Fluorescent tagging of proteins via accessible cysteine residues is of paramount importance. In this study, model proteins of interest (mitogen-activated protein kinases) were labeled successfully in native state on their free thiols by direct fluorescence derivatization, or in a sequential manner where conjugation of the site specific linker and the fluorophore is carried out in two steps. To this end we designed and prepared two novel chemical reporters carrying vinyl sulfone as Cys targeting function and cyclooctyne motifs, suitable for subsequent conjugation with fluorogenic azides via copper free strain-promoted azide-alkyne click chemistry. Direct and sequential labeling reaction steps were analyzed by native PAGE, capillary zone electrophoresis and tandem mass spectrometry. The efficiency of tagging was correlated with solvent accessibility of the Cys residues. Our results indicated that conjugation of native proteins by vinyl sulfone linkers was fast and thiol-selective. Subsequent click reaction with fluorogenic dyes generates intensive fluorescence signals and fulfills all requirements of bioorthogonality.
Bioorthogonal click-reactions represent ideal means for labeling biomolecules selectively and specifically with suitable small synthetic dyes. Genetic code expansion (GCE) technology enables efficient site-selective installation of bioorthogonal handles onto proteins of interest (POIs). Incorporation of bioorthogonalized non-canonical amino acids is a minimally perturbing means of enabling the study of proteins in their native environment. The growing demand for the multiple modification of POIs has triggered the quest for developing orthogonal bioorthogonal reactions that allow simultaneous modification of biomolecules. The recently reported bioorthogonal [4 + 1] cycloaddition reaction of bulky tetrazines and sterically demanding isonitriles has prompted us to develop a non-canonical amino acid (ncAA) bearing a suitable isonitrile function. Herein we disclose the synthesis and genetic incorporation of this ncAA together with studies aiming at assessing the mutual orthogonality between its reaction with bulky tetrazines and the inverse electron demand Diels–Alder (IEDDA) reaction of bicyclononyne (BCN) and tetrazine. Results showed that the new ncAA, bulky-isonitrile-carbamate-lysine (BICK) is efficiently and specifically incorporated into proteins by genetic code expansion, and despite the slow [4 + 1] cycloaddition, enables the labeling of outer membrane receptors such as insulin receptor (IR) with a membrane-impermeable dye. Furthermore, double labeling of protein structures in live and fixed mammalian cells was achieved using the mutually orthogonal bioorthogonal IEDDA and [4 + 1] cycloaddition reaction pair, by introducing BICK through GCE and BCN through a HaloTag technique.
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