DOI:
10.1039/D1QO00703C
(Research Article)
Org. Chem. Front., 2021,
8, 5092-5097
Copper-catalyzed [3 + 2]/[3 + 2] carboannulation of dienynes and arylsulfonyl chlorides enabled by Smiles rearrangement: access to cyclopenta[a]indene-fused quinolinones†
Received
4th May 2021
, Accepted 11th July 2021
First published on 13th July 2021
Abstract
On one hand, the construction of two fused five-membered carbocyclic rings remains an extremely challenging topic in organic synthesis. On the other hand, transition-metal-catalyzed dienyne cycloaddition reactions have become one of the most powerful methods for the construction of diverse cyclic frameworks. Nevertheless, these methods are limited to noble transition-meal catalysis and non-radical cycloaddition modes. Here, a radical Smiles rearrangement strategy for allowing an unprecedented [3 + 2]/[3 + 2] carboannulation of dienynes with arylsulfonyl chlorides using cheap copper catalysis is described. This cascade method represents a novel cycloaddition mode for dienyne chemistry, which occurs by the sequence of addition of arylsulfonyl radical to a dienyne, a Smiles rearrangement and radical annulation to access cyclopenta[a]indene-fused quinolinones with excellent diastereoselectivity.
Introduction
Until now, the construction of two fused five-membered carbocyclic rings, especially with two vicinal chiral carbon atoms, has remained an extremely challenging topic in organic synthesis. Conventional methods often require multiple steps with low overall yields or the use of cyclopentane-based starting materials.1 Therefore, the development of one-pot strategies for directly accessing two fused five-membered carbocyclic frameworks is in great demand.
The cycloaddition reaction is well-known and recognized as one of the most powerful and straightforward methodologies for efficient access to cyclic compounds in a single step, often along with the generation of multiple diastereo-centers.2 In the past several decades, cycloaddition of dienynes (generally alkyne-tethered 1,3-dienes) has received considerable attention because this methodology is particularly appealing for rapid construction of diverse complex carbo- and hetero-cyclic structures, including the challenging seven- to nine-membered ring systems.3–6 Typical methodologies can be divided into three types of non-radical annulation modes (Scheme 1a), including (i) Diels–Alder reaction via intramolecular [4 + 2] cycloaddition/isomerization,4 (ii) intramolecular cycloisomerization/Cope rearrangement,5 and (iii) intermolecular [4 + 2 + n] annulation.6 However, these methods require expensive transition metal catalysts (such as Rh, Au, Pt, and Ni) and/or harsh thermal conditions. Although the last [4 + 2 + n] cycloaddition of dienynes with external n-atom units can readily incorporate functional groups as well as controllably tune the ring scaffolds and has been well investigated, the scope of external n-atom units (such as carbene units, alkyne, ethyl cyclopropylideneacetate, and boryl(isopropoxy)silane) is limited. To the best of our knowledge, approaches that employ dienynes to undergo cycloaddition with external x-atom units for the construction of five-membered carbocyclic frameworks, especially those including two carbocyclic rings in a single step, have never been reported. Thus, the development of novel dienyne cycloaddition modes, especially including mechanistically distinguishable strategies using inexpensive transition metal catalysis, to widely expand the dienyne applications is desirable.
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| Scheme 1 Annulation modes of dienynes. | |
The Smiles rearrangement has emerged as one of the most powerful methods for the formation of chemical bonds in synthesis, and has been applied to difunctionalization of unsaturated hydrocarbons (such as alkenes and alkynes) by releasing SO2 in recent years.7–11 In a pioneering study, the group of Nevado has reported a new Smiles rearrangement tactic for enabling the addition of various radicals across the CC bonds of N-(arylsulfonyl)acrylamides and their derivatives through radical addition/aryl migration/desulfonylation cascades to produce diverse N-heterocycles.8 However, these methods largely rely on tailored acryl sulfonamide motifs.8,9 Recently, Stephenson11a and Zhu11b–e made a significant breakthrough in the radical Smiles rearrangement to realize two-component difunctionalization of alkenes, in which external sulfonyl-based starting materials are converted to nitrogen- or sp3 hybridized carbon-center radicals, and then they undergo addition across the CC bonds and Smiles rearrangement cascades. On this basis, we envisioned that by the addition of the external sulfonyl radicals across the CC bonds of the dienynes would arise an unprecedented cycloaddition reaction for the construction of new cyclic systems.
