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1. Catalytic undirected methylation of unactivated C(sp3)−H bonds suitable for complex molecules

Author

Jin-Fay Tan, Yi Cheng Kang, and John F. Hartwig

Subjects
Science
Abstract

Abstract In pharmaceutical discovery, the “magic methyl” effect describes a substantial improvement in the pharmacological properties of a drug candidate with the incorporation of methyl groups. Therefore, to expedite the synthesis of methylated drug analogs, late-stage, undirected methylations of C(sp3)−H bonds in complex molecules would be valuable. However, current methods for site-selective methylations are limited to activated C(sp3)−H bonds. Here we describe a site-selective, undirected methylation of unactivated C(sp3)−H bonds, enabled by photochemically activated peroxides and a nickel(II) complex whose turnover is enhanced by an ancillary ligand. The methodology displays compatibility with a wide range of functional groups and a high selectivity for tertiary C−H bonds, making it suitable for the late-stage methylation of complex organic compounds that contain multiple alkyl C−H bonds, such as terpene natural products, peptides, and active pharmaceutical ingredients. Overall, this method provides a synthetic tool to explore the “magic methyl” effect in drug discovery.

Published
2024
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8. Catalytic deconstruction of waste polyethylene with ethylene to form propylene

Author

Richard J. Conk, Steven Hanna, Jake X. Shi, Ji Yang, Nicodemo R. Ciccia, Liang Qi, Brandon J. Bloomer, Steffen Heuvel, Tyler Wills, Ji Su, Alexis T. Bell, and John F. Hartwig

Subjects
Multidisciplinary, Waste Management, Polyethylene, Polyenes, Alkenes, Ethylenes, Iridium, Silicon Dioxide, Carbon, Catalysis, Platinum
Abstract

The conversion of polyolefins to monomers would create a valuable carbon feedstock from the largest fraction of waste plastic. However, breakdown of the main chains in these polymers requires the cleavage of carbon–carbon bonds that tend to resist selective chemical transformations. Here, we report the production of propylene by partial dehydrogenation of polyethylene and tandem isomerizing ethenolysis of the desaturated chain. Dehydrogenation of high-density polyethylene with either an iridium-pincer complex or platinum/zinc supported on silica as catalysts yielded dehydrogenated material containing up to 3.2% internal olefins; the combination of a second-generation Hoveyda-Grubbs metathesis catalyst and [PdP( t Bu) 3 (μ-Br)] 2 as an isomerization catalyst selectively degraded this unsaturated polymer to propylene in yields exceeding 80%. These results show promise for the application of mild catalysis to deconstruct otherwise stable polyolefins.

Published
2022
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11. Discovery of the Azaserine Biosynthetic Pathway Uncovers a Biological Route for α‐Diazoester Production

Author

Devon Van Cura, Tai L. Ng, Jing Huang, Harry Hager, John F. Hartwig, Jay D. Keasling, and Emily P. Balskus

Subjects
Diazoesters, General Chemistry, General Medicine, Natural Products, Biosynthesis, Catalysis, Azaserine, N−N Bonds
Abstract

Azaserine is a bacterial metabolite containing a biologically unusual and synthetically enabling α-diazoester functional group. Herein, we report the discovery of the azaserine (aza) biosynthetic gene cluster from Glycomyces harbinensis. Discovery of related gene clusters reveals previously unappreciated azaserine producers, and heterologous expression of the aza gene cluster confirms its role in azaserine assembly. Notably, this gene cluster encodes homologues of hydrazonoacetic acid (HYAA)-producing enzymes, implicating HYAA in α-diazoester biosynthesis. Isotope feeding and biochemical experiments support this hypothesis. These discoveries indicate that a 2-electron oxidation of a hydrazonoacetyl intermediate is required for α-diazoester formation, constituting a distinct logic for diazo biosynthesis. Uncovering this biological route for α-diazoester synthesis now enables the production of a highly versatile carbene precursor in cells, facilitating approaches for engineering complete carbene-mediated biosynthetic transformations in vivo.

Published
2023
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15. Progress, Challenges, and Opportunities with Artificial Metalloenzymes in Biosynthesis

Author

Brandon J. Bloomer, Douglas S. Clark, and John F. Hartwig

Subjects
Biochemistry
Abstract

In this Perspective, we present progress, outstanding challenges, and opportunities for the incorporation of artificial metalloenzymes (ArMs) into biosynthetic pathways. We first explain discoveries within the field of ArMs that led to the potential inclusion of these enzymes in biosynthesis. We then describe the specific barriers that our laboratory, in collaboration with the laboratories of Keasling and Mukhopadhyay, addressed to establish a biosynthetic pathway containing an ArM. This biosynthesis produced an unnatural cyclopropyl terpenoid by combining heterologous production of the terpene with modification of its terminal alkene by an ArM built from a cytochrome P450. Finally, we describe the remaining challenges and opportunities related to the application of ArMs in synthetic biology.

Published
2022
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18. Palladium‐Catalyzed Aryldifluoromethylation of Aryl Halides with Aryldifluoromethyl Trimethylsilanes

Author

Kyoungmin Choi, Michael G. Mormino, Eric D. Kalkman, John Park, and John F. Hartwig

Subjects
Hydrocarbons, Fluorinated, General Medicine, Cobalt, Fluorine, General Chemistry, Ketones, Silanes, Ligands, Carbon, Catalysis, Sulfones, Methane, Palladium, Ethers
Abstract

Diaryl difluoromethanes are valuable targets for medicinal chemistry because they are bioisosteres of diaryl ethers and can function as replacements for diaryl methane, ketone, and sulfone groups. However, methods to prepare diaryl difluoromethanes are scarce, especially methods starting from abundant aryl halides. We report the Pd-catalyzed aryldifluoromethylation of aryl halides with aryldifluoromethyl trimethylsilanes (TMSCF

Published
2022
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19. In Praise of Basic Research as a Vehicle to Practical Applications: Palladium-Catalyzed Coupling to Form Carbon-Nitrogen Bonds

Author

Stephen L. Buchwald and John F. Hartwig

Subjects
Coupling, Carbon nitrogen, Computational chemistry, Chemistry, Basic research, media_common.quotation_subject, chemistry.chemical_element, General Chemistry, Praise, Article, Catalysis, media_common, Palladium
Abstract

Two groups’ research initiated to address two very different questions on problems of basic chemical research led, after much effort on catalyst development and studies of reaction mechanism, to the discovery and development of the coupling of amines with aryl halides in a practical fashion.

