Polyunsaturated fatty acids (PUFAs) are important constituents in all organisms. They fulfil many functions, ranging from modulating the structure of membranes to acting as precursors of physiologically important molecules, such as the prostaglandins, which for a long time were the most prominent cyclic PUFA metabolites. However, since the beginning of the 1990s a large variety of cyclic metabolites have been discovered that form under autoxidative conditions in vivo to a much larger extent than do prostaglandins. These compounds--isoprostanes, neuroprostanes, phytoprostanes, and isofurans--proved subsequently to be ubiquitous in nature. They display a wide range of biological activities, and isoprostanes have become the currently most reliable indicators of oxidative stress in humans. In a relatively short time, the structural variety, properties, and applications of the autoxidatively formed cyclic PUFA derivatives have been uncovered.
Acceptor‐Substituted Ferrocenium Salts as Strong, Single‐Electron Oxidants: Synthesis, Electrochemistry, Theoretical Investigations, and Initial Synthetic Application
A series of mono- and 1,1'-diheteroatom-substituted ferrocene derivatives as well as acylated ferrocenes was prepared efficiently by a unified strategy that consists of selective mono- and 1,1'-dilithiation reactions and subsequent coupling with carbon, phosphorus, sulfur and halogen electrophiles. Chemical oxidation of the ferrocene derivatives by benzoquinone, 2,3-dichloro-5,6-dicyanobenzoquinone, AgPF(6), or 2,2,6,6-tetramethyl-1-oxopiperidinium hexafluorophosphate provided the corresponding ferrocenium salts. The redox potentials of the synthesized ferrocenes were determined by cyclic voltammetry, and it was observed that all new ferrocenium salts have stronger oxidizing properties than standard ferrocenium hexafluorophosphate. An initial application of selected derivatives in an oxidative bicyclization revealed that they mediate the transformation under considerably milder conditions than ferrocenium hexafluorophosphate. Quantum chemical calculations of the reduction potentials of the substituted ferrocenium ions were carried out by using a standard thermodynamic cycle that involved the gas-phase energetics and solvation energies of the contributing species. A remarkable agreement between theory and experiment was found: the mean average deviation amounted to only 0.030 V and the maximum deviation to 0.1 V. This enabled the analysis of various physical contributions to the computed reduction potentials of these ferrocene derivatives, thereby providing insight into their electronic structure and physicochemical properties.
Evolution of moth sex pheromone composition by a single amino acid substitution in a fatty acid desaturase
For sexual communication, moths primarily use blends of fatty acid derivatives containing one or more double bonds in various positions and configurations, called sex pheromones (SPs). To study the molecular basis of novel SP component (SPC) acquisition, we used the tobacco hornworm (Manduca sexta), which uses a blend of mono-, di-, and uncommon triunsaturated fatty acid (3UFA) derivatives as SP. We identified pheromone-biosynthetic fatty acid desaturases (FADs) MsexD3, MsexD5, and MsexD6 abundantly expressed in the M. sexta female pheromone gland. Their functional characterization and in vivo application of FAD substrates indicated that MsexD3 and MsexD5 biosynthesize 3UFAs via E/Z14 desaturation from diunsaturated fatty acids produced by previously characterized Z11-desaturase/conjugase MsexD2. Site-directed mutagenesis of sequentially highly similar MsexD3 and MsexD2 demonstrated that swapping of a single amino acid in the fatty acyl substrate binding tunnel introduces E/Z14-desaturase specificity to mutated MsexD2. Reconstruction of FAD gene phylogeny indicates that MsexD3 was recruited for biosynthesis of 3UFA SPCs in M. sexta lineage via gene duplication and neofunctionalization, whereas MsexD5 representing an alternative 3UFA-producing FAD has been acquired via activation of a presumably inactive ancestral MsexD5. Our results demonstrate that a change as small as a single amino acid substitution in a FAD enzyme might result in the acquisition of new SP compounds.fatty acid desaturase | Manduca sexta | sex pheromone biosynthesis | pheromone evolution | substrate specificity S ex pheromones (SPs) are a diverse group of chemical compounds that are central to mate-finding behavior in insects (1). Variation in SP composition between closely related species and among populations is well documented. Despite this variation, SPs are presumed to be under strong stabilizing selection, and thus the genetic mechanisms driving SP diversification represented an enigma (2). Research on SPs in moths (Insecta: Lepidoptera) helped establish the hypothesis of asymmetric tracking as a major driving force in SP diversification. In this scenario, abrupt changes in female SP composition via a shift in component ratio or the inclusion or loss of a component result in a distinct SP that attracts males with more broadly or differentially tuned SP preference (3). Assortative mating, the preferential mating of females producing a novel SP with males attracted to this SP, restricts gene flow between subpopulations with differing SP compositions. This can ultimately lead to speciation and fixation of novel communication channels (4). Work in insect models such as wasps (5), fruit flies (6), and especially moths (7-9) is helping uncover the genetic basis of SP diversification.In the majority of moth species, females use species-specific mixtures of SP components (SPCs) consisting of volatile fatty acid (FA) derivatives to attract conspecific males at long range. These SPCs are predominantly long-chain aliphatic (C12-C18) acetates, alcoh...
