ARTICLE

Received 10 Feb 2015 | Accepted 13 May 2015 | Published 17 Jun 2015

Fluoroalkenes represent a class of privileged structural motifs, which found widespread use in medicinal chemistry. However, the synthetic access to uoroalkenes was much under-developed with previous reported methods suffering from either low step economy or harsh reaction conditions. Here we present a RhIII-catalysed tandem CH/CF activation for the synthesis of (hetero)arylated monouoroalkenes. The use of readily available gem-diuoroalkenes as electrophiles provides a highly efcient and operationally simple method for the introduction of a-uoroalkenyl motifs onto (hetero)arenes under oxidant-free conditions. Furthermore, the employment of alcoholic solvent and the in-situ generated hydrogen uoride are found to be benecial in this transformation, indicating the possibility of the involvement of hydrogen bond activation mode with regards to the CF bond cleavage step.

DOI: 10.1038/ncomms8472 OPEN

Rhodium-catalysed C(sp2)C(sp2) bond formation via CH/CF activation

Panpan Tian1, Chao Feng1,2 & Teck-Peng Loh1,2

1 Hefei National Laboratory for Physical Sciences at the Microscale and Department of Chemistry, University of Science and Technology of China, Hefei 230026, China. 2 Division of Chemistry and Biological Chemistry, Nanyang Technological University, 50 Nanyang Avenue, Singapore 639798, Singapore. Correspondence and requests for materials should be addressed to C.F. (email: mailto:[email protected]

Web End [email protected] ) or to T.-P.L. (email: mailto:[email protected]

Web End [email protected] ).

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Fluorine, small atom with a big ego, due to its intrinsic properties such as small size and high electronegativity in comparison with other halogen atoms, has played a key role

in all elds of science1,2. More specically, the incorporation of uorine or uorine-containing structural motifs into organic molecule brings about substantial improvement in its bioactivity and provides unique chemical and physical properties, thus enabling the widespread use of this strategy in the eld of medicinal chemistry35. In this context, uoroalkenes represent a class of very important molecules owing to their biological properties and also their synthetic potential in synthetic organic chemistry6,7. Furthermore, as favourable peptide bond mimetics, both electrostatically and geometrically, as well as their resistant nature to enzymatic degradation, the uoroalkene structural motifs have been attracting increasing interest in medicinal chemistry and drug-discovery research812. Albeit their great importance, compared with the development of analogous uorination and triuoromethylation methodologies1318, the synthetic access to alkenyl uorides remains largely underdeveloped, with most of the reported protocols suffering from the need of substrate pre-activation or using non-readily available starting materials, low regio- or stereo-selectivity and poor functional group tolerance due to the employment of sensitive reagents1921. By taking advantage of the Pd/Cucatalysed CH activation strategy, Hoarau and colleagues22,23 reported elegant works on the uoroalkenylation of heteroarenes either through CH/CBr or CH/CO2H couplings (Fig. 1d).

Notwithstanding the advance attained, the development of a new synthetic method, which streamlines the access to uoroalkene motifs using readily available building blocks while avoiding substrate pre-activation steps, would still be of meaningful importance in both the synthetic organic chemistry and pharmaceuticals development.

With explosive advancements achieved in the past decade, the directing group assisted CH bond activation has emerged as a powerful and competent tool, which not only result in fundamental changes in the retrosynthesis but more importantly represents the state-of-the-art in the organic synthesis and shows

