Molecular Spatiomics by Proximity Labeling

Kang, Minchul; Rhee, Hyun‐Woo

doi:10.1021/acs.accounts.2c00061

Cited by 36 publications

(26 citation statements)

References 72 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…2 On the other hand, it theoretically allows the simultaneous introduction of many different functional molecules into a given cell membrane, with little restriction on the number of molecular species. At present, the state-of-the-art covalent labeling strategies with spatial specificity from outside of cells mainly include two categories: (1) genetically fusing peroxidases (APEX, 23 APEX2, 24 or HRP 25 ) or biotin ligases (BioID 26 and TurboID 27 ) to a target region, which can catalyze the covalent labeling to proximal proteins 28,29 and (2) using affinity recognition to drive covalent labeling to occur at specific locations. 2,30−42 In a groundbreaking approach by MacMillan et al, Ir complex-conjugated antibodies were utilized for spatially localizing carbene generation to map the microenvironment of immune cells.…”

Section: ■ Introductionmentioning

confidence: 99%

“…At present, the state-of-the-art covalent labeling strategies with spatial specificity from outside of cells mainly include two categories: (1) genetically fusing peroxidases (APEX, APEX2, or HRP) or biotin ligases (BioID and TurboID) to a target region, which can catalyze the covalent labeling to proximal proteins , and (2) using affinity recognition to drive covalent labeling to occur at specific locations. ,− …”

Section: Introductionmentioning

confidence: 99%

“…], thus allowing labeling to be restricted to target cells . Furthermore, by linking tyramine to different functional moieties, phenol-containing molecules can be simply synthesized in a modular manner …”

Section: Introductionmentioning

confidence: 99%

“…37 Furthermore, by linking tyramine to different functional moieties, phenol-containing molecules can be simply synthesized in a modular manner. 29 Herein, we report an aptamer-enabled proximity catalytic labeling (APCL) platform for cell-selective multifunctional surface reconfiguration in mixed cell populations (Scheme 1). We carefully investigate the labeling process and attribute the cell selectivity to the increased local concentration of phenoxy radicals on the surface of target cells by Apt, as well as the short lifetime of phenoxy radicals.…”

Section: ■ Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Cell-Selective Multifunctional Surface Covalent Reconfiguration Using Aptamer-Enabled Proximity Catalytic Labeling

et al. 2023

View full text Add to dashboard Cite

Cell surface engineering provides access to custom-made cell interfaces with desirable properties and functions. However, cell-selective covalent labeling methods that can simultaneously install multiple molecules with different functions are scarce. Herein, we report an aptamer-enabled proximity catalytic covalent labeling platform for multifunctional surface reconfiguration of target cells in mixed cell populations. By conjugating peroxidase with cell-selective aptamers, the probes formed can selectively bind target cells and catalyze target-cell-localized covalent labeling in situ. The universal applicability of the platform to different phenol-modified functional molecules allows us to perform a variety of manipulations on target cells, including labeling, tracking, assembly regulation, and surface remodeling. In particular, the platform has the ability of multiplexed covalent labeling, which can be used to install two mutually orthogonal click reactive molecules simultaneously on the surface of target cells. We thus achieve “multitasking” in complex multicellular systems: programming and tracking specific cell–cell interactions. We further extend the functional molecules to carbohydrates and perform ultrafast neoglycosylation on target living cells. These newly introduced sugars on the cell membrane can be recognized and remodeled by a glycan-modifying enzyme, thus providing a method package for cell-selective engineering of the glycocalyx.

show abstract

Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Cell-Selective Multifunctional Surface Covalent Reconfiguration Using Aptamer-Enabled Proximity Catalytic Labeling

et al. 2023

View full text Add to dashboard Cite

show abstract

“…Proximity labeling using small-molecule catalysts has recently been investigated [ 22 , 23 , 24 ]. We also developed photocatalytic proximity-labeling reactions that proceed in proximity to photocatalysts.…”

Section: Introductionmentioning

confidence: 99%

Switching of Photocatalytic Tyrosine/Histidine Labeling and Application to Photocatalytic Proximity Labeling

Nakane

Nagasawa

Fujimura

et al. 2022

IJMS

View full text Add to dashboard Cite

Weak and transient protein interactions are involved in dynamic biological responses and are an important research subject; however, methods to elucidate such interactions are lacking. Proximity labeling is a promising technique for labeling transient ligand–binding proteins and protein–protein interaction partners of analytes via an irreversible covalent bond. Expanding chemical tools for proximity labeling is required to analyze the interactome. We developed several photocatalytic proximity-labeling reactions mediated by two different mechanisms. We found that numerous dye molecules can function as catalysts for protein labeling. We also identified catalysts that selectively modify tyrosine and histidine residues and evaluated their mechanisms. Model experiments using HaloTag were performed to demonstrate photocatalytic proximity labeling. We found that both ATTO465, which catalyzes labeling by a single electron transfer, and BODIPY, which catalyzes labeling by singlet oxygen, catalyze proximity labeling in cells.

show abstract

A Cell‐Permeable Photosensitizer for Selective Proximity Labeling and Crosslinking of Aggregated Proteome

Feng,

Zhao,

Zhao

et al. 2024

Advanced Science

View full text Add to dashboard Cite

Intracellular proteome aggregation is a ubiquitous disease hallmark with its composition associated with pathogenicity. Herein, this work reports on a cell‐permeable photosensitizer (P8, Rose Bengal derivative) for selective photo induced proximity labeling and crosslinking of cellular aggregated proteome. Rose Bengal is identified out of common photosensitizer scaffolds for its unique intrinsic binding affinity to various protein aggregates driven by the hydrophobic effect. Further acetylation permeabilizes Rose Bengal to selectively image, label, and crosslink aggregated proteome in live stressed cells. A combination of photo‐chemical, tandem mass spectrometry, and protein biochemistry characterizations reveals the complexity in photosensitizing pathways (both Type I & II), modification sites and labeling mechanisms. The diverse labeling sites and reaction types result in highly effective enrichment and identification of aggregated proteome. Finally, aggregated proteomics and interaction analyses thereby reveal extensive entangling of proteostasis network components mediated by HSP70 chaperone (HSPA1B) and active participation of autophagy pathway in combating proteasome inhibition. Overall, this work exemplifies the first photo induced proximity labeling and crosslinking method (namely AggID) to profile intracellular aggregated proteome and analyze its interactions.

show abstract

Molecular Spatiomics by Proximity Labeling

Cited by 36 publications

References 72 publications

Cell-Selective Multifunctional Surface Covalent Reconfiguration Using Aptamer-Enabled Proximity Catalytic Labeling

Cell-Selective Multifunctional Surface Covalent Reconfiguration Using Aptamer-Enabled Proximity Catalytic Labeling

Switching of Photocatalytic Tyrosine/Histidine Labeling and Application to Photocatalytic Proximity Labeling

A Cell‐Permeable Photosensitizer for Selective Proximity Labeling and Crosslinking of Aggregated Proteome

Contact Info

Product

Resources

About