A Tandem Green-Red Heterodimeric Fluorescent Protein with High FRET Efficiency

ChemBioChem ◽  
2016 ◽  
Vol 17 (24) ◽  
pp. 2361-2367 ◽  
Author(s):  
Matthew D. Wiens ◽  
Yi Shen ◽  
Xi Li ◽  
M. Alaraby Salem ◽  
Nick Smisdom ◽  
...  
Keyword(s):  
Fluorescent Protein ◽  
Fret Efficiency

scholarly journals Corrigendum: A Tandem Green-Red Heterodimeric Fluorescent Protein with High FRET Efficiency

ChemBioChem ◽  
2016 ◽  
Vol 19 (6) ◽  
pp. 647-647
Author(s):  
Matthew D. Wiens ◽  
Yi Shen ◽  
Xi Li ◽  
M. Alaraby Salem ◽  
Nick Smisdom ◽  
...  
Keyword(s):  
Fluorescent Protein ◽  
Fret Efficiency

Abstract 16905: Fluorescence Resonance Energy Transfer Reveals that Cardiac Calcium ATPase Dimerizes and Forms a Complex with Phospholamban in a 2:1 Stoichiometry

Circulation ◽  
2014 ◽  
Vol 130 (suppl_2) ◽  
Author(s):  
Daniel Blackwell ◽  
Seth L Robia
Keyword(s):  
Energy Transfer ◽  
Fluorescence Resonance Energy Transfer ◽  
Fluorescent Protein ◽  
Yellow Fluorescent Protein ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Calcium Atpase ◽  
The Other ◽  
Fret Efficiency ◽  
Fluorescence Resonance

The sarco/endoplasmic reticulum calcium ATPase (SERCA) has been proposed to form functional dimers in vitro. In order to investigate whether SERCA forms homo-dimers in live cells, we fused canine SERCA2a to cerulean (Cer) or yellow fluorescent protein (YFP), and quantified SERCA-SERCA interactions by fluorescence resonance energy transfer (FRET). SERCA-SERCA FRET efficiency was dependent on the labeling position of the fluorescent protein tags, with the highest FRET efficiency achieved when the respective fluorescent proteins were fused to SERCA N-termini. FRET was reduced by competition with unlabeled SERCA, suggesting that the observed FRET was due to specific protein-protein interactions. Progressive photobleaching of YFP showed that Cer intensity increased linearly with decreasing YFP intensity, suggesting that the stoichiometry of the SERCA complex is a dimer. In contrast, a control experiment with phospholamban (PLB) oligomer showed a non-linear YFP/Cer relationship, consistent with its well-known pentameric stoichiometry. We also investigated whether SERCA dimers could interact with PLB, the regulatory binding partner of SERCA. Interestingly, while average maximal FRET was 28% between SERCA and PLB, fluorescence lifetime measurements revealed two different lifetimes, consistent with two different populations of FRET donors. One population showed very low FRET, while the other population exhibited high FRET- approximately double the measured average maximal FRET efficiency. The data are consistent with a single PLB bound to each SERCA homo-dimer; in this regulatory complex one SERCA protomer is in close proximity to PLB (50 Å), while the other is too far away to participate in FRET with PLB.

scholarly journals Genetically encoded ratiometric indicators for potassium ion

2018 ◽  
Author(s):  
Yi Shen ◽  
Sheng-Yi Wu ◽  
Vladimir Rancic ◽  
Yong Qian ◽  
Shin-Ichiro Miyashita ◽  
...  
Keyword(s):  
Fluorescent Protein ◽  
Temporal Dynamics ◽  
Biological Activities ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Potassium Ion ◽  
Live Cells ◽  
Fret Efficiency

AbstractPotassium ion (K+) homeostasis and dynamics play critical roles in regulating various biological activities, and the ability to monitor K+ spatial-temporal dynamics is critical to understanding these biological functions. Here we report the design and characterization of a Förster resonance energy transfer (FRET)-based genetically encoded K+ indicator, KIRIN1, constructed by inserting a bacterial cytosolic K+ binding protein (Kbp) between a fluorescent protein (FP) FRET pair, mCerulean3 and cp173Venus. Binding of K+ induces a conformational change in Kbp, resulting in an increase in FRET efficiency. KIRIN1 was able to detect K+ at physiologically relevant concentrations in vitro and is highly selective toward K+ over Na+. We further demonstrated that KIRIN1 allowed real-time imaging of pharmacologically induced depletion of cytosolic K+ in live cells, and KIRIN1 also enabled optical tracing of K+ efflux and reuptake in neurons upon glutamate stimulation in cultured primary neurons. These results demonstrate that KIRIN1 is a valuable tool to detect K+in vitro and in live cells.

