Green fluorescent protein (GFP) from jellyfish Aequorea victoria is the most extensively studied and widely used in cell biology protein. GFP-like proteins constitute a fast growing family as several naturally occurring GFP-like proteins have been discovered and enhanced mutants of Aequorea GFP have been created. These mutants differ from wild-type GFP by conformational stability, quantum yield, spectroscopic properties (positions of absorption and fluorescence spectra) and by photochemical properties. GFP-like proteins are very diverse, as they can be not only green, but also blue, orange-red, far-red, cyan, and yellow. They also can have dual-color fluorescence (e.g., green and red) or be non-fluorescent. Some of them possess kindling property, some are photoactivatable, and some are photoswitchable. This review is an attempt to characterize the main color groups of GFP-like proteins, describe their structure and mechanisms of chromophore formation, systemize data on their conformational stability and summarize the main trends of their utilization as markers and biosensors in cell and molecular biology.
Comparative analysis of conformational stabilities was performed for two widely used genetic reporters, EGFP and DsRed, proteins exhibiting similar beta-can folds, but possessing different oligomeric organization and chromophore structures. Two factors affecting protein stability in vitro, such as elevated temperatures and a chaotropic agent guanidine hydrochloride, were studied. In vivo tolerance of the fluorescence proteins to proteasomal-based degradation was studied in insect and mammalian cells, and in Xenopus embryos. The apparent rate constants of thermal and GdmCl-induced denaturation were several orders of magnitude lower for DsRed than for EGFP. DsRed lifetimes severalfold longer than those of EGFP were observed in cultured cells and in embryos. The remarkable fluorescence stability of DsRed under the all conditions that have been studied is attributed to a significant extent to its tetrameric organization. Therefore, DsRed can be used as a genetic reporter and advanced population marker with a significantly extended intracellular lifespan.
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