Here, we report an unprecedented copper-catalyzed [3 + 2]/[3 + 2] carboannulation of dienynes with arylsulfonyl chlorides for diastereoselectively producing cyclopenta[a]indene-fused quinolinones (Scheme 1b). This method enables one-pot formation of four new C–C bonds in a single step via radical addition cyclization, Smiles rearrangement and annulation cascades, and represents a new dienyne annulation mode to form two fused five-membered carbocyclic rings in a single step.
Results and discussion
We commenced our studies with the reaction of N-methyl-2-methylene-N-(2-(phenylethynyl)phenyl)but-3-enamide 1a with 4-methylbenzenesulfonyl chloride 2a in the presence of copper catalysts (Table 1). After investigating various reaction parameters, we were pleased to find that the [3 + 2]/[3 + 2] carboannulation could be successfully achieved by a simple catalytic system composed of CuCl (10 mol%), Na2CO3 (3 equiv.), and mesitylene at 130 °C, leading to the formation of 3aa in 58% yield (entry 1). The structure of 3aa was clearly confirmed by X-ray crystallography. Other alternative copper catalysts, including monovalent (CuBr, Cu2O, and CuOAc) and bivalent copper salts (CuCl2), did not give better results (entries 2–5). Further examination of other bases, including K2CO3, K3PO4, NaOAc, and Cs2CO3, revealed that all of them were less effective than Na2CO3 (entries 6–9). Solvents were proved to have a vital effect on this reaction: using toluene derivatives such as o-xylene, m-xylene, and p-xylene as media could smoothly afford the target products, albeit with greatly reduced yields (entries 10–12). However, no desired product was observed when mesitylene was replaced by DMF as medium (entry 13). Finally, this reaction showed lower conversion efficiency on changing the reaction temperature to 120 °C or 140 °C (entries 14 and 15). Notably, we attempted to perform the reaction scaling up to 1 mmol of 1a, delivering the product 3aa in a 46% yield (entry 1).
Table 1 Optimization of reaction conditionsa
With the optimal reaction conditions identified, we set out to examine the substrate scope of this protocol with respect to arylsulfonyl chlorides. As shown in Scheme 2, a range of arylsulfonyl chlorides 2b–h were subjected to [3 + 2]/[3 + 2] carboannulation with aniline-linked conjugated dienynes 1a to furnish the desired products 3ab–ah in moderate yields. For example, benzenesulfonyl chloride could afford benzo[4,5]pentaleno[6a,1-c]quinolin-12-one 3ab in a 56% yield. Electron-donating methoxy and methyl substituted sulfonyl chlorides were also competent substrates, delivering the target products in 53% and 58% yields (3ac and 3ag). Importantly, halogen atom substituted sulfonyl chlorides at the para-position of the benzene ring were smoothly converted into products 3ad–af, which could provide a promising opportunity for further manipulation. Gratifyingly, the reaction of naphthalene-1-sulfonyl chloride 2h with 1a proceeded favorably, resulting in a 47% yield of 3ah.
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| Scheme 2 Variations of the arylsulfonyl chlorides (2). Reaction conditions: 1a (0.2 mmol), 2 (0.4 mmol), CuCl (20 mol%), Na2CO3 (3 equiv.), and mesitylene (2 mL) at 130 °C under a N2 atmosphere for 12 h; d.r. >20:1. | |
We next turned our attention to the investigation of the scope of aniline-linked conjugated dienynes 1. To our delight, the [3 + 2]/[3 + 2] carboannulation was applicable to a wide range of conjugated dienynes 1, thus furnishing the target products 3ba–ta in moderate yields (Scheme 3). Initially, the alkyne moiety of conjugated dienynes 1 was studied in detail. The reaction tolerated a variety of substrates 1b–i with different aromatic substituents (4-MeC6H4, 4-OMeC6H4, 4-FC6H4, 4-ClC6H4, 4-BrC6H4, 3-MeC6H4, 3-ClC6H4, and 2-ClC6H4) at the alkyne terminus, furnishing pentacyclic-fused quinolin-12-one 3ba–ia in moderate yields. The electronic and steric effects of substituents on the benzene ring had no significant influence on the cascade reaction. The heterocyclic thienyl group could also survive, delivering quinolin-12-one 3ja in 43% yield. Unfortunately, chain alkynes did not give the desired product 3ka. Afterward, we tested the variations in the aniline moiety. To our delight, various substituents such as electron-donating groups (Me and OMe) and electron-withdrawing groups (F, Cl, and Br) on the benzene ring were all well tolerated (3la–ra). When the methyl group on the nitrogen atom was replaced by a benzyl group, the anticipated product 3sa could be obtained in 63% yield.
