Crystallographic structures of Discosoma red fluorescent protein with immature and mature chromophores: linking peptide bond trans-cis isomerization and acylimine formation in chromophore maturation

The mature self-synthesizing p-hydroxybenzylideneimidazolinone-like fluorophores of Discosoma red fluorescent protein (DsRed) and Aequorea victoria green fluorescent protein (GFP) are extensively studied as powerful biological markers. Yet, the spontaneous formation of these fluorophores by cyclization, oxidation, and dehydration reactions of tripeptides within their protein environment remains incompletely understood. The mature DsRed fluorophore (Gln 66, Tyr 67, and Gly 68) differs from the GFP fluorophore by an acylimine that results in Gln 66 Calpha planar geometry and by a Phe 65-Gln 66 cis peptide bond. DsRed green-to-red maturation includes a green-fluorescing immature chromophore and requires a chromophore peptide bond trans-cis isomerization that is slow and incomplete. To clarify the unique structural chemistry for the individual immature "green" and mature "red" chromophores of DsRed, we report here the determination and analysis of crystal structures for the wild-type protein (1.4 A resolution), the entirely green DsRed K70M mutant protein (1.9 A resolution), and the DsRed designed mutant Q66M (1.9 A resolution), which shows increased red chromophore relative to the wild-type DsRed. Whereas the mature, red-fluorescing chromophore has the expected cis peptide bond and a sp(2)-hybridized Gln 66 Calpha with planar geometry, the crystal structure of the immature green-fluorescing chromophore of DsRed, presented here for the first time, reveals a trans peptide bond and a sp(3)-hybridized Gln 66 Calpha with tetrahedral geometry. These results characterize a GFP-like immature green DsRed chromophore structure, reveal distinct mature and immature chromophore environments, and furthermore provide evidence for the coupling of acylimine formation with trans-cis isomerization.     

The crystal structure of the Y66L variant of green fluorescent protein supports a cyclization-oxidation-dehydration mechanism for chromophore maturation

The crystal structure of a colorless variant of green fluorescent protein (GFP) containing the Y66L substitution has been determined to 1.5 A. Crystallographic evidence is presented for the formation of a trapped intermediate on the pathway of chromophore maturation, where the peptide backbone of residues 65-67 has condensed to form a five-membered heterocyclic ring. The hydroxyl leaving group remains attached to the ring as confirmed by high-resolution electrospray mass spectrometry. The alpha-carbon of residue 66 exhibits trigonal planar geometry, consistent with ring oxidation by molecular oxygen. Side chain positions of surrounding residues are not perturbed, in contrast to structural results obtained for the GFPsol-S65G/Y66G variant [Barondeau, D. P., Putnam, C. D., Kassmann, C. J., Tainer, J. A., and Getzoff, E. D. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 12111-12116]. The data are in accord with a reaction pathway in which dehydration is the last of three chemical steps in GFP chromophore formation. A novel mechanism for chromophore biosynthesis is proposed: when the protein folds, the backbone condenses to form a cyclopentyl tetrahedral intermediate. In the second step, the ring is oxidized by molecular oxygen. In the third and final step, elimination of the hydroxyl leaving group as water is coupled to a proton transfer reaction that may proceed via hydrogen-bonded solvent molecules. Replacement of the aromatic Tyr66 with an aliphatic residue appears to have a profound effect on the efficiency of ring dehydration. The proposed mechanism has important implications for understanding the factors that limit the maturation rate of GFP.     

