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A setup for fluorescence measurements of surfaces of biological samples, in particular the plasma membrane of living
cells, is described. The method is based on splitting of a laser beam and multiple total internal reflections (TIR) within
the bottom of a microtiter plate, such that up to 96 individual samples are illuminated simultaneously by an evanescent
electromagnetic field. Two different screening procedures for the detection of fluorescence arising from the plasma
membrane of living cells by High Throughput Screening (HTS) and High Content Screening (HCS), are distinguished. In
the first case a rapid measurement of large sample numbers based on fluorescence intensity, and in the second case a
high content of information from a single sample based on the parameters fluorescence lifetime (Fluorescence Lifetime
Screening, FLiS) and fluorescence anisotropy (Fluorescence Lifetime Polarization Screening, FLiPS) is achieved. Both
screening systems were validated using cultivated cells incubated with different fluorescent markers (e. g. NBD-cholesterol)
as well as stably transfected cells expressing a fluorescent membrane-associating protein. In addition,
particularly with regard of potential pharmaceutical applications, the kinetics of the intracellular translocation of a
fluorescent protein kinase c fusion protein upon stimulation of the cells was determined. Further, a caspase sensor based
on Förster Resonance Energy Transfer (FRET) between fluorescent proteins was tested. Enhanced cyan fluorescent
protein (ECFP) anchored to the inner leaflet of the plasma membrane of living cells transfers its excitation energy via a
spacer (DEVD) to an enhanced yellow fluorescent protein (EYFP). Upon apoptosis DEVD is cleaved, and energy
transfer is disrupted, as proven by changes in fluorescence intensity and decay times.
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