Hyperbaric oxygen inhibits the growth of cultured rabbit lens epithelial cells without affecting glutathione level.

Studies on human patients and experimental animals indicate that hyperbaric O2 can opacify the lens nucleus and damage the lens epithelium in vivo. Here we investigate the effects of hyperbaric O2 on cultured rabbit lens epithelial cells (LECs). When the cells were exposed to 50 atm O2 (99% O2 + 1% CO2) for 3 hr there were no immediate effects on morphology, viability and transport processes (uptake of 86Rb and 14C-alpha AIB). In addition, the O2 treatment did not lower the high level of reduced glutathione or increase the low level of oxidized glutathione. However, 50 atm O2 did produce a near doubling in the glycolytic rate which maintained ATP at levels only slightly lower than normal. Although the 3-hr O2 treatment was not lethal, it completely inhibited cell division for 2 days. After 2 days, growth was initiated and, at day 7 the rate of growth was faster than the controls (control cells were treated with ambient air or 50 atm N2 for 3 hr). Cells treated with 8 atm O2 for 3 hr exhibited a slowed rate of growth, relative to controls, while exposure to 2 atm O2, did not inhibit mitosis. Changes in morphology (multilayering and elongation) of cells exposed to 50 atm O2, but not the controls, were evident 7 days after the 3-hr exposure. The incorporation of [35S]methionine into individual polypeptides and [3H]thymidine into DNA was significantly inhibited immediately following a 3-hr treatment with 50 atm O2, but both parameters recovered within 2 days. DNA strand breaks were observed in LECs following hyperbaric O2 treatment as low as 4 atm O2 for 3 hr and increased with higher pressures of O2, but not N2. Treatment with 50 atm O2 nearly doubled the activity of the DNA repair enzyme, poly-ADP-ribose polymerase, and decreased the level of its substrate NAD+; the latter effect was reduced by 3-aminobenzamide, an inhibitor of the enzyme. Thus, although LECs tolerated brief exposures to high pressures of O2 without cell death, DNA damage occurred at relatively low pressures of O2. All of the effects of hyperbaric O2 on LECs occurred without any alteration of the normal levels of reduced and oxidized glutathione. It appears that GSH is important in maintaining cell viability during exposure to an elevated level of O2, but that it is incapable of preventing O2-induced effects on growth and DNA.