Bioisostere-conjugated fluorescent probes for live-cell protein imaging without non-specific organelle accumulation.

Specific labeling of proteins using membrane-permeable fluorescent probes is a powerful technique for bioimaging. Cationic fluorescent dyes with high fluorescence quantum yield, photostability, and water solubility provide highly useful scaffolds for protein-labeling probes. However, cationic probes generally show undesired accumulation in organelles, which causes a false-positive signal in localization analysis.

No-wash fluorogenic labeling of proteins for reversible photoswitching in live cells.

Photoswitchable fluorescent molecules (PSFMs) are positioned as valuable tools for biomolecule localization tracking and super-resolution imaging technologies due to their unique ability to reversibly control fluorescence intensity upon light irradiation. Despite the high demand for PSFMs that are suitable for live-cell imaging, no general method has been reported that enables reversible fluorescence control on proteins of interest in living cells. Herein, we have established a platform to realize reversible fluorescence switching in living cells by adapting a protein labeling system.

Visualization of multiple localizations of GLUT4 by fluorescent probes of PYP-tag with designed unnatural warhead.

Within a cell, multiple copies of the same protein coexist in different pathways and behave differently. Being able to individually analyze the constant actions of proteins in a cell is crucial to know the pathways through which they pass and which physiological functions they are deeply involved in. However, until now, it has been difficult to distinguish protein copies with distinct translocation properties by fluorescence labeling with different colors in living cells.

Efficient visible/NIR light-driven uncaging of hydroxylated thiazole orange-based caged compounds in aqueous media.

In photoactivation strategies with bioactive molecules, one-photon visible or two-photon near-infrared light-sensitive caged compounds are desirable tools for biological applications because they offer reduced phototoxicity and deep tissue penetration. However, visible-light-sensitive photoremovable protecting groups (PPGs) reported so far have displayed high hydrophobicity and low uncaging cross sections ( < 50) in aqueous media, which can obstruct the control of bioactivity with high spatial and temporal precision. In this study, we developed hydroxylated thiazole orange (HTO) derivatives as visible-light-sensitive PPGs with high uncaging cross sections ( ≈ 370) in aqueous solution.

An "OFF-ON-OFF" fluorescence protein-labeling probe for real-time visualization of the degradation of short-lived proteins in cellular systems.

The ability to monitor proteolytic pathways that remove unwanted and damaged proteins from cells is essential for understanding the multiple processes used to maintain cellular homeostasis. In this study, we have developed a new protein-labeling probe that employs an 'OFF-ON-OFF' fluorescence switch to enable real-time imaging of the expression (fluorescence ON) and degradation (fluorescence OFF) of PYP-tagged protein constructs in living cells. Fluorescence switching is modulated by intramolecular contact quenching interactions in the unbound probe (fluorescence OFF) being disrupted upon binding to the PYP-tag protein, which turns fluorescence ON.

Fluorogenic probes for detecting deacylase and demethylase activity towards post-translationally-modified lysine residues.

Reversible enzymatic post-translational modification of the ε-amino groups of lysine residues (-acylation reactions) plays an important role in regulating the cellular activities of numerous proteins. This study describes how enzyme catalyzed N-deprotection of lysine residues of non-fluorescent peptide-coumarin probes can be used to generate N-deprotected peptides that undergo spontaneous - to -ester transfer reactions (uncatalyzed) to generate a highly fluorescent -carbamoyl peptide. This enables detection of enzyme catalyzed -deacetylation, -demalonylation, -desuccinylation and -demethylation reactions activities towards the N-modified lysine residues of these probes using simple 'turn on' fluorescent assays.

Near-infrared fluorescent probes: a next-generation tool for protein-labeling applications.

The development of near-infrared (NIR) fluorescent probes over the past few decades has changed the way that biomolecules are imaged, and thus represents one of the most rapidly progressing areas of research. Presently, NIR fluorescent probes are routinely used to visualize and understand intracellular activities. The ability to penetrate tissues deeply, reduced photodamage to living organisms, and a high signal-to-noise ratio characterize NIR fluorescent probes as efficient next-generation tools for elucidating various biological events.

Rapid no-wash labeling of PYP-tag proteins with reactive fluorogenic ligands affords stable fluorescent protein conjugates for long-term cell imaging studies.

Covalent labeling systems that employ protein-tags or chemical probes to convert proteins into fluorescent conjugates are powerful tools for carrying out real time imaging and pulse-chase tracking studies that enable the spatiotemporal role of proteins in complex biological systems to be investigated. In this study, we have covalently modified a specific nucleophilic cysteine residue of the PYP-tag protein with weakly fluorescent α,β-unsaturated ketone (conjugate addition) and α-halomethyl ketone (S2 reaction) acceptors to afford highly fluorescent PYP-tag-dimethylaminocoumarin (DMAC) conjugates, whose ligands are covalently bound to the PYP-protein through stable thioether linkers. A chloromethylketone derived DMAC-CMK reagent was found to afford the best kinetic and stability profile for labeling the PYP-tag in cellular systems, with studies demonstrating that PYP-DMAC-CMK conjugates exhibit excellent photostability and cellular stability profiles which enables them to be used for long-term protein imaging studies in cellular systems.