Published
2022

20. Ruthenium-Catalyzed, Chemoselective and Regioselective Oxidation of Polyisobutene

Author

John F. Hartwig, Adam Uliana, Katerina G. Malollari, and Liye Chen

Subjects
Chemistry, Regioselectivity, chemistry.chemical_element, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Combinatorial chemistry, Catalysis, 0104 chemical sciences, Ruthenium, Commodity plastics, Colloid and Surface Chemistry, Surface modification
Abstract

Polyolefins are important commodity plastics, yet their lack of functional groups limits their applications. The functionalization of C-H bonds holds promise for incorporating functionalities into polymers of ethylene and

Published
2021
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21. Site Selective Chlorination of C(sp 3 )−H Bonds Suitable for Late‐Stage Functionalization

Author

John F. Hartwig, Alexander Fawcett, M. Josephine Keller, and Zachary Herrera

Subjects
Active ingredient, 010405 organic chemistry, Halogenation, chemistry.chemical_element, General Chemistry, General Medicine, 010402 general chemistry, 01 natural sciences, Chloride, Combinatorial chemistry, Small molecule, Copper, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Functional group, polycyclic compounds, medicine, Molecule, Surface modification, medicine.drug
Abstract

C(sp3 )-Cl bonds are present in numerous biologically active small molecules, and an ideal route for their preparation is by the chlorination of a C(sp3 )-H bond. However, most current methods for the chlorination of C(sp3 )-H bonds are insufficiently site selective and tolerant of functional groups to be applicable to the late-stage functionalization of complex molecules. We report a method for the highly selective chlorination of tertiary and benzylic C(sp3 )-H bonds to produce the corresponding chlorides, generally in high yields. The reaction occurs with a mixture of an azidoiodinane, which generates a selective H-atom abstractor under mild conditions, and a readily-accessible and inexpensive copper(II) chloride complex, which efficiently transfers a chlorine atom. The reaction's exceptional functional group tolerance is demonstrated by the chlorination of >30 diversely functionalized substrates and the late-stage chlorination of a dozen derivatives of natural products and active pharmaceutical ingredients.

Published
2021
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22. Site-Selective Silver-Catalyzed C–H Bond Deuteration of Five-Membered Aromatic Heterocycles and Pharmaceuticals

Author

Adrian Tlahuext-Aca and John F. Hartwig

Subjects
Hydrogen, viruses, hydrogen isotope exchange, chemistry.chemical_element, 010402 general chemistry, complex mixtures, 01 natural sciences, Medicinal chemistry, Article, Catalysis, Organic molecules, Inorganic Chemistry, fluids and secretions, mental disorders, Site selective, C-H activation, deuteration, C h bond, 010405 organic chemistry, Organic Chemistry, silver catalyst, heteroarenes, General Chemistry, Chemical Engineering, 0104 chemical sciences, chemistry, C–H activation, Absorption (chemistry), Silver catalyst
Abstract

Catalytic methods for the direct introduction of hydrogen isotopes into organic molecules are essential to the development of improved pharmaceuticals and to the alteration of their absorption, distribution, metabolism, and excretion (ADME) properties. However, the development of homogeneous catalysts for selective incorporation of isotopes in the absence of directing groups under practical conditions remains a long-standing challenge. Here, we show that a phosphine-ligated, silver-carbonate complex catalyzes the site-selective deuteration of C–H bonds in five-membered aromatic heterocycles and active pharmaceutical ingredients that have been resistant to catalytic H/D exchange. The reactions occur with CH(3)OD as a low-cost source of the isotope. The silver catalysts react with five-membered heteroarenes lacking directing groups, tolerate a wide range of functional groups, and react in both polar and nonpolar solvents. Mechanistic experiments, including deuterium kinetic isotope effects, determination of kinetic orders, and identification of the catalyst resting state, support C–H bond cleavage from a phosphine-ligated, silver-carbonate intermediate as the rate-determining step of the catalytic cycle.

Published
2021
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23. Selective, Catalytic Oxidations of C–H Bonds in Polyethylenes Produce Functional Materials with Enhanced Adhesion

Author

Katerina G. Malollari, Adam Uliana, Phillip B. Messersmith, Liye Chen, John F. Hartwig, and Daniel L. Sanchez

Subjects
Ethylene, Chemistry, General Chemical Engineering, Biochemistry (medical), chemistry.chemical_element, 02 engineering and technology, General Chemistry, Adhesion, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Combinatorial chemistry, 0104 chemical sciences, Ruthenium, Catalysis, chemistry.chemical_compound, Commodity plastics, Monomer, Catalytic oxidation, Materials Chemistry, Environmental Chemistry, Surface modification, 0210 nano-technology
Abstract

Summary The synthesis of functional and processable polyethylenes from simple vinyl monomers with controlled molecular weights and architectures has been a grand challenge of polymer chemistry. Post-polymerization modification of the homopolymers of ethylene is attractive for this purpose but has been hampered by the lack of efficient methods for the selective functionalization of C–H bonds in polyolefins. We report the selective, catalytic oxidation of C–H bonds in commodity polyethylenes with varying molecular weights and architectures. Remarkably, the functionalized materials, even at low levels of functionalization, exhibit physical properties that are absent in unmodified polyolefins, such as strong adhesion and the ability to be painted with common waterborne latex paint. Such observations indicate that selectively modified polyethylenes as described here may help to transform existing commodity plastics into more valuable and potentially more sustainable materials.

Published
2021
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24. Ruthenium-Catalyzed Hydroamination of Unactivated Terminal Alkenes with Stoichiometric Amounts of Alkene and an Ammonia Surrogate by Sequential Oxidation and Reduction

Author

John F. Hartwig, Casey L. Olen, Senjie Ma, and Christopher K. Hill

Subjects
inorganic chemicals, Aminopyridines, chemistry.chemical_element, Chemical, Alkenes, 010402 general chemistry, 01 natural sciences, Biochemistry, Redox, Ruthenium, Article, Catalysis, Ammonia, chemistry.chemical_compound, Colloid and Surface Chemistry, Models, Coordination Complexes, Density Functional Theory, Amination, chemistry.chemical_classification, Chemistry, Alkene, General Chemistry, Combinatorial chemistry, 0104 chemical sciences, Models, Chemical, Chemical Sciences, Hydroamination, Oxidation-Reduction, Stoichiometry
Abstract

Hydroamination of alkenes catalyzed by transition-metal complexes is an atom-economical method for the synthesis of amines, but reactions of unactivated alkenes remain inefficient. Additions of N-H bonds to such alkenes catalyzed by iridium, gold, and lanthanide catalysts are known, but they have required a large excess of the alkene. New mechanisms for such processes involving metals rarely used previously for hydroamination could enable these reactions to occur with greater efficiency. We report ruthenium-catalyzed intermolecular hydroaminations of a variety of unactivated terminal alkenes without the need for an excess of alkene and with 2-aminopyridine as an ammonia surrogate to give the Markovnikov addition product. Ruthenium complexes have rarely been used for hydroaminations and have not previously catalyzed such reactions with unactivated alkenes. Identification of the catalyst resting state, kinetic measurements, deuterium labeling studies, and DFT computations were conducted and, together, strongly suggest that this process occurs by a new mechanism for hydroamination occurring by oxidative amination in concert with reduction of the resulting imine.