Crystal structure of venus,a yellow fluorescent protein with improved maturation and reduced environmental sensitivity

Yellow emission variants of green fluorescent protein (GFP) have been found useful in a variety of applications in biological systems due to their red-shifted emission spectrum and sensitivity to environmental parameters, such as pH and ionic strength. However, slow maturation properties and new requirements for more intense fluorescence necessitated further mutagenesis studies of these proteins. Venus, a new variant with improved maturation and brightness, as well as reduced environmental dependence, was recently developed by introducing five mutations into the well characterized variant, enhanced yellow fluorescent protein (EYFP). In this paper, we present the crystal structure of Venus at 2.2 A resolution, which enabled us to correlate its novel features with these mutation points. The rearrangement of several side chains near the chromophore, initiated by the F46L mutation, was found to improve maturation at 37 degrees C by removing steric and energetic constraints, which may hinder folding of the polypeptide chain, and by accelerating the oxidation of the Calpha-Cbeta bond of Tyr(66) during chromophore formation. M153T, V163A, and S175G were also found to improve the rate of maturation by creating regions of greater flexibility. F64L induced large conformational changes in the molecule, leading to the removal of halide sensitivity by preventing ion access to the binding site.     

Alternative cyclization in GFP-like proteins family. The formation and structure of the chromophore of a purple chromoprotein from Anemonia sulcata

Anemonia sulcata purple protein (asFP595) belongs to a family of green fluorescent protein (GFP)-like proteins from the Anthozoa species. Similar to GFP, asFP595 apparently forms its chromophore by modifying amino acids within its polypeptide chain. Until now, the GFP-like proteins from Anthozoa were thought to contain chromophores with the same imidazolidinone core as GFP. Mass spectral analysis of a chromophore-containing tryptic pentapeptide from asFP595 demonstrates that chromophore formation in asFP595 is stoichiometrically the same as that in GFP: one H(2)O and two H(+) are released while a Schiff base and dehydrotyrosine are formed. However, structural studies of this asFP595 chromopeptide show that in contrast to GFP, the other peptide bond nitrogen and carbonyl carbon are required for chromophore cyclization, a reaction that yields the six-membered heterocycle 2-(4-hydroxybenzylidene)-6-hydroxy-2,5-dihydropyrazine. Spectrophotometric titration reveals three pH-dependent forms of the asFP595 chromopeptide: yellow (absorption maximum = 430 nm) at pH 3.0; red (absorption maximum = 535 nm) at pH 8.0; and colorless (absorption maximum = 380 nm) at pH 14.0. The pK(a) values for these spectral transitions (6.8 and 10.9) are consistent with the ionization of the phenolic group of dehydrotyrosine and deprotonation of the amidinium cation in the chromophore heterocycle, respectively. The amidinium group in asFP595 accounts for the unique absorption spectrum of the protein, which is substantially red-shifted relative to that of GFP. When the asFP595 chromophore cyclizes, the Cys-Met bond adjacent to the chromophore hydrolyzes, splitting the chromoprotein into 8- and 20-kDa fragments. High performance liquid chromatography analysis of a tryptic digest of denatured asFP595 shows that a pentapeptide with the cleaved Cys-Met bond is the only fragment associated with the red-shifted absorbance. These results imply that fragmentation of asFP595 is a critical step in protein maturation.     

Base catalysis of chromophore formation in Arg96 and Glu222 variants of green fluorescent protein

In green fluorescent protein (GFP), chromophore biosynthesis is initiated by a spontaneous main-chain condensation reaction. Nucleophilic addition of the Gly67 amide nitrogen to the Ser65 carbonyl carbon is catalyzed by the protein fold and leads to a heterocyclic intermediate. To investigate this mechanism, we substituted the highly conserved residues Arg96 and Glu222 in enhanced GFP (EGFP). In the R96M variant, the rate of chromophore formation is greatly reduced (time constant = 7.5 x 10(3) h, pH 7) and exhibits pH dependence. In the E222Q variant, the rate is also attenuated at physiological pH (32 h, pH 7) but is accelerated severalfold beyond that of EGFP at pH 9-10. In contrast, EGFP maturation is pH-independent and proceeds with a time constant of 1 h (pH 7-10). Mass spectrometric results for R96M and E222Q indicate accumulation of the pre-cyclization state, consistent with rate-limiting backbone condensation. The pH-rate profile implies that the Glu222 carboxylate titrates with an apparent pK(a) of 6.5 in R96M and that the Gly67 amide nitrogen titrates with an apparent pK(a) of 9.2 in E222Q. These data suggest a model for GFP chromophore synthesis in which the carboxylate of Glu222 plays the role of a general base, facilitating proton abstraction from the Gly67 amide nitrogen or the Tyr66 alpha-carbon. Arg96 fulfills the role of an electrophile by lowering the respective pK values and stabilizing the alpha-enolate. Modulating the base strength of the proton-abstracting group may aid in the design of fast-maturing GFPs with improved characteristics for real-time monitoring of cellular events.     

