NMR-derived Topology of a GFP-photoprotein Energy Transfer Complex

Titushin, Maxim S.; Feng, Yingang; Stepanyuk, Galina A.; Li, Yang; Markova, Svetlana V.; Gölz, Stefan; Wang, Bi-Cheng; Lee, John; Wang, Jinfeng; Vysotski, Eugene S.; Liu, Zhijie

doi:10.1074/jbc.m110.133843

Cited by 47 publications

(70 citation statements)

References 52 publications

(37 reference statements)

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“…The effect is less with obelin and Clytia GFP, suggesting specificity in the interaction, as also observed with the above mentioned other cases . The same argument used previously was that the spectral effect at these concentrations of Clytia GFP implied the presence of a protein–protein complex with K D in the μ m range but a search using standard methods, analytical ultracentrifugation, size‐exclusion chromatography, surface plasmon resonance or polarization fluorometry, failed to detect any complex with a K D < 100 μ m .…”

Section: Firefly and Coelenterazinesupporting

confidence: 72%

Perspectives on Bioluminescence Mechanisms

Lee

2016

Photochem & Photobiology

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The molecular mechanisms of the bioluminescence systems of the firefly, bacteria and those utilizing imidazopyrazinone luciferins such as coelenterazine are gradually being uncovered using modern biophysical methods such as dynamic (ns-ps) fluorescence spectroscopy, NMR, X-ray crystallography and computational chemistry. The chemical structures of all reactants are well defined, and the spatial structures of the luciferases are providing important insight into interactions within the active cavity. It is generally accepted that the firefly and coelenterazine systems, although proceeding by different chemistries, both generate a dioxetanone high-energy species that undergoes decarboxylation to form directly the product in its S 1 state, the bioluminescence emitter. More work is still needed to establish the structure of the products completely. In spite of the bacterial system receiving the most research attention, the chemical pathway for excitation remains mysterious except that it is clearly not by a decarboxylation. Both the coelenterazine and bacterial systems have in common of being able to employ "antenna proteins," lumazine protein and the greenfluorescent protein, for tuning the color of the bioluminescence. Spatial structure information has been most valuable in informing the mechanism of the Ca 2+ -regulated photoproteins and the antenna protein interactions.

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Section: Firefly and Coelenterazinesupporting

confidence: 72%

Perspectives on Bioluminescence Mechanisms

Lee

2016

Photochem & Photobiology

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“…This apparently minimizes energy dissipation upon fluorescence excitation to favor a high quantum yield of the Clytia GFP fluorescence (0.86; maximum 500 nm upon excitation at 470 nm) . From analytical ultracentrifugation, size-exclusion chromatography and fluorescence anisotropy data, Clytia GFP is an obligate dimer (Titushin et al, 2010;Malikova et al, 2011). The dimerization interface of the Clytia GFP monomer reveals hydrogen bonding and an accessible surface area value (1370 Å 2 ) favorable for strong dimerization (Jones and Thornton, 1996).…”

Section: Structure Of Clytia Gfpmentioning

confidence: 99%

“…As in the case of bacterial luciferase and lumazine protein, the energy transfer in the Clytia GFP-clytin system is rationalized by the FRET mechanism. The requirement of donor-acceptor separation to be less than 100 Å at micromolar concentrations of clytin and Clytia GFP can only be achieved assuming a tight protein-protein interaction (Förster, 1960;Wu and Brand, 1994;Titushin et al, 2010;Markova et al, 2010). Although the bioluminescence spectrum shift is complete at micromolar amounts of proteins, implying K D of Clytia GFP-clytin complexation to be in the micromolar range, no evidence for protein-protein association could be found from analytical ultracentrifugation, size-exclusion chromatography, surfaceplasmon resonance, or polarization fluorometry experiments, which are capable of detecting complexation with a K D below 10 -4 mol/L (Titushin et al, 2010;Malikova et al, 2011 (Fig.…”

Section: Clytia Gfp-clytin Interactionmentioning

confidence: 99%

“…Several lines of evidence indicate that delivery of luciferin from the binding protein to the luciferase as well as modulation of bioluminescence spectra as a result of energy transfer to the antenna proteins, involves protein-protein interactions (Morise et al, 1974;Ward andCormier, 1976, 1978;Nicolas et al, 1991;Cutler, 1995;Schultz et al, 2005;Titushin et al, 2008Titushin et al, , 2010Stepanyuk et al, 2009;. The interactions are of a transient nature, with K D in the range of 10 −6 -10 −3 mol/L, which highly impedes direct detection of the complexes, or their structural studies with Xray crystallography or NMR methods.…”

Section: Introductionmentioning

confidence: 99%

“…For those bioluminescent systems where crystal structures of the individual proteins are known, the topologies of the protein-protein complexes were solved by means of data-driven computer modeling. Among the structures available so far, there are those of the lumazine protein-luciferase complex from the bacteria Photobacterium (Sato et al, 2010), the GFPphotoprotein clytin complex from the jellyfish Clytia (Titushin et al, 2010), and the coelenterazine-binding protein-luciferase complex from the soft coral Renilla (Stepanyuk et al, 2009). The main goal of this review is to cover the mentioned bioluminescence systems, where extensive biochemical studies of the protein-protein interactions have been complemented with structural data, resulting in new insight into the bioluminescence mechanism with regard to the role of the protein-protein complexes.…”

Section: Introductionmentioning

confidence: 99%

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Protein-protein complexation in bioluminescence

et al. 2011

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In this review we summarize the progress made towards understanding the role of protein-protein interactions in the function of various bioluminescence systems of marine organisms, including bacteria, jellyfish and soft corals, with particular focus on methodology used to detect and characterize these interactions. In some bioluminescence systems, protein-protein interactions involve an "accessory protein" whereby a stored substrate is efficiently delivered to the bioluminescent enzyme luciferase. Other types of complexation mediate energy transfer to an "antenna protein" altering the color and quantum yield of a bioluminescence reaction. Spatial structures of the complexes reveal an important role of electrostatic forces in governing the corresponding weak interactions and define the nature of the interaction surfaces. The most reliable structural model is available for the protein-protein complex of the Ca 2+ -regulated photoprotein clytin and green-fluorescent protein (GFP) from the jellyfish Clytia gregaria, solved by means of Xray crystallography, NMR mapping and molecular docking. This provides an example of the potential strategies in studying the transient complexes involved in bioluminescence. It is emphasized that structural studies such as these can provide valuable insight into the detailed mechanism of bioluminescence.

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Transient‐state kinetic analysis of complex formation between photoprotein clytin and GFP from jellyfish Clytia gregaria

Eremeeva

Berkel²,

Vysotski

2016

FEBS Letters

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Luminous organisms use different protein-mediated strategies to modulate light emission color. Here, we report the transient-state kinetic studies of the interaction between photoprotein clytin from Clytia gregaria and its antenna protein, cgreGFP. We propose that cgreGFP forms a transient complex with Ca 2+ -bound clytin before the excited singlet state of the coelenteramide product is formed. From the spectral distribution and donor-acceptor separation distance, we infer that clytin reaction intermediates may interact only with the middle side part of cgreGFP.

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NMR-derived Topology of a GFP-photoprotein Energy Transfer Complex

Cited by 47 publications

References 52 publications

Perspectives on Bioluminescence Mechanisms

Perspectives on Bioluminescence Mechanisms

Protein-protein complexation in bioluminescence

Transient‐state kinetic analysis of complex formation between photoprotein clytin and GFP from jellyfish Clytia gregaria

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