Published
2020
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25. Catalytic asymmetric addition of an amine N–H bond across internal alkenes

Author

Senjie Ma, Yumeng Xi, and John F. Hartwig

Subjects
Nitrogen, Phosphines, Aminopyridines, Chemistry Techniques, Synthetic, Alkenes, Iridium, Ligands, 010402 general chemistry, 01 natural sciences, Catalysis, Article, chemistry.chemical_compound, Ammonia, Amines, Amination, chemistry.chemical_classification, Multidisciplinary, 010405 organic chemistry, Chemistry, Alkene, Ligand, Aryl, Enantioselective synthesis, Combinatorial chemistry, 0104 chemical sciences, Catalytic cycle, Indicators and Reagents, Hydroamination, Phosphine, Hydrogen
Abstract

Hydroamination of alkenes, the addition of the N-H bond of an amine across an alkene, is a fundamental, yet challenging, organic transformation that creates an alkylamine from two abundant chemical feedstocks, alkenes and amines, with full atom economy1-3. The reaction is particularly important because amines, especially chiral amines, are prevalent substructures in a wide range of natural products and drugs. Although extensive efforts have been dedicated to developing catalysts for hydroamination, the vast majority of alkenes that undergo intermolecular hydroamination have been limited to conjugated, strained, or terminal alkenes2-4; only a few examples occur by the direct addition of the N-H bond of amines across unactivated internal alkenes5-7, including photocatalytic hydroamination8,9, and no asymmetric intermolecular additions to such alkenes are known. In fact, current examples of direct, enantioselective intermolecular hydroamination of any type of unactivated alkene lacking a directing group occur with only moderate enantioselectivity10-13. Here we report a cationic iridium system that catalyses intermolecular hydroamination of a range of unactivated, internal alkenes, including those in both acyclic and cyclic alkenes, to afford chiral amines with high enantioselectivity. The catalyst contains a phosphine ligand bearing trimethylsilyl-substituted aryl groups and a triflimide counteranion, and the reaction design includes 2-amino-6-methylpyridine as the amine to enhance the rates of multiple steps within the catalytic cycle while serving as an ammonia surrogate. These design principles point the way to the addition of N-H bonds of other reagents, as well as O-H and C-H bonds, across unactivated internal alkenes to streamline the synthesis of functional molecules from basic feedstocks.

Published
2020
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26. Mechanism of Ni-Catalyzed Oxidations of Unactivated C(sp3)–H Bonds

Author

Yehao Qiu and John F. Hartwig

Subjects
Alkane, chemistry.chemical_classification, Chemistry, Radical, Alcohol, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Medicinal chemistry, Decomposition, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Reactivity (chemistry), Selectivity, Alkyl
Abstract

The Ni-catalyzed oxidation of unactivated alkanes, including the oxidation of polyethylenes, by meta-chloroperbenzoic acid (mCPBA) occur with high turnover numbers under mild conditions, but the mechanism of such transformations has been a subject of debate. Putative, high-valent nickel-oxo or nickel-oxyl intermediates have been proposed to cleave the C-H bond, but several studies on such complexes have not provided strong evidence to support such reactivity toward unactivated C(sp3)-H bonds. We report mechanistic investigations of Ni-catalyzed oxidations of unactivated C-H bonds by mCPBA. The lack of an effect of ligands, the formation of carbon-centered radicals with long lifetimes, and the decomposition of mCPBA in the presence of Ni complexes suggest that the reaction occurs through free alkyl radicals. Selectivity on model substrates and deuterium-labeling experiments imply that the m-chlorobenzoyloxy radical derived from mCPBA cleaves C-H bonds in the alkane to form an alkyl radical, which subsequently reacts with mCPBA to afford the alcohol product and regenerate the aroyloxy radical. This free-radical chain mechanism shows that Ni does not cleave the C(sp3)-H bonds as previously proposed; rather, it catalyzes the decomposition of mCPBA to form the aroyloxy radical.

Published
2020
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27. Copper-Catalyzed Defluorinative Borylation and Silylation of gem-Difluoroallyl Groups

Author

Trevor W. Butcher, John F. Hartwig, and Jonathan Lee Yang

Subjects
Silylation, Chemistry, Organic Chemistry, Copper catalyzed, Organic chemistry, Stereoselectivity, Physical and Theoretical Chemistry, Biochemistry, Borylation
Abstract

Stereodefined (Z)-fluoroalkenes are bioisosteres of amides and synthetic precursors to value-added fluorinated compounds, but their stereoselective synthesis remains challenging. Herein, we report ...

Published
2020
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28. Palladium-Catalyzed Oxidative Dehydrosilylation for Contra-Thermodynamic Olefin Isomerization

Author

Tyler Wills, John F. Hartwig, Steven Hanna, and Trevor W. Butcher

Subjects
Olefin fiber, 010405 organic chemistry, Hydrosilylation, chemistry.chemical_element, General Chemistry, Oxidative phosphorylation, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Chain walking, Yield (chemistry), Polymer chemistry, Isomerization, Palladium
Abstract

We report a newly developed, palladium-catalyzed dehydrosilylation of terminal alkylsilanes that combines with chain-walking hydrosilylation to create a one-pot isomerization of internal olefins to...