Three-dimensional structure of yellow fluorescent protein zYFP538 from Zoanthus sp. at the resolution 1.8 angstrom

The three-dimensional structure of yellow fluorescent proteins zYFP538 (zFP538) from the button polyp Zoanthus sp. was determined at a resolution of 1.8 angstrom by X-ray analysis. The monomer of zYFP538 adopts a structure characteristic of the green fluorescent protein (GFP) family, a beta-barrel formed from 11 antiparallel beta segments and one internal alpha helix with a chromophore embedded into it. Like the TurboGFP, the beta-barrel of zYFP538 contains a water-filled pore leading to the chromophore Tyr67 residue, which presumably provides access of molecular oxygen necessary for the maturation process. The post-translational modification of the chromophore-forming triad Lys66-Tyr67-Gly68 results in a tricyclic structure consisting of a five-membered imidazolinone ring, a phenol ring of the Tyr67 residue, and an additional six-membered tetrahydropyridine ring. The chromophore formation is completed by cleavage of the protein backbone at the Calpha-N bond of Lys66. It was suggested that the energy conflict between the buried positive charge of the intact Lys66 side chain in the hydrophobic pocket formed by the Ile44, Leu46, Phe65, Leu204 and Leu219 side chains is the most probable trigger that induces the transformation of the bicyclic green form to the tricyclic yellow form. A stereochemical analysis of the contacting surfaces at the intratetramer interfaces helped reveal a group of conserved key residues responsible for the oligomerization. Along with others, these residues should be taken into account in designing monomeric forms suitable for practical application as markers of proteins and cell organelles.     

Chromophore aspartate oxidation-decarboxylation in the green-to-red conversion of a fluorescent protein from Zoanthus sp. 2

The red fluorescence of a Discosoma coral protein is the result of an additional autocatalytic oxidation of a green fluorescent protein (GFP)-like chromophore. This reaction creates an extra pi-electron conjugation by forming a C=N-C=O substituent. Here we show that the red fluorescence of a protein from Zoanthus sp. 2 (z2FP574) arises from a coupled oxidation-decarboxylation of Asp-66, the first amino acid of the chromophore-precursory DYG sequence. Comparative mutagenesis of highly homologous green (zFP506) and red (z2FP574) fluorescent proteins from Zoanthus species reveals that an aspartate at position 66 is critical for the development of red fluorescence. The maturation kinetics of wild-type z2FP574 and the zFP506 N66D mutant indicates that the "green" GFP-like form is the actual intermediate in producing the red species. Furthermore, via maturation kinetics analysis of zFP506 N66D, combined with mass spectrometry, we determined that the oxidation-decarboxylation of Asp-66 occurs without detectable intermediate products. According to mass spectral data, the minor "red" chromophore of the z2FP574 D66E mutant appears to be oxidized and completely decarboxylation deficient, indicating that the side chain length of acidic amino acid 66 is critical in controlling efficient oxidation-decarboxylation. Substitutions with aspartate at the equivalent positions of a Condylactis gigantea purple chromoprotein and Dendronephthya sp. green fluorescent protein imply that additional oxidation of a GFP-like structure is a prerequisite for chromophore decarboxylation. In summary, these results lead to a mechanism that is related to the chemistry of beta-keto acid decarboxylation.     

Mutants of Discosoma red fluorescent protein with a GFP-like chromophore

The green fluorescent protein (GFP)-homologous red fluorescent protein (RFP) from Discosoma (drFP583) which emits bright red fluorescence peaking at 583 nm is an interesting novel genetic marker. We show here that RFP maturation involves a GFP-like fluorophore which can be stabilized by point mutations selected from a randomly mutated expression library. By homology modeling, these point mutations cluster near the imidazolidinone ring of the chromophore. Exciting the GFP-like absorption band in the mutant proteins produces both green and red fluorescence. Upon unfolding and heating, the absorption spectrum of the RFP chromophore slowly becomes similar to that of the GFP chromophore. This can be interpreted as a covalent modification of the GFP chromophore in RFP that appears to occur in the final maturation step.     

zFP538, a yellow-fluorescent protein from Zoanthus, contains a novel three-ring chromophore

Crystal structures of the tetrameric yellow-fluorescent protein zFP538 from the button polyp Zoanthus sp. and a green-emitting mutant (K66M) are presented. The atomic models have been refined at 2.7 and 2.5 A resolution, with final crystallographic R factors of 0.206 (R(free) = 0.255) and 0.190 (R(free) = 0.295), respectively, and have excellent stereochemistry. The fold of the protomer is very similar to that of green (GFP) and red (DsRed) fluorescent proteins; however, evidence from crystallography and mass spectrometry suggests that zFP538 contains a three-ring chromophore derived from that of GFP. The yellow-emitting species (lambda(em)(max) = 538 nm) is proposed to result from a transimination reaction in which a transiently appearing DsRed-like acylimine is attacked by the terminal amino group of lysine 66 to form a new six-membered ring, cleaving the polypeptide backbone at the 65-66 position. This extends the chromophore conjugation by an additional double bond compared to GFP, lowering the absorption and emission frequencies. Substitution of lysine 66 with aspartate or glutamate partially converts zFP538 into a red-fluorescent protein, providing additional support for an acylimine intermediate. The diverse and unexpected roles of the side chain at position 66 give new insight into the chemistry of chromophore maturation in the extended family of GFP-like proteins.     

Three-dimensional structure of yellow fluorescent protein zYFP538 from <Emphasis Type="Italic">Zoanthus</Emphasis> sp. at the resolution 1.8 Å

The three-dimensional structure of yellow fluorescent proteins zYFP538 (zFP538) from the button polyp Zoanthus sp. was determined at a resolution of 1.8 Å by X-ray analysis. The monomer of zYFP538 adopts a structure characteristic of the green fluorescent protein (GFP) family, a β-barrel formed from 11 antiparallel β segments and one internal α helix with a chromophore embedded into it. Like the TurboGFP, the β-barrel of zYFP538 contains a water-filled pore leading to the chromophore Tyr67 residue, which presumably provides access of molecular oxygen necessary for the maturation process. The post-translational modification of the chromophore-forming triad Lys66-Tyr67-Gly68 results in a tricyclic structure consisting of a five-membered imidazolinone ring, a phenol ring of the Tyr67 residue, and an additional six-membered tetrahydropyridine ring. The chromophore formation is completed by cleavage of the protein backbone at the C ^α -N bond of Lys66. It was suggested that the energy conflict between the buried positive charge of the intact Lys66 side chain in the hydrophobic pocket formed by the Ile44, Leu46, Phe65, Leu204 and Leu219 side chains is the most probable trigger that induces the transformation of the bicyclic green form to the tricyclic yellow form. A stereochemical analysis of the contacting surfaces at the intratetramer interfaces helped reveal a group of conserved key residues responsible for the oligomerization. Along with others, these residues should be taken into account in designing monomeric forms suitable for practical application as markers of proteins and cell organelles.     

