Circular permutation and receptor insertion within green fluorescent proteins (original) (raw)
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Circularly permuted variants of the green fluorescent protein
Febs Letters, 1999
Folding of the green fluorescent protein (GFP) from Aequorea victoria is characterized by autocatalytic formation of its p-hydroxybenzylideneimidazolidone chromophore, which is located in the center of an 11-stranded L L-barrel. We have analyzed the in vivo folding of 20 circularly permuted variants of GFP and find a relatively low tolerance towards disruption of the polypeptide chain by introduction of new termini. All permuted variants with termini in strands of the L L-barrel and about half of the variants with termini in loops lost the ability to form the chromophore. The thermal stability of the permuted GFPs with intact chromophore is very similar to that of the wild-type, indicating that chromophore-side chain interactions strongly contribute to the extraordinary stability of GFP.
Photochemistry and Photobiology, 2001
New variants of green fluorescent protein (GFP) can be engineered by circular permutation of their amino acid sequence. We characterized a series of permuted enhanced GFP (PEGFP) with new termini introduced at N144-Y145 and linkers of 1, 3, 5 and 6 residues inserted between G232 and M1, as well as a variant with an extended 7-residues linker between K238 and M1. A minimum linker length of 3 residues was necessary for a functional chromophore to be formed, and linkers exceeding 4 residues yielded almost the same fluorescence quantum yield as enhanced GFP (EGFP). PEGFP exhibited dual-wavelength absorption and fluorescence excitation with peaks at 395 and 490 nm but single-wavelength emission at 512 nm. Fluorescence emission increased with increasing pH for all excitation wavelengths with a pKa of 7.7. Between the pH values of 6 and 8 optical absorption showed an isobestic point at 445 nm. PEGFP rapidly denatured in urea between 50 and 60؇C. Renaturation proceeded with a short (ϳ29 s) and a longer (Ͼ150 s) time constant. Transient transfection of HEK293 and HeLa cells revealed the expression dynamics of PEGFP to be similar to that of EGFP. Laser-scanning microscopy of HeLa cells demonstrated that the PEGFP are particularly well suited as fluorescent indicators in two-photon imaging.
Circular Permutation of Red Fluorescent Proteins
PLoS ONE, 2011
Circular permutation of fluorescent proteins provides a substrate for the design of molecular sensors. Here we describe a systematic exploration of permutation sites for mCherry and mKate using a tandem fusion template approach. Circular permutants retaining more than 60% (mCherry) and 90% (mKate) brightness of the parent molecules are reported, as well as a quantitative evaluation of the fluorescence from neighboring mutations. Truncations of circular permutants indicated essential N-and C-terminal segments and substantial flexibility in the use of these molecules. Structural evaluation of two cp-mKate variants indicated no major conformational changes from the previously reported wild-type structure, and cis conformation of the chromophores. Four cp-mKates were identified with over 80% of native fluorescence, providing important new building blocks for sensor and complementation experiments.
Biochemistry, 2009
Green fluorescent protein (GFP) has been used as a proof of concept for a novel "leave-one-out" biosensor design in which a protein that has a segment omitted from the middle of the sequence by circular permutation and truncation binds the missing peptide and reconstitutes its function. Three variants of GFP have been synthesized that are each missing one of the 11 β-strands from its βbarrel structure, and in two of the variants, adding the omitted peptide sequence in trans reconstitutes fluorescence. Detailed biochemical analysis indicates that GFP with β-strand 7 "left out" (t7SPm) exists in a partially unfolded state. The apo form t7SPm binds the free β-strand 7 peptide with a dissociation constant of ~0.5 µM and folds into the native state of GFP, resulting in fluorescence recovery. Folding of t7SPm, both with and without the peptide ligand, is at least a three-state process and has a rate comparable to that of the full-length and unpermuted GFP. The conserved kinetic properties strongly suggest that the rate-limiting steps in the folding pathway have not been altered by circular permutation and truncation in t7SPm. This study shows that structural and functional reconstitution of GFP can occur with a segment omitted from the middle of the chain, and that the unbound form is in a partially unfolded state. Removal of a segment from a protein chain is often disastrous to its folding and stability, but in many cases, it is possible to reconstitute the structure and function by adding back the complementary sequence as an autonomous peptide (1-9). Analogous to "leave-one-out" experiments in statistics, where data omitted from a training set is nonetheless accurately predicted by modeling the remaining data, the truncated sequence sometimes retains enough information about its native structure to form a specific binding pocket that is complementary to, and binds tightly to, the missing piece. If the reconstituted protein has a self-reporting signal such as fluorescence, then the leave-one-out protein is a sensor for its missing piece. In this study, we use green fluorescent protein (GFP) 1 to prove this concept.
