Fluorescent Proteins for Cell Biology

The discovery and development of multicoloured fluorescent proteins has led to the exciting possibility of observing a remarkable array of subcellular structures and dynamics in living cells. This minireview highlights a number of the more common fluorescent protein probes in plants and is a testimonial to the fact that the plant cell has not lagged behind during the live-imaging revolution and is ready for even more in-depth exploration.

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Differential equation methods for simulation of GFP kinetics in non–steady state experiments

Molecular Biology of the Cell ◽

10.1091/mbc.e17-06-0396 ◽

2018 ◽

Vol 29 (6) ◽

pp. 763-771 ◽

Cited By ~ 2

Author(s):

Robert D. Phair

Keyword(s):

Differential Equation ◽

Steady State ◽

Fluorescence Microscopy ◽

Cell Biology ◽

Fluorescent Proteins ◽

Quantitative Information ◽

Tracer Kinetics ◽

Mathematical Framework ◽

Experimental Protocols ◽

Tracer Kinetic

Genetically encoded fluorescent proteins, combined with fluorescence microscopy, are widely used in cell biology to collect kinetic data on intracellular trafficking. Methods for extraction of quantitative information from these data are based on the mathematics of diffusion and tracer kinetics. Current methods, although useful and powerful, depend on the assumption that the cellular system being studied is in a steady state, that is, the assumption that all the molecular concentrations and fluxes are constant for the duration of the experiment. Here, we derive new tracer kinetic analytical methods for non–steady state biological systems by constructing mechanistic nonlinear differential equation models of the underlying cell biological processes and linking them to a separate set of differential equations governing the kinetics of the fluorescent tracer. Linking the two sets of equations is based on a new application of the fundamental tracer principle of indistinguishability and, unlike current methods, supports correct dependence of tracer kinetics on cellular dynamics. This approach thus provides a general mathematical framework for applications of GFP fluorescence microscopy (including photobleaching [FRAP, FLIP] and photoactivation to frequently encountered experimental protocols involving physiological or pharmacological perturbations (e.g., growth factors, neurotransmitters, acute knockouts, inhibitors, hormones, cytokines, and metabolites) that initiate mechanistically informative intracellular transients. When a new steady state is achieved, these methods automatically reduce to classical steady state tracer kinetic analysis.

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Intracellular Imaging with Genetically Encoded RNA-based Molecular Sensors

Nanomaterials ◽

10.3390/nano9020233 ◽

2019 ◽

Vol 9 (2) ◽

pp. 233 ◽

Cited By ~ 17

Author(s):

Zhining Sun ◽

Tony Nguyen ◽

Kathleen McAuliffe ◽

Mingxu You

Keyword(s):

Cell Biology ◽

Design Principle ◽

Fluorescent Proteins ◽

Rna Recognition ◽

Molecular Sensors ◽

Intracellular Imaging ◽

Biological Targets ◽

Target Analytes ◽

Wide Range ◽

Reporting Systems

Genetically encodable sensors have been widely used in the detection of intracellular molecules ranging from metal ions and metabolites to nucleic acids and proteins. These biosensors are capable of monitoring in real-time the cellular levels, locations, and cell-to-cell variations of the target compounds in living systems. Traditionally, the majority of these sensors have been developed based on fluorescent proteins. As an exciting alternative, genetically encoded RNA-based molecular sensors (GERMS) have emerged over the past few years for the intracellular imaging and detection of various biological targets. In view of their ability for the general detection of a wide range of target analytes, and the modular and simple design principle, GERMS are becoming a popular choice for intracellular analysis. In this review, we summarize different design principles of GERMS based on various RNA recognition modules, transducer modules, and reporting systems. Some recent advances in the application of GERMS for intracellular imaging are also discussed. With further improvement in biostability, sensitivity, and robustness, GERMS can potentially be widely used in cell biology and biotechnology.

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Genetically encoded fluorescent tags

Molecular Biology of the Cell ◽

10.1091/mbc.e16-07-0504 ◽

2017 ◽

Vol 28 (7) ◽

pp. 848-857 ◽

Cited By ~ 44

Author(s):

Kurt Thorn

Keyword(s):

Flow Cytometry ◽

Nucleic Acid ◽

Light Microscopy ◽

Cell Biology ◽

Fluorescent Proteins ◽

Protein Sequences ◽

Biological Properties ◽

Protein Abundance ◽

Fluorescent Tags ◽

Exogenous Fluorophores

Genetically encoded fluorescent tags are protein sequences that can be fused to a protein of interest to render it fluorescent. These tags have revolutionized cell biology by allowing nearly any protein to be imaged by light microscopy at submicrometer spatial resolution and subsecond time resolution in a live cell or organism. They can also be used to measure protein abundance in thousands to millions of cells using flow cytometry. Here I provide an introduction to the different genetic tags available, including both intrinsically fluorescent proteins and proteins that derive their fluorescence from binding of either endogenous or exogenous fluorophores. I discuss their optical and biological properties and guidelines for choosing appropriate tags for an experiment. Tools for tagging nucleic acid sequences and reporter molecules that detect the presence of different biomolecules are also briefly discussed.

