Indoles borