Stereocontrolled Organocatalytic Strategy for the Synthesis of Optically Active 2,3‐Disubstituted cis‐2,3‐Dihydrobenzofurans

An intramolecular, organocatalyzed Michael addition has been developed to obtain biologically important 2,3‐disubstituted cis‐2,3‐dihydrobenzofurans. By using mandelic acid salts of primary aminocatalysts, derived from cinchona alkaloids, the intramolecular cyclization reaction has been developed to proceed in high yield, with moderate to good diastereoselectivity, and up to 99 % ee. Based on the absolute configuration of the formed 2,3‐disubstituted‐cis‐2,3‐dihydrobenzofurans and by considering the observed substrate scope restrictions, a mechanistic rationalization has been presented.     

Nouvelle Classe de Sucres a Liaison Osidique Stabilisee : 1-Desoxy-1,1,1-trifluoro-pent(hex)-2-uloses; Obtention de Quelques Derives

Abstract

L'hydrolyse acide des acétals et en particulier des osides fait intervenir un carbocation intermédiaire stabilisé par l'oxygène voisin; un substituant électroattracteur en α de l'atome d'oxygène ou de carbone d'un tel cation déstabilise cedernier et rend l'hydrolyse des acétals plus difficile. C'est ainsi que pour un 2-méthoxy-tétrahydropyrane, le remplacement en C-6 d'un groupement CH₂OH par CO₂Et¹ provoque une diminution de la vitesse d'hydrolyse d'un facteur de 200. Il est également bien connu que les 2-désoxy glycosides sont hydrolysés bien plus rapidement que leurs analogues 2-hydroxylés. Le même résultat est obtenu avec un atome d'halogène; c'est ainsi que Horton et coll.² en introduisant un atome d'iode en position 2′ d'analogues de la daunorubicine et de l'adriamycine ont pu augmenter leur efficacité in vivo. Compte tenu de la taille réduite de l'atome de fluor qui modifie peu l'encombrement de la molécule, plusieurs travaux ont été consacrés à l'introduction d'un fluor en position 2 d'osides pour ralentir leur vitesse d'hydrolyse in vivo. ^3-5 Cette même démarche a conduit d'autres auteurs à synthétiser des 2,2-difluorosucres.⁶ On pouvait donc envisager de remplacer l'hydrogène en C-1 de certains sucres par un groupement trifluorométhyle pour obtenir ainsi une nouvelle classe d'osides, dont la liaison osidique serait très stabilisée, ce qui devrait accroître leur durée de vie in vivo; on sait en effet ⁷ que les acétals de trifluorométhylcétones sont très difficiles à hydrolyser. Nous avons récemment décrit⁸ l'obtention des composés 1 et 9 et, on pouvait envisager de substituer l'hydroxyle anomérique de tels 2-uloses par divers nucléophiles. Les substitution nucléophiles en α d'un groupe CF₃ sont difficiles^9,10 et font en général intervenir un carbocation du type CF₃-C⁺R¹-XR² stabilisé par un hétéroatome X(O, S)^11-15 ou par un phényle.⁹ Ce carbocation est formé dans quelques cas par voie électrochimique,^14-15 mais, dans la plupart des travaux, il résulte soit de la rupture d'une liaison CR¹-Y assistée par un acide de Lewis soit de la solvolyse de cette liaison.⁹ Pour éviter l'emploi d'un acide de Lewis incompatible avec des groupes protecteurs acido-sensibles, nous avons mésylé l'hydroxyle anomérique pour obtenir un meilleur groupe partant. Nous décrivons dans cette note les résultats préliminaires obtenus principalement par action de divers nucléophiles sur ces mésylates.     

Carbon–chalcogen bond formation initiated by [Al(NONDipp)(E)]− anions containing Al–E{16} (E{16} = S,Se) multiple bonds

Multiply-bonded main group metal compounds are of interest as a new class of reactive species able to activate and functionalize a wide range of substrates. The aluminium sulfido compound K[Al(NON^Dipp)(S)] (NON^Dipp = [O(SiMe₂NDipp)₂]²⁻, Dipp = 2,6-ⁱPr₂C₆H₃), completing the series of [Al(NON^Dipp)(E)]⁻ anions containing Al–E{16} multiple bonds (E{16} = O, S, Se, Te), was accessed via desulfurisation of K[Al(NON^Dipp)(S₄)] using triphenylphosphane. The crystal structure showed a tetrameric aggregate joined by multiple K⋯S and K⋯π(arene) interactions that were disrupted by the addition of 2.2.2-cryptand to form the separated ion pair, [K(2.2.2-crypt)][Al(NON^Dipp)(S)]. Analysis of the anion using density functional theory (DFT) confirmed multiple-bond character in the Al–S group. The reaction of the sulfido and selenido anions K[Al(NON^Dipp)(E)] (E = S, Se) with CO₂ afforded K[Al(NON^Dipp)(κ²E,O-EC{O}O)] containing the thio- and seleno-carbonate groups respectively, consistent with a [2 + 2]-cycloaddition reaction and C–E bond formation. An analogous cycloaddition reaction took place with benzophenone affording compounds containing the diphenylsulfido- and diphenylselenido-methanolate ligands, [κ²E,O-EC{O}Ph₂]²⁻. In contrast, when K[Al(NON^Dipp)(E)] (E = S, Se) was reacted with benzaldehyde, two equivalents of substrate were incorporated into the product accompanied by formation of a second C–E bond and complete cleavage of the Al–E{16} bonds. The products contained the hitherto unknown κ²O,O-thio- and κ²O,O-seleno-bis(phenylmethanolate) ligands, which were exclusively isolated as the cis-stereoisomers. The mechanisms of these cycloaddition reactions were investigated using DFT methods.