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| Scheme 3 Variations of the dienynes (1). Reaction conditions: 1a (0.2 mmol), 2 (0.4 mmol), CuCl (20 mol%), Na2CO3 (3 equiv.), and mesitylene (2 mL) at 130 °C under a N2 atmosphere for 12 h; d.r. >20:1. | |
Several control experiments were carried out to explore if a radical process was involved in this reaction (Scheme 4). First, the formation of product 3aa was greatly suppressed when a stoichiometric amount of radical inhibitors such as TEMPO and BHT was added to the model reaction of 1a with 2a under the standard conditions (eqn (1) and (2)). 1,1-Diphenyl ethylene 4 and 4-methylbenzenesulfonyl chloride 2a were next subjected to the above optimal reaction conditions, leading to the generation of (2-tosylethene-1,1-diyl)dibenzene 5 in 36% yield (eqn (3)). These results indicated that the [3 + 2]/[3 + 2] carboannulation possibly involved a radical pathway, which was initiated by arylsulfonyl radicals generated from arylsulfonyl chlorides 2.
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| Scheme 4 Mechanistic experiments. | |
On the basis of the above results and previous reports,10 a possible mechanism for the [3 + 2]/[3 + 2] carboannulation protocol is presented in Scheme 5. Initially, the reaction is triggered by a single electron transfer process of 4-methylbenzenesulfonyl chloride and CuI species under heating and basic conditions, thus producing 4-methylbenzenesulfonyl radicals and CuII species. Subsequently, the addition of the 4-methylbenzenesulfonyl radical to the CC double bond of conjugated dienynes generates the allyl radical intermediate A, which continues to undergo a radical addition/annulation tandem reaction to form intermediate C. Then, the Smiles rearrangement of intermediate C, including ipso-cyclization, 1,4-arylmigration, and SO2-release, occurs to afford the alkyl radical intermediate E. The intramolecular radical addition to the vicinal benzene ring results in a cyclization of intermediate E to form intermediate F. Eventually, intermediate F undergoes a sequence of single electron oxidation with the CuII species and deprotonation to afford the desired fused pentacyclic product 3aa.
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| Scheme 5 Proposed mechanism of [3 + 2]/[3 + 2] carboannulation. | |
Conclusions
In summary, we have developed an unprecedented copper-catalyzed [3 + 2]/[3 + 2] carboannulation of dienynes with arylsulfonyl chlorides via a radical Smiles rearrangement strategy. In this protocol, arylsulfonyl radicals generated from readily available arylsulfonyl chlorides undergo a radical addition cyclization/Smiles rearrangement/ring closure sequence to achieve [3 + 2]/[3 + 2] carbocyclization of dienynes, thus providing cyclopenta[a]indene-fused quinolinone pentacyclic frameworks with excellent diastereoselectivity. Note that four C–C bonds can be formed by this complex radical cascade process. Further applications of the dienynes are still in progress in our laboratory.
Conflicts of interest
The authors declare no competing interests.
Acknowledgements
The authors thank the National Natural Science Foundation of China (No. 21625203, 21871126, 21901071 and 21971061) and the Science and Technology Planning Project of Hunan Province (2018TP1017) for financial support.
Notes and references
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Footnotes |
† Electronic supplementary information (ESI) available. CCDC 2059099. For ESI and crystallographic data in CIF or other electronic format see DOI: 10.1039/d1qo00703c |
‡
The authors contributed equally.
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