Lithium malonate enolates 4 or 13 are oxidized to the corresponding radicals by ferrocenium hexafluorophosphate (1) or CuCl2 (2). Trapping by TEMPO (5) to produce 6, dimerization to 7, or radical 5‐exo cyclizations are possible subsequent reaction steps following radical generation. The structure of the radical cyclization acceptor determines the outcome of the overall reaction sequence. Tertiary benzylic, alkyl, and α‐alkoxy radicals are oxidized by 1. The carbenium ions are stabilized by nucleophilic trapping or deprotonation to give compounds 14 and 18. Secondary alkyl and vinyl radicals are not oxidized and, in the absence of trapping reagents, form radical‐derived products. Radical 5‐exo cyclization of 13 induced by CuCl2 (2) was also efficient. At least for alkyl radicals, however, ligand transfer is the exclusive stabilization pathway, giving access to chloroalkylcyclopentane derivatives 21. Radical scavenging studies revealed that malonyl radical trapping is slow, so that 5‐exo cyclizations occurred. The cyclized radicals couple with TEMPO (5) to afford oxygenated cyclopentane derivatives 31, depending on the rate of radical SET oxidation. The reaction behavior of compounds 14, 22, 23, and 31 was investigated. Mechanistic issues are discussed and implications for synthetic planning are given.
Conspectus One of the constant challenges of synthetic chemistry is the molecular design and synthesis of nonionic, metal-free superbases as chemically stable neutral organic compounds of moderate molecular weight, intrinsically high thermodynamic basicity, adaptable kinetic basicity, and weak or tunable nucleophilicity at their nitrogen, phosphorus, or carbon basicity centers. Such superbases can catalyze numerous reactions, ranging from C–C bond formation to cycloadditions and polymerization, to name just a few. Additional benefits of organic superbases, as opposed to their inorganic counterparts, are their solubility in organic reaction media, mild reaction conditions, and higher selectivity. Approaching such superbasic compounds remains a continuous challenge. However, recent advances in synthetic methodology and theoretical understanding have resulted in new design principles and synthetic strategies toward superbases. Our computational contributions have demonstrated that the gas-phase basicity region of 350 kcal mol–1 and even beyond is easily reachable by organosuperbases. However, despite record-high basicities, the physical limitations of many of these compounds become quickly evident. The typically large molecular weight of these molecules and their sensitivity to ordinary reaction conditions prevent them from being practical, even though their preparation is often not too difficult. Thus, obviously structural limitations with respect to molecular weight and structural complexity must be imposed on the design of new synthetically useful organic superbases, but strategies for increasing their basicity remain important. The contemporary design of novel organic superbases is illustrated by phosphazenyl phosphanes displaying gas-phase basicities (GB) above 300 kcal mol–1 but having molecular weights well below 1000 g·mol–1. This approach is based on a reconsideration of phosphorus(III) compounds, which goes along with increasing their stability in solution. Another example is the preparation of carbodiphosphoranes incorporating pyrrolidine, tetramethylguanidine, or hexamethylphosphazene as a substituent. With gas-phase proton affinities of up to 300 kcal mol–1, they are among the top nonionic carbon bases on the basicity scale. Remarkably, the high basicity of these compounds is achieved at molecular weights of around 600 g·mol–1. Another approach to achieving high basicity through the cooperative effect of multiple intramolecular hydrogen bonding, which increases the stabilization of conjugate acids, has recently been confirmed. This Account focuses on our efforts to produce superbasic molecules that embody many desirable traits, but other groups’ approaches will also be discussed. We reveal the crucial structural features of superbases and place them on known basicity scales. We discuss the emerging potential and current limits of their application and give a general outlook into the future.
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