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1. Secondary amine selective Petasis (SASP) bioconjugation

   https://doi.org/10.1039/C9SC04697F  

   Sim, Yonnette E. ; Nwajiobi, Ogonna ; Mahesh, Sriram ; Cohen, Ryan D. ; Reibarkh, Mikhail Y. ; Raj, Monika ( January 2020 , Chemical Science)

   Selective modification of proteins enables synthesis of antibody-drug conjugates, cellular drug delivery and construction of new materials. Many groups have developed methods for selective N-terminal modification without affecting the side chain of lysine by judicious pH control. This is due to lower basicity of the N-terminus relative to lysine side chains. But none of the methods are capable of selective modification of secondary amines or N-terminal proline, which has similar basicity as lysine. Here, we report a secondary amine selective Petasis (SASP) reaction for selective bioconjugation at N-terminal proline. We exploited the ability of secondary amines to form highly electrophilic iminium ions with aldehydes, which rapidly reacted with nucleophilic organoboronates, resulting in robust labeling of N-terminal proline under biocompatible conditions. This is the first time the Petasis reaction has been utilized for selective modification of secondary amines on completely unprotected peptides and proteins under physiological conditions. Peptide screening results showed that the reaction is highly selective for N-terminal proline. There are no other chemical methods reported in literature that are selective for N-terminal proline in both peptides and proteins. This is a multicomponent reaction leading to the synthesis of doubly functionalized bioconjugates in one step that can be difficult to achieve using other methods. The key advantage of the SASP reaction includes its high chemoselective and stereoselective (>99% de) nature, and it affords dual labeled proteins in one pot. The broad utility of this bioconjugation is highlighted for a variety of peptides and proteins, including aldolase and creatine kinase. 

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2. Mechanistic studies of a “Declick” reaction

   https://doi.org/10.1039/c9sc00690g  

   Meadows, Margaret K. ; Sun, Xiaolong ; Kolesnichenko, Igor V. ; Hinson, Caroline M. ; Johnson, Kenneth A. ; Anslyn, Eric V. ( October 2019 , Chemical Science)

   A kinetic analysis of a “declick” reaction is described. Compound 1 , previously reported to couple an amine and a thiol ( i.e. “click”) under mild aqueous conditions to create 2 , undergoes release of the unaltered coupling partners upon triggering with dithiothreitol ( DTT ). In the study reported herein various aniline derivatives possessing para-electron donating and withdrawing groups were used as the amines. UV/vis spectroscopy of the declick reaction shows time-dependent spectra lacking isosbestic points, implying a multi-step mechanism. Global data fitting using numerical integration of rate equations and singular value decomposition afforded the spectra and time-dependence of each species, as well as rate constants for each step. The kinetic analysis reveals a multi-step process with an intermediate where both thiols of DTT have added prior to expulsion of the aniline leaving group, followed by rearrangement to the final product. Hammett plots show a negative rho value on two of the steps, indicating positive charge building ( i.e. reduction of a negative charge) in the step leading to the intermediate and its rate-determining breakdown. Overall, the kinetic study reported herein gives a complete mechanistic picture of the declick reaction. 

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3. Synthesis of Symmetric and Unsymmetric Secondary Amines from the Ligand Promoted Ruthenium Catalyzed Deaminative Coupling Reaction of Primary Amines

   Arachchige, P. T. ; Hanbin Lee, H. ; Chae S. Yi, C. S. ( January 2018 , Journal of organic chemistry)

   The catalytic system generated in-situ from the tetranuclear Ru–H complex with a catechol ligand (1/L1) was found to be effective for the direct deaminative coupling of two primary amines to form secondary amines. The catalyst 1/L1 was highly chemoselective for promoting the coupling of two different primary amines to afford unsymmetric secondary amines. The analogous coupling of aniline with primary amines formed aryl-substituted secondary amines. The treatment of aniline-d7 with 4-methoxybenzylamine led to the coupling product with significant deuterium incorporation on CH2 (18% D). The most pronounced carbon isotope effect was observed on the -carbon of the product isolated from the coupling reaction of 4-methoxybenzylamine (C(1) = 1.015(2)). Hammett plot was constructed from measuring the rates of the coupling reaction of 4-methoxyaniline with a series of para-substituted benzylamines 4-X-C6H4CH2NH2 (X = OMe, Me, H, F, CF3). ( = -0.79 ± 0.1). A plausible mechanistic scheme has been proposed for the coupling reaction on the basis of these results. The catalytic coupling method provides an operationally simple and chemoselective synthesis of secondary amine products without using any reactive reagents or forming wasteful byproducts. 

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4. α-Branched amines through radical coupling with 2-azaallyl anions, redox active esters and alkenes

   https://doi.org/10.1039/D2SC00500J  

   Duan, Shengzu ; Zi, Yujin ; Wang, Lingling ; Cong, Jielun ; Chen, Wen ; Li, Minyan ; Zhang, Hongbin ; Yang, Xiaodong ; Walsh, Patrick J. ( March 2022 , Chemical Science)

   α-Branched amines are fundamental building blocks in a variety of natural products and pharmaceuticals. Herein is reported a unique cascade reaction that enables the preparation of α-branched amines bearing aryl or alkyl groups at the β- or γ-positions. The cascade is initiated by reduction of redox active esters to alkyl radicals. The resulting alkyl radicals are trapped by styrene derivatives, leading to benzylic radicals. The persistent 2-azaallyl radicals and benzylic radicals are proposed to undergo a radical–radical coupling leading to functionalized amine products. Evidence is provided that the role of the nickel catalyst is to promote formation of the alkyl radical from the redox active ester and not promote the C–C bond formation. The synthetic method introduced herein tolerates a variety of imines and redox active esters, allowing for efficient construction of amine building blocks. 

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5. Synthesis of Aldehydes by Organocatalytic Formylation Reactions of Boronic Acids with Glyoxylic Acid

   https://doi.org/10.1002/ange.201703127  

   Huang, He ; Yu, Chenguang ; Li, Xiangmin ; Zhang, Yongqiang ; Zhang, Yueteng ; Chen, Xiaobei ; Mariano, Patrick S. ; Xie, Hexin ; Wang, Wei ( June 2017 , Angewandte Chemie)

   Reported herein is a conceptually novel organocatalytic strategy for the formylation of boronic acids. New reactivity is engineered into the α‐amino‐acid‐forming Petasis reaction occurring between aryl boronic acids, amines, and glyoxylic acids to prepare aldehydes. The operational simplicity of the process and its ability to generate structurally diverse and valued aryl, heteroaryl, and α,β‐unsaturated aldehydes containing a wide array of functional groups, demonstrates the practical utility of the new synthetic strategy.

    

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