scholarly journals Quantitative analysis of chromatin compaction in living cells using FLIM–FRET

2009 ◽  
Vol 187 (4) ◽  
pp. 481-496 ◽  
Author(s):  
David Llères ◽  
John James ◽  
Sam Swift ◽  
David G. Norman ◽  
Angus I. Lamond
Keyword(s):  
Fluorescent Protein ◽  
Trichostatin A ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Human Cell Line ◽  
Live Cells ◽  
Fluorescence Lifetime Imaging ◽  
Chromatin Compaction ◽  
Fret Efficiency ◽  
Green Fluorescent

We present a quantitative Förster resonance energy transfer (FRET)–based assay using multiphoton fluorescence lifetime imaging microscopy (FLIM) to measure chromatin compaction at the scale of nucleosomal arrays in live cells. The assay uses a human cell line coexpressing histone H2B tagged to either enhanced green fluorescent protein (FP) or mCherry FPs (HeLaH2B-2FP). FRET occurs between FP-tagged histones on separate nucleosomes and is increased when chromatin compacts. Interphase cells consistently show three populations of chromatin with low, medium, or high FRET efficiency, reflecting spatially distinct regions with different levels of chromatin compaction. Treatment with inhibitors that either increase chromatin compaction (i.e., depletion of adenosine triphosphate) or decrease chromosome compaction (trichostatin A) results in a parallel increase or decrease in the FLIM–FRET signal. In mitosis, the assay showed variation in compaction level, as reflected by different FRET efficiency populations, throughout the length of all chromosomes, increasing to a maximum in late anaphase. These data are consistent with extensive higher order folding of chromatin fibers taking place during anaphase.

scholarly journals High-Throughput and Facile Assay of Antimicrobial Peptides Using pH-Controlled Fluorescence Resonance Energy Transfer

2006 ◽  
Vol 50 (10) ◽  
pp. 3330-3335 ◽  
Author(s):  
Young Soo Kim ◽  
Hyung Joon Cha
Keyword(s):  
Antimicrobial Activity ◽  
Energy Transfer ◽  
Antimicrobial Peptides ◽  
Fluorescence Resonance Energy Transfer ◽  
High Throughput ◽  
Fluorescent Protein ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Fret Efficiency ◽  
Ph Controlled

ABSTRACT Amphipathic antimicrobial peptides can destroy bacteria cells by inducing membrane permeabilization, forming one strategy for innate defense by various organisms. However, although the antimicrobial peptides are considered a promising alternative for use against multidrug-resistant bacteria, large-scale screening of potential candidate antimicrobial peptides will require a simple, rapid assay for antimicrobial activity. Here, we describe a novel fluorescence resonance energy transfer (FRET)-based assay system for antimicrobial peptides which takes advantage of pH-related changes in FRET efficiency due to the instability of enhanced yellow fluorescent protein versus the stability of enhanced cyan fluorescent protein in a reduced-pH environment. We successfully showed that quantification of antimicrobial activity is possible through a difference of FRET efficiency between ECFP-EYFP fusion molecules released from disrupted Escherichia coli in an extracellular environment (pH 6) and those retained in an intracellular environment (pH ∼7). Thus, we herein suggest a new simple, effective, and efficient pH-controlled FRET-based antimicrobial peptide screening method applicable to high-throughput screening of candidate peptide libraries.

Fluorescent proteins for in vivo imaging, where's the biliverdin?

2020 ◽  
Vol 48 (6) ◽  
pp. 2657-2667
Author(s):  
Felipe Montecinos-Franjola ◽  
John Y. Lin ◽  
Erik A. Rodriguez
Keyword(s):  
Hydrogen Peroxide ◽  
In Vivo Imaging ◽  
Near Infrared ◽  
Fluorescent Protein ◽  
Fluorescent Proteins ◽  
Fluorescent Imaging ◽  
Infrared Light ◽  
Red Fluorescent Protein ◽  
Color Palette