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Photoactivation in Fluorescence Microscopy

Microscopy Today ◽

10.1017/s1551929509000194 ◽

2009 ◽

Vol 17 (4) ◽

pp. 8-13 ◽

Cited By ~ 4

Author(s):

David W. Piston ◽

Gert-Jan Kremers ◽

Richard K.P. Benninger ◽

Michael W. Davidson

Keyword(s):

Cell Biology ◽

Fluorescent Proteins ◽

Photophysical Properties ◽

Live Cells ◽

General Description ◽

Caged Compounds ◽

Introductory Overview ◽

Photoactivatable Gfp ◽

Genetic Labeling ◽

New Applications

The use of photoactive compounds in microscopy has a long history. Caged compounds have been used for almost forty years, not only to elicit chemical reactions in cells, but also to mark specific cells or regions within cells by photoactivation of fluorescence. During the last seven years, the advent of photoactivatable GFP (PA-GFP) and its successors has opened up a myriad of new applications. All of this work has, of course, been greatly facilitated in live cells through the possibility of genetic labeling that is given by the fluorescent proteins. However, even as more photo-activatable and photo-switchable proteins are discovered, they are still limited in terms of wavelength ranges and photophysical properties. Thus, there has been a resurgence of interest in small organic photoactive molecules for cell biology experiments. In this short introductory overview, we will present the basic concepts of photoactivation and discuss many of the strengths and limitations of various approaches. We will also provide a general description of the kinds of applications for which these probes can be used.

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Quantification of very low-abundant proteins in bacteria using the HaloTag and epi-fluorescence microscopy

10.1101/237248 ◽

2017 ◽

Cited By ~ 1

Author(s):

Alessia Lepore ◽

Hannah Taylor ◽

Dirk Landgraf ◽

Burak Okumus ◽

Sebastián Jaramillo-Riveri ◽

...

Keyword(s):

Cell Biology ◽

Quantitative Methods ◽

Fluorescent Protein ◽

Detection Efficiency ◽

Fluorescent Proteins ◽

Attractive Alternative ◽

Highly Sensitive ◽

Endogenous Proteins ◽

Photo Stability ◽

Better Than

ABSTRACTCell biology is increasingly dependent on quantitative methods resulting in the need for microscopic labelling technologies that are highly sensitive and specific. Whilst the use of fluorescent proteins has led to major advances, they also suffer from their relatively low brightness and photo-stability, making the detection of very low abundance proteins using fluorescent protein-based methods challenging. Here, we characterize the use of the self-labelling protein tag called HaloTag, in conjunction with an organic fluorescent dye, to label and accurately count endogenous proteins present in very low numbers (<7) in individualEscherichia colicells. This procedure can be used to detect single molecules in fixed cells with conventional epifluorescence illumination and a standard microscope. We show that the detection efficiency of proteins labelled with the HaloTag is ≥80%, which is on par or better than previous techniques. Therefore, this method offers a simple and attractive alternative to current procedures to detect low abundance molecules.

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mCherry contains a fluorescent protein isoform that interferes with its reporter function

10.1101/2021.12.07.471677 ◽

2021 ◽

Author(s):

Maxime Fages-Lartaud ◽

Lisa Tietze ◽

Florence Elie ◽

Rahmi Lale ◽

Martin Frank Hohmann-Marriott

Keyword(s):

Cell Biology ◽

Fluorescent Protein ◽

Fluorescent Proteins ◽

Initiation Site ◽

Translation Initiation Site ◽

Red Fluorescent Protein ◽

Functional Protein ◽

Red Fluorescent Proteins ◽

Expression Studies ◽

Protein Isoform

AbstractFluorescent proteins are essential reporters in cell biology and molecular biology. Here, we reveal that red-fluorescent proteins possess an alternative translation initiation site that produces a short functional protein isoform. The short isoform creates significant background fluorescence that biases the outcome of expression studies. Our investigation identifies the short protein isoform, traces its origin, and determines the extent of the issue within the family of red fluorescent protein. Our analysis shows that the short isoform defect of the red fluorescent protein family may affect the interpretation of many published studies. Finally, we provide a re-engineered mCherry variant that lacks background expression as an improved tool for imaging and protein expression studies.

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VIPER is a genetically encoded peptide tag for fluorescence and electron microscopy

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1808626115 ◽

2018 ◽

Vol 115 (51) ◽

pp. 12961-12966 ◽

Cited By ~ 17

Author(s):

Julia K. Doh ◽

Jonathan D. White ◽

Hannah K. Zane ◽

Young Hwan Chang ◽

Claudia S. López ◽

...

Keyword(s):

Electron Microscopy ◽

Cell Biology ◽

Iron Uptake ◽

Fluorescent Proteins ◽

Coiled Coil ◽

Protein Targets ◽

Cellular Environment ◽

Fluorescence And Electron Microscopy ◽

Specific Proteins ◽

Peptide Tag

Many discoveries in cell biology rely on making specific proteins visible within their native cellular environment. There are various genetically encoded tags, such as fluorescent proteins, developed for fluorescence microscopy (FM). However, there are almost no genetically encoded tags that enable cellular proteins to be observed by both FM and electron microscopy (EM). Herein, we describe a technology for labeling proteins with diverse chemical reporters, including bright organic fluorophores for FM and electron-dense nanoparticles for EM. Our technology uses versatile interacting peptide (VIP) tags, a class of genetically encoded tag. We present VIPER, which consists of a coiled-coil heterodimer formed between the genetic tag, CoilE, and a probe-labeled peptide, CoilR. Using confocal FM, we demonstrate that VIPER can be used to highlight subcellular structures or to image receptor-mediated iron uptake. Additionally, we used VIPER to image the iron uptake machinery by correlative light and EM (CLEM). VIPER compared favorably with immunolabeling for imaging proteins by CLEM, and is an enabling technology for protein targets that cannot be immunolabeled. VIPER is a versatile peptide tag that can be used to label and track proteins with diverse chemical reporters observable by both FM and EM instrumentation.

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