Study of the in vitro cytotoxic potential of natural and synthetic coumarin derivatives using human normal and neoplastic skin cell lines.

A selection of natural and synthetic coumarin compounds, including the hydroxylated and nitrated derivatives, were assessed for their cytotoxic potential using the microculture 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay for cellular viability. For the first time this study utilized both human skin malignant melanocytes (SK-MEL-31) and normal human skin fibroblastic cells (HS613.SK), allowing identification of those coumarin derivatives that are selectively toxic. Coumarin was found to exhibit comparatively low toxicity in both cell types, while 7-hydroxycoumarin (7-OHC) and coumarin had similar activity in SK-MEL-31 cells. The entire series of hydroxylated coumarins were considerably more toxic in HS613.SK than in SK-MEL-31 cells. Novel synthetic nitrated coumarins, 6-nitro-7-hydroxycoumarin (6-NO2-7-OHC) and 3,6,8-nitro-7-hydroxycoumarin (3,6,8-NO2-7-OHC), were shown to be significantly more toxic to SK-MEL-31 than HS613.SK cells. In the malignant melanocyte skin cell line (SK-MEL-31) the cytotoxic effects of these nitro-derivatives were shown to be dose and time dependent. Therefore, the cytotoxic potential of coumarins appears to be highly dependent on the nature and position of the functional group. In addition, nitration of 7-OHC produced compounds that were cytotoxic to malignant melanocytes, suggesting that these nitro-derivatives may have a chemotherapeutic role in the future.

Regulation of catalase synthesis in Salmonella typhimurium.

The specific activity of catalase in Salmonella typhimurium and other enteric bacteria decreased during the logarithmic phase of growth and increased at the onset and during the stationary phase. The increase in catalase synthesis at the end of the exponential phase in S. typhimurium cells coincided with the lowest pH value reached by the culture. Maintenance of the pH at a constant neutral value did not alter the typical pattern of synthesis in contradiction of the results previously reported (McCarthy and Hinshelwood. 1959). A sudden decrease in the pH value of an S. typhimurium culture during exponential growth by addition of HC1 did not cause an alteration in the catalase synthesis pattern. Addition of hydrogen peroxide to S. typhimurium cultures within the range 1 muM TO 2MM during the exponential growth phase stimulated catalase synthesis. The extent of catalase synthesis depended on the concentration of hydrogen peroxide; the maximum stimulation was observed at 80 muM. Increased catalase synthesis was not detected for 10 to 15 min after hydrogen peroxide addition. Hydrogen peroxide was produced by S. typhimurium cultures during the exponential and stationary growth phases. However, no direct relationship between hydrogen peroxide accumulation and synthesis of catalase was observed.