Substrate control in stereoselective lanthionine biosynthesis.

Enzymes are typically highly stereoselective catalysts that enforce a reactive conformation on their native substrates. We report here a rare example in which the substrate controls the stereoselectivity of an enzyme-catalysed Michael-type addition during the biosynthesis of lanthipeptides. These natural products contain thioether crosslinks formed by a cysteine attack on dehydrated Ser and Thr residues. We demonstrate that several lanthionine synthetases catalyse highly selective anti-additions in which the substrate (and not the enzyme) determines whether the addition occurs from the re or si face. A single point mutation in the peptide substrate completely inverted the stereochemical outcome of the enzymatic modification. Quantum mechanical calculations reproduced the experimentally observed selectivity and suggest that conformational restraints imposed by the amino-acid sequence on the transition states determine the face selectivity of the Michael-type cyclization

Cycloadditions of cyclohexynes and cyclopentyne.

We report the strategic use of cyclohexyne and the more elusive intermediate, cyclopentyne, as a tool for the synthesis of new heterocyclic compounds. Experimental and computational studies of a 3-substituted cyclohexyne are also described. The observed regioselectivities are explained by the distortion/interaction model

Enantioselective Synthesis of Dialkylated N-Heterocycles by Palladium-Catalyzed Allylic Alkylation

The enantioselective synthesis of α-disubstituted N-heterocyclic carbonyl compounds has been accomplished using palladium-catalyzed allylic alkylation. These catalytic conditions enable access to various heterocycles, such as morpholinone, thiomorpholinone, oxazolidin-4-one, 1,2-oxazepan-3-one, 1,3-oxazinan-4-one, and structurally related lactams, all bearing fully substituted α-positions. Broad functional group tolerance was explored at the α-position in the morpholinone series. We demonstrate the utility of this method by performing various transformations on our useful products to readily access a number of enantioenriched compounds

Sequential dual site-selective protein labelling enabled by lysine modification.

Methods that allow for chemical site-selective dual protein modification are scarce. Here, we provide proof-of-concept for the orthogonality and compatibility of a method for regioselective lysine modification with strategies for protein modification at cysteine and genetically encoded ketone-tagged amino acids. This sequential, orthogonal approach was applied to albumin and a therapeutic antibody to create functional dual site-selectively labelled proteins

An artificial metalloenzyme for a bimolecular Diels–Alder reaction

The Diels–Alder reaction, one of the most important in organic chemistry, forms functionalized six-membered cycloadducts in a single step. While widely used to construct complex biologically active molecules in the laboratory, [4+2] cycloadditions are rarely employed for natural product biosynthesis in cells owing to the lack of appropriate enzymes. Creating artificial metalloenzymes able to exploit Lewis acid catalysis for substrate activation could change this situation. Embedding a metal ion in a chiral protein binding pocket potentially combines the best aspects of two worlds – transition metal and enzymatic catalysis – to achieve both high activity and selectivity. Here we report the transformation of a zinc-binding helical bundle into an artificial metalloenzyme that efficiently catalyzes a hetero-Diels–Alder reaction between 3-vinyl indole and an azachalcone derivative by a process of design and laboratory evolution. The best enzyme, DA7, performed \u3e15,000 turnovers per active site and produced only a single product stereoisomer (\u3e99% ee). Detailed kinetic analysis showed that this catalyst is more than two orders of magnitude more proficient than other known Diels–Alderases, including many designed catalysts and natural enzymes involved in polyketide natural products biosynthesis. The remarkable activity of DA7 can be ascribed to the Zn(II) ion, which activates the heterodiene for reaction, and a shape complementary binding pocket that preorganized the reactants for efficient reaction and exacting control over chemo-, diastereo-, and enantioselectivity. These results establish the feasibility of combining design and evolution to harness the structural and functional properties of metal ions to produce remarkably active enzymes for an important abiological reaction. Extending this approach to metal ions other than zinc, and to scaffolds beyond helical bundles, can be expected to produce proficient custom-metalloenzymes for a wide spectrum of unnatural chemical transformations

Bifunctional chiral dehydroalanines for peptide coupling and stereoselective <i>S</i>-Michael addition