Mechanistic characterization of omega-3 desaturation in the green alga Chlorella vulgaris

alpha-Linolenic acid (ALA, 9(Z),12(Z),15(Z)-octadecatrienoic acid) derivatives are important plant lipids which play a critical key role in cold tolerance. The final steps of ALA biosynthesis feature a series of regio- and stereoselective dehydrogenation reactions which are catalyzed by a set of enzymes known as fatty acid desaturases. In conjunction with ongoing research into the structural biology of these remarkable catalysts, we have examined the mechanism of double bond introduction at C15,16 as it occurs in a model photosynthetic organism, Chlorella vulgaris. The individual deuterium kinetic isotope effects associated with the C-H bond cleavages at C-15 and C-16 of a thialinoleoyl analogue were measured via competition experiments using appropriately deuterium-labelled 7-thia substrates. A large kinetic isotope effect (KIE) (k(H)/k(D)=10.2+/-2.8) was observed for the C-H bond-breaking step at C-15 while the C-H bond cleavage at C-16 was found to be relatively insensitive to deuterium substitution (k(H)/k(D)=0.8+/-0.2). These results point to C-15 as the site of initial oxidation in omega-3 desaturation and imply that the Chlorella and corresponding plant systems share a common active site architecture.     

zFP538, a yellow fluorescent protein from coral, belongs to the DsRed subfamily of GFP-like proteins but possesses the unexpected site of fragmentation

The yellow fluorescent protein (zFP538) from coral Zoanthus sp. belongs to a family of green fluorescent protein (GFP). Absorption and emission spectra of zFP538 show an intermediate bathochromic shift as compared with a number of recently cloned GFP-like red fluorescent and nonfluorescent chromoproteins of the DsRed subfamily. Here we report that the zFP538 chromophore is very close, if not identical, in chemical structure to that of DsRed. To gain insight into the mechanism of zFP538 fluorescence and chromophore structure and chemistry, we studied three chromophore-containing peptides isolated from enzymatic digests of zFP538. Like GFP and DsRed chromophores, these contain a p-hydroxybenzylideneimidazolinone moiety formed by Lys-66, Tyr-67, and Gly-68 of zFP538. One of the peptides studied, the hexapeptide FKYGDR derivative, is a proteolysis product of the zFP538 full-length polypeptide containing a GFP-type chromophore already formed and arrested at an earlier stage of maturation. The two other peptides are the derivatives of the pentapeptide KYGDR resulted from the protein in which the chromophore maturation process had been completed. One of these has an oxogroup at Lys-66 C(alpha) and is a hydrolysis product of another one, with the imino group at Lys-66 C(alpha). The N-unsubstituted imino moiety of the latter is generated by spontaneous polypeptide chain fragmentation at a very unexpected site, the former peptide bond between Phe-65 C' and Lys-66 N(alpha). Also observed in the entire protein under mild denaturing conditions, this fragmentation is likely the feature of native zFP538 chromophore that distinguishes it chemically from the DsRed chromophore.     

Defining the role of arginine 96 in green fluorescent protein fluorophore biosynthesis

Aequoria victoria green fluorescent protein (GFP) is a revolutionary molecular biology tool because of its spontaneous peptide backbone cyclization and chromophore formation from residues Ser65, Tyr66, and Gly67. Here we use structure-based design, comprehensive targeted mutagenesis, and high-resolution crystallography to probe the significant functional role of conserved Arg96 (R96) in chromophore maturation. The R96M GFP variant, in which the R96M side chain is similar in volume but lacks the R96 positive charge, exhibits dramatically slower chromophore maturation kinetics (from hours to months). Comparison of the precyclized conformation of the chromophore-forming residues with the mature R96M chromophore reveals a similar Y66 conformer, contrary to the large Y66 conformational change previously defined in the slowly maturing R96A variant [Barondeau, D. P., Putnam, C. D., Kassmann, C. J., Tainer, J. A., and Getzoff, E. D. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 12111-12116]. Comprehensive R96 mutagenesis and fluorescent colony screening indicate that only the R96K substitution restores wild-type maturation kinetics. Further, we show that the slowly maturing R96A variant can be complemented with a Q183R second-site mutation designed to restore the missing R96 positive charge and rapid fluorophore biosynthesis. Moreover, comparative structural analysis of R96M, R96K, R96A/Q183R, and wild-type GFP reveals the importance of the presence of positive charge, rather than its exact position. Together, these structural, mutational, and biochemical results establish a pivotal role for the R96 positive charge in accelerating the GFP post-translational modification, with implications for peptide backbone cyclization in GFP, its homologues, and related biological systems.     

