Expanding the scope of the nucleophile catalyzed aldol lactonization (NCALl) process and transformations of the resulting beta-lactones

Matla, Andrea Slava

15 May 2009

Expanding the uses of the NCAL and finding the spectrum of substrates best suited for such a transformation has been the main effort of my research. Previous studies had focused on aldedydes as the requisite functionality that would provide the needed electrophilicity in order to complete the aldol; however, recent advancements have introduced ketones as a viable carbonyl. With an established protocol in hand, I set out to explore various substrates that could yield Beta-lactones in good to moderate yields such as amino acid derivatives, diones, and large cyclic formations as well as simple, straight chain acids with varying groups Alpha to the ketone. In general, I was able to establish a basic framework of substrates that are highly and/or moderately susceptible towards the NCAL and current studies continue to further expand the scope. In addition to making Beta-lactones, I investigated alkyl cuprates as soft nucleophiles to afford addition at the Beta carbon yielding a variety of acids. Substrates for cuprate additions have been expanded to bulkier and multi-cyclic Beta-lactones and applied to the synthesis of a Merck IND intermediate. Additions to bi- and tri-chloro Beta-lactones due to the presence of the resulting moity in natural products are currently being studied.

beta-lactones

New Diazo Reagents and Applications of β-Lactones for Synthesis and Biological Evaluation of Natural Products

Chamni, Supakarn

2011 December 1900

Natural products are essential tools for basic cellular studies leading to the identification of medically relevant protein targets and the discovery of potential therapeutic agents. We have developed a set of second generation diazo reagents with small steric footprints, namely an alpha-trifluoroethyl (HTFB) diazo reagent, for simultaneous arming and SAR studies of bioactive natural products. The Rh(II)-catalyzed O-H insertions of several alcohol-containing natural products, including the potent translation inhibitor lactimidomycin, are investigated and useful reactivity and both chemo- and site- (chemosite) selectivities are observed. The alpha-trifluoroethyl diazo reagents (HTFB) shows clear differences in the IL-2 reporter assay with FK506 derivatives and provides greater retention of biological activity in a hMetAP2 proliferation assay of fumagillol derivatives compared to the first generation pbromophenyl diazo reagent (HBPA). The synthetic utilities of the new alpha-trifluoroethyl diazo reagent (HTFB) provide a great new tool for basic cellular studies facilitating the discovery of new drug candidates for human disease. Furthermore, we are interested in methodologies for beta-lactone synthesis and transformations. In this study, we demonstrated synthetic versatilities of beta-lactones for the synthesis of beta-lactam congeners of orlistat as fatty acid synthase inhibitors via SnCl4- promoted tandem Mukaiyama aldol-lactonization (TMAL) reaction and a one-pot, mild conversion of beta-lactones to beta-lactams. The inhibitory activities of the derived beta-lactam derivatives are determined in a biochemical fluorogenic assay using recombinant FASTE, and the micro-molar range FAS-TE inhibitory activities were observed. Additionally, we pursued synthetic studies toward the total synthesis of spongiolactone, which is a unique beta-lactone-containing marine diterpenoid, isolated from the marine sponge Spongionella gracilis. This natural product bears a unique tricyclic beta-lactone core possessing four contiguous stereogenic centers and an additional stereogenic quaternary carbon on a cyclohexyl appendage. We completed the total synthesis of 6,15-bis-epi-spongiolactone by employing an intramolecular nucleophilecatalyzed aldol-lactonization (NCAL) process as the key step to construct the fused tricyclic beta-lactone core. Importantly, we developed a double diastereoselective and, for the first time, a kinetic resolution via the NCAL process that enables an enantioselective strategy to the tricyclic beta-lactone core of (+)-spongiolactone.