Published
2020
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29. Diverse functionalization of strong alkyl C–H bonds by undirected borylation

Author

Sam He, Isaac Yu, Erik A. Romero, Raphael J. Oeschger, Christian Ehinger, John F. Hartwig, and Bo Su

Subjects
chemistry.chemical_classification, Multidisciplinary, chemistry.chemical_element, Substrate (chemistry), Chemical synthesis, Borylation, Article, Catalysis, Solvent, chemistry, Polymer chemistry, Iridium, Selectivity, Alkyl
Abstract

Speeding up borylation Catalytic borylation is the rare reaction that can selectively target stronger over weaker saturated carbon–hydrogen (C–H) bonds. However, the trade-off has been that the reaction is slow and requires high excess of the hydrocarbon. Oeschger et al. now report that the right ligand (2-methylphenanthroline) coordinated to iridium can accelerate the reaction by 50- to 80-fold. This rate enhancement enables selective borylation of primary C–H bonds with the hydrocarbon as limiting reagent. The reaction is also unusually selective for β-C–H bonds in saturated heterocycles. Science , this issue p. 736

Published
2020
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30. Mechanism of the Iridium-Catalyzed Silylation of Aromatic C–H Bonds

Author

John F. Hartwig and Caleb Karmel

Subjects
Steric effects, Molecular Structure, Silylation, Hydride, Phenanthroline, Aryl, chemistry.chemical_element, General Chemistry, Iridium, 010402 general chemistry, 01 natural sciences, Biochemistry, Medicinal chemistry, Article, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Coordination Complexes, Molecule, Organosilicon Compounds, Phenanthrolines
Abstract

Phenanthroline ligands and [Ir(cod)(OMe)](2) form complexes that catalyze the silylation of aromatic and aliphatic C–H bonds. However, no experimental data on the identity of complexes related to the mechanism of this process or the mechanisms by which they react to functionalize C–H bonds have been reported. Herein, we describe our studies on the mechanism of the iridium-catalyzed silylation of aryl C–H bonds. The resting state of the catalyst is an iridium disilyl hydride complex (phenanthroline)Ir(SiMe(OTMS)(2))(2)(H)(L), in which L varies with the arene and additives. An iridium disilyl hydride complex was isolated, characterized, and allowed to react with arenes to form aryl silanes. The kinetics of the reactions of electron-rich and electron-poor arenes showed that the rate-limiting step varies with the electronic properties of the arene. Computational studies on related iridium silyl complexes revealed that the high activity of iridium complexes containing sterically encumbered phenanthroline ligands is due to a change in the number of silyl groups bound to iridium between the resting state of the catalyst containing the hindered phenanthroline and that containing less-hindered phenanthroline.

Published
2020
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31. Copper‐Mediated Fluorination of Aryl Trisiloxanes with Nucleophilic Fluoride

Author

Daniel P. Schwinger, Philip Boehm, John F. Hartwig, and Ruth Dorel

Subjects
Steric effects, Silylation, 010405 organic chemistry, Aryl, Organic Chemistry, chemistry.chemical_element, Regioselectivity, General Chemistry, 010402 general chemistry, 01 natural sciences, Copper, Medicinal chemistry, Article, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Nucleophile, Functional group, Fluoride
Abstract

A method for the nucleophilic fluorination of heptamethyl aryl trisiloxanes to form fluoroarenes is reported. The reaction proceeds in the presence of Cu(OTf)(2) and KHF(2) as the fluoride source under mild conditions for a broad range of heptamethyltrisiloxyarenes with high functional group tolerance. The combination of this method with the silylation of aryl C–H bonds enables the regioselective fluorination of non-activated arenes controlled by steric effects following a two-step protocol.

Published
2020
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32. Contra-thermodynamic Olefin Isomerization by Chain-Walking Hydroboration and Dehydroboration

Author

Steven Hanna, Brandon Bloomer, Nicodemo R. Ciccia, Trevor W. Butcher, Richard J. Conk, and John F. Hartwig

Subjects
Chemical Sciences, Organic Chemistry, Physical and Theoretical Chemistry, Biochemistry, Article
Abstract

We report a dehydroboration process that can be coupled with chain-walking hydroboration to create a one-pot, contra-thermodynamic, short- or long-range isomerization of internal olefins to terminal olefins. This dehydroboration occurs by a sequence comprising activation with a nucleophile, iodination, and base-promoted elimination. The isomerization proceeds at room temperature without the need for a fluoride base, and the substrate scope of this isomerization is expanded over those of previous isomerizations we have reported with silanes.

Published
2022

33. Enantioselective hydroamination of unactivated terminal alkenes

Author

Senjie Ma, Yumeng Xi, Haoyu Fan, Sven Roediger, and John F. Hartwig

Subjects
General Chemical Engineering, Biochemistry (medical), Materials Chemistry, Environmental Chemistry, General Chemistry, Biochemistry, Article, Macromolecular and Materials Chemistry
Abstract

Asymmetric alkene hydroamination could be a direct route to valuable chiral amines from abundant feedstocks. However, most asymmetric hydroaminations have limited synthetic value because they require a large excess of alkene, occur with modest enantioselectivity, and proceed with limited tolerance of functional groups. We report an enantioselective, intermolecular hydroamination of unactivated terminal alkenes that occurs with equimolar amounts of alkene and amine, tolerates many functional groups, and occurs in high yield, with high enantioselectivity and turnover numbers. Mechanistic studies revealed factors, including reversibility of the addition, reversible oxidation of the product amine, competing isomerization of the alkene reactant, and unfavorable replacement of sacrificial ligands in standard catalyst precursors by the chiral bisphosphine, that needed to be addressed to achieve enantioselective N-H additions to alkenes.

Published
2022

34. Directed Evolution of Artificial Metalloenzymes in Whole Cells

Author

Yang Gu, Brandon J. Bloomer, Zhennan Liu, Reichi Chen, Douglas S. Clark, and John F. Hartwig

Subjects
Hemeprotein, Operon, Stereochemistry, Mutant, whole cell, Article, Catalysis, Cofactor, chemistry.chemical_compound, Rare Diseases, artificial metalloenzymes, N-H insertion, Metalloproteins, directed evolution, Heme, N−H insertion, chemistry.chemical_classification, Amino esters, biology, Chemistry, Organic Chemistry, General Medicine, General Chemistry, Directed evolution, Enzyme, Chemical Sciences, biology.protein, P450, Biotechnology
Abstract

Artificial metalloenzymes (ArMs), created by introducing synthetic cofactors into protein scaffolds, are an emerging class of catalyst for non-natural reactions. Although many classes of ArMs are known, in vitro reconstitution of cofactors and proteins has been a limiting step in the high-throughput screening and directed evolution of ArMs because purification of individual host proteins is time-consuming. We describe the application of a platform to combine mutants of the P450 enzyme CYP119 and the cofactor Ir(Me)MPIX in vivo, by coexpression of the CYP119 mutants with the heme transporter encoded by the hug operon, to the directed evolution of ArMs containing Ir(Me)MPIX in whole cells. We applied this platform to the development an ArMs catalyzing the insertion of the acyclic carbene from a-diazopropanoate esters (Me-EDA) into the N-H bonds of N -alkyl anilines, a combination of carbene and amine classes for which mutant enzymes of natural hemoproteins previously reacted with low enantioselectivity. The mutants of the artificial metalloenzyme Ir(Me)CYP119 identified by an evolution campaign involving more than 4000 mutants are shown to catalyze the reaction of Me-EDA with N -methyl anilines to form chiral chiral amino esters with high TON and good enantioselectivity, thereby demonstrating that the directed evolution of ArMs can rival that of natural enzymes in vivo. .

