Abstract
The MoS2-catalyzed transamidation reaction with high yields using N,N-dimethylformamide and other amides as carbonyl sources is developed here. The protocol is simple, does not require any additive such as acid, base, ligand, etc., and encompasses a broad substrate scope for primary, secondary and heterocyclic amines. Moreover, the acetylation and propanylation of amines also can be achieved with good to excellent yield by this strategy.
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Introduction
Transamidation reaction is very important in organic synthesis chemistry1,2,3,4,5,6. And the amide framework is widely applied in medicines7,8,9,10, natural products11, and functional materials (Fig. 1)12. Several organic small molecules have been served as carbonyl sources in transamidation reactions, including DMF/DMA13,14,15,16,17,18,19,20,21,22,23,24, formic acid/formate25,26,27,28,29,30,31, methanol32,33,34,35,36, ester37,38,39,40,41, and others42,43. Among them, DMF is well known as a cheap and readily available industrial organic solvent. Additionally, DMF has also been widely applied as a source of dimethylamino, formyl, carbonyl, −CONMe2, and methyl44,45,46,47,48.
The catalyzed transamidation reactions using DMF as carbonyl source have been reported. Various catalysts, including metal catalysts, such as Ni13, Ce14, Fe15, Cu16, L-Proline17, Pd49 and metal-free catalysts, such as boronic acid18 and their derivatives19,20, and imidazole50 and its derivatives21 have been succeed in this transformation. However, these strategies are often suffered from drawbacks such as use of unreadily available and costly catalysts, large amount of catalyst, essential additives, limited scope, and etc.
Herein, a highly efficient MoS2-catalyzed transamidation reaction using DMF and other amides as carbonyl sources has been developed (Fig. 2). This method has advantages such as using inexpensive catalyst and reagents, no need for any other additives. Moreover, this strategy has a broad substrate scope that both primary and secondary amines with different groups are suitable for this reaction and good to excellent yields can be achieved. Particularly, acetylation and propanylation reaction using the corresponding amides as reagents could be achieved with almost the same good results as formylation reaction.
Results and Discussion
Initially, the transamidation of tetrahydroisoquinoline and DMF catalyzed by MoS2 was investigated as the model reaction (Fig. 3). Various reaction conditions were optimized, such as catalyst, temperature, reaction time, and atmosphere. The results showed the yield of desired product is very poor in the absence of Mo catalyst (entry 1). When MoS2 (12.5 mol%) and (NH4)2MoO4·4H2O (12.5 mol%) were used as catalyst, an excellent yield of 99% and 97% can be obtained, respectively (entries 2 and 3). Afterward, other metal salts, such as Fe(OAc)2·4H2O, Mn(OAc)3·2H2O, Cu(OAc)2, and Ni(OAc)2·4H2O were investigated as catalysts. Satisfactory yields could also be achieved, but none of these catalyst worked better than MoS2. Therefore, MoS2 was selected as the optimal catalyst (entries 5–8). This reaction can be completed within 18 hours (entries 1, 11–13). Decreasing the reaction temperature (entry 14) proved to be unfavorable to this transformation. Additionally, the presence of air was harmful to this reaction (entry 15). Finally, this reaction was conducted by using stoichiometric amounts of DMF (1.5 equiv.) as the reagent in another solvent, but only poor yield was obtained (entries 16–17).
With the optimized condition in hand, various amines, including primary, secondary and heterocyclic amines, were tested for this reaction (Fig. 4). The results indicated that tetrahydroisoquinoline or its analogs could be converted to desired product with good to excellent yields (2a–f). This reaction was tolerable for various functional groups such as methoxy, bromide, and nitro. Notably, the electron-withdrawing group is unfavorable to this reaction (2d), and a lower yield would be found. In the case of heterocyclic amines, this transformation proceeded well and the transamidation products were obtained with excellent yields (2g–h). Other secondary amines, either circular or linear amines, underwent this reaction smoothly with high yields in most cases (2i–o). Remarkably, compound 2o which containing trifluoromethyl group, a marker for fluoxetine51, could be synthesized by this strategy with good yield (78%). However, the substrate with obvious steric hindrance group, such as ethyl (1j) on nitrogen was suffered from a reduced yield. This transamidation strategy was also applicable to primary amines, and good results as well as secondary amines were achieved (2p–v). Particularly, substrate containing hydroxyl group also converted to desired product with good yield (2 u). The transamidation reaction and the corresponding product are valuable in organic synthesis reaction. For example, the natural product homoveratrylamine (1x) can be modified with formyl group by this strategy, and the corresponding product 2x could be converted to a series of natural compounds such as pseudopalmatine, 8-oxopseudopalmatine, and ilicifoline B52. However, when aromatic amines such as aniline, tetrahydroquinoline and tetrahydroindole were used as substrates, only trace amount of desired products could be detected.
