Abstract
Cultured rat fibroblasts were exposed to 50 fluorescent probes of varied physicochemical characteristics. Probe concentrations, fluorochrome excitation wavelength and period of illumination, and cell-probe contact time were varied. Structure-activity relationships defining a number of classes of fluorescent probes for lysosomes and related processes and compartments were demonstrated. Numerical specifications are now available for several familiar classes of probes: (a) acidotropic weak bases, used as markers for low pH compartments; (b) markers of adsorptive pinocytosis, involving non-specific protein binding; (c) markers for fluid phase pinocytosis; and (d) viability stains involving intralysosomal enzymic activity. Two novel classes of probes have also been specified numerically: (a) acid-precipitated weak acids, as markers for low pH compartments; and (b) lipid-binding markers of adsorptive pinocytosis. Overall, these structure-activity models provide a tool for predicting whether or not compounds enter cells; and whether they accumulate in lysosomes and related compartments. Pathways of entry are also predicted. This tool should permit design and selection of improved probes, and provide a better understanding of existing reagents. Moreover these models are expected to be applicable to interactions between any non-polymeric xenobiotic with lysosomes and related compartments.
Published Version
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