Understanding the role of Arg96 in structure and stability of green fluorescent protein.

Arg96 is a highly conservative residue known to catalyze spontaneous green fluorescent protein (GFP) chromophore biosynthesis. To understand a role of Arg96 in conformational stability and structural behavior of EGFP, the properties of a series of the EGFP mutants bearing substitutions at this position were studied using circular dichroism, steady state fluorescence spectroscopy, fluorescence lifetime, kinetics and equilibrium unfolding analysis, and acrylamide-induced fluorescence quenching. During the protein production and purification, high yield was achieved for EGFP/Arg96Cys variant, whereas EGFP/Arg96Ser and EGFP/Arg96Ala were characterized by essentially lower yields and no protein was produced when Arg96 was substituted by Gly. We have also shown that only EGFP/Arg96Cys possessed relatively fast chromophore maturation, whereas it took EGFP/Arg96Ser and EGFP/Arg96Ala about a year to develop a noticeable green fluorescence. The intensity of the characteristic green fluorescence measured for the EGFP/Arg96Cys and EGFP/Arg96Ser (or EGFP/Arg96Ala) was 5- and 50-times lower than that of the nonmodified EGFP. Intriguingly, EGFP/Arg96Cys was shown to be more stable than EGFP toward the GdmCl-induced unfolding both in kinetics and in the quasi-equilibrium experiments. In comparison with EGFP, tryptophan residues of EGFP/Arg96Cys were more accessible to the solvent. These data taken together suggest that besides established earlier crucial catalytic role, Arg96 is important for the overall folding and conformational stability of GFP.

Comparative studies on the structure and stability of fluorescent proteins EGFP, zFP506, mRFP1, "dimer2", and DsRed1.

To obtain more information about the structural properties and conformational stabilities of GFP-like fluorescent proteins, we have undertaken a systematic analysis of series of green and red fluorescent proteins with different association states. The list of studied proteins includes EGFP (green monomer), zFP506 (green tetramer), mRFP1 (red monomer), "dimer2" (red dimer), and DsRed1 (red tetramer). Fluorescent and absorbance parameters, near-UV and visible CD spectra, the accessibility of the chromophores and tryptophans to acrylamide quenching, and the resistance of these proteins to the guanidine hydrochloride unfolding and kinetics of the approaching of the unfolding equilibrium have been compared. Tetrameric zFP506 was shown to be dramatically more stable than the EGFP monomer, assuming that association might contribute to the protein conformational stability. This assumption is most likely valid even though the sequences OF GFP and zPF506 are only approximately 25% identical. Interestingly, red FPs possessed comparable conformational stabilities, where monomeric mRFP1 was the most stable species under the equilibrium conditions, whereas the tetrameric DsRed1 possessed the slowest unfolding kinetics. Furthermore, EGFP is shown to be considerably less stable than mRFP1, whereas tetrameric zFP506 is the most stable species analyzed in this study. This means that the quaternary structure, being an important stabilizing factor, does not represent the only circumstance dictating the dramatic variations between fluorescent proteins in their conformational stabilities.

High stability of Discosoma DsRed as compared to Aequorea EGFP.

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.