β-lactone

β-lactam

diazo reagent

O-H insertion

Studies of Tricyclic β-lactams as Novel Antimicrobial Agents / 新規三環式β-ラクタム系抗生物質の探索研究

Sato, Jun

24 November 2023

京都大学 / 新制・論文博士 / 博士(工学) / 乙第13581号 / 論工博第4212号 / 新制||工||1990(附属図書館) / (主査)教授 松原 誠二郎, 教授 中尾 佳亮, 教授 浦山 健治 / 学位規則第4条第2項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

β-lactam antibiotic

tricyclic β-lactam

carbapenem-resistant Enterobacterale

β-lactamase

500

NITROGEN-LIGATED (POLY)CATIONIC IODINE(III) REAGENTS: PLATFORMS FOR REAGENT DEVELOPMENT AND DIVERSE HETEROCYCLIC SYNTHESES

Walters, Jennifer Caroll

January 2019

Hypervalent iodine (HVI) reagents are easily accessed, highly tunable, mild, selective oxidants that are less toxic and more environmentally benign compared to their heavy metal counterparts. λ3-Iodanes, which possess an iodine center bound to one aryl substituent and two heteroatom ligands, have been the subject of recent interest due to their electrophilicity and hypernucleofugality. A central focus of the Wengryniuk laboratory has been the further development and application of a class of electrostatically activated (bis)cationic nitrogen-ligated HVI (N-HVI) reagents. N-HVIs feature datively bound heterocyclic ligands which results in dramatically enhanced electrophilicity and redox potentials. Despite being a highly tunable platform for reagent development, N-HVIs remain a relatively underexplored class of λ3-iodanes. This dissertation focuses on demonstrating N-HVI’s synthetic potential and developing novel variants to enhance their synthetic utility. Chapter 1 of this dissertation serves as a general background and introduction to nitrogen-ligated HVI reagents. Chapter 2 outlines our efforts in N-HVI library expansion, novel syntheses, and characterization. With a library of 33 novel N-HVIs in hand, ligand effects on N-HVI reactivity were analyzed via qualitative and quantitative methods. Chapter 3 describes our first synthetic application of N-HVIs in the development of novel oxidative rearrangements of simple and complex cyclic alcohols. This chapter describes the chemoselective ring expansion of 2° and 3° cyclic alcohols accessing medium-sized cyclic acetal products in good to excellent yields with applicability to Complexity-to-Diversity (CTD) efforts. Chapter 4 demonstrates our initial efforts toward the development of another synthetic method where the functionalized N-heterocyclic ligands of the N-HVIs can be regioselectivity incorporated into a molecule following N-HVI activation of an olefin. The pyridinium lactone salts formed from olefinic acids were isolated in excellent yields via simple trituration, supplying a synthetically useful functional handle that was easily derivatized via known methods. These four chapters summarize the current state of the research with nitrogen-ligated HVI salts, expand upon our initial publications to highlight the development of novel heterocyclic syntheses, and provide a useful guide to further explore the reactivity of these tunable reagents. / Chemistry

Chemistry, Organic

Hypervalent Iodine

Iodine(iii)

Iodonium Salts

Nitrogen-ligated

Oxidative Rearrangement

Pyridinium Lactonization

Rapid Synthesis, Characterization, and Catalytic Function of Rhodium(III) and Iridium(III) Chloro-bridged Dimers

