Molecular anchoring and fluorescent labeling in animals compatible with tissue clearing for 3D imaging.

Analyzing the quantity and distribution of molecules throughout intact biological tissue is crucial for understanding various biological phenomena. Traditional methods involving destructive extraction result in the loss of spatial information. Conversely, tissue-clearing techniques combined with fluorescence imaging have recently emerged as a powerful tool for deep tissue imaging without sacrificing spatial coverage. Key to this approach is the anchoring and labeling of targets in intact tissue. In this review, methods for anchoring and labeling proteins, lipids, carbohydrates, and small molecules are presented. Future directions include the development of activity-based probes that work in vivo and mark transient events with spatial information to enable a deeper understanding of biological phenomena.

Tyrosinase-Based Proximity Labeling in Living Cells and In Vivo.

Characterizing the protein constituents of a specific organelle and protein neighbors of a protein of interest (POI) is essential for understanding the function and state of the organelle and protein networks associated with the POI. Proximity labeling (PL) has emerged as a promising technology for specific and efficient spatial proteomics. Nevertheless, most enzymes adopted for PL still have limitations: APEX requires cytotoxic H2O2 for activation and thus is poor in biocompatibility for in vivo application, BioID shows insufficient labeling kinetics, and TurboID suffers from high background biotinylation. Here, we introduce a bacterial tyrosinase (BmTyr) as a new PL enzyme suitable for H2O2-free, fast (≤10 min in living cells), and low-background protein tagging. BmTyr is genetically encodable and enables subcellular-resolved PL and proteomics in living cells. We further designed a strategy of ligand-tethered BmTyr for in vivo PL, which unveiled the surrounding proteome of a neurotransmitter receptor (Grm1 and Drd2) in its resident synapse in a live mouse brain. Overall, BmTyr is one promising enzyme that can improve and expand PL-based applications and discoveries.

Revisiting PFA-mediated tissue fixation chemistry: FixEL enables trapping of small molecules in the brain to visualize their distribution changes.

Various small molecules have been used as functional probes for tissue imaging in medical diagnosis and pharmaceutical drugs for disease treatment. The spatial distribution, target selectivity, and diffusion/excretion kinetics of small molecules in structurally complicated specimens are critical for function. However, robust methods for precisely evaluating these parameters in the brain have been limited. Herein, we report a new method termed "fixation-driven chemical cross-linking of exogenous ligands (FixEL)," which traps and images exogenously administered molecules of interest (MOIs) in complex tissues. This method relies on protein-MOI interactions and chemical cross-linking of amine-tethered MOI with paraformaldehyde used for perfusion fixation. FixEL is used to obtain images of the distribution of the small molecules, which addresses selective/nonselective binding to proteins, time-dependent localization changes, and diffusion/retention kinetics of MOIs such as the scaffold of PET tracer derivatives or drug-like small molecules.

Protocol to visualize the distribution of exogenously administered small molecules in the mouse brain.

Here, we present fixation-driven chemical crosslinking of exogenous ligands, a protocol to visualize the distribution of exogenously administered small molecules in the mouse brain. We first describe the probe design of the small molecules of interest and the probe microinjection into a live mouse brain in detail. We then detail procedures for paraformaldehyde-perfusion fixation. This approach is especially useful for imaging-based evaluation of the small-molecule ligands distribution in mouse brain tissue relying on their interaction with endogenous proteins. For complete details on the use and execution of this protocol, please refer to Nonaka et al.1.

Recent applications of N-acyl imidazole chemistry in chemical biology.

N-Acyl imidazoles are unique electrophiles that exhibit moderate reactivity, relatively long-half life, and high solubility in water. Thanks to their tunable reactivity and chemical selectivity, the application of N-acyl imidazole derivatives has launched to a number of chemical biology researches, which include chemical synthesis of peptide/protein, chemical labeling of native proteins of interest (POIs), and structural analysis and functional manipulation of RNAs. Since proteins and RNAs play pivotal roles in numerous biological events in all living organisms, the methods that enable the chemical modification of endogenously existing POIs and RNAs in live cells may offer a variety of opportunities not only for fundamental scientific study but also for biotechnology and drug development. In this review, we discuss the recent progress of N-acyl imidazole chemistry that contributes to the chemical labeling and functional control of endogenous proteins and RNAs under multimolecularly crowded biological conditions of live cells.