Beyond O6-Benzylguanine: O6-(5-Pyridylmethyl)guanine as a Substrate for the Self-Labeling Enzyme SNAP-Tag

Advances in Organic Fluorescent Probes for Intracellular Zn2+ Detection and Bioimaging

Zinc ions (Zn2+) play a key role in maintaining and regulating protein structures and functions. To better understand the intracellular Zn2+ homeostasis and signaling role, various fluorescent sensors have been developed that allow the monitoring of Zn2+ concentrations and bioimaging in live cells in real time. This review highlights the recent development of organic fluorescent probes for the detection and imaging of intracellular Zn2+, including the design and construction of the probes, fluorescent response mechanisms, and their applications to intracellular Zn2+ detection and imaging on-site. Finally, the current challenges and prospects are discussed.

SNAP-tagging live cells via chelation-assisted copper-catalyzed azide-alkyne cycloaddition

SNAP-tag is a single-turnover enzyme that has become a powerful tool, hence a popular choice, of targeted cellular protein labeling. Three SNAP-tag substrates that carry the copper-chelating 2-picolyl azide moiety are prepared, one of which has an unconventional 5-pyridylmethyl-substituted guanine structure, rather than the usual benzylguanine that is optimized to be accepted by SNAP-tag. All three substrates are effective in transferring a 2-picolyl azide moiety to SNAP-tag in live cells under conventional labeling conditions (30-minute incubation of cells with labeling reagents at 37 °C under 5% CO2). Live cells that are decorated with chelating azido groups on the extracellular side of membranes undergo copper-catalyzed azide-alkyne cycloaddition (CuAAC) with an ethynyl-functionalized fluorophore to accomplish membrane protein labeling by a fluorescent dye. The chelation-assisted CuAAC labeling step is rapid (<1 minute) with a relatively low dose of the copper catalyst (20 μM), and consequently exerts no ill effect on the labeled cells. A SNAP-tag substrate that carries a non-chelating azide moiety, on the other hand, fails to produce satisfactory labeling under the same constraints. The rapid, live cell-compatible SNAP-tag/chelation-assisted CuAAC two-step method expands the utility of SNAP-tag in protein labeling applications.

Using the SNAP-Tag technology to easily measure and demonstrate apoptotic changes in cancer and blood cells with different dyes

In vitro and ex vivo development of novel therapeutic agents requires reliable and accurate analyses of the cell conditions they were preclinical tested for, such as apoptosis. The detection of apoptotic cells by annexin V (AV) coupled to fluorophores has often shown limitations in the choice of the dye due to interference with other fluorescent-labeled cell markers. The SNAP-tag technology is an easy, rapid and versatile method for functionalization of proteins and was therefore used for labeling AV with various fluorophores. We generated the fusion protein AV-SNAP and analyzed its capacity for the specific display of apoptotic cells in various assays with therapeutic agents. AV-SNAP showed an efficient coupling reaction with five different fluorescent dyes. Two selected fluorophores were tested with suspension, adherent and peripheral blood cells, treated by heat-shock or apoptosis-inducing therapeutic agents. Flow cytometry analysis of apoptotic cells revealed a strong visualization using AV-SNAP coupled to these two fluorophores exemplary, which was comparable to a commercial AV-Assay-kit. The combination of the apoptosis-specific binding protein AV with the SNAP-tag provides a novel solid method to facilitate protein labeling using several, easy to change, fluorescent dyes at once. It avoids high costs and allows an ordinary exchange of dyes and easier use of other fluorescent-labeled cell markers, which is of high interest for the preclinical testing of therapeutic agents in e.g. cancer research.

Quantitative Imaging of Labile Zn2+ in the Golgi Apparatus Using a Localizable Small-Molecule Fluorescent Probe

Fluorescent Zn²⁺ probes used for the quantitative analysis of labile Zn²⁺ concentration ([Zn²⁺]) in target organelles are crucial for understanding the role of Zn²⁺ in biological processes. Although several fluorescent Zn²⁺ probes have been developed to date, there is still a lack of consensus concerning the [Zn²⁺] in intracellular organelles. In this study, we describe the development of ZnDA-1H, a small-molecule fluorescent probe for Zn²⁺, which exhibits less pH sensitivity, high Zn²⁺ selectivity, and large fluorescence enhancement upon binding to Zn²⁺. Through protein labeling technology, ZnDA-1H was precisely targeted in various intracellular organelles, such as the nucleus, mitochondria, endoplasmic reticulum, and Golgi apparatus. ZnDA-1H exhibited a reversible fluorescence response toward labile Zn²⁺ in these organelles in live cells. Using this probe, the [Zn²⁺] in the Golgi apparatus was estimated to be 25 ± 1 nM, suggesting that labile Zn²⁺ plays a physiological role in the secretory pathway.

Fluorescent Labeling of Proteins of Interest in Live Cells: Beyond Fluorescent Proteins

Live cell imaging brings us into a new era of direct visualization of biological processes and molecular dynamics in real time. To visualize dynamic cellular processes and virus-host interactions, fluorescent labeling of proteins of interest is often necessary. Fluorescent proteins are widely used for protein imaging, but they have some intrinsic deficiencies such as big size, photobleaching, and spectrum restriction. Thus, a variety of labeling strategies have been established and continuously developed. To protect the natural biological function(s) of the protein of interest, especially in viral life cycle, in vivo labeling requires smaller-sized tags, more specificity, and lower cytotoxicity. Here, we briefly summarized the principles, development, and their applications mainly in the virology field of three strategies for fluorescent labeling of proteins of interest including self-labeling enzyme derivatives, stainable peptide tags, and non-canonical amino acid incorporation. These labeling techniques greatly expand the fluorescent labeling toolbox and provide new opportunities for imaging biological processes.

Expanding the substrate selectivity of SNAP/CLIP-tagging of intracellular targets

SNAP-tag belongs to a class of genetic tools of protein labeling that complements fluorescent proteins. This single-turnover enzyme is a mutant of human DNA repair protein O⁶-alkylguanine-DNA alkyltransferase (hAGT). It accepts, in most cases, label-carrying O⁶-benzylguanines or benzyl-2-chloro-6-aminopyrimidines as suitable substrates. In this article, strategies and methods to expand the scope of the labels for intracellular proteins of live cells via the actions of SNAP-tag are presented. CLIP-tag is another mutant of the hAGT that was engineered to have mutually exclusive substrate specificity from SNAP-tag. The use of complementary bioorthogonal chemical reactions in conjunction with orthogonal enzymatic SNAP/CLIP-tags for the purpose of dual-color intracellular labeling is also described.