Brown, Loren

03 June 2019

Rh(III) and Ir(III) dimeric complexes with tunable cyclopentadienyl (Cp) rings have proven versatile for both catalysis and as synthetic precursors. An efficient microwave method to synthesize Rh(III) and Ir(III) dimeric complexes [(η5-ring)MCl]2(μ2-Cl)2, (where (η5-ring)MCl = (η5-Me4C5R)Rh(III)Cl or (η5-Me4C5R)Ir(III)Cl) was developed. A modular design for the substituted cyclopentadienes HC5Me4R was based on Grignard reactions of 2,3,4,5-tetramethylcyclopent-2-en-1-one (R = alkyl, 12 examples; R = aryl, 3 examples) or by SNAr reactions of potassium tetramethylcyclopentadienide with perfluoroarenes (R = perfluoroaryl, 3 examples). Reaction of the Me4CpHR ligands with [M(COD)](μ2-Cl)2 (M = Rh, Ir; COD = 1,5-cyclooctadiene) produced the dimeric complexes [Cp*RMCl]2(μ2-Cl)2 in moderate to excellent yield. The resulting dimers were characterized by nuclear magnetic resonance (NMR) spectroscopy, single-crystal X-ray diffraction (XRD), high-resolution mass spectrometry (HRMS), elemental analysis, and examined as catalysts for oxidative lactonization of 1,4- and 1,5-diols. Oxidative lactonization of 1,4-butanediol to afford γ-butyrolactone proceeded selectively and efficiently using [(η5-Me4C5R)IrCl]2(μ2-Cl)2 as the catalyst. Several R substituents were tested to assess electronic substituent effects. The most active complex contained an electron donating group, R = CHMe2 and successfully catalyzed the formation of diols to lactones across a range of 1,4- and 1,5-diols, generally in high yield. Computational analysis of the rate-determining b-hydrogen elimination reactions provided an atomistic account of observed trends in reaction yield and selectivity as a function of substrate structure, while accounting neatly for the observed selective formation of lactones (vs. succinaldehyde) in the transfer dehydrogenation of 1,4-butyrolactone. / Doctor of Philosophy / Rhodium(III) and iridium(III) complexes are useful synthetic precursors, catalysts, and biologically active compounds. This dissertation explores a rapid synthesis of these metal complexes and their subsequent catalytic applications with 1,4- and 1,5-diols. The oxidative lactonization of diols with rhodium and iridium complexes is an attractive one-pot synthesis, opening a variety of lactones to be produced. Structural studies involving novel fluorinated rhodium and iridium chloro-bridged dimers are discussed in detail.

iridium

rhodium

lactone

oxidative lactonization

transfer dehydrogenation

microwave synthesis

ligand effects

The use of candida antarctica lipase B for the synthesis of macrocycles and polymers based on natural products

Champagne, Élyse

08 1900

Les matériaux utilisés pour les applications biomédicales doivent être biocompatibles, et idéalement biodégradables. Les acides biliaires proviennent de sources naturelles et sont présents dans le corps humain. De plus, les polyetsers composés en partie de ces molécules possèdent des liens hydrolysables, une mémoire de forme thermique, et leur flexibilité peut être variée. Jusqu’à présent, la synthèse de ces matériaux exigeait l’utilisation de catalyseurs contenant des métaux de transition lourds pour l’étape de macrocyclisation. Puisque la polymérisation par ouverture de cycle nécessite des précurseurs cycliques, l’étape de lactonisation fut réalisée par voie enzymatique, au lieu d’utiliser des catalyseurs à plus grande toxicité. De plus, une seule étape enzymatique a pu remplacer deux étapes de synthèse organique, avec un rendement de 58 % et l’obtention d’un matériel transparent. Ces macrocycles nouvellement obtenus ont par la suite été polymérisés par ouverture de cycle, de façon similaire à la technique élaborée par notre groupe en 2013, tout en optimisant la durée de réaction. En 15 heures, une masse molaire relativement grande de 40 000 g/mol fut obtenue, tout en maintenant la dispersité sous 1.4 et la température de transition vitreuse à 12 °C. Pour valider le principe de cyclisation et de polymérisation enzymatique, les conditions optimales pour combiner l’acide thapsique et le 1,10-decanediol furent préalablement déterminées. Entre autres, la durée de réaction et la quantité d’enzyme nécessaire furent analysées. Les polymères semi-crystallins obtenus possèdent aussi de grandes masses molaires et de basses dispersités. Or, il est possible d’utiliser un enzyme à la fois pour la fermeture et pour l’ouverture de cycle de molécules rigides à cœur stéroïdal, telles que les acides biliaires. Cette synthèse permet la production de matériaux plus biocompatibles, tout en favorisant plusieurs principes de chimie verte. / Materials used in biomedical applications need to be biocompatible and ideally biodegradable. Bile acids are natural occurring compounds found in humans, and their polyesters possess hydrolyzable bonds, thermal shape memory and tunable flexibility. Until now, the synthetic pathway to obtain such materials required transition metal catalysts for the macrocyclization step, which is necessary to perform ring-opening polymerization (ROP). To circumvent the need for such catalysts, enzymatic ring closing was performed using lipases. Conveniently, two synthetic steps were replaced with a single step, using a renewable and reusable catalyst, with 58 % yield and a colorless product. The bile acid-containing macrocycles were then enzymatically polymerized as described in our previous work, while optimizing the reaction time. In 15 hours, relatively high Mw of 40 000 g/mol were obtained, while maintaining the dispersity ≤ 1.4 and a glass transition temperature of about 12 °C. As a proof-of-concept, conditions for the enzymatic ring closure of thapsic acid with 1,10-decanediol were determined beforehand. While optimizing for enzyme amount and reaction time, enzymatic ROP conditions to obtain di- and tetralactones from these monomers were established. The resulting semi-crystalline polymers also possess relatively high molecular weight and low dispersity. Hence, the use of lipases for both ring-closing and ring-opening reactions now shows potential for large, rigid moieties in addition to more mobile structures, using the same enzyme. This is a step towards the production of more biocompatible polymers, with a synthetic pathway that follows many green chemistry principles.

