The formation and excision of 313-nm light-induced cyclobutane-type pyrimidine photodimers were determined in confluent cultures of human fibroblasts. A new method was developed for the resolution and determination of cytosine-thymine (CT) and thymine-thymine dimers (TT) by using sodium borohydride reduction and high-pressure liquid chromatography. This assay can detect as little as 1.8 TT or 5.6 CT per 10(8) daltons, levels induced in monolayers of human skin fibroblasts by doses of 1 and 2 kJ m-2 of 313-nm light, respectively. CT formation was 20% more efficient than TT formation in the physiological dose range of 2.25-15 k m-2 at 37 degrees C. Normal fibroblasts removed 61% TT within the first 8 h of incubation following a dose of 5.5 kJ m-2. CT was removed approximately twice as efficiently as TT during the same time period following exposure to 10 kJ m-2. The lack of removal of CT as well as TT observed in xeroderma pigmentosum fibroblasts indicates that the repair deficiency in these cells affects the repair of both classes of dimers.
Photobiological research in the last 30 yr has shown the existence of ultraweak photon emission in biological tissue, which can be detected with sophisticated photomultiplier systems. Although the emission of this ultraweak radiation, often termed biophotons, is extremely low in mammalian cells, it can be efficiently increased by ultraviolet light. Most recently it was shown that UV-A (330 to 380 nm) releases such very weak cell radiation in differentiated human skin fibroblasts. Based on these findings, a new and powerful tool in the form of UV-A-laser-induced biophotonic emission of cultured cells was developed with the intention to detect biophysical changes between carcinogenic and normal cells. With suspension densities ranging from 1 to 8 x 10(6) cells/mL, it was evident that an increase of the UV-A-laser-light induced photon emission intensity could be observed in normal as well as melanoma cells. Using this new detection procedure of ultraweak light emission, photons in cell suspensions as low as 100 microL could be determined, which is a factor of 100 lower compared to previous procedures. Moreover, the detection procedure has been further refined by turning off the photomultiplier system electronically during irradiation leading to the first measurements of induced light emission in the cells after less than 10 micros instead of 150 ms, as reported in previous procedures. This improvement leads to measurements of light bursts up 10(7) photons/s instead of several hundred as found with classical designs. Overall, we find decreasing induction ratings between normal and melanoma cells as well as cancer-prone and melanoma cells. Therefore, it turns out that this highly sensitive and noninvasive device enables us to detect high levels of ultraweak photon emission following UV-A-laser-induced light stimulation within the cells, which enables future development of new biophysical strategies in cell research.
In our present studies, the time-resolved emission spectrum of delayed luminescence of cell cultures of human fibroblast and human melanoma have been measured using a sophisticated single photon device. Noticeable differences have been found both in the emission spectra, which are time dependent, and in the timing aspects of the different spectral components. This powerful and noninvasive technique can be applied in all fields of skin research, such as the investigation of skin abnormalities and to test the effect of products involved in regeneration, antiaging, and UV-light protection in order to prevent skin cancer.
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