the direction of development beyond what traditional synthetic methodologies could bring about24,25. As a subclass, the Rh(III)-catalysed CH functionalization is booming rapidly in the recent years2630. Although a diverse range of synthetically useful transformations have already been attained in this context, the application of Rh(III)-catalysed CH activation in the uorine chemistry is unprecedented and more importantly the employment of C(sp2)-X as electrophilic coupling partner is totally unrecognized in high valent rhodium catalysis31,32. Therefore, the development of a Rh(III)-catalysed CH functionalization protocol that enables the easy access of biologically relevant uoroalkenes is highly desirable and the feasibility of such protocol was based on the following considerations: (i) Rh(III)-catalysed alkenylation has evolved to be a competent and reliable method for the introduction of olen segments, although stoichiometric amount of external oxidant was always required to fulll the redox demand (Fig. 1a)33,34;(ii) notwithstanding its high dissociation energy, the CF bond could be activated by transition metal or through the formation of hydrogen bond, provided that suitable hydrogen bond donor is present (Fig. 1b)3540; (iii) gem-diuoroalkenes represent a class of appealing synthetic intermediates with the CC double bond being highly polarized because of the electronegativity of uorine and also the repulsion effect stemming from its unpaired electrons41,42. Furthermore, it is well-known that heteronucleophiles could undergo facile nucleophilic addition or substitution reactions under basic conditions (Fig. 1c)4346. We reasoned that the putative carbocation character of gem-diuoroalkenes is of critical importance in ensuring the regioselectivity of carborhodationic step and the employment of hydrogen-bond donor would result in the activation of CF bond. Assuming the viability of our proposal, there comes with an afliated bonus, as no external oxidant was required because of the redox neutral property of this transformation32. With our ongoing interest in rhodium and uorine chemistry4749, herein we would like to present the chelation-assisted CH activation strategy for the direct incorporation of the a-uoroalkenyl unit using gem-diuoroalkene as the uoroalkene donor (Fig. 1e)50.

F

DG

H R2

Rh(III) Oxidant

DG R1

R2

F

+

R1

DG

H

R1

Rh(III)

DG R1

R2

+

R2

F

CH activation

R2

R2

-defluoration

R1-M

+ TM

R1

Fn Fn

R1 R

1

F

Regioselective insertion

DG

DG

Rh

F

F F

F

DG

R

Rh

R

F

F

Base or

F

F F

H

X

X X

H+

Hydroarylation

HX

Stereospecific

Oxidant free

Wide functionality tolerance Readily available substrates

F

+

R

HetAr

X R HetAr

F

Pd(II)/Cu

H

R F F

F

+

H

F

R

Figure 1 | Proposed method of rhodium-catalysed a-uoroalkenylation. (a) Oxidative alkenylation through Rh(III)-catalysed CH activation.(b) Transition-metal-catalysed CC bond formation through CF activation. M, metal; TM, transition metal. (c) Base-promoted inter- or intramolecular nucleophilic addition or substitution of gem-diuoroalkenes with heteronucleophiles. X, hetero atom. (d) Pd/Cu-catalysed CH uoroalkenylation of heteroarenes. X, Br or CO2H. (e) In this report, oxidant-free Rh(III)-catalysed a-uoroalkenylation of (hetero)arenes. The hydrogen bonding interaction is believed to promote the cleavage of CF bond, which, in turn, renders this reaction redox neutral. DG, directing group.

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ResultsReaction condition optimization for 3aa. To test our hypothesis, the cross-coupling between 1-(2, 2-diuorovinyl)-4-methoxybenzene (2a) and 1-(pyrimidin-2-yl)-1H-indole (1a) was selected as the model reaction. After examination of a considerable variety of reaction parameters, we were rather pleased to nd that the anticipated uoroalkenylation product could be obtained in 89% yield when using [RhCp*(CH3CN)3](SbF6)2 as the catalyst and methanol as solvent, and at 80 C for 16 h (see Supplementary Tables 13 for details of reaction optimization). In accordance with our hypothesis mentioned above, this reaction occurred in an excellent regio- and stereo-selective manner due to the intrinsic property of gem-diuoro substituents. Considering the fact that hydrogen uoride (HF) itself is a strong hydrogen-bond donor, which could provide a resultant stabilization energy in the cleavage of C(sp3)F bond process, as well as to evaluate whether such an interaction was present and in turn facilitated our reaction process, control experiments with external HF sequesters were conducted37. As expected, the addition of exogenous bases such as NaHCO3, Na2CO3 and 2,6-di-tert-butyl-4-methylpyridine for the neutralization of the HF generated in the reaction was proved to be detrimental to this transformation. Taking this phenomenon together with the superiority of alcoholic solvents into consideration, it is reasonable to assume that the activation of CF bond through

hydrogen-bond formation is involved and proved to be crucial for the execution of this protocol. Furthermore, the hydroarylation product arising from the protonation of carborhodation intermediate was not observed throughout the whole reaction, implying the kinetic favourability of the b-deuorination step51.

