One-Photon and Two-Photon Excitation of Fluorescent Proteins

Nifosı̀, Riccardo; Tozzini, Valentina

doi:10.1007/4243_2011_26

Cited by 5 publications

(5 citation statements)

References 119 publications

(172 reference statements)

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“…After the discovery of GFP in the 1960s, and later the cloning of the gene, it has been shown that GFP can be expressed in other organisms and yet remain fluorescent. , Significant investment has been made into improving the photophysical properties of fluorescent proteins (FP) for their nonobtrusive use in real-time bioimaging. A great variety of fluorescent proteins have been synthesized and characterized, spanning a broad spectrum from blue to red fluorescent proteins. , The color of fluorescence is mainly controlled by the chromophore that is formed by three precursory residues. , By altering these amino acids, different maturation routes lead to different chromophore structures (many examples are mentioned in this work). In addition to the chromophore, the surrounding protein structure can also influence various photophysical properties of the protein .…”

Section: Introductionmentioning

confidence: 99%

“…A great variety of fluorescent proteins have been synthesized and characterized, spanning a broad spectrum from blue to red fluorescent proteins. 5,6 The color of fluorescence is mainly controlled by the chromophore that is formed by three precursory residues. 7,8 By altering these amino acids, different maturation routes lead to different chromophore structures (many examples are mentioned in this work).…”

Section: Introductionmentioning

confidence: 99%

“…9 Two-photon spectroscopy of cells expressing FPs has received less attention than one-photon spectroscopy but is recently gaining more interest. 5 It is less damaging to the biological system, as it involves the absorption of photons of longer wavelengths (and lower energy). Furthermore, the twophoton absorption (TPA) probability is proportional to the square of the incident light intensity.…”

Section: Introductionmentioning

confidence: 99%

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Two-Photon Absorption in Fluorescent Protein Chromophores: TDDFT and CC2 Results

Salem

Brown

2014

J. Chem. Theory Comput.

110

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Two-photon spectroscopy of fluorescent proteins is a powerful bioimaging tool. Considerable effort has been made to measure absolute two-photon absorption (TPA) for the available fluorescent proteins. Being a technically involved procedure, there is significant variation in the published experimental measurements even for the same protein. In this work, we present a time-dependent density functional theory (TDDFT) study on isolated chromophores comparing the ability of four functionals (PBE0, B3LYP, CAM-B3LYP, and LC-BLYP) combined with the 6-31+G(d,p) basis set to reproduce averaged experimental TPA energies and cross sections. The TDDFT energies and TPA cross sections are also compared to corresponding CC2/6-31+G(d,p) results for excitation to S1 for the five smallest chromophores. In general, the computed TPA energies are less functional dependent than the TPA cross sections. The variation between functionals is more pronounced when higher-energy transitions are studied. Changes to the conformation of a chromophore are shown to change the TPA cross-section considerably. This adds to the difficulty of comparing an isolated chromophore to the one embedded in the protein environment. All functionals considered give moderate agreement with the corresponding CC2 results; in general, the TPA cross sections determined by TDDFT are 1.5-10 times smaller than the corresponding CC2 values for excitation to S1. LC-BLYP and CAM-B3LYP give erroneously large TPA cross sections in the higher-energy regions. On the other hand, B3LYP and PBE0 yield values that are of the same order of magnitude and in some cases very close to the averaged experimental data. Thus, based on the results reported here, B3LYP and PBE0 are the preferred functionals for screening chromphores for TPA. However, at best, TDDFT can be used to semiquantitatively scan chromophores for potential TPA probes and highlight spectroscopic peaks that could be present in the mature protein.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Two-Photon Absorption in Fluorescent Protein Chromophores: TDDFT and CC2 Results

Salem

Brown

2014

J. Chem. Theory Comput.

110

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“…A representation is provided in Figure . The different structure of the chromophore combined with a different local environment tune the spectroscopic properties of the three GFP variants. − The chosen GFP variants span the broad variation of excitation energy of GFP-like fluorescent proteins containing the same 4-( p -hydroxybenzylidene)-5-imidazolinone chromophore in the anionic protonation state: mTFP and PhiYFP are among, respectively, the most blue-shifted and most red-shifted variants, while Dronpa is the intermediate between the two. The measured excitation energies of 2.74, 2.46, and 2.36 eV are experimentally observed for mTFP , Dronpa , and PhiYFP , respectively.…”

Section: Application To Gfpsmentioning

confidence: 99%

Energy, Structures, and Response Properties with a Fully Coupled QM/AMOEBA/ddCOSMO Implementation

Nottoli

Nifosı̀

Mennucci

et al. 2021

J. Chem. Theory Comput.

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We present the implementation of a fully coupled polarizable QM/MM/continuum model based on the AMOEBA polarizable force field and the domain decomposition implementation of the conductor-like screening model. Energies, response properties, and analytical gradients with respect to both QM and MM nuclear positions are available, and a generic, atomistic cavity can be employed. The model is linear scaling in memory requirements and computational cost with respect to the number of classical atoms and is therefore suited to model large, complex systems. Using three variants of the green-fluorescent protein, we investigate the overall computational cost of such calculations and the effect of the continuum model on the convergence of the computed properties with respect to the size of the embedding. We also demonstrate the fundamental role of polarization effects by comparing polarizable and nonpolarizable embeddings to fully QM ones.

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“…The main advantages of FPs are that, in contrast to synthetic organic fluorophores, they are produced by cells via gene transcription and translation, so that FPs can be expressed in distinct cell compartments, such as organelles and membranes. Comprehensive reviews of FPs' applications in biochemistry, as well as their structure tuning and the outline of anticipated future improvements are available elsewhere [133][134][135].…”

Section: Fluorescent Proteinsmentioning

confidence: 99%

Using fluorescence for studies of biological membranes: a review

Kyrychenko¹

2015

Methods Appl. Fluoresc.

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Fluorescence techniques have become powerful and widely used tools for studies of biochemical and biophysical processes occurring in biological membranes. Various fluorescence methods have played and continue to play key roles in modern membrane science, so that there have been several focused reviews on this topic. Here, I present the progress and recent achievements in various fluorescence approaches commonly utilized in studies of biological membranes. Applications of numerous fluorescence methods have been reviewed, including single molecule detection, confocal scanning fluorescence microscopy and fluorescence lifetime imaging. I focus on the benefits and limitations of various fluorescence techniques and their combinations, as well as the available methods of in vivo studying. A separate section is dedicated to discussing and comparing different classes of fluorescent membrane probes and their applications to the study of biological membranes. The review should provide researchers from chemistry, biochemistry, and biophysics with the necessary background to identify a range of suitable fluorescence methods in order to successfully design and conduct experimental studies on model lipid bilayers and biological membranes.

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One-Photon and Two-Photon Excitation of Fluorescent Proteins

Cited by 5 publications

References 119 publications

Two-Photon Absorption in Fluorescent Protein Chromophores: TDDFT and CC2 Results

Two-Photon Absorption in Fluorescent Protein Chromophores: TDDFT and CC2 Results

Energy, Structures, and Response Properties with a Fully Coupled QM/AMOEBA/ddCOSMO Implementation

Using fluorescence for studies of biological membranes: a review

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