Scanning microspectrofluorometry of rhodamine 123 in multidrug‐resistant cells

Abstract

Scanning microspectrofluorometry has been developed to perform the mapping of fluorescence spectra from all locations in a living cell. This new method has been applied to study the molecular environment of rhodamine 123 (R123) in sensitive (K562, CEM) and multidrug-resistant (K562-R, CEM/VLB₁₀₀) tumor cells. All cells exposed to R123 showed a similar distribution of fluorescence in the perinuclear region. A lower cytoplasmic fluorescence intensity corresponding to a reduced drug accumulation was observed in resistant cells, as expected in the multidrug resistance process. Fluorescence emission spectra of R123 are useful to probe the polarity of the R123 environment. Thus, fluorescence spectra of R123-treated cells have been analyzed as a linear combination of model spectra: R123 in water and R123 in tensio-active Triton X-100. In sensitive cells, emission spectra of R123 underwent a red shift, equivalent to those observed in isolated coupled mitochondria. This suggests the formation of a complex in hydrophobic sites. In contrast, R123 spectra were less shifted in resistant cells, showing two types of both hydrophobic and hydrophilic binding sites. This could be related to an intracellular redistribution of R123 in resistant cells.