Noninvasive fluorescent imaging requires far-red and near-infrared fluorescent proteins for deeper imaging. Near-infrared light penetrates biological tissue with blood vessels due to low absorbance, scattering, and reflection of light and has a greater signal-to-noise due to less autofluorescence. Far-red and near-infrared fluorescent proteins absorb light >600 nm to expand the color palette for imaging multiple biosensors and noninvasive in vivo imaging. The ideal fluorescent proteins are bright, photobleach minimally, express well in the desired cells, do not oligomerize, and generate or incorporate exogenous fluorophores efficiently. Coral-derived red fluorescent proteins require oxygen for fluorophore formation and release two hydrogen peroxide molecules. New fluorescent proteins based on phytochrome and phycobiliproteins use biliverdin IXα as fluorophores, do not require oxygen for maturation to image anaerobic organisms and tumor core, and do not generate hydrogen peroxide. The small Ultra-Red Fluorescent Protein (smURFP) was evolved from a cyanobacterial phycobiliprotein to covalently attach biliverdin as an exogenous fluorophore. The small Ultra-Red Fluorescent Protein is biophysically as bright as the enhanced green fluorescent protein, is exceptionally photostable, used for biosensor development, and visible in living mice. Novel applications of smURFP include in vitro protein diagnostics with attomolar (10−18 M) sensitivity, encapsulation in viral particles, and fluorescent protein nanoparticles. However, the availability of biliverdin limits the fluorescence of biliverdin-attaching fluorescent proteins; hence, extra biliverdin is needed to enhance brightness. New methods for improved biliverdin bioavailability are necessary to develop improved bright far-red and near-infrared fluorescent proteins for noninvasive imaging in vivo.

A Unified Model for Photophysical and Electro-Optical Properties of Green Fluorescent Proteins

2019 ◽  
Author(s):  
Chi-Yun Lin ◽  
Matthew Romei ◽  
Luke Oltrogge ◽  
Irimpan Mathews ◽  
Steven Boxer
Keyword(s):  
Driving Force ◽  
Fluorescent Protein ◽  
Charge Transfer Band ◽  
Photophysical Properties ◽  
Polymethine Dyes ◽  
Emission Rates ◽  
Unified Framework ◽  
Underlying Factor ◽  
Green Fluorescent ◽  
Protein Environment

Green fluorescent protein (GFPs) have become indispensable imaging and optogenetic tools. Their absorption and emission properties can be optimized for specific applications. Currently, no unified framework exists to comprehensively describe these photophysical properties, namely the absorption maxima, emission maxima, Stokes shifts, vibronic progressions, extinction coefficients, Stark tuning rates, and spontaneous emission rates, especially one that includes the effects of the protein environment. In this work, we study the correlations among these properties from systematically tuned GFP environmental mutants and chromophore variants. Correlation plots reveal monotonic trends, suggesting all these properties are governed by one underlying factor dependent on the chromophore's environment. By treating the anionic GFP chromophore as a mixed-valence compound existing as a superposition of two resonance forms, we argue that this underlying factor is defined as the difference in energy between the two forms, or the driving force, which is tuned by the environment. We then introduce a Marcus-Hush model with the bond length alternation vibrational mode, treating the GFP absorption band as an intervalence charge transfer band. This model explains all the observed strong correlations among photophysical properties; related subtopics are extensively discussed in Supporting Information. Finally, we demonstrate the model's predictive power by utilizing the additivity of the driving force. The model described here elucidates the role of the protein environment in modulating photophysical properties of the chromophore, providing insights and limitations for designing new GFPs with desired phenotypes. We argue this model should also be generally applicable to both biological and non-biological polymethine dyes.<br>

Site-Specific Protein Covalent Attachment to Nanotubes and Its Electronic Impact on Single Molecule Function

2019 ◽  
Author(s):  
Adam Beachey ◽  
Harley Worthy ◽  
William David Jamieson ◽  
Suzanne Thomas ◽  
Benjamin Bowen ◽  
...  
Keyword(s):  
Single Molecule ◽  
Fluorescent Protein ◽  
Functional Integration ◽  
Attachment Site ◽  
Covalent Attachment ◽  
Great Promise ◽  
Functional Coupling ◽  
Phenyl Azide ◽  
Electronic Impact ◽  
Protein Attachment

<p>Functional integration of proteins with carbon-based nanomaterials such as nanotubes holds great promise in emerging electronic and optoelectronic applications. Control over protein attachment poses a major challenge for consistent and useful device fabrication, especially when utilizing single/few molecule properties. Here, we exploit genetically encoded phenyl azide photochemistry to define the direct covalent attachment of three different proteins, including the fluorescent protein GFP, to carbon nanotube side walls. Single molecule fluorescence revealed that on attachment to SWCNTs GFP’s fluorescence changed in terms of intensity and improved resistance to photobleaching; essentially GFP is fluorescent for much longer on attachment. The site of attachment proved important in terms of electronic impact on GFP function, with the attachment site furthest from the functional center having the larger effect on fluorescence. Our approach provides a versatile and general method for generating intimate protein-CNT hybrid bioconjugates. It can be potentially applied easily to any protein of choice; attachment position and thus interface characteristics with the CNT can easily be changed by simply placing the phenyl azide chemistry at different residues by gene mutagenesis. Thus, our approach will allow consistent construction and modulate functional coupling through changing the protein attachment position.</p>

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