Ultraviolet (UV) irradiation of the skin induces a variety of responses in the epidermis, including sunburn cell formation, epidermal hyperplasia, and a dose-dependent permeability barrier abnormality, an effect that appears to be dependent upon both UVB-induced hyperplasia and T-cell activation. Since intrinsically aged epidermis displays decreased epidermal turnover, diminished inflammatory response to various stimuli, including UVR, and impaired immune function, we investigated the effects of UVB on both epidermal barrier function and proliferation in hairless mice of increasing chronologic age (27, 61, and 90 wk). After a single UVB exposure (0.15 J/cm2 7.5 MED), a barrier abnormality developed (i.e., increased transepidermal water loss; TEWL), after a delay of > or = 48 h, regardless of age. In young mice (27 wk old), TEWL levels peaked at 72-96 h (9.9-fold over untreated controls), whereas increased epidermal [3H]thymidine incorporation preceded the peak TEWL increase (i.e., approximately 570% increase over controls at 48 h). In contrast, the UVB-induced increased in both TEWL and DNA synthesis were significantly diminished, with decreased epidermal hyperplasia evident, in intrinsically aged versus young mouse epidermis. Baseline epidermal thickness decreased with animal age (i.e., 16.8 +/- 3.1 vs. 27.9 +/- 0.7 microm for 90- vs. 27-wk-old animals, respectively; p < 0.02), suggesting that the diminished barrier response with aging reflects an attenuation of events subsequent to initial UVB exposure, rather than an increase in the UV dose delivered. These results demonstrate that (i) murine epidermis becomes less sensitive to UVB-induced barrier alterations with age and (ii) decreased DNA synthesis after UVB correlates with the age-related decrease in barrier dysfunction.