Anionic selectivity sequence of the Cl(-)-H+ symporter in the synaptosomal preparation from rat brain cortex.

The Na(+)/H(+) exchanger has been the only unequivocally demonstrated H(+)-transport mechanism in the synaptosomal preparation. We had previously suggested that a Cl(-)-H(+) symporter (in its acidifying mode) is involved in cytosolic pH regulation in the synaptosomal preparation. Supporting this suggestion, we now show that: (1) when synaptosomes are transferred from PSS to either gluconate or sulfate solutions, the Fura-2 ratio remains stable instead of increasing as it does in 50 mM K solution. This indicates that these anions do not promote a plasma membrane depolarization. (2) Based in the recovery rate from the cytosolic alkalinization, the anionic selectivity of the Cl(-)-H(+) symporter is NO(3)(-) > Br(-) > Cl(-) >> I(-) = isethionate = sulfate = methanesulfonate = gluconate. (3) PCMB 10 muM inhibits the gluconate-dependent alkalinization by 30 +/- 6%. (4) Neither Niflumic acid, 9AC, Bumetanide nor CCCP inhibits the recovery from the cytosolic alkalinization.

Role of ionic fluxes in the apoptotic cell death of cultured cerebellar granule neurons.

Cultured cerebellar granule neurons (CGC) increase survival in a medium containing 25 mM KCl (K25), and they die apoptotically when cultures are treated with staurosporine (St) or are transferred to a 5-mM KCl containing medium (K5). Apoptotic CGC show nuclear condensation and caspase-3 activation. Cell death induced by these conditions was partially prevented when cultures were maintained under alkaline conditions, which also induced a marked reduction of the caspase-3 activation. The acidification of the medium further increased cell death induced by both stimuli. Cultures transferred to K5 suffered an immediate intracellular alkalinization that remained constant during the time K5 was present. In contrast, St did not modify cytosolic pH at any of the evaluated times. On the other hand, DIDS, furosemide, and bumetanide prevented CGC death induced by K5 and St. Other drugs such as amiloride, EIPA, tamoxifen, NEM, or NPPB did not modify cell death induced by these conditions. Both DIDS and bumetanide markedly inhibited the processing and activation of caspase-3, and DIDS prevented the nuclear condensation induced by K5 and St. These findings suggest that pH is a condition that could contribute to the modulation of cell death induced by some stimuli and that other ions, such as potassium, could have a role in the initial phase of apoptotic death of CGC.

Regulation of pH in rat brain synaptosomes. I. Role of sodium, bicarbonate, and potassium.

1. We investigated the regulation of intracellular pH (pHi) in rat brain isolated nerve terminals (synaptosomes), using fluorescence pH indicators and time-resolved fluorescence spectroscopy. 2. The resting pHi was not significantly affected by the presence or absence of HCO3-. Removal of external Na+, in the absence or presence of HCO3- caused a rapid acidification of pHi. The recovery from acid loads was primarily due to the activity of the Na+/H+ exchanger, confirming the relevance of this transport system in synaptosomes. 3. Our data revealed that in synaptosomes the activity of the Na+/H+ exchanger was not regulated by either protein kinase C or kinase A. In contrast, Ca2+ played an important role in the regulation of Na+/H+ exchanger. This was supported by the observation that 4Br-A23187 induced a Na(+)-dependent alkalinization of the resting pHi and greatly enhanced the initial rate and the degree of the recovery from acid loads. 4. In most eukaryotic cells, HCO3(-)-based transport mechanisms play an important role in pHi regulation. In synaptosomes, however, HCO3- transport is not significantly involved in pHi regulation, because the presence or absence of HCO3- does not affect resting pHi nor the rate of pHi recovery to acid loads. Further studies to address the role of Cl- and HCO3- in pHi regulation in synaptosomes are discussed in the companion paper. 5. Increasing the concentration of Ko+ also resulted in a rise of steady-state pHi by a processes that is Ca2+ and HCO3- independent. This alkalinization could be due to either K+/H+ exchanger activity, K(+)-induced depolarization, reduction of delta microH+, or a direct reduction of delta microK+. Calculated H+ driving forces suggest that the reduction in the inwardly directed H+ leak is sufficient to explain this K(+)-induced alkalinization because it changes the delta microH+ by virtue of setting the membrane potential difference (Em) to the K+ equilibrium potential (EK+).

[Molecular mechanism of noradrenaline transport by rat auricles in vitro]. / Mecanismos moleculares del transporte de noradrenalina por auriculas de rata in vitro

The transport of tritium-labelled noradrenaline (3H-NA) into bisected rat auricular appendages in vitro, has been studied, using 14C-inulin as an extracellular space tracer, thus allowing a precise measurement of the 3H-NA transported into the cells. The NA transport time course is relatively fast, and initial rates lasted 5 min. in 150 mM sodium, 3 min. in 26 mM sodium, and about 1 min. in 50 mM potassium. Intracellular accumulation of 3H-NA by synaptic vesicles, was found not to be important in the first minute of transport. In the presence of 150 mM sodium a transport Km for NA of 0.59 +/- 0.06 muM (mean +/- S.E.M.) and a maximal velocity (Vmax.) of 2.44 +/- 0.43 pmol/mg. protein/min. were estimated. When sodium was lowered to 26 mM, the Km increased to 2.26 +/- 0.7 muM (P less than 0.001), while Vmax. showed no change. With 0 mM sodium (choline substitution) active NA transport is completely suppressed, and only a diffusional component can be discerned. No binding of NA to beta adrenergic receptors was found, and a small but highly significant binding to the non-specific catechol receptors could be detected.