Substrate scope. Having obtained the optimized reaction conditions, the issues with respect to functional group tolerance and scope of gem-diuoroalkene was thus addressed and the results were summarized in Table 1. In general, with respect to aryl substituted gem-diuoroalkenes, both electron-donating and electron-withdrawing functional groups, regardless of the substitution patterns, on the arene moiety were all well tolerated, affording the desired products in high to excellent yield. When electron-rich substituents such as Me or OMe are present in the ortho, meta or para positions, the reaction proceeded well, leading to the formation of the desired products with the yields ranging from 69% to 91% (3ab3ae). However, when 2f was used as a substrate, the reaction afforded product 3af in 46% yield, which may be attributed to the competitive chelation effect of nitrogen substituent in this case. Substrates with synthetically useful functional groups such as NO2, CF3, Ac, CO2Me and CN (2g2k)

participated in this reaction efciently, to deliver the

Table 1 | Scope of gem-diuoroalkene for the CH/CF activation reaction.

R

F

N N

+

R F

F

[Cp Rh(CH CN) ](SbF ) (4.0 mol%)

MeOH, 80 C, 16 h

N

N N

N

1a 2 3

Me

N

N N

F

F O

Me

F

N

F N N

N

N N

N

F Me N N

N

N N

N

3ab, 69% 3ac, 73% 3ad, 91% 3ae, 75%

3aj, 77% 3ak, 81%

3af, 46%

O

CF

CO Me

NO

CN

N N

N N

F

F

F

F

F

N

N N

N

N N

N N

N

N

N

3ag, 91% 3ah, 96%

3ar, 94% 3as, 91%

3ai, 88%

F

Br

I

N N

N N

F

F Cl

F

F

F

N

N N

N

N N

N

N

F N N

N

3al, 81%

3an, 99% 3ao, 88%

3am, 99% 3ap, 97%

O

S

S

Ph

O

F

N N

F

F

N N

N N

N N

N N

F

F

N

N

N

N

N

3aq, 91% 3au, 81%

3at, 71%

Experiments were performed with 1 (0.1 mmol), 2a (0.15 mmol) and [Cp*Rh(MeCN) ](SbF ) (0.004 mmol) in MeOH (0.5 ml) for 16 h at 80 C.

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Table 2 | Scope of indole and 2-arylpyridine derivatives in the CH/CF activation reaction.

[Cp*Rh(CH3CN)3](SbF6)2 (4.0 mol%)

2a, MeOH, 80oC, 16 h

X N

or

Ar

N

N N

R

X N

F

N

N N

F

or

Ar

R

R

Ar = 4-OMeC6H4

1 3

3ca, 88%

4

5

Me

Me

Me

Ar

MeO

Ar

Ar

Ar

Ar

F

F

F

F

F

N

N

N

N

N

N

N

N

N

Me

N

N

N

N

N

N

3ba, 85%

R

3da, 85%

3ea, 99%

3na, 83%* 3oa, 89%* 3pa, 72%

3fa, 72%

Cl

F

Ar

F N

N

N

Ar

Br

Ar

Ar

Ar

F

F

F

F

N

N

N

N

N

N

F

N

N

Br N

N

N

N

3ga, 96%

3ha, 92% 3ia, 90%

3ma, 28%

3ja, 92%

3ka, 57%

CO2Me

Ar

MeO2C N

N

N

NC

Ar

Ar

Ar

F

F

Me

O

F

S F

Ar

F

N

N

N

N

N

N

N

N

N

N

N

3la, 64%

N

N

N

N

N

N F

F

F

F

F

F

Ar

Ar

Ar

Ar

R

Ar

Ar

R OMe CO2Me O

5aa, 68%

R = Me, 5ba, 57% R = OMe, 5ca, 41%

R = Me, 5da, 68% R = OMe, 5ea, 80%

5fa, 44%

5ga, 70%*

5ha, 58%*

(mono:di = 11.4:1) (mono:di = 8.3:1)