Published
2021
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35. Development of Chiral Ligands for the Transition‐Metal‐Catalyzed Enantioselective Silylation and Borylation of C−H Bonds

Author

John F. Hartwig and Bo Su

Subjects
Boron Compounds, Solid-state chemistry, Molecular Structure, Silylation, Chemistry, Silicon Compounds, Enantioselective synthesis, Stereoisomerism, General Medicine, General Chemistry, Ligands, Combinatorial chemistry, Borylation, Article, Catalysis, Transition metal, Transition Elements
Abstract

Enantioselective reactions that install functional groups at the positions of unactivated C–H bonds can be envisioned to produce intermediates for the synthesis of the active ingredients in pharmaceuticals and agrochemicals directly from simple feedstocks. Among these C–H bond functionalization reactions, those that form carbon–silicon (C–Si) and carbon–boron (C–B) bonds have been pursued because the products of these reactions can be converted to those containing a wide range of functional groups and because compounds containing silicon and boron possess unique properties that can be valuable for medicinal and materials chemistry. Although the silylation and borylation of C–H bonds have undergone extensive development during the past two decades, enantioselective versions of these reactions were not known until a few years ago. In this Minireview, we present the rapid development of enantioselective silylation and borylation of C–H bonds, with an emphasis on the design and development of the types of chiral ligands needed to achieve these reactions and an intention to inspire an expansion of these types of transformations.

Published
2021
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36. Transition‐Metal‐Catalyzed Monofluoroalkylation: Strategies for the Synthesis of Alkyl Fluorides by C−C Bond Formation

Author

Trevor W. Butcher, Willi M. Amberg, and John F. Hartwig

Subjects
chemistry.chemical_classification, chemistry.chemical_element, General Medicine, General Chemistry, Organofluorine chemistry, Catalysis, chemistry.chemical_compound, Transition metal, chemistry, Nucleophile, Electrophile, Fluorine, Organic chemistry, Radical fluorination, Alkyl
Abstract

Alkyl fluorides modulate the conformation, lipophilicity, metabolic stability, and pKa of compounds containing aliphatic motifs and, therefore, have been valuable for medicinal chemistry. Despite significant research in organofluorine chemistry, the synthesis of alkyl fluorides, especially chiral alkyl fluorides, remains a challenge. Most commonly, alkyl fluorides are prepared by the formation of C-F bonds (fluorination), and numerous strategies for nucleophilic, electrophilic, and radical fluorination have been reported in recent years. Although strategies to access alkyl fluorides by C-C bond formation (monofluoroalkylation) are inherently convergent and complexity-generating, they have been studied less than methods based on fluorination. This Review provides an overview of recent developments in the synthesis of chiral (enantioenriched or racemic) secondary and tertiary alkyl fluorides by monofluoroalkylation catalyzed by transition-metal complexes. We expect this contribution will illuminate the potential of monofluoroalkylations to simplify the synthesis of complex alkyl fluorides and suggest further research directions in this growing field.

Published
2021
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37. Mechanistic Investigation of the Iron-Catalyzed Azidation of Alkyl C(sp(3))─H Bonds with Zhdankin’s λ(3)-Azidoiodane

Author

Ruchira Chatterjee, Alexander Fawcett, John F. Hartwig, and Craig S. Day

Subjects
Models, Molecular, Radical, Iron, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, law.invention, Colloid and Surface Chemistry, law, Models, Polymer chemistry, Organometallic Compounds, Molecule, Electron paramagnetic resonance, Alkyl, chemistry.chemical_classification, Molecular Structure, 010405 organic chemistry, Substrate (chemistry), Molecular, Hydrogen Bonding, General Chemistry, 0104 chemical sciences, Homolysis, chemistry, Reagent, Chemical Sciences
Abstract

An in-depth study of the mechanism of the azidation of C(sp(3))─H bonds with Zhdankin’s λ(3)-azidoiodane reagent catalyzed by iron(II)(pybox) complexes is reported. Previously, it was shown that tertiary and benzylic C(sp(3))─H bonds of a range of complex molecules underwent highly site-selective azidation by reaction with a λ(3)-azidoiodane reagent and an iron(II)(pybox) catalyst under mild conditions. However, the mechanism of this reaction was unclear. Here, a series of mechanistic experiments are presented that reveal critical features responsible for the high selectivity and broad scope of this reaction. These experiments demonstrate the ability of the λ(3)-azidoiodane reagent to undergo I─N bond homolysis under mild conditions to form λ-iodanyl and azidyl radicals that undergo highly site-selective and rate-limiting abstraction of a hydrogen atom from the substrate. The resultant alkyl radical then combines rapidly with a resting state iron(III)-azide complex, which is generated by the reaction of the λ(3)-azidoiodane with the iron(II)(pybox) complex, to form the C(sp(3))─N(3) bond. This mechanism is supported by the independent synthesis of well-defined iron complexes characterized by cyclic voltammetry, X-ray diffraction, and EPR spectroscopy, and by the reaction of the iron complexes with alkanes and the λ(3)-azidoiodane. Reaction monitoring and kinetic studies further reveal an unusual effect of the catalyst on the rate of formation of product and consumption of reactants and suggest a blueprint for the development of new processes leading to late-stage functionalization of C(sp(3))─H bonds.