After the expanded substrate scope of amines, we then considered other appropriate carbonyl sources except DMF (Fig. 5). The results showed this reaction could also be proceeded with excellent yield by using formamide or N-methylformamide as formyl sources (entries 1–2). However, in the case of using sterically hindered amide such as N,N-diethylformamide as substrate, the yield would be reduced seriously (entry 3). Delightedly, acetamide and propionamide could be applied as carbonyl sources, and the corresponding N-acetylation and N-propionylation reaction were achieved with excellent yields (entries 4–5). These results further confirmed the transamidation strategy developed by us has a broad scope and is valuable. Moreover, in the case of aromatic amides used as carbonyl sources, a yield of 30~40% still could be found (entries 6–7).
To verification the practicability of this strategy, the N-acetylation and N-propionylation reaction were expanded (Fig. 6). Either primary amines or secondary amines were converted to corresponding products with good to excellent yields (2zc-zl).
Significantly, the gram-scale synthesis of 2g using only 3 mol% MoS2 as catalyst was proceeded (Fig. 7A), and an excellent yield of 93% was obtained with an extended reaction time (4 days). Subsequently, the radical blocking experiments were performed using 1 equiv butylated hydroxytoluene (BHT), quinone, or 1,1-diphenylethene as a blocker, and the transamidation products were achieved with 80%, 83%, and 82% yield, respectively (Fig. 7B). These results indicated that this process is not a radical reaction, but a nucleophilic reaction.
Based on the radical blocking experiments and previous reported metal-catalyzed transamidation reactions13,14,15, the reaction mechanism was proposed (Fig. 8). First, MoS2 coordinated with DMF, and the carbonyl group is activated. Then, substrate amine acting as a nucleophilic reagent attacks the carbonyl group of the activated DMF. Subsequently, a tetrahedral intermediate (I) is generated. And then, the sterically congested intermediate (I) is disintegrated with a proton transfer, and intermediate II is formed. Finally, a ligand exchange reaction occurs between intermediate II and DMF to release the target molecule (T.M.).
Conclusions
In summary, an efficient MoS2-catalyzed transamidation reaction using amides as carbonyl sources was reported. The advantages of this reaction are the readily available and inexpensive metal applied as catalyst, cheap amides applied as carbonyl source, scalable, broad scopes, free of any additives such as acid, base, ligand, and etc.
Materials and Methods
General Information
The prepared thin-layer chromatography (Prep TLC) was performed for product purification using Sorbent Silica Gel 60 F254 TLC plates and visualized with ultraviolet light. IR spectra were recorded on a new Fourier transform infrared spectroscopy. 1H, 13C and 19F NMR spectra were recorded on 400, 100, 377 MHz NMR spectrometer using CDCl3 as solvent unless otherwise stated. HRMS were made by means of ESI. Melting points were measured on micro melting point apparatus and uncorrected. Unless otherwise noted, all reagents were weighed and handled in the air, and all reactions were carried out in a sealed tube under an atmosphere of argon. Unless otherwise noted, all reagents were purchased from reagent company, and used without further purifications. Notably, the powder MoS2 were used in this work.
Experimental Section
A typical experimental procedure for transamidation was conducted as follows: A solution of amine (0.2 mmol), MoS2 (12.5 mol%, 4 mg) in DMF (1.0 mL) was stirred in a sealed tube under an atmosphere of argon at 150 °C for 18 h. After being cooled to room temperature, the reaction mixture was filtered, washed with ethyl acetate (20 mL). Afterward, the solution was added 10 mL water and extracted with ethyl acetate (3 × 15 mL), and then the combined organic layers were dried with Na2SO4. The solvent was evaporated under vacuum and the crude product was purified by Prep TLC on silica gel with petroleum ether and ethyl acetate to obtain the pure product.
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Acknowledgements
We are grateful to the National Natural Science Foundation of Hunan Province (No. 2018JJ2389), National Natural Science Foundation of China (No. 21402168), Hunan 2011 Collaborative Innovation Center of Chemical Engineering & Technology with Environmental Benignity and Effective Resource Utilization and the Project of Innovation Team of the Ministry of Education (IRT_17R90) for their support of our research.
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Conceived and designed the experiments: L.L. and J.M. performed the experiments. H.G. and F.Z. supervised all research. H.G. also wrote the manuscript. All authors contributed to reagents/materials/technical support to this study.
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Zhang, F., Li, L., Ma, J. et al. MoS2-Catalyzed transamidation reaction. Sci Rep 9, 2536 (2019). https://doi.org/10.1038/s41598-019-39210-5
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DOI: https://doi.org/10.1038/s41598-019-39210-5
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