Isothiourea-Catalyzed [2 + 2] Cycloaddition of C(1)-Ammonium Enolates and N-Alkyl Isatins

Enantioselective [2 + 2] cycloaddition of C(1)-ammonium enolates generated catalytically using the isothiourea HyperBTM with N-alkyl isatins gives spirocyclic β-lactones. In situ ring opening with an amine nucleophile generates isolable highly enantioenriched products in up to 92:8 dr and in >99:1 er.

β-Lactones are versatile synthetic building blocks and significant components of many bioactive natural products. 1,2 As a consequence, a range of enantioselective synthetic methods for their preparation has been developed, with both Lewis acid and Lewis base catalyzed approaches common. 3 In terms of Lewis base catalysis using tertiary amines, the use of cinchona alkaloids and chiral DMAP derivatives has been extensively used to promote β-lactone formation through the generation of an intermediate C(1)-ammonium enolate. 4 Although versatile, these methods typically rely on the generation of reactive monosubstituted ketenes (formed in situ from acyl chlorides) or isolable but sensitive disubstituted ketenes as starting materials. 5 In an alternative approach, Romo introduced the NCAL (nucleophile-catalyzed aldollactonization) process to prepare β-lactones from keto-acids (Scheme 1a). 6 Key to this protocol was the development of carboxylic acids as the C(1)-ammonium enolate precursor, with a modified Mukaiyama reagent used for in situ generation of a reactive ester. Addition of either a cinchona alkaloid or isothiourea catalyst was used to generate the desired C(1)ammonium enolate, with subsequent intramolecular formal [2 + 2]-cycloaddition onto the pendant carbonyl giving highly enantioenriched β-lactones. Building on this work, we previously demonstrated the use of symmetric arylacetic anhydrides as alternative C(1)-ammonium enolate precursors. 7 These anhydrides are generally readily prepared from the parent carboxylic acid, are easy to handle, and can be used in conjunction with isothiourea catalysts without requiring the excess base that is a recognized limitation of alternative protocols using carboxylic acids as starting materials. This approach was applied to the HyperBTM-catalyzed enantioselective intermolecular formation of β-lactones with perfluoroalkyl ketones and arylacetic anhydrides (Scheme 1b). Mechanistic studies using natural abundance 13 C kinetic isotope effect experiments, together with computational analyses, indicated the operation of a concerted asynchronous [2 + 2] cycloaddition. 8 To date, the isothiourea-catalyzed intermolecular [2 + 2] cycloaddition approach has not been demonstrated using cyclic ketones as substrates; in this manuscript the application of N-protected isatins as electrophiles to initially generate spirooxindole β-lactones is investigated. 9 Attempted isolation of the β-lactones led to spontaneous decarboxylation, but postcatalysis addition of an amine nucleophile led to β-lactone ring opening to give isolable highly enantioenriched products (Scheme 1c). Mechanistic studies are consistent with in situ epimerization of the initially formed β-lactone, leading to a mixture of βhydroxy amide diastereoisomers in highly enantioenriched form (up to 92:8 dr, >99:1 er for both diastereoisomers).
