We used the fluorescent pH-sensitive dye 2',7'-bis(carboxyethyl)-5,6-c
arboxyfluorescein (BCECF) to monitor intracellular pH (pH(i)) in singl
e astrocytes cultured from the forebrain of neonatal rats. When expose
d to a nominally CO2/HCO3--free medium buffered to pH 7.40 with HEPES
at 37-degrees-C, the cells had a mean pH(i) of 6.89. Switching to a me
dium buffered to pH 7.40 with 5% CO2 and 25 mM HCO:, caused the steady
-state pH(i) to increase by an average of 0.35, suggesting the presenc
e of a HCO3--dependent acid-extrusion mechanism. The sustained alkalin
ization was sometimes preceded by a small transient acidification. In
experiments in which astrocytes were exposed to nominally HCO3--free (
HEPES-buffered) solutions, the application and withdrawal of 20 mM ext
racellular NH4+ caused pH(i) to fall to a value substantially below th
e initial one. pH(i) spontaneously recovered from this acid load, stab
ilizing at a value approximately 0.1 higher than the one prevailing be
fore the application of NH4+. In other experiments conducted on cells
bathed in HEPES-buffered solutions, removing extracellular Na+ caused
pH(i) to decrease rapidly by 0.5. Returning the Na+ caused pH(i) to in
crease rapidly, indicating the presence of an Na+-dependent/HCO3--inde
pendent acid-extrusion mechanism; the final pH(i) after returning Nawas approximately 0.08 higher than the initial value. This pH(i) recov
ery elicited by returning Na+ was not substantially affected by 50 muM
ethylisopropylamiloride (EIPA), but was speeded up by 50 muM 4,4'-dii
sothiocyanostilbene-2,2'-disulfonate (DIDS). Increasing K+!o from 5 t
o 25 mM caused pH(i) to increase reversibly by approximately 0.2 in no
minally CO2/HCO3--free solutions, and by approximately 0.1 in CO2/HCO3
--containing solutions, although the initial pH(i) was approximately 0
.17 higher in the presence of CO2/HCO3-. These results suggest the pre
sence of a depolarization-induced alkalinization. Our results suggest
the presence of both HCO3- dependent and -independent acid-base transp
ort systems in cultured mammalian astrocytes, and indicate that astroc
yte pH(i) is sensitive to changes in either membrane voltage or K+!o
per se. (C) 1993 Wiley-Liss, Inc.