Ph

Ph

N

F

N F

N N

F

N F

Ar

Ar

Ar

Ar

N

N

Ar

CF3

F

F Ar

5ma, 84%

F

5ia, 52%*

5ja, 65%*

5ka, 55% 5na, 83%

5la, 73%

(mono:di = 37.1:1) (mono:di = 11.7:1)

Experiments were performed with 1 (0.1 mmol), 2a (0.15 mmol) and [Cp*Rh(MeCN) ](SbF ) (0.004 mmol) in MeOH (0.5 ml) for 16 h at 80 C. *Use triuoroethanol as reaction solvent instead of MeOH.

uoroalkenylation products in high to excellent yields. Furthermore, we were pleased to nd that halogen substituents were also well tolerated in this reaction, which offers the opportunity for further synthetic elaborations (2l2p). The benzo[d][1,3]dioxole and naphthalyl derived substrates 2q, 2r were also amenable to this reaction conditions to deliver the desired products in 91% and 94% yield, respectively. Notably, heterocycle based gemdiuoroalkenes, such as thiophene (2s) and benzo[b]thiophene (2t), also proved to be viable substrates, leading to valuable products in high yields. Pleasingly, this protocol also

accommodates the alkyl derived gem-diuoroakenes, and when 2u was employed as substrate the desired product 2au was obtained in 81% yield.

The reaction generality of indole derivatives was subsequently investigated and the results were summarized in Table 2. It was found that electron-releasing groups, regardless of their positions on the substrates, were proved to be benecial, leading to the desired products in excellent yields (3ba3fa). Again, halogen atoms were nicely tolerated (3ga3ka). Substituents with strong electron-withdrawing ability have somewhat deleterious effect on

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Table 3 | Scope of benzamide in the CH/CF activation reaction.

[RhCp*Cl2]2, AgOAc

2a, t-AmylOH, 80oC, 16 h

O

O

NR1R2

R

R

NR1R2

Ar

Ar = 4-OMeC6H4

F

6 7

O

Me

O

O

NHTs

Ar

NHTs

Ar

NHTs

Ar

NHTs

Ar

Me

MeO

F

F F

F

F

7aa, 68% 7ba, 66%

7ca, 68% 7da, 52%

O

O

O

O

S

NHTs

NHTs

Ar

NHTs

Ar

BocHN

Me

NHTs

Ar

F3C

MeO2C

F

F F

Ar

7ha, 52%

F

7ea, 60% 7fa, 65%

O

7ga, 50%

O

F

O

F

O

F

O

N(i-Pr)2

N(i-Pr)2

N(i-Pr)2

N(i-Pr)2

Ar

Me MeO

S

Ar

Ar

Ar

7la, 30%*

Experiments were performed with 6 (0.1 mmol), 2a (0.15 mmol), [RhCp*Cl ] (0.0025 mmol) and AgOAc (0.02 mmol) in t-AmylOH (0.5 ml) for 16 h at 80 C. *Use [Cp*Rh(MeCN) ](SbF )(0.004 mmol) as catalyst, 1,2-dichloroethane as reaction solvent.

N

N N

F

7ia, 36%*

7ja, 34%*

7ka, 34%*

Ar

t-BuOK (4.0 equiv.)

N H

R

N

F

R

Ar

F

N Ar

THF, 100 C, 23 h

t-BuOK (4.0 equiv.)