Oxidative chemistry in the GFP active site leads to covalent cross-linking of a modified leucine side chain with a histidine imidazole: implications for the mechanism of chromophore formation

The mechanism of chromophore biosynthesis in green fluorescent protein (GFP) is triggered by a spontaneous main chain cyclization reaction of residues 65-67. Here, we demonstrate that the initially colorless Y66L variant, designed to trap chromophore precursor states, is oxidatively modified to generate yellow chromophores that absorb at 412 and 374 nm. High- and low-pH crystal structures determined to 2.0 and 1.5 A resolution, respectively, are consistent with pi-orbital conjugation of a planar Leu66-derived adduct with the imidazolinone ring, which is approximately 90 and 100% dehydrated, respectively. Time-, base-, and oxygen-dependent optical properties suggest that the yellow chromophores are generated from a 338 nm-absorbing intermediate, interpreted to be the Y66L analogue of the wild-type GFP chromophore. Generation of this species is catalyzed by a general base such as formate, and proceeds via a cyclization-oxidation-dehydration mechanism. The data suggest that a hydration-dehydration equilibrium exists in the cyclic form of the peptide, and that dehydration is favored upon extensive conjugation with the modified side chain. We conclude that the mechanism of GFP chromophore biosynthesis is not driven by the aromatic character of residue 66. In the low-pH X-ray structure, a highly unusual cross-link is observed between His148 and the oxidized Leu66 side chain, suggesting a conjugate addition reaction of the imidazole nitrogen to the highly electrophilic diene group of the yellow chromophore. The reactivity described here further expands the chemical diversity observed in the active site of GFP-like proteins, and may allow for covalent attachment of functional groups to the protein scaffold for catalytic purposes.     

基因编码3-氯酪氨酸改造荧光蛋白

蛋白质翻译后修饰产生的3-氯酪氨酸 (3-Cl-Tyr)与多种疾病相关,包括帕金森病、哮喘、动脉粥样硬化等． 在动脉粥样硬化患者中发现AopA1 192位酪氨酸有高水平的氯化, 显示此种修饰可能会促进病变．为了研究酪氨酸氯代对蛋白质功能的调控作用,我们发展了将3-Cl-Tyr定点特异插入到蛋白质中的方法． 因为3-Cl-Tyr酚羟基上的质子比酪氨酸(Tyr)更容易解离,具有更低的pKa,在绿色荧光蛋白GFP及其突变体,以及光转化荧光蛋白mEOS2荧光活性中心中分别用3-Cl-Tyr取代Tyr,使得GFP发色基团的pKa降低到4.7,并且具有与EGFP相似的量子产率,使mEOS2 发色基团的pKa降低到4.2.这样使得荧光蛋白的发色基团在酸性条件下仍然能以去质子化形式存在,在500 nm以上仍然具有较强吸收,避免了用400 nm左右激光激发及其对细胞及细胞器造成的光损伤．这种新型的荧光蛋白突变体将适用于溶酶体、吞噬酶体等酸性细胞器．     

Expression of truncated and fused green fluorescent protein genes and analysis of their properties

