A novel technique for visualizing the intracellular localization and distribution of transported polyamines in cultured pulmonary artery smooth muscle cells.

The use of a combination of monofluorescein adducts of spermidine (FL-SPD) and spermine (FL-SPM) with confocal laser scanning microscopy (CLSM) provides a useful means for monitoring the fate and time-dependent changes in the distribution of transported polyamines within living cells. Polyamine-fluorescein adducts were synthesized from fluorescein isothiocyanate and the appropriate polyamine. Monofluorescein polyamine adducts (ratio 1:1) were isolated using thin layer chromatography, and the structure and molecular weight of the monofluorescein polyamine adducts were confirmed using NMR and mass spectroscopy, respectively. The covalent linkage of the fluorescent adduct moiety to SPD and SPM did not influence their rate of uptake by bovine pulmonary artery smooth muscle cells (PASMC). Similar to 14C-SPD and 14C-SPM, the rate of uptake of 14C-FL-SPD and 14C-FL-SPM in PASMC was temperature-dependent. Treatment for 24 h with difluoromethylornithine (DFMO), a selective blocker of the enzyme ornithine decarboxylase and an inducer of the polyamine transport system, significantly increased the cellular uptake of 14C-FL-SPD and 14C-FL-SPM compared to that of control cells. When compared to control cells, treatment of PASMC with the pyrrolizidine alkaloid monocrotaline for 24 h also significantly increased the cellular uptake of 14C-FL-SPD and 14C-FL-SPM. On the other hand, 24 h treatment of PASMC with a polymer of SPM, a selective blocker of the polyamine transport system, or with free spermine, markedly reduced the cellular accumulation of 14C-FL-SPD and 14C-FL-SPM. After a 20-min treatment of PASMC with FL-SPD or FL-SPM, CLSM revealed that adduct fluorescence was localized in the cytoplasm of living cells. Treatment with DFMO increased the cytoplasmic accumulation of both FL-SPD and FL-SPM. In addition, the fluorescence observed in the cytoplasm of chinese hamster ovary cells (CHO) was significantly higher than that detected in the cytoplasm of their polyamine transport deficient variants (CHOMGBG). The results of this study provide the first evidence of the utility of a novel method for visualizing the uptake, distribution, and cellular localization of transported polyamines in viable cultured mammalian cells.