the uptake of choline upon the H+ and OH- gradients. Taking into account the characteristics already known of the transport of choline into nerve cells, such a dependence adds new insight in the mechanisms underlying the transport and indicates another possible regulation of choline entry, eventually directed towards the synthesis of acetylcholine.

Ion dependent efflux from neuronal and glial cell cultures.

A spontaneous efflux of choline originating from the cytoplasmic free choline compartment and, partly, from metabolized form was measured from neurons and glial cells in culture. The efflux was stimulated by an excess of K(+) and by the absence of Ca(2+) ions from the incubation medium in both types of culture. The two effects did not appear to be synergistic. The stimulation produced by an excess of K(+) (100 mM) was blocked in neurons by 0.5 ?M BaCl(2) and in glia cells by 0.1 ?M BaCl(2) (in the presence of 30 mM K(+)). The stimulation produced by the absence of Ca(2+) instead was not blocked by Ba(2+) ions in either of the two types of culture. The results suggest that the stimulation induced by K(+) (high concentration and long time of incubation) might be of biochemical rather than physiological nature and that choline may be driven out of the cells in correlation with the K(+) gradient. The greater sensitivity of glial cells to K(+) ions may also suggest a supportive role of these cells with respect to neurons, as they seem capable of furnishing choline for neuronal needs during depolarization.

Effect of CDP-choline on hypocapnic neurons in culture.

Neuronal cultures from chick embryo cerebral hemispheres were protected against a hypocapnic injury by adding to their growth medium 10(-6)M CDP-choline before or after the injury. The protection obtained with CDP-choline was analyzed by a morphometric analysis and showed that pretreatment of neuronal cultures with CDP-choline maintained the number of cell aggregates and of primary neuronal processes at control values after hypocapnic shock. Various experiments showed that the intact molecule was responsible for the protective action, since pretreatment with different concentrations of various nucleosides and nucleotides (up to 10(-5) M), choline, and phosphorylcholine was without protective effect. The addition of CDP-choline after the hypocapnic injury resulted in a protection of the cultures as shown by morphological observation. Incubation of neurons with radioactive choline showed that hypocapnia increased the incorporation of the label into phospholipids whereas the presence of CDP-choline reduced it. The de novo synthesis of choline was affected by neither hypocapnia nor CDP-choline treatment. The results indicate that CDP-choline may have the capacity to protect neurons under conditions of basic pH and that cellular proliferation may be stimulated by the compound.

Uptake of ethanolamine in neuronal and glial cell cultures.

The uptake of radioactive ethanolamine has been studied in exclusively neuronal and glial cell cultures from dissociated cerebral hemispheres of chick embryos. Both cell types show saturable kinetics; neurons have an apparent Km of 6.7 microM, Vmax 41.4 pmol mg prot.-1 min-1 and glial cells a Km of 119.6 microM, Vmax 3,917 pmol mg prot-1 min-1. The lower affinity of the transport and the 100 fold increase in Vmax observed in glial cells correlated with a more important accumulation of free ethanolamine found in glial cells and with a higher degree of phosphorylation of ethanolamine. The uptake appeared to be temperature and Na+ ions dependent but was not affected by CN- or ouabain. Monomethyl-, dimethylethanolamine and choline were effective in inhibiting the uptake. Little or no effect was observed with serine, methionine, carnitine, alanine or glutamate.

Uptake and metabolism of choline in primary isolated neurons and glial cells in culture.

The influx and metabolism of choline have been studied in primary cultures of isolated neurons and glial cells from chick embryo dissociated cerebral hemispheres. The results showed a correlation between both influx and metabolism of choline and the exogenous concentrations of choline. When neurons and glial cells were preincubated (10 min) and incubated in Krebs-Ringer phosphate solution with concentrations of choline lower (0.5 ?M) or higher (150 ?M) than the one present in the growth medium, the metabolism of choline, as a function of time, approached saturation following unusual kinetics. This suggests a non steady state of the endocellular concentrations of free choline. Moreover, when both neurons and glial cells were preincubated (10 min) with 50 ?M choline and then incubated (2 min) with various concentrations of choline, only one uptake mechanism was measured, while the preincubation in the absence of choline followed by the incubation of the cells with various concentrations of choline showed the presence of two apparent K(m)'s with different affinities. The results also indicate the capacity of glial cells to incorporate choline suggesting a storage function for the cells.