FEBS letters, 2018
The mechanism of green fluorescent protein (GFP) chromophore formation is still not clearly defined. Two mechanisms have been proposed: cyclisation-dehydration-oxidation (Mechanism A) and cyclisation-oxidation-dehydration (Mechanism B). To distinguish between these mechanisms, we generated a non-fluorescent mutant of GFP, S65T/G67A-GFP. This mutant folds to a stable, native-like structure but lacks fluorescence due to interruption of the chromophore maturation process. Mass spectrometric analysis of peptides derived from this mutant reveal that chromophore formation follows only mechanism A, but that the final oxidation reaction is suppressed. This result is unexpected within the pool of examined GFP mutants, since for the wild-type GFP, there is strong support for mechanism B.
Protein Science, 2014
Wild-type green fluorescent protein (GFP) folds on a time-scale of minutes. The slow step in folding is a cis-trans peptide bond isomerization. The only conserved cis-peptide bond in the native GFP structure, at P89, was remodeled by the insertion of two residues, followed by iterative energy minimization and side chain design. The engineered GFP was synthesized and found to fold faster and more efficiently than its template protein, recovering 50% more of its fluorescence upon refolding. The slow phase of folding is faster and smaller in amplitude, and hysteresis in refolding has been eliminated. The elimination of a previously reported kinetically trapped state in refolding suggests that X-P89 is trans in the trapped state. A 2.55Å resolution crystal structure revealed that the new variant contains only trans-peptide bonds, as designed. This is the first instance of a computationally remodeled fluorescent protein that folds faster and more efficiently than wild-type. Protein Science 6 folding, help to define the structure of the observed trapped state, and elucidate the sequence requirements for chromophore maturation.
Biotechnology Letters, 2006
By experimenting with many different circularly permutated yellow fluorescent protein (cpYFP) variants as acceptors in fluorescence resonance energy transfer based biosensors, the optimal dynamic range can be discovered by sampling the possibilities of relative fluorophore orientations before and after bioactivity. Hence, to facilitate the sampling process, we introduced a new approach to construct a library of cpYFP variants using fluorescence screening and a tandem fusion template. This new approach is rapid because it does not require creating intermediate N- and C-terminal fragments and it allows quick screening for positive colonies by fluorescence. As a demonstration, eleven cpYFP variants were created and eight showed fluorescence. The emission and excitation spectra of these cpYFP variants showed strong similarity to YFP and therefore can be used in replacement.
Circularly Permuted Fluorescent Protein-Based Indicators: History, Principles, and Classification
International Journal of Molecular Sciences, 2019
Genetically encoded biosensors based on fluorescent proteins (FPs) are a reliable tool for studying the various biological processes in living systems. The circular permutation of single FPs led to the development of an extensive class of biosensors that allow the monitoring of many intracellular events. In circularly permuted FPs (cpFPs), the original N- and C-termini are fused using a peptide linker, while new termini are formed near the chromophore. Such a structure imparts greater mobility to the FP than that of the native variant, allowing greater lability of the spectral characteristics. One of the common principles of creating genetically encoded biosensors is based on the integration of a cpFP into a flexible region of a sensory domain or between two interacting domains, which are selected according to certain characteristics. Conformational rearrangements of the sensory domain associated with ligand interaction or changes in the cellular parameter are transferred to the cpF...