Ar

THF, 100 C, 23 h

MeO

8d, 60%

Ar = 4-OMeC6H4

3 8

Ar = 4-OMeC6H4

R = H, 8a, 77%

R = 4-Me, 8b, 83% R = 5-F, 8c, 91%

MeO

5ea

Ph Br

Br

Standard condition

N

N N

Br

Ph

N N F

Ar

F

F

+

Standard condition

N

N N

Ph

R R

R= OMe 5fa R= CO2Me 5ga

Ph F

4f/4g (1:1)

MeO

2a (1 eq)

Ar = 4-OMeC6H4

1a

N

N

N

5fa/5ga (2.7:1)

Figure 2 | Control experiments and synthetic application. (a) Base-promoted dehydrouoration for the synthesis of 2-alkynyl indole derivatives.(b) Base-promoted dehydrouoration for the synthesis of pyridine derivative. (c) Competitive reaction between 4f and 4g. (d) Control reactions between 1a and gem-dibromoalkene and mono-uoroalkene.

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this reaction and the impact became more severe with regard to 5-CN-based indole substrate 1m, which afforded the coupling product 3ma in low yield. Furthermore, it was realized that this protocol was not restricted to indole-derived heterocycles as demonstrated in the cases of 1n to 1p. It needs to be noted that the switch to triuoroethanol as solvent was proved to be critical for achieving high reactivity when pyrrole substrates 1n and 1o were employed32. The superiority of CF3CH2OH as the reaction solvent in these cases was attributed to its ability of acting as a better hydrogen-bond donor than MeOH. When 2-(thiophen-2-yl) pyrimidine 1p was used, the reaction also worked well to afford the desired product (3pa) in 72% yield. To further challenge the reaction scope of this reaction, 2-arylpyridine derivatives were subsequently examined. We were pleased to nd that when simple 2-phenyl pyridine was tested, the desired product 5aa was obtained in synthetically useful yield. For substrates containing ortho-substituents, such as 4b4c, the reaction efciency was slightly decreased because of the steric hindrance involved, whereas in the cases of 4d and 4e, which have meta-substituents, the reaction proceeded selectively on the sterically more accessible site to afford the desired products in good yields. In accordance with the solvent effect encountered in the cases of 3na and 3oa formations, the use of triuoroethanol as solvent was shown to be benecial with respect to the reaction efciency when using substrates containing electron-withdrawing groups, although at the expense of high selectivity for mono-uoroalkenylations in some cases (5ga5ja). Furthermore, substrates that possess substituents on the pyridine ring also engaged well in this reaction to furnish the desired products in moderate to good yields (5ka and 5na). Finally, 2-phenylpyrimidine and benzo[h] quinoline were all viable substrates and participated in this reaction nicely to produce the desired products in high yields (5la5ma).

To further extend the reaction scope and to gain more insight into the limitation of this reaction, substrates that do not contain strong chelation-directing groups, such as pyridine and pyrimi-dine, were examined and the results were presented in Table 3. Although at the present stage ketone, imine and anilide proved to be not suitable substrates, benzamide derivatives were found to be effective coupling partners, especially the Ts-imide analogues, which provide the desired uoroalkenylation products in moderate yields, with slight modication of the reaction condition. Specically, Ts-imide substrates with either electron-donating or electron-withdrawing groups reacted smoothly under modied reaction condition to deliver the desired products (7aa7ga). The ortho-substitute was nicely tolerated without any deleterious effect on the reaction efcacy being observed compared with the para-analogue (7aa versus 7ba). When substrates that contain other potential chelation groups, such as ester and carbamate were employed, the reaction selectively occurred on the ortho-position of Ts-imide directing group (7fa and 7ga). It should be pointed out that thiophene-derived substrate also worked efciently to produce the product 7ha in synthetically useful yield. In contrast to the effectiveness of using Ts-imide as directing group, when the reaction was carried out with N,N-diisopropylbenzamides as substrates, the reaction tend to afford the desired products in relatively low yields, which was due to the low conversion of starting materials (7ia7la).