Lipases

Lactonization

Polymérisation par ouverture de cycle

Acides biliaires

Green chemistry

Chimie verte

Bile acids

Ring-opening polymerization

Développement de réactions énantiosélectives organocatalysées pour la synthèse de molécules cycliques énantioenrichies / Development of asymmetric organocatalyzed reactions for the synthesis of enantioenriched cyclic molecules

Gelis, Coralie

23 November 2018

Le développement de méthodes de synthèse asymétrique est très important pour l’accès à des molécules à visées thérapeutiques. Dans ce contexte, nous nous sommes intéressés à l’utilisation d’organocatalyseurs chiraux pour la synthèse de molécules cycliques énantioenrichies. Dans une première partie sont présentées des réactions de cycloadditions formelles (3+2), (4+2) et (4+3) à partir d’ènecarbamates ou de diènecarbamates catalysées par des acides phosphoriques chiraux. Ces derniers étant bifonctionnel, ils permettent l’activation des deux partenaires de cycloaddition menant à la synthèse d’indolines, de 2,3-dihydrobenzofuranes, de benzoquinones carbonannulées, de cyclohepta[b]indoles et de tétrahydroquinolines de façon hautement stéréosélective. Dans une seconde partie, nous nous sommes intéressés à l’utilisation de composés d’iode hypervalent chiraux comme organocatalyseurs. En effet, ces composés présentent une réactivité intéressante tout en étant stable et faiblement toxique. Ainsi, leur utilisation dans une réaction de lactonisation à partir de substrats flexibles a permis l’obtention de divers hétérocycles avec de bons résultats. / The development of new enantioselective methodologies is essential for the synthesis of bioactive compounds. In this context, we were interested in using organocatalysts for the synthesis of enantioenriched cyclic molecules. In a first part will be describe chiral phosphoric acid catalyzed (3+2), (4+2) and (4+3) formal cycloadditions using enecarbamate or dienecarbamate. These catalysts are bifunctional and can interact with both cycloaddition partners leading to the synthesis of 2,3-dihydrobenzofuranes, carboannulated benzoquinones, cyclohepta[b]indoles and tetrahydroquinolines with high stereocontrol. In a second phase, we were interested in using chiral hypervalent iodine as organocatalyst. Theses compounds present interesting reactivity while being stable and not very toxic. Their use permits us to develop a lactonisation starting from flexible substrate and led to the synthesis of various heterocycles with good results.

Organocatalyse asymétrique

Acides phosphoriques chiraux

Cycloadditions formelles

Iode Hypervalent Chiral

Lactonisation

Asymmetric organocatalysis

Chiral phosphoric acids

Formal cycloadditions

Chiral Hypervalent Iodine

Lactonization