Steric and Electronic Effects on an Antibody‐Catalyzed <i>Diels–Alder</i> Reaction

Gozin, Yael; Hilvert, Donald

doi:10.1002/hlca.200290015

Cited by 7 publications

(4 citation statements)

References 30 publications

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“…The antibody‐catalysed Diels–Alder cycloaddition reaction between tetrachlorothiophene dioxide ( 5 ) and N ‐ethylmaleimide ( 6 ) proceeds via a transition state that looks very much like hexachloronorbornene derivative 7 (Scheme ), which was used as a hapten to generate the catalytic antibodies. The unstable intermediate spontaneously eliminates sulfur dioxide to give a product that rapidly undergoes in situ oxidation to produce N ‐ethylphthalimide . Moreover, site‐specific mutagenesis was utilised to produce a Cu II binding protein motif by introducing coordinating amino acids at geometrically appropriate positions in a thermostable protein and subsequently leading to the construction of a metalloenzyme mimic for Diels–Alder cycloaddition .…”

Section: Enzyme Mimics and Their Applicationsmentioning

confidence: 99%

“…Eur.J.2016, 22,8404 -8430 www.chemeurj.org duce N-ethylphthalimide. [287] Moreover,s ite-specific mutagenesis was utilised to produce aC u II binding protein motif by introducing coordinating amino acids at geometrically appropriate positions in at hermostablep rotein and subsequently leading to the construction of am etalloenzyme mimic for Diels-Alder cycloaddition. [288] Experimental evidence clearly showed that the Cu II is coordinatively bound to the amino acids at the artificial binding site where asymmetric Diels-Alder reactions occur.B yg rafting an ew active site (a Cu II -binding bidentate ligand)t oadimeric protein, Bose tal.…”

Section: "Diels-alderase" Forc Hemical Synthesismentioning

confidence: 99%

“…Scheme7.Diels-Alder cycloaddition reaction between tetrachlorothiophene dioxide ( 5)and N-ethylmaleimide (6;reproduced with permission from ref. [287]).…”

Section: Manganese Metalloporphyrins As Epoxidation Catalystsmentioning

confidence: 99%

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Enzyme Mimics: Advances and Applications

Kuah

Toh

Yee

et al. 2016

Chemistry A European J

277

151

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Enzyme mimics or artificial enzymes are a class of catalysts that have been actively pursued for decades and have heralded much interest as potentially viable alternatives to natural enzymes. Aside from having catalytic activities similar to their natural counterparts, enzyme mimics have the desired advantages of tunable structures and catalytic efficiencies, excellent tolerance to experimental conditions, lower cost, and purely synthetic routes to their preparation. Although still in the midst of development, impressive advances have already been made. Enzyme mimics have shown immense potential in the catalysis of a wide range of chemical and biological reactions, the development of chemical and biological sensing and anti-biofouling systems, and the production of pharmaceuticals and clean fuels. This Review concerns the development of various types of enzyme mimics, namely polymeric and dendrimeric, supramolecular, nanoparticulate and proteinic enzyme mimics, with an emphasis on their synthesis, catalytic properties and technical applications. It provides an introduction to enzyme mimics and a comprehensive summary of the advances and current standings of their applications, and seeks to inspire researchers to perfect the design and synthesis of enzyme mimics and to tailor their functionality for a much wider range of applications.

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Section: Enzyme Mimics and Their Applicationsmentioning

confidence: 99%

Section: "Diels-alderase" Forc Hemical Synthesismentioning

confidence: 99%

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Enzyme Mimics: Advances and Applications

Kuah

Toh

Yee

et al. 2016

Chemistry A European J

277

151

View full text Add to dashboard Cite

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“…Initial velocities were determined by starch±I 2 bleaching at 606 nm at several concentrations of NEM while holding the concentration of TCTD constant at 150 mm. [26,38] The data were corrected for the uncatalyzed reaction and fitted to the Michaelis±Menten Equation:…”

Section: Kinetic Assaysmentioning

confidence: 99%

Immunological Optimization of a Generic Hydrophobic Pocket for High Affinity Hapten Binding and Diels–Alder Activity

Piatesi

Hilvert

2004

ChemBioChem

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Antibody 1E9, which binds a tetrachloronorbornene derivative with subnanomolar affinity and catalyzes the Diels-Alder reaction between tetrachlorothiophene dioxide and N-ethylmaleimide with high efficiency, arose from a family of highly restricted germ-line immunoglobulins that bind diverse hydrophobic ligands. Two somatic mutations, one at position L89 in the light chain (SerL89Phe) and another at position H47 in the heavy chain (TrpH47Leu), have been postulated to be responsible for the unusually high degree of shape and chemical complementarity observed in the crystal structure of 1E9 complexed with its hapten. To test this hypothesis, the germ-line sequence at these two positions was restored by site-directed mutagenesis. The ensuing 160 to 3900-fold decrease in hapten affinity and the complete loss of catalytic activity support the hypothesis that these somatic mutations substantially remodel the antibody binding pocket. Mutation of the highly conserved hydrogen-bond donor AsnH35, which sits at the bottom of the active site and is a hallmark of this family of antibodies, is also catastrophic with respect to hapten binding and catalysis. In contrast, residues in the CDR H3 loop, which contributes a significant fraction of the hapten-contacting protein surface, have a more subtle influence on the properties of 1E9. Interestingly, while most changes in this loop have neutral or modestly deleterious effects, replacement of MetH100b at the floor of the pocket with phenylalanine leads to a significant sevenfold increase in catalytic activity. The latter result is surprising given the unusually close fit of the parent antibody to the transition-state analogue. Further fine-tuning of the interactions between 1E9 and its ligands by introducing mutations outside the active site could conceivably yield substantially more active catalysts.

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Extrusion Reactions Affording Aromatic Systems, Dienes and Polyenes

Guziec

2022

Organic Reactions

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Extrusion reactions may be defined as chemical reactions in which an atom or small molecular fragment Y connected to two other atoms W and Z is lost from a molecule, leading to a product in which W becomes directly bonded to Z. Cheletropic reactions that afford aromatic or conjugated π systems by loss of a stable atomic or molecular fragment have also been classified as extrusion reactions. Typically, the fragments liberated in these reactions are small, stable inorganic molecules or atoms such as carbon monoxide, carbon dioxide, sulfur, sulfur monoxide, sulfur dioxide, selenium, tellurium, oxygen and nitrogen. This chapter primarily deals with the synthesis of arenes, heterocycles, 1,3‐dienes and polyenes using such extrusion processes. The utility of these reactions in the synthesis of sterically hindered molecules, dendrimers, pheromones, and other natural products are highlighted. The use of extrusion reactions for the “Click and Release” approach in drug development is also introduced.

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Steric and Electronic Effects on an Antibody‐Catalyzed Diels–Alder Reaction

Cited by 7 publications

References 30 publications

Enzyme Mimics: Advances and Applications

Enzyme Mimics: Advances and Applications

Immunological Optimization of a Generic Hydrophobic Pocket for High Affinity Hapten Binding and Diels–Alder Activity

Extrusion Reactions Affording Aromatic Systems, Dienes and Polyenes

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