Photocaged fluorescent molecules are important research tools for tracking molecular dynamics with high spatiotemporal resolution in biological systems. We have designed and synthesized a new class of caged coumarin fluorophores. These coumarin cages displayed more than 200-fold fluorescence enhancement after UV photolysis. Remarkably, the uncaging cross section of a 1-(2-nitrophenyl)ethyl (NPE)-caged coumarin is 6600 at wavelength of 365 nm, about 2 orders of magnitude higher than previously described caged fluorophores. Product analysis of the photolytic reaction showed clean conversion of NPE-caged coumarin to 2-nitrosoacetophenone and the parent coumarin, suggesting that the mechanism of the photolysis follows the known photochemical reaction pathway of the 2-nitrobenzyl group. We have also measured the two-photon uncaging cross sections of NPE-caged coumarins 2a and 5 at 740 nm to be near 1 Goeppert-Mayer (GM). The mechanistic study, together with the two-photon uncaging data, suggested that the coumarin moiety serves as an antenna to enhance the light harvesting efficiency of the coumarin cage and that the photonic energy absorbed by coumarin was utilized efficiently to photolyze the NPE group. Future explorations of this type of "substrate-assisted photolysis" may yield other cages of high uncaging cross sections. For cellular imaging applications, we prepared a cell permeable and caged coumarin fluorophore, NPE-HCCC2/AM (10), which can be loaded into fully intact cells to high concentrations. Initial tests of this probe in a number of cultured mammalian cells showed desired properties for the in vivo imaging applications. The combined advantages of robust fluorescence contrast enhancement, remarkably high uncaging cross sections, noninvasive cellular delivery, and flexible chemistry for bioconjugations should generate broad applications of these caged coumarins in biochemical and biological research.
Using a new class of photo-activatible fluorophores, we have developed a new imaging technique for measuring molecular transfer rates across gap junction connexin channels in intact living cells. This technique, named LAMP, involves local activation of a molecular fluorescent probe, NPE-HCCC2/AM, to optically label a cell. Subsequent dye transfer through gap junctions from labeled to unlabeled cells was quantified by fluorescence microscopy. Additional uncagings after prior dye transfers reached equilibrium enabled multiple measurements of dye transfer rates in the same coupled cell pair. Measurements in the same cell pair minimized variation due to differences in cell volume and number of gap junctions, allowing us to track acute changes in gap junction permeability. We applied the technique to study the regulation of gap junction coupling by intracellular Ca(2+) ([Ca(2+)](i)). Although agonist or ionomycin exposure can raise bulk [Ca(2+)](i) to levels higher than those caused by capacitative Ca(2+) influx, the LAMP assay revealed that only Ca(2+) influx through the plasma membrane store-operated Ca(2+) channels strongly reduced gap junction coupling. The noninvasive and quantitative nature of this imaging technique should facilitate future investigations of the dynamic regulation of gap junction communication.
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