Published
2021

38. Direct Observation of Diastereomeric α-C-Bound Enolates during Enantioselective α-Arylations: Synthesis, Characterization, and Reactivity of Arylpalladium Fluorooxindole Complexes

Author

Eric D. Kalkman and John F. Hartwig

Subjects
Models, Molecular, SEGPHOS, Molecular Structure, Stereochemistry, Aryl, Diastereomer, Enantioselective synthesis, Stereoisomerism, General Chemistry, Biochemistry, Catalysis, Reductive elimination, Stereocenter, Oxindoles, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Coordination Complexes, Stereoselectivity, Enantiomer, Density Functional Theory, Palladium
Abstract

The Pd-catalyzed asymmetric α-arylation of carbonyl compounds is a valuable strategy to form benzylic stereocenters. However, the origin of the stereoselectivity of these reactions is poorly understood, and little is known about the reactivity of the putative diastereomeric arylpalladium enolate intermediates. To this end, we report the synthesis and characterization of a series of diphosphine-ligated arylpalladium fluoroenolate complexes, including complexes bearing a metal-bound, stereogenic carbon and an enantioenriched chiral diphosphine ligand. These complexes reductively eliminate to form chiral α-aryl-α-fluorooxindoles with enantioselectivities and rates that are relevant to those of the catalytic process with SEGPHOS as the ancillary ligand. Kinetic studies showed that the rate of reductive elimination is slightly slower than the rate of epimerization of the intermediate, causing the reductive elimination step to impart the greatest influence on the enantioselectivity. DFT calculations of these processes are consistent with these experimental rates and suggest that the minor diastereomer forms the major enantiomer of the product. The rates of reductive elimination from complexes containing a variety of electronically varied aryl ligands revealed the unusual trend that complexes bearing more electron-rich aryl ligands react faster than those bearing more electron-poor aryl ligands. Noncovalent Interaction (NCI) and Natural Bond Orbital (NBO) analyses of the transition-state structures for reductive elimination from the SEGPHOS-ligated complexes revealed key donor-acceptor interactions between the Pd center and the fluoroenolate fragment. These interactions stabilize the pathway to the major product enantiomer more strongly than they stabilize that to the minor enantiomer.

Published
2021

39. Effects of ligands on the migratory insertion of alkenes into rhodium-oxygen bonds

Author

Sven Roediger, Casseday P. Richers, Victor Laserna, and John F. Hartwig

Subjects
chemistry.chemical_classification, Olefin fiber, Denticity, Alkene, Migratory insertion, chemistry.chemical_element, General Chemistry, Combinatorial chemistry, Oxygen, Rhodium, Catalysis, Chemistry, chemistry, Isomerization
Abstract

Migratory insertions of olefins into metal–oxygen bonds are elementary steps of important catalytic processes, but well characterised complexes that undergo this reaction are rare, and little information on the effects of ancillary ligands on such reactions has been gained. We report a series of alkoxo alkene complexes of rhodium(i) that contain a range of bidentate ligands and that undergo insertion of the alkene. Our results show that complexes containing less electron-donating ancillary ligands react faster than their counterparts containing more electron-donating ancillary ligands, and that complexes possessing ligands with larger bite angles react faster than those with smaller bite angles. External added ligands had several effects on the reactions, including an inhibition of olefin isomerisation in the product and acceleration of the displacement of the product from complexes of ancillary ligands with small bite angles. Complementary computational studies help elucidate the details of these insertion processes., A series of diphosphine-ligated rhodium(i) alkoxo alkene complexes is reported and the migratory insertion of the alkene moiety into the rhodium–oxygen bond in these complexes was studied, revealing the effects of the ligand on the insertion process.

Published
2021

40. Sequential Xanthalation and O-Trifluoromethylation of Phenols: A Procedure for the Synthesis of Aryl Trifluoromethyl Ethers

Author

Yajing Lian, Makoto Yoritate, John F. Hartwig, and Allyn T. Londregan

Subjects
Reaction conditions, Trifluoromethyl, 010405 organic chemistry, Chemistry, Trifluoromethylation, Aryl, Organic Chemistry, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Reagent, Molecule, Phenol, Organic chemistry, Phenols
Abstract

Molecules containing trifluoromethoxyaryl groups are of interest in pharmaceutical, agrochemical, and materials science research, due to their unique physical and electronic properties. Many of the known methods to synthesize aryl trifluoromethyl ethers require harsh reagents and highly controlled reaction conditions and rarely occur when heteroaromatic units are present. The two-step O-trifluoromethylation of phenols via aryl xanthates is one such method that suffers from these drawbacks. Herein, we report a method for the synthesis of aryl trifluoromethyl ethers from phenols by the facile conversion of the phenol to the corresponding aryl and heteroaryl xanthates with newly synthesized imidazolium methylthiocarbonothioyl salts and conversion of these xanthates to the trifluoromethyl ethers under mild reaction conditions.

Published
2019
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41. Palladium‐Catalyzed Amination of Aryl Halides

Author

Rebecca A. Green, Shashank Shekhar, Kevin H. Shaughnessy, and John F. Hartwig

Subjects
chemistry.chemical_compound, Chemistry, Aryl, chemistry.chemical_element, Halide, Oxidative addition, Medicinal chemistry, Phosphine, Amination, Reductive elimination, Catalysis, Palladium
Published
2019
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42. Site‐Selective Functionalization of (sp 3 )C−H Bonds Catalyzed by Artificial Metalloenzymes Containing an Iridium‐Porphyrin Cofactor

Author

Yang Gu, Zhennan Liu, Sean N. Natoli, John F. Hartwig, and Douglas S. Clark

Subjects
Steric effects, 010405 organic chemistry, Stereochemistry, chemistry.chemical_element, General Chemistry, 010402 general chemistry, 01 natural sciences, Porphyrin, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Biocatalysis, Structural isomer, Molecule, Iridium, Methylene
Abstract

The selective functionalization of one C-H bond over others in nearly identical steric and electronic environments can facilitate the construction of complex molecules. We report site-selective functionalizations of C-H bonds, differentiated solely by remote substituents, catalyzed by artificial metalloenzymes (ArMs) that are generated from the combination of an evolvable P450 scaffold and an iridium-porphyrin cofactor. The generated systems catalyze the insertion of carbenes into the C-H bonds of a range of phthalan derivatives containing substituents that render the two methylene positions in each phthalan inequivalent. These reactions occur with site-selectivity ratios of up to 17.8:1 and, in most cases, with pairs of enzyme mutants that preferentially form each of the two constitutional isomers. This study demonstrates the potential of abiotic reactions catalyzed by metalloenzymes to functionalize C-H bonds with site selectivity that is difficult to achieve with small-molecule catalysts.

Published
2019
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43. Iridium-catalyzed silylation of unactivated C–H bonds

Author

Erik A. Romero and John F. Hartwig

Subjects
Silylation, 010405 organic chemistry, Organic Chemistry, chemistry.chemical_element, Alcohol, 010402 general chemistry, 01 natural sciences, Biochemistry, Combinatorial chemistry, Article, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, chemistry, Docking (molecular), Intramolecular force, Drug Discovery, Surface modification, Amine gas treating, Iridium
Abstract

The functionalization of primary C-H bonds has been a longstanding challenge in catalysis. Our group has developed a series of silylations of primary C-H bonds that occur with site selectivity and diastereoselectivity resulting from an approach to run the reactions as intramolecular processes. These reactions have become practical by using an alcohol or amine as a docking site for a hydrosilyl group, thereby leading to intramolecular silylations of C-H bonds at positions dictated by the presence common functional groups in the reactants. Oxidation of the C-Si bond leads to the introduction of alcohol functionality at the position of the primary C-H bond of the reactant. The development, scope, and applications of these functionalization reactions is described in this minireview.