Initial studies began with the reaction of (2R,3S)-HyperBTM 1 (5 mol %) with phenylacetic anhydride 2 and N-benzyl isatin 3, in CH 2 Cl 2 . Although β-lactone 5 could be observed by 1 H NMR spectroscopic analysis of the crude reaction product, attempted chromatographic purification resulted in the isolation of alkene 4 in 58% yield [66:34 (E)/(Z)], consistent with decarboxylation of β-lactone 5. 10 As an alternative, the crude reaction mixture was treated in situ with excess benzylamine (3.0 equiv) to give the isolable βhydroxyamide derivative 6 (76:24 dr). 11 Chromatographic purification gave the separable diastereoisomers in 81% combined yield and >99:1 er for each diastereomer (Scheme 2a). In situ formation of a mixed anhydride, using phenylacetic acid and pivaloyl chloride, and subsequent HyperBTMcatalyzed cycloaddition followed by ring opening led to slightly decreased levels of diastereoselectivity (69:31 dr, >99:1 er) and product yield (57%). Further attempted optimization through variation in catalyst, solvent, and reaction temperature gave no significant improvement in either product dr or yield (see Supporting Information (SI) for full information) with consistent high enantioselectivity observed. Intrigued by the observation that both product diastereoisomers were highly enantioenriched (>99:1 er), further investigations probed if the stereochemical outcome (76:24 dr, >99:1 er) was intrinsic to the catalyzed process, or alternatively a consequence of in situ epimerization of the β-lactone 5 or βhydroxyamide product 6. Control experiments showed that retreatment of a single diastereoisomer of β-hydroxyamide 6 (>95:5 dr, 99:1 er) to the reaction conditions, or with excess i Pr 2 NEt, led to no change in dr or er. In situ reaction monitoring at room temperature using 1 H NMR spectroscopy allowed the concentration and dr of β-lactone 5 to be quantified over the reaction course (Scheme 2b). After 10 min, a single diastereoisomer of β-lactone 5 (60% conversion of isatin 3) was observed, with the dr gradually reducing with time to 85:15 dr after 2 h (∼80% conversion). Extending the reaction time to 16 h gave the β-lactone 5 in 70:30 dr and reduced yield (70%) due to the observation of (E)/(Z) alkenes 4 from decarboxylation in the reaction mixture. These results are consistent with an initial highly stereoselective catalytic process giving β-lactone 5 in high diastereo-and enantioselectivity, with in situ epimerization giving a mixture of diastereoisomers. 12 To further probe this process, variation of the reaction time before addition of benzylamine, plus the use of alternative amine nucleophiles for derivatization, was investigated (Scheme 2c). At 0°C, addition of benzylamine after a 30-min reaction time gave product 6 in an improved 95:5 dr and >99:1 er but with reduced yield (36%) compared to the standard 3 h reaction time (81%, 76:24 dr, >99:1 er). The use of morpholine and pyrrolidine gave the corresponding products 7 and 8 respectively in uniformly excellent enantioselectivity (>99:1 er), but varying diastereoselectivity (85:15 and 68:32 dr respectively). The variation in dr presumably reflects competition between the basicity (promoting epimerization alongside i Pr 2 NEt) and nucleophilicity (promoting ring opening) of these amines and their relative reaction rates. Consistent with these observations, X-ray crystal structure analysis allowed the relative and absolute configuration of the product minor diastereoisomer 9 to be unambiguously determined (Scheme 2d). 13 The observed (S)-configuration at C(2) is opposite to that expected based Scheme 2. Optimization and β-Lactone Epimerization a a Yield of isolated products. Reported er of major diastereoisomer (er always >99:1 for minor diastereoisomer). 1 H NMR of the crude reaction product was used to determine dr. (b) 30 min reaction time before addition of amine; (c) 3 h reaction time before addition of amine.
Following these observations, the scope and limitations of this process were examined through variation of the isatin, anhydride, and ring-opening nucleophile reaction components ( Figure 1). Alternative N-substituents within the isatin were tolerated, with N-methyl, N-allyl protected isatins giving the corresponding products 10 and 11 in good yields and consistently high enantioselectivity (>99:1 er). Interestingly, using N-Boc protected isatin led to product 12 in >99:1 er as a result of ring opening of the β-lactone and the oxindole presumably facilitated by the N-Boc substituent. 15 Variation of the isatin component was expanded to incorporate 5-, 6-, and 7-substituted isatins, as well as variation of the N-substituent. Substitution at the 5-, 6-, and 7-position was consistently tolerated, with good product yields observed for both electron-withdrawing and electron-donating substituents, giving products 13−19 with excellent enantioselectivity (>99:1 er) and consistent diastereoselectivity (from 72:28 to 78:22 dr). Unfortunately, 4-substitution of the isatin was not tolerated, with 4-Cl isatin giving <10% conversion to products. The poor conversion in this case is ascribed to the spatial proximity to the reaction center, disfavoring nucleophilic addition.
