Quantitative pH imaging in cells using confocal fluorescence lifetime imaging microscopy.

The pH-sensitive probe carboxy SNAFL-1 can be used for imaging using ratiometric and fluorescence lifetime techniques. The former method suffers from the drawback that quantitative pH imaging in cells requires a time-consuming and cumbersome calibration procedure. In contrast, straightforward calibrations in buffer suffice for fluorescence lifetime imaging. This is illustrated here by a comparative study of the two techniques under different controlled conditions. The effect of probe concentration, protein concentration, and hydrophobicity, the contents of damaged cells and living cells on the emission ratio, and the fluorescence lifetime of carboxy SNAFL-1 were studied. The results clearly demonstrate that the fluorescence lifetime imaging technique is more convenient than the ratiometric method for pH determination.

[Application of confocal laser microscopy in studying the effect of epidermal growth factor on the seminiferous epithelium]. / Application de la microscopie laser confocale à l'étude de l'effet de l'EGF sur l'épithélium séminifère.

Effects of epidermal growth factor (EGF) on pH transients in aggregates of Sertoli cells and germinal cells have been investigated with confocal microscopy using a fluorescent pH sensitive indicator. In some Sertoli cells EGF caused a rapid rise in the pH whereas other Sertoli cells did not respond to EGF. Some Sertoli cells showed a delayed response which coincidated with a similar pH change in neighbouring germinal cells. Since isolated germinal cells never showed a pH response after exposure to EGF, we have concluded that some Sertoli cells may communicate with germinal cells via gap junctions.

Confocal fluorescence lifetime imaging of free calcium in single cells.

Ca(2+) concentrations in biological cells are widely studied with fluorescent probes. The probes have a high selectivity for free calcium and exhibit marked changes in their photophysical properties upon binding. The differences in the fluorescent lifetime of the probes can now be used as a contrast mechanism for imaging purposes. This technique can be further exploited for the quantitative determination of ion concentrations within the cells. We describe the use of a fast fluorescence lifetime imaging method in combination with a standard confocal laser scanning microscope for the determination of Ca(2+) concentrations in single rat cardiac myocytes using the intensity probe Calcium Green.