Lactic acid inhibition of gap junctional intercellular communication in in vitro astrocytes as measured by fluorescence recovery after laser photobleaching
Lactic acid can permeate plasma membranes, causing intracellular acidosis. Gap junctions are sensitive to pHi and can be reversibly uncoupled by weak acids. In this study, dye coupling between in vitro astrocytes, presumably mediated by gap junctions, was measured in the absence and presence of lactic acid. Fluorescence recovery after laser photobleaching (gap-FRAP analysis) was used to measure dye coupling. Astrocytes bathed in Eagle's minimum essential medium (EMEM) with lactic acid, pHo 5.5-6, showed no difference in their dye coupling (mean recovery of fluorescence 30%) when compared to control astrocytes (mean recovery of fluorescence 26%). However, 24 mM lactic acid in EMEM, pHo 4.5, decreased dye coupling (mean recovery of fluorescence 2.0%). This effect occurred within 5 min of treatment. When lactic acid-EMEM, pH 4.5, was removed from astrocytes after 30 min and the cells were incubated in EMEM for 24 hr, decreased coupling was not reversed (mean recovery 4.0%). When lactic acid-treated astrocytes were incubated in EMEM for 48 hr, the mean recovery of fluorescence increased to 15% (i.e., 42% of the recovery seen in controls). These observations suggest that brief exposure to high concentrations of lactic acid can have immediate and long-lasting effects on glial gap junctional communication. Under pathological circumstances, such a sequence could be initiated, and this might impair astrocytic control of the central nervous system microenvironment mediated by spatial buffering.
- Research Organization:
- Uniformed Services Univ. of the Health Sciences, F. Edward Hebert School of Medicine, Bethesda, MD (USA)
- OSTI ID:
- 6071094
- Journal Information:
- Glia (NY); (United States), Vol. 1:6
- Country of Publication:
- United States
- Language:
- English
Similar Records
H1-antihistamines induce vacuolation in astrocytes through macroautophagy
The phosphorylation status and cytoskeletal remodeling of striatal astrocytes treated with quinolinic acid
Related Subjects
LACTIC ACID
BIOLOGICAL EFFECTS
LASER RADIATION
NERVE CELLS
BIOLOGICAL RECOVERY
CELL MEMBRANES
FLUORESCENCE
IN VITRO
INHIBITION
LASERS
ANIMAL CELLS
CARBOXYLIC ACIDS
CELL CONSTITUENTS
ELECTROMAGNETIC RADIATION
HYDROXY ACIDS
LUMINESCENCE
MEMBRANES
ORGANIC ACIDS
ORGANIC COMPOUNDS
RADIATIONS
RECOVERY
SOMATIC CELLS
560400* - Other Environmental Pollutant Effects