Published
2019
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44. Stereodivergent Construction of Tertiary Fluorides in Vicinal Stereogenic Pairs by Allylic Substitution with Iridium and Copper Catalysts

Author

John F. Hartwig, Zhi-Tao He, and Xingyu Jiang

Subjects
chemistry.chemical_classification, Allylic rearrangement, Enantioselective synthesis, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Medicinal chemistry, Catalysis, 0104 chemical sciences, Stereocenter, Colloid and Surface Chemistry, chemistry, Nucleophile, Chemical Sciences, Electrophile, Stereoselectivity, Alkyl, Vicinal
Abstract

Although much effort has been spent on the enantioselective synthesis of tertiary alkyl fluorides, the synthesis of compounds containing such a stereogenic center within an array of stereocenters, particularly two vicinal ones, remains a synthetic challenge, and no method to control the configuration of each stereogenic center independently has been reported. We describe a strategy to achieve such a stereodivergent synthesis of vicinal stereogenic centers, one containing a fluorine atom, by forming the connecting carbon-carbon bond with a catalyst system comprising an iridium complex that controls the configuration at the electrophilic carbon and a copper catalyst that controls the configuration at the nucleophilic fluorine-containing carbon. These reactions occur with alkyl- and aryl-substituted allylic esters and the unstabilized enolates of azaaryl ketones, esters, and amides in high yield, diastereoselectivity, and enantioselectivity (generally >90% yield, >20:1 dr, 97-99% ee). Access to all four stereoisomers of products demonstrates the precise control of the two configurations independently. This methodology extends to the stereodivergent construction of vicinal quaternary and tertiary stereocenters in similarly high yield and selectivity. DFT calculations uncover the origin of stereoselectivity of copper enolate in allylic substitution.

Published
2019
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45. A Multicatalytic Approach to the Hydroaminomethylation of α‐Olefins

Author

Jeffrey C. Holder, John F. Hartwig, and Steven Hanna

Subjects
Formates, chemistry.chemical_element, Alkenes, Iridium, 010402 general chemistry, Transfer hydrogenation, Methylation, 01 natural sciences, Reductive amination, Article, Catalysis, Rhodium, chemistry.chemical_compound, Coordination Complexes, Amines, Alkyl, Amination, chemistry.chemical_classification, Sulfonamides, Molecular Structure, 010405 organic chemistry, Sodium formate, Aryl, General Chemistry, General Medicine, Combinatorial chemistry, 0104 chemical sciences, chemistry, Hydrogenation, Hydroformylation
Abstract

We report an approach to conducting the hydroaminomethylation of diverse α-olefins with a wide range of alkyl, aryl, and heteroarylamines at low temperatures (70–80 °C) and pressures (1.0–3.4 bar) of synthesis gas. This approach is based on simultaneously using two distinct catalysts that are mutually compatible. The hydroformylation step is catalyzed by a rhodium diphosphine complex, and the reductive amination step, which is conducted as a transfer hydrogenation with aqueous, buffered sodium formate as the reducing agent, is catalyzed by a cyclometallated iridium complex. By adjusting the ratio of CO to H(2), we conducted the reaction at one atmosphere of gas with little change in yield. A diverse array of olefins and amines, including hetreroarylamines that do not react under more conventional conditions with a single catalyst, underwent hydroaminomethylation with this new system, and the pharmaceutical ibutilide was prepared in higher yield and under milder conditions than those reported with a single catalyst.

Published
2019
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46. Noble−Metal Substitution in Hemoproteins: An Emerging Strategy for Abiological Catalysis

Author

John F. Hartwig and Sean N. Natoli

Subjects
Hemeproteins, Chemistry Techniques, Synthetic, engineering.material, 010402 general chemistry, 01 natural sciences, Chemical synthesis, Chemical reaction, Catalysis, chemistry.chemical_compound, Molecular recognition, Metals, Heavy, Metalloproteins, Animals, Reactivity (chemistry), Organic Chemicals, 010405 organic chemistry, Substrate (chemistry), Stereoisomerism, General Medicine, General Chemistry, Archaea, Porphyrin, Combinatorial chemistry, 0104 chemical sciences, chemistry, engineering, Noble metal
Abstract

Enzymes have evolved to catalyze a range of biochemical transformations with high efficiencies and unparalleled selectivities, including stereoselectivities, regioselectivities, chemoselectivities, and substrate selectivities, while typically operating under mild aqueous conditions. These properties have motivated extensive research to identify or create enzymes with reactivity that complements or even surpasses the reactivity of small-molecule catalysts for chemical reactions. One of the limitations preventing the wider use of enzymes in chemical synthesis, however, is the narrow range of bond constructions catalyzed by native enzymes. One strategy to overcome this limitation is to create artificial metalloenzymes (ArMs) that combine the molecular recognition of nature with the reactivity discovered by chemists. This Account describes a new approach for generating ArMs by the formal replacement of the natural iron found in the porphyrin IX (PIX) of hemoproteins with noble metals. Analytical techniques coupled with studies of chemical reactivity have demonstrated that expression of apomyoglobins and apocytochrome P450s (for which "apo-" denotes the cofactor-free protein) followed by reconstitution with metal-PIX cofactors in vitro creates proteins with little perturbation of the native structure, suggesting that the cofactors likely reside within the native active site. By means of this metal substitution strategy, a large number of ArMs have been constructed that contain varying metalloporphyrins and mutations of the protein. The studies discussed in this Account encompass the use of ArMs containing noble metals to catalyze a range of abiological transformations with high chemoselectivity, enantioselectivity, diastereoselectivity, and regioselectivity. These transformations include intramolecular and intermolecular insertion of carbenes into C-H, N-H, and S-H bonds, cyclopropanation of vinylarenes and of internal and nonconjugated alkenes, and intramolecular insertions of nitrenes into C-H bonds. The rates of intramolecular insertions into C-H bonds catalyzed by thermophilic P450 enzymes reconstituted with an Ir(Me)-PIX cofactor are now comparable to the rates of reactions catalyzed by native enzymes and, to date, 1000 times greater than those of any previously reported ArM. This reactivity also encompasses the selective intermolecular insertion of the carbene from ethyl diazoacetate into C-H bonds over dimerization of the carbene to form alkenes, a class of carbene insertion or selectivity not reported to occur with small-molecule catalysts. These combined results highlight the potential of well-designed ArMs to catalyze abiological transformations that have been challenging to achieve with any type of catalyst. The metal substitution strategy described herein should complement the reactivity of native enzymes and expand the scope of enzyme-catalyzed reactions.