A selection of anhydrides was next synthesized from the parent carboxylic acids and tested in this cycloaddition/ringopening process. Notably, incorporating the 4-MeOC 6 H 4substituent within the anhydride gave product 20 in 77% yield with 92:8 dr and >99:1 er. The higher dr (compared to 6) presumably reflects the electron-donating nature of the aryl substituent that reduces the acidity of the C(3)−H within the β-lactone intermediate. This effect was also observed for the 4-MeC 6 H 4 -substrate 21 (88:12 dr, >99:1 er). Halogencontaining phenylacetic anhydrides were tolerated, giving the corresponding products 22−24 in variable diastereoselectivity (from 69:31 to 83:17 dr) but with excellent enantiocontrol. A 1-naphthyl-derivative 25 was prepared in 50% yield and >99:1 er, while extension to a 3-thiophene derivative 26 was also tolerated (85:15 dr, >99:1 er). While the use of simple alkyl anhydride derivatives did not generate any product (see SI for further information), the use of an (E)-alkenyl substituent was tolerated, giving 27 in excellent yield, dr, and er (91%, >95:5 dr, >99:1 er) that was amenable to scale-up to 10 mmol scale, giving >4.1 g of product. Finally, five examples using morpholine as the derivatizing agent were demonstrated (7, 28−31). Generally, good yields and higher diastereocontrol were observed than in the corresponding benzylamides, with excellent enantiocontrol maintained (>99:1 er). Reduced yield was observed for the 5-chloro 30 and N-(para-tertbutylbenzyl) 31 derivatives, with the low solubility of 30 complicating the purification process.
Based upon these observations, alongside previous work in this area, a catalytic cycle is proposed (Figure 2). Initial addition of (2R,3S)-HyperBTM 1 to the phenylacetic anhydride 2 results in the formation of acyl ammonium ion pair 32. Deprotonation at C(2)-gives the corresponding (Z)ammonium enolate 33, 16 with a stabilizing 1,5-O···S chalcogen bonding interaction (n O to σ* S−C ) 17−19 providing a conformational bias and ensuring coplanarity between the 1,5-O-and Satoms. The observed product configuration is consistent with that observed in the related [2 + 2]-cycloaddition of C(1)ammonium enolates and trifluoromethylketones, 8 so by analogy a similar concerted asynchronous [2 + 2]-cycloaddition pathway via transition state assembly 34 to give 35 is proposed. Subsequent catalyst release generates the β-lactone 5 in high diastereo-and enantioselectivity. In situ epimerization of the lactone at C(3)-leads to a mixture of β-lactone diastereoisomers, with the subsequent addition of an amine nucleophile promoting ring opening to give the isolable βhydroxyamide products.

Organic Letters pubs.acs.org/OrgLett Letter
In summary, a procedure for the generation of highly enantioenriched β-hydroxyamides (>99:1 er) has been developed. This protocol involves the in situ preparation of β-lactones from isatins and 2-arylacetic anhydrides using the isothiourea HyperBTM 1 to promote a concerted asynchronous [2 + 2]-cycloaddition, followed by in situ ring opening with a nucleophile. Mechanistic studies suggest a basepromoted epimerization leads to a reduction in the diastereoselectivity of the initially formed β-lactone product, giving rise to a diastereoisomeric mixture of isolable products each in high er (>99:1 er). Further work from this laboratory is focused upon alternative application of isothioureas and other Lewis bases in enantioselective catalysis.
Full experimental procedures, characterization data, NMR spectra and HPLC chromatograms for all new compounds, as well as crystallographic data for 9 (CCDC 2153991) (PDF)