A second generation of chiral bicyclic dehydroalanines easily accessible from serine has been developed. These scaffolds behaved as excellent S-Michael acceptors when tri-O-acetyl-2-acetamido-2-deoxy-1-thio-α-d-galactopyranose (abbreviated as GalNAc-α-SH) was used as a nucleophile. This addition proceeds with total chemo- and stereoselectivity, complete atom economy, quickly, and at room temperature, making it a true click reaction. The Michael adducts were easily transformed into S-(2-acetamido-2-deoxy-α-d-galactopyranosyl)-l- and -d-cysteines, which can be regarded as mimics of the Tn antigen derived from l-Ser (α-d-GalNAc-l-Ser) and d-Ser (α-d-GalNAc-d-Ser), respectively.Peer Reviewe

Unravelling the Time Scale of Conformational Plasticity and Allostery in Glycan Recognition by Human Galectin-1

The interaction of human galectin-1 with a variety of oligosaccharides, from di-(N-acetyllactosamine) to tetra-saccharides (blood B type-II antigen) has been scrutinized by using a combined approach of different NMR experiments, molecular dynamics (MD) simulations, and isothermal titration calorimetry. Ligand- and receptor-based NMR experiments assisted by computational methods allowed proposing three-dimensional structures for the different complexes, which explained the lack of enthalpy gain when increasing the chemical complexity of the glycan. Interestingly, and independently of the glycan ligand, the entropy term does not oppose the binding event, a rather unusual feature for protein-sugar interactions. CLEANEX-PM and relaxation dispersion experiments revealed that sugar binding affected residues far from the binding site and described significant changes in the dynamics of the protein. In particular, motions in the microsecond-millisecond timescale in residues at the protein dimer interface were identified in the presence of high affinity ligands. The dynamic process was further explored by extensive MD simulations, which provided additional support for the existence of allostery in glycan recognition by human galectin-1.This research was supported by the European Research Council (ERC-2017-AdG, project 788143-RECGLYCANMR to J.J.-B.), Agencia Estatal Investigacion of Spain (AEI; grant RTI2018-094751-B-C21 to J.J.-B., RTI2018-099592-B-C22 to G.J.O, RTI2018-101269-B-I00 to O. M., and Ramon y Cajal Contract to A. A.) and the Severo Ochoa Excellence Accreditation (SEV-2016-0644 to J.J.-B.). We also thank Instituto de Salud Carlos III of Spain, ISCIII (grant PRB3 IPT17/0019 to A. G.) and the Mizutani Foundation for Glycoscience (grant 200077 to G.J.O.)

Precise Installation of Diazo-Tagged Side-Chains on Proteins to Enable In Vitro and In-Cell Site-Specific Labeling.

The chemistry of diazo compounds has generated a huge breadth of applications in the field of organic synthesis. Their versatility combined with their tunable reactivity, stability, and chemoselectivity makes diazo compounds desirable reagents for chemical biologists. Here, we describe a method for the precise installation of diazo handles on proteins and antibodies in a mild and specific approach. Subsequent 1,3-cycloaddition reactions with strained alkynes enable both bioimaging through an in-cell "click" reaction and probing of the cysteine proteome in cell lysates. The selectivity and efficiency of these processes makes these suitable reagents for chemical biology studies

Merging the Isonitrile‐Tetrazine (4+1) cycloaddition and the Ugi four‐component reaction into a single multicomponent process

© 2023 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.Multicomponent reactions are of utmost importance at generating a unique, wide, and complex chemical space. Herein we describe a novel multicomponent approach based on the combination of the isonitrile-tetrazine (4+1) cycloaddition and the Ugi four-component reaction to generate pyrazole amide derivatives. The scope of the reaction as well as mechanistic insights governing the 4H-pyrazol-4-imine tautomerization are provided. This multicomponent process provides access to a new chemical space of pyrazole amide derivatives and offers a tool for peptide modification and stapling.This work was supported by a Marie Skłodowska-Curie grant (Agreement No. 101018454) from the European Union's Horizon 2020 research and innovation program. We thank the DFG (post-doctoral fellowship, grant no. 493006134, to A. V. V.), Fundação para a Ciência e a Tecnologia (Ph.D. studentship 2022.09827.BD to A. L. D.) and MCIN/AEI/10.13039/501100011033 (PID2021-125946OB-I00 to G. J. O. and CEX2021-001136-S to CIC bioGUNE).info:eu-repo/semantics/publishedVersio