Eos (protein)
EosFP is a photoactivatable green to red fluorescent protein. Its green fluorescence switches to red upon UV irradiation of ~390 nm due to a photo-induced modification resulting from a break in the peptide backbone near the chromophore. Eos was first discovered as a tetrameric protein in the stony coral Lobophyllia hemprichii''.'' Like other fluorescent proteins, Eos allows for applications such as the tracking of fusion proteins, multicolour labelling and tracking of cell movement. Several variants of Eos have been engineered for use in specific study systems including mEos2, mEos4 and CaMPARI.
History
EosFP was first discovered in 2005 during a large scale screen for PAFPs within the stony coral Lobophyllia hemprichii. It has since been successfully cloned in Escherichia coli and fusion constructs have been developed for use in human cells. Eos was named after the Greek goddess of dawn.Unlike the tetrameric fluorescent proteins derived from anthozoan coral, which can interfere with normal cellular function due to interactions between protein subunits, EosFP has been broken up into dimeric and monomeric variants through the introduction of single point mutations. These variants have been successful in the tracking of cellular components without disturbing function in the host cell and maintain the same photophysical properties as wild-type Eos.
Since their discovery, monomeric Eos probes have been shown to localize in the cytosol, plasma membrane, endosomes, prevacuolar vesicles, vacuoles, the endoplasmic reticulum, golgi bodies, peroxisomes, mitochondria, invaginations, filamentous actin and cortical microtubules. mEos fusion proteins allow for differential colour labelling in single cells, or groups of cells in developing organs. They can also be used for the understanding of spatial/ temporal interactions between organelles and vesicles. The two fluorescent forms of mEosFP are compatible with CFP, GFP, YFP and RFP for multicolour labelling.
Function
EosFP emits a strong green fluorescence that changes irreversibly to red when irradiated with UV-light of 390 nm. This modification occurs due to a break in the peptide backbone next to the chromophore. This mechanism allows for localized tagging of the protein and makes EosFP an appropriate tool for tracking protein movement within living cells. Formation of the red chromophore involves cleaving the peptide backbone but includes almost no other changes in the protein structure.According to single-molecule fluorescence spectroscopy, EosFP is tetrameric, and exhibits strong Forster resonance coupling within individual fluorophores. Like other fluorescent proteins, Eos can be used to report diverse signals in cells, tissues and organs without disturbing complex biological machinery. While the use of fluorescent proteins was once limited to the green fluorescent protein, in recent years many other fluorescent proteins have been cloned. Unlike GFPs, which are derived from the luminescent jellyfish Aequorea victoria, fluorescent proteins derived from anthozoa, including Eos, emit fluorescence in the red spectral range. The novel property of photoinduced green-to-red conversion in Eos is useful because it allows for localized tracking of proteins in living cells. EosFP is unique because it has a large separation in the wavelengths it can emit which allows for easy identification of peak colours. All green-to-red photoinducible fluorescent proteins, including Eos, contain a chromophoric unit derived from the tripeptide his-tyr-gly. This green-to-red conversion is completed by light rather than chemical oxidation such as in other FPs.
Structure and Absorbance Properties
Primary structure
EosFP consists of 226 amino acids. It has a molecular mass of 25.8 kDa and its pI is 6.9. Eos has 84% identical residues to Kaede, a fluorescent protein that originated in a different scleractinian coral Trachyphyllia geoffroyi, but can also be irreversibly converted from a green to red emitting form using UV light. Excluding residues Phe-61 and His-62, the chromophore environment and chromophore itself are unaffected by photochemical modification. Wild-type EosFP has a tetrameric arrangement of subunits where each subunit has the same β-can structure as GFP. This structure includes an 11-stranded barrel and, down the central axis, the fluorophore-containing helix.Structure of Green EosFP
In its anionic form, the green chromophore has an absorption maxima at 506 nm and an emission maxima at 516 nm. It is formed autocatalytically from amino acids His-62, Tyr-63 and Gly-64. Immediately surrounding the chromophore there is a cluster of charged or polar amino acids as well as structural water molecules. Above the plane of the chromophore, there is a network of hydrogen bond interactions between Glu-144, His-194, Glu-212 and Gln-38. Arg-66 and Arg-91 participate in hydrogen bonding with the carbonyl oxygen of green Eos's imidazolinone moiety. The His-62 side chain lies in an unpolar environment. Conversion from the green to red form depends on the presence of a histidine in the first position of the tripeptide HYG that forms the chromophore. When this histidine residue is substituted with M, S, T or L, Eos only emits bright green light and no longer acts as a photoconvertible fluorescent protein.Structure of Red EosFP
The red chromophore, which is generated by cleavage of the peptide backbone, has an absorption maxima at 571 nm and an emission maxima at 581 nm, in its anionic form. The break in the peptide backbone that leads to this chromophore is between His-62 Nα and Cα. The observed red fluorescence occurs due to an extension of the chromophore's π-conjugation where the His-62 imidazole ring connects to the imidazolinone. The hydrogen bond patterns of the red and green chromophores are almost identical.Photochemical conversion
Photochemical conversion occurs due to interactions between the chromophoric unit and residues in its vicinity. Glu-212 functions as a base that removes a proton from His-62 aiding in the cleavage of the His-62-Nα-Cα bond. Replacing Glu-212 with glutamine prevents photoconversion. At low pH, the yield of Eos involved in photoconversion is greatly increased as the fraction of molecules in the protonated form increases. The action spectrum for photoconversion is closely related to the action spectrum for Eos's protonated form. These observations suggest that the neutral form of the green chromophore, including a protonated Tyr-63 side chain, is the gateway structure for photoconversion. Proton ejection from the Tyr-63 phenyl side chain is an important event in the conversion mechanism where a proton is transferred from the His-62 imidazole, which is hydrogen-bonded to the Phe-61 carbonyl. The extra proton causes His-62 to donate a proton to the Phe-61 carbonyl forming a leaving group out of the peptide bond between His and Phe in the elimination reaction. The His-62 side chain is protonated during photoexcitation and assists the reaction by donating a proton to the Phe-61 carbonyl in the leaving group. After the backbone is cleaved, the hydrogen bond between His-62 and Phe-61 is reformed. When His-62 is replaced with other amino acids, EosFP loses its ability to photoconvert, providing evidence that His-62 is a necessary component of the photoconversion mechanism. The internal charge distribution of the green chromophore is altered during photo excitation to assist in the elimination reaction.Spectroscopy
Both the fluorescence excitation and emission spectrums of wild-type EosFP are shifted ~65 nm to the right upon excitation toward the red end of the spectrum. This spectral change is caused by an extension of the chromophore accompanied by a break in the peptide backbone between Phe-61 and His-62 in an irreversible mechanism. The presence of a crisp isosbestic point at 432 nm also suggests an interconversion between two species. An absorption peak at 280 nm is visible due to aromatic amino acids which transfer their excitation energy to the green chromophore. The quantum yield of the green-emitting form of Eos is 0.7. In the red shifted species, there are pronounced vibronic sidebands separate from the main peak at 533 nm and 629 nm in the excitation spectrum and emission spectrum respectively. There is another peak in the red excitation spectrum at 502 nm likely due to FRET excitation of the red fluorophore. The quantum yield of the red-emitting form is 0.55.EosFPs variants show almost no difference in spectroscopic properties, therefore, it is likely that the structural modifications which arise from separation of interfaces have little to no effect on the structure of the fluorophore-binding site.