Reaction of Al–E (E = S, Se) multiple bonds with C O functionalities generates new C–E bonds.     

Organocatalytic Asymmetric Formation of Steroids

A novel and simple one‐step approach for the construction of optically active steroids in a highly stereoselective manner by using organocatalysis is presented. The reaction of (di)enals with cyclic dienophiles in the presence of a TMS‐protected prolinol catalyst leads to the construction of important 14 β‐steroids. This new reaction allows an easy access to optically active steroids with a variety of substituents in the A ring in high yields and up to greater than 99 % ee. The reaction has been extended to include the construction of B‐ and D ‐homosteroids as well as steroids containing heteroatoms in the B ring. The angular substituent at C13 can be varied and alkyl, ester, and sulfone functionalities are introduced with excellent stereoselectivities. Simple synthetic procedures provide access to a range of naturally occurring steroids such as estrone and related analogues.     

Organocatalytic enantioselective nucleophilic vinylic substitution by alpha-substituted-alpha-cyanoacetates under phase-transfer conditions

The organocatalytic enantioselective formation of vinyl-substituted all-carbon quaternary stereocenters via nucleophilic vinylic substitution by alpha-substituted-alpha-cyanoacetates is presented. The reaction proceeds well for different alpha-substituted-alpha-cyanoacetates and beta-chloroalkenones using a dimeric cinchona alkaloid phase-transfer catalyst giving the products in good yield and with enantioselectivities up to 98% ee.     

Hydrogen‐Bonding in Aminocatalysis: From Proline and Beyond

This Concept article summarizes recent progress in the field of hydrogen‐bonding aminocatalysis using proline‐derived systems. The aminocatalysts available in the literature are categorized by the incorporated hydrogen‐bonding scaffold and its mode of recognition. Both mono‐ and double‐hydrogen‐bonding motifs are discussed and examples of their application in asymmetric synthesis are given.     

Stereoselective Oxidative Bioconjugation of Amino Acids and Oligopeptides to Aldehydes

The first stereoselective, near-equimolar, and metal-free oxidative bioconjugation of amino acids and oligopeptides to aldehydes is presented. Based on a newly developed organocatalytic oxidative concept, the C-terminal and side-chain carboxylic acid functionalities of amino acids and oligopeptides are shown to couple in a stereoselective manner to α-branched aldehydes catalyzed by a chiral primary amine and a quinone as oxidizing agent. The oxidative coupling generally proceeds in high yield. For aspartic acid, selective coupling of the side-chain, or the C-terminal carboxylic acid, is demonstrated depending on the protection strategy. The stereoselective, oxidative bioconjugation concept is extended to a series of oligopeptides where coupling to carboxylic acid functionalities is presented. Bioorthogonal linker molecules for further functionalization are obtained by merging the oxidative coupling strategy with the click concept. It is demonstrated that the configuration of the new stereocenter is determined exclusively by the organocatalyst.     

Synthèse et étude conformationnelle de dioxa-1,3 aza-9 spiro[5,5]undecanes

Synthesis of the new l,3-dioxa-9-azaspiro[5.5]undecane ring, was realized by the scheme represented in Figure 2. Butyro-phenones 6 posses neuroleptic activity similar to that of halo-peridol. The pharmacological activity was reported in another publication (2). Conformational study of l,3-dioxa-9-azaspiro-[5.5]undecanes shows the existence of four conformations A, B, C and D, which are shown in Figure 4. The existence of these conformations depends on the nature of the substituents R and R' on the dioxane ring. Thus, in the compounds where R ≠ H, R' = H, the four conformations are possible with a preponderance of A and B. If R and R' are different from H only the conformation A is present in 99% concentration. Lastly, when R = R' = H, the four conformations are possible with equal population for the couple A, B and the couple C, D; the first couple predominating. The presence of a fluorophenylbutyric moiety on the piperidine nitrogen does not seem to stereochemically modify the heterocyclic group.     

Catalytic Asymmetric Oxidative γ‐Coupling of α,β‐Unsaturated Aldehydes with Air as the Terminal Oxidant

A novel concept for catalytic asymmetric coupling reactions is presented. Merging organocatalysis with single‐electron oxidation by using a catalytic amount of a copper(II) salt and air as the terminal oxidant, we have developed a highly stereoselective carbon–carbon oxidative coupling reaction of α,β‐unsaturated aldehydes. The concept relies on the generation of a dienamine intermediate, which is oxidized to an open‐shell activated species that undergoes highly selective γ‐homo‐ and γ‐heterocoupling reactions. In the majority of examples presented, only a single stereoisomer was formed.