Dattatraya Gautam Rawale scite author profile

Chemical biology research often requires precise covalent attachment of labels to the native proteins. Such methods are sought after to probe, design, and regulate the properties of proteins. At present, this demand is largely unmet due to the lack of empowering chemical technology. Here, we report a chemical platform that enables site-selective labeling of native proteins. Initially, a reversible intermolecular reaction places the "chemical linchpins" globally on all the accessible Lys residues. These linchpins have the capability to drive site-selective covalent labeling of proteins. The linchpin detaches within physiological conditions and capacitates the late-stage installation of various tags. The chemical platform is modular, and the reagent design regulates the site of modification. The linchpin is a multitasking group and facilitates purification of the labeled protein eliminating the requirement of additional chromatography tag. The methodology allows the labeling of a single protein in a mixture of proteins. The precise modification of an accessible residue in protein ensures that their structure remains unaltered. The enzymatic activity of myoglobin, cytochrome C, aldolase, and lysozyme C remains conserved after labeling. Also, the cellular uptake of modified insulin and its downstream signaling process remain unperturbed. The linchpin directed modification (LDM) provides a convenient route for the conjugation of a fluorophore and drug to a Fab and monoclonal antibody. It delivers trastuzumabdoxorubicin and trastuzumab-emtansine conjugates with selective antiproliferative activity toward Her-2 positive SKBR-3 breast cancer cells.

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Single-site glycine-specific labeling of proteins

Purushottam

Adusumalli

Singh

et al. 2019

Nat Commun

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Labeling of native proteins invites interest from diverse segments of science. However, there remains the significant unmet challenge in precise labeling at a single site of a protein. Here, we report the site-specific labeling of natural or easy-to-engineer N-terminus Gly in proteins with remarkable efficiency and selectivity. The method generates a latent nucleophile from N-terminus imine that reacts with an aldehyde to deliver an aminoalcohol under physiological conditions. It differentiates N-Gly as a unique target amongst other proteinogenic amino acids. The method allows single-site labeling of proteins in isolated form and extends to lysed cells. It administers an orthogonal aldehyde group primed for late-stage tagging with an affinity tag, 19 F NMR probe, and a fluorophore. A user-friendly protocol delivers analytically pure tagged proteins. The mild reaction conditions do not alter the structure and function of the protein. The cellular uptake of fluorophore-tagged insulin and its ability to activate the insulin-receptor mediated signaling remains unperturbed.

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Chemoselective and Site‐Selective Lysine‐Directed Lysine Modification Enables Single‐Site Labeling of Native Proteins

et al. 2020

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The necessity for precision labeling of proteins emerged during the efforts to understand and regulate their structure and function. It demands selective attachment of tags such as affinity probes, fluorophores, and potent cytotoxins. Here, we report a method that enables single‐site labeling of a high‐frequency Lys residue in the native proteins. At first, the enabling reagent forms stabilized imines with multiple solvent‐accessible Lys residues chemoselectively. These linchpins create the opportunity to regulate the position of a second Lys‐selective electrophile connected by a spacer. Consequently, it enables the irreversible single‐site labeling of a Lys residue independent of its place in the reactivity order. The user‐friendly protocol involves a series of steps to deconvolute and address chemoselectivity, site‐selectivity, and modularity. Also, it delivers ordered immobilization and analytically pure probe‐tagged proteins. Besides, the methodology provides access to antibody‐drug conjugate (ADC), which exhibits highly selective anti‐proliferative activity towards HER‐2 expressing SKBR‐3 breast cancer cells.

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Chemical Methods for Selective Labeling of Proteins

et al. 2019

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Protein bioconjugation poses outstanding questions of selectivity to the organic transformations. Besides, the presence of a pool of functional groups in the structural outfit of a protein brings its own set of characteristics. In this minireview, we highlight the challenges faced by a chemical transformation to deliver selectivity in the modification of proteins. The examples of pre‐engineered proteins outline the attributes associated with chemoselectivity and chemical orthogonality. Building on this foundation, we discuss the complexity of site‐selectivity in the single‐site modification of native proteins. The gradual evolution of chemical methods while addressing the challenges associated with different amino acids are outlined. The modular methods for labeling a residue independent of its reactivity order closes the discussion.

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Linchpins empower promiscuous electrophiles to enable site-selective modification of histidine and aspartic acid in proteins

et al. 2021

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