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Structural characterization of a blue chromoprotein and its yellow mutant from the sea anemone Cnidopus japonicus

Green fluorescent protein (GFP) and its relatives (GFP protein family) have been isolated from marine organisms such as jellyfish and corals that belong to the phylum Cnidaria (stinging aquatic invertebrates). They are intrinsically fluorescent proteins. In search of new members of the family of green fluorescent protein family, we identified a non-fluorescent chromoprotein from the Cnidopus japonicus species of sea anemone that possesses 45% sequence identity to dsRed (a red fluorescent protein). This newly identified blue color protein has an absorbance maximum of 610 nm and is hereafter referred to as cjBlue. Determination of the cjBlue 1.8 A crystal structure revealed a chromophore comprised of Gln(63)-Tyr(64)-Gly(65). The ring stacking between Tyr(64) and His(197) stabilized the cjBlue trans chromophore conformation along the Calpha2-Cbeta2 bond of 5-[(4-hydroxyphenyl)methylene]-imidazolinone, which closely resembled that of the "Kindling Fluorescent Protein" and Rtms5. Replacement of Tyr(64) with Leu in wild-type cjBlue produced a visible color change from blue to yellow with a new absorbance maximum of 417 nm. Interestingly, the crystal structure of the yellow mutant Y64L revealed two His(197) imidazole ring orientations, suggesting a flip-flop interconversion between the two conformations in solution. We conclude that the dynamics and structure of the chromophore are both essential for the optical appearance of these color proteins.     

Photo-induced peptide cleavage in the green-to-red conversion of a fluorescent protein

Green fluorescent protein from the jellyfish (Aequorea GFP) and GFP-like proteins from coral species encode light-absorbing chromophores within their protein sequences. A coral fluorescent protein, Kaede, contains a tripeptide, His(62)-Tyr(63)-Gly(64), which acts as a green chromophore that is photoconverted to red. Here, we present the structural basis for the green-to-red photoconversion. As in Aequorea GFP, a chromophore, 4-(p-hydroxybenzylidene)-5-imidazolinone, derived from the tripeptide mediates green fluorescence in Kaede. UV irradiation causes an unconventional cleavage within Kaede protein between the amide nitrogen and the alpha carbon (Calpha) at His(62) via a formal beta-elimination reaction, which requires the whole, intact protein for its catalysis. The subsequent formation of a double bond between His(62)-Calpha and -Cbeta extends the pi-conjugation to the imidazole ring of His(62), creating a new red-emitting chromophore, 2-[(1E)-2-(5-imidazolyl)ethenyl]-4-(p-hydroxybenzylidene)-5-imidazolinone. The present study not only reveals diversity in the chemical structure of fluorescent proteins but also adds a new dimension to posttranslational modification mechanisms.     

Synthesis and maturation of green fluorescent protein in a cell-free translation system

Summary A cell-free translation system producing mature green fluorescent protein (GFP) can be a useful tool for studying the mechanism and kinetics of GFP chromophore formation, as well as for fast protein engineering. We report here that the mature GFP can be formed in the cell-free translation system from E.coli. The synthesis of GFP in the cell-free system reaches a plateau in 30 to 40 min whereas its maturation is completed in 4 h from the beginning of translation. The delay between the GFP synthesis and the chromophore formation in the cell-free system provides the possibility to isolate and to analyse maturation intermediates for elucidation of the modification pathway.     

Electronic spectroscopy and solvatochromism in the chromophore of GFP and the Y66F mutant.

The electronic spectra of the chromophore of the wild type green fluorescent protein, GFP, and of a mutant form Y66F GFP in which the chromophore lacks the hydroxyl group have been studied. The acid-base properties, solvatochromism, vibronic structure and edge excitation red shift have all been measured. The results are compared with the spectra of the chromophore in the protein environment. These data suggest that the transition energy for the GFP chromophore is influenced by a number of factors in its environment, and in particular by hydrogen bonding.