Palladium-mediated cleavage of proteins with thiazolidine-modified backbone in live cells

Guy Mann; Satish Gandhesiri; Roman Meledin; Ganga B. Vamisetti; Ashraf Brik

doi:10.1002/anie.201906545

Palladium-mediated cleavage of proteins with thiazolidine-modified backbone in live cells

Guy Mann, Satish Gandhesiri, Roman Meledin, Ganga B. Vamisetti, Ashraf Brik

Chemistry

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Chem. protein synthesis and biorthogonal modification chemistries allow production of unique proteins for a range of biol. studies. Bond-forming reactions for site-selective protein labeling are commonly used in these endeavors. Selective bond-cleavage reactions, however, are much less explored and still pose a great challenge. In addition, most of studies with modified proteins prepared by either total synthesis or semisynthesis have been applied mainly for in vitro experiments with very limited extension to live cells. Reported here is an approach for studying uniquely modified proteins containing a traceless cell delivery unit and palladium-based cleavable element for chem. activation, and monitoring the effect of these proteins in live cells. This approach is demonstrated for the synthesis of a caged ubiquitin-aldehyde, which was decaged for the inhibition of deubiquitinases in live cells.

Original language	American English
Pages (from-to)	13540-13549
Number of pages	10
Journal	Angewandte Chemie - International Edition
Volume	58
Issue number	38
DOIs	https://doi.org/10.1002/anie.201906545
State	Published - 16 Sep 2019

Keywords

TAMRA FITC labeled peptide ligation
cells
fluorescence
inhibitors
palladium
protein synthesis palladium based bond cleavage live cell
proteins
solid phase peptide synthesis cell delivery unit cleavable element
ubiquitin aldehyde synthesis deubiquitinase inhibition live cell

All Science Journal Classification (ASJC) codes

Catalysis
General Chemistry

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10.1002/anie.201906545

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title = "Palladium-mediated cleavage of proteins with thiazolidine-modified backbone in live cells",

abstract = "Chem. protein synthesis and biorthogonal modification chemistries allow production of unique proteins for a range of biol. studies. Bond-forming reactions for site-selective protein labeling are commonly used in these endeavors. Selective bond-cleavage reactions, however, are much less explored and still pose a great challenge. In addition, most of studies with modified proteins prepared by either total synthesis or semisynthesis have been applied mainly for in vitro experiments with very limited extension to live cells. Reported here is an approach for studying uniquely modified proteins containing a traceless cell delivery unit and palladium-based cleavable element for chem. activation, and monitoring the effect of these proteins in live cells. This approach is demonstrated for the synthesis of a caged ubiquitin-aldehyde, which was decaged for the inhibition of deubiquitinases in live cells.",

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doi = "10.1002/anie.201906545",

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AU - Vamisetti, Ganga B.

AU - Brik, Ashraf

N1 - CAplus AN 2019:1641085; MEDLINE PMID: 31402546 (Journal; Article; Research Support, Non-U.S. Gov't; Review) M1 - Copyright © 2023 American Chemical Society (ACS). All Rights Reserved.; Copyright © 2023 U.S. National Library of Medicine.

PY - 2019/9/16

Y1 - 2019/9/16

N2 - Chem. protein synthesis and biorthogonal modification chemistries allow production of unique proteins for a range of biol. studies. Bond-forming reactions for site-selective protein labeling are commonly used in these endeavors. Selective bond-cleavage reactions, however, are much less explored and still pose a great challenge. In addition, most of studies with modified proteins prepared by either total synthesis or semisynthesis have been applied mainly for in vitro experiments with very limited extension to live cells. Reported here is an approach for studying uniquely modified proteins containing a traceless cell delivery unit and palladium-based cleavable element for chem. activation, and monitoring the effect of these proteins in live cells. This approach is demonstrated for the synthesis of a caged ubiquitin-aldehyde, which was decaged for the inhibition of deubiquitinases in live cells.

AB - Chem. protein synthesis and biorthogonal modification chemistries allow production of unique proteins for a range of biol. studies. Bond-forming reactions for site-selective protein labeling are commonly used in these endeavors. Selective bond-cleavage reactions, however, are much less explored and still pose a great challenge. In addition, most of studies with modified proteins prepared by either total synthesis or semisynthesis have been applied mainly for in vitro experiments with very limited extension to live cells. Reported here is an approach for studying uniquely modified proteins containing a traceless cell delivery unit and palladium-based cleavable element for chem. activation, and monitoring the effect of these proteins in live cells. This approach is demonstrated for the synthesis of a caged ubiquitin-aldehyde, which was decaged for the inhibition of deubiquitinases in live cells.

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KW - fluorescence

KW - inhibitors

KW - palladium

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KW - proteins

KW - solid phase peptide synthesis cell delivery unit cleavable element

KW - ubiquitin aldehyde synthesis deubiquitinase inhibition live cell

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Palladium-mediated cleavage of proteins with thiazolidine-modified backbone in live cells

Abstract

Keywords

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