Synthetic elaboration and mechanistic investigation. To further showcase the synthetic applicability of these uoroalkenylation products, base-promoted dehydrouoration protocol for the synthesis of alkynes were attempted. After the examination of a variety of reaction conditions, we were delighted to nd that the alkyne product 8a could be isolated in 77% yield when 3aa was treated with 4 equivalent of t-BuOK in a solution of

tetrahydrofuran (THF) at 100 C for 23 h. With this strategy, 2-alkynyl indoles 8b and 8c were readily obtained in excellent yield (Fig. 2a). Furthermore, the t-BuOK-promoted dehydrouoration was also proved to be effective for the synthesis of 2-(2-(alkynyl)phenyl)pyridine derivatives and when 5ea was employed, the desired product 8d was generated in 60% yield (Fig. 2b). To gain insight into the electronic bias of the CH activation step, competition experiments between 4f/4g was examined. When an equimolar mixture of 4f, 4g and 2a were subjected to the optimized reaction condition, the desired products 5fa and 5ga were formed in the ratio of 2.7:1, thus indicating that electron-rich substrate was more favoured in the CH activation step in this reaction (Fig. 2c). To determine the role of gem-diuoro substituents in this reaction, substrates with gem-dibromo and monouoro substituents were subjected to the optimized reaction condition; however, neither led to the formation of the desired products. These experiments clearly demonstrated that the gemdiuoro substituents was indispensable for the activation of the CC double bond, which is in full agreement with our hypothesis (Fig. 2d).

DiscussionA highly effective rhodium(III)-catalysed a-uoroalkenylation of (hetero)arenes through CH/CF bond activations was developed. This reaction proceeds smoothly and stereoselectively under base- and oxidant-free reaction conditions to deliver a diverse range of synthetically useful and pharmaceutically relevant cis-alkenyl uorides in good yields. Furthermore, the involvement of activation of the CF bond through hydrogen-bond formation is crucial for the success of this transformation. Last but not the least, the success of incorporation of a-uoroalkenyl unit onto (hetero)arenes through CH/CF activation manifold was in principle amenable to be extended to other processes wherein the key intermediates arylrhodiums were not formed by CH activation, provided that each elemental reaction step was compatible and balanced, thereby offering a more generalized and versatile protocol for the synthesis of functionalized uoroalkene derivatives.

Methods

Materials. For 1H, 13C NMR spectra of compounds in this manuscript, see Supplementary Figs 166. For optimization of reaction conditions,see Supplementary Tables 13. For details of the synthetic procedures, see Supplementary Methods.

Syntheses of products 3 and 5. An oven-dried 10-ml Schlenk tube with a magnetic stirring bar was charged with 1 or 4 (0.1 mmol), [RhCp*(CH3CN)3] (SbF6)2 (3.3 mg, 0.004 mmol), 2 (0.15 mmol) in sequence, followed by adding anhydrous MeOH (0.5 ml) through syringe. The reaction tube was sealed with Teon-coated screw cap and the reaction solution was stirred at 80 C for 16 h. After cooling the reaction mixture to room temperature and removing the solvent in vacuo, the resulting residue was puried by silica gel column chromatography to afford the desired product 3 or 5.

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Acknowledgements

This study is dedicated to Professor Chunxu Lv on the occasion of his 72th birthday. We gratefully acknowledge the funding support of the State Key Program of National Natural Science Foundation of China (21432009). We also thank the Nanyang Technological University for the funding of this research. We are grateful to Mr. Koh Peng Fei Jackson for his careful proofreading of the nal manuscript.

Author contributions

C.F. and T.P.L. directed the project. P.P.T. and C.F. conducted the experiments. C.F. wrote the manuscript with the assistance of P.P.T. C.F. conceived and designed the project. All authors participated in data analyses and discussions.

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How to cite this article: Tian, P. et al. Rhodium-catalysed C(sp2)C(sp2) bond formation via CH/CF activation. Nat. Commun. 6:7472 doi: 10.1038/ncomms8472 (2015).

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