Published
2019
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47. Carbon(sp3)-nitrogen bond-forming reductive elimination from phosphine-ligated alkylpalladium(II) amide complexes: A DFT study

Author

Thomas R. Cundari, John F. Hartwig, D. Matthew Peacock, and Quan Jiang

Subjects
Steric effects, Ligand, Organic Chemistry, Substituent, chemistry.chemical_element, Biochemistry, Nitrogen, Medicinal chemistry, Reductive elimination, Solvent, chemistry.chemical_compound, chemistry, Amide, Drug Discovery, Phosphine
Abstract

DFT methods were employed to investigate C(sp3)-N bond-formation via reductive elimination from alkylpalladium(II) amide complexes. The hemi-lability of an ortho-methoxy substituent is computed to have minimal impact on reductive elimination barriers. In general, for both anilide and phosphine substituents, their steric impact is more substantial than electronic/Hammett factors. β-Hydrogen elimination is competitive with reductive elimination while β-methyl elimination is much less favorable. For phosphine-ligated Pd(II) amide complexes, the solvent impact on reductive elimination free energy barriers is small, and overall the substituent effects on either the phosphine or anilide ligand are subtle.

Published
2019
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48. Abiotic reduction of ketones with silanes catalysed by carbonic anhydrase through an enzymatic zinc hydride

Author

Yang Gu, Pengfei Ji, John F. Hartwig, Douglas S. Clark, and Jeeyoung Park

Subjects
General Chemical Engineering, Zinc hydride, Chemical, 010402 general chemistry, 01 natural sciences, Carbonic Anhydrase II, Article, Enzyme catalysis, Catalysis, chemistry.chemical_compound, Models, Carbonic anhydrase, Humans, Carbonic Anhydrases, chemistry.chemical_classification, Silanes, biology, 010405 organic chemistry, Hydride, Stereoisomerism, General Chemistry, Ketones, Combinatorial chemistry, 0104 chemical sciences, Molecular Docking Simulation, Zinc, Enzyme, Models, Chemical, chemistry, Biocatalysis, Alcohols, biology.protein, Oxidation-Reduction, Hydrogen, Protein Binding
Abstract

Enzymatic reactions through mononuclear metal hydrides are unknown in nature, despite the prevalence of such intermediates in the reactions of synthetic transition-metal catalysts. If metalloenzymes would react through abiotic intermediates like these, then the scope of enzyme-catalyzed reactions would expand. Here we show that zinc-containing carbonic anhydrase enzymes catalyze hydride transfers from silanes to ketones with high enantioselectivity and report mechanistic data providing strong evidence that the process involves a mononuclear zinc hydride. This work shows that abiotic silanes can act as reducing equivalents in an enzyme-catalyzed process and that monomeric hydrides of electropositive metals, which are typically unstable in protic environments, can be catalytic intermediates in enzymatic processes. Overall, this work bridges a gap between the types of transformations in molecular catalysis and biocatalysis., Graphical Abstract

Published
2021

49. Oxalohydrazide Ligands for Copper-Catalyzed C−O Coupling Reactions with High Turnover Numbers

Author

Ritwika Ray and John F. Hartwig

Subjects
inorganic chemicals, chemistry.chemical_element, 010402 general chemistry, Ligands, 01 natural sciences, Medicinal chemistry, Coupling reaction, Article, Catalysis, chemistry.chemical_compound, Pyrrole, Indole test, Molecular Structure, 010405 organic chemistry, Ligand, Aryl, General Chemistry, General Medicine, Copper, 0104 chemical sciences, Hydrazines, chemistry, Boronic acid, Ethers
Abstract

The development of nitrogen- and oxygen-based ligands for copper-catalyzed coupling reactions lags behind that of phosphines for analogous palladium-catalyzed coupling reactions. In particular, ligands that generate copper catalysts reacting with lifetimes resembling those of palladium catalysts have been lacking. Here, we report a class of ligands based on oxalohydrazide cores and N-amino pyrrole and N-amino indole units that generates long-lived copper catalysts for couplings that form the C–O bonds in biaryl ethers. These Cu-catalyzed coupling of phenols with aryl bromides occurred with turnovers up to 8000, a value which is nearly two orders of magnitude higher than those of prior couplings to form biaryl ethers and nearly an order of magnitude higher than those of any prior copper-catalyzed coupling of aryl bromides and chlorides. This ligand also led to copper systems that catalyze the coupling of aryl chlorides with phenols and the coupling of aryl bromides and iodides with primary benzylic and aliphatic alcohols. A wide variety of functional groups including nitriles, halides, ethers, ketones, amines, esters, amides, vinylarenes, alcohols and boronic acid esters were tolerated, and reactions occurred with aryl bromides in pharmaceutically related structures.

Published
2021

50. Direct Arylation of Simple Arenes with Aryl Bromides by Synergistic Silver and Palladium Catalysis

Author

Sarah Yunmi Lee, Adrian Tlahuext-Aca, John F. Hartwig, and Shu Sakamoto

Subjects
palladium and silver catalysts, 010405 organic chemistry, Aryl, direct arylation, Organic Chemistry, chemistry.chemical_element, General Chemistry, Chemical Engineering, 010402 general chemistry, 01 natural sciences, Combinatorial chemistry, Article, Catalysis, 0104 chemical sciences, Inorganic Chemistry, chemistry.chemical_compound, chemistry, Simple (abstract algebra), synergistic catalysis, Synergistic catalysis, C–H activation, aryl bromides, C-H activation, Palladium
Abstract

The direct, catalytic arylation of simple arenes in small excess with aryl bromides is disclosed. The developed method does not require the assistance of directing groups and relies on a synergistic catalytic cycle in which phosphine-ligated silver complexes cleave the aryl C-H bond, while palladium catalysts enable the formation of the biaryl products. Mechanistic experiments, including kinetic isotope effects, competition experiments, and hydrogen-deuterium exchange, support a catalytic cycle in which cleavage of the C-H bond by silver is the rate-determining step.

Published
2021

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