A. Diarra et al., Anoxia-evoked intracellular pH and Ca2+ concentration changes in cultured postnatal rat hippocampal neurons, NEUROSCIENC, 93(3), 1999, pp. 1003-1016
The ratiometric indicators 2',7'-bis-(2-carboxyethyl)-5-(and-6)-caroxyfluor
escein and Fura-2 were employed to examine, respectively, intracellular pH
(pH(i)) and calcium ([Ca2+](i)) changes evoked by anoxia in cultured postna
tal rat hippocampal neurons at 37 degrees C. Under both HCO3-/CO2- and HEPE
S-buffered conditions, 3-, 5- or 10-min anoxia induced a triphasic change i
n pH(i) consisting of an initial fall in pHi, a subsequent rise in pH(i) in
the continued absence of O-2 and, finally, a further rise in pH(i) upon th
e return to normoxia, which recovered towards preanoxic steady-state pH(i)
values if the duration of the anoxic insult was less than or equal to 5 min
. In parallel experiments performed an sister cultures, anoxia of 3, 5 or 1
0 min duration evoked rises in [Ca2+](i) which, in all cases, commenced aft
er the start of the fall in pHi, reached a peak at or just following the re
turn to normoxia and then declined towards preanoxic resting levels. Remova
l of external Ca2+ markedly attenuated increases in [Ca2+](i), but failed t
o affect the pH(i) changes evoked by 5 min anoxia.
The latency from the start of anoxia to the start of the increase in pH(i)
observed during anoxia was increased by perfusion with media containing eit
her 2 mM Na+, 20 mM glucose or 1 mu M tetrodotoxin. Because each of these m
anoeuvres is known to delay the onset and/or attenuate the magnitude of ano
xic depolarization, the results suggest that the rise in pH(i) observed dur
ing anoxia may be consequent upon membrane depolarization. This possibility
was also suggested by the findings that Zn2+ and Cd2+, known blockers of v
oltage-dependent proton conductances, reduced the magnitude of the rise in
pH(i) observed during anoxia.
Under HCO3-/CO2-free conditions, reduction of external Na+ by substitution
with N-methyl-D-glucamine (but not Li+) attenuated the magnitude of the pos
tanoxic alkalinization, suggesting that increased Na+/H+ exchange activity
contributes to the postanoxic rise in pH(i). In support, rates of pH(i) rec
overy from internal acid loads imposed following anoxia were increased comp
ared to control values established prior to anoxia in the same neurons. In
contrast, rates of pH(i) recovery from acid loads imposed during anoxia wer
e reduced, suggesting the possibility that Na+/H+ exchange is inhibited dur
ing anoxia.
We conclude that the steady-state pHi response of cultured rat hippocampal
neurons to transient anoxia is independent of changes in [Ca2+](i) and is c
haracterized by three phases which are determined, at least in part, by alt
erations in Na+/H+ exchange activity and, possibly, by a proton conductance
which is activated during membrane depolarization. (C) 1999 IBRO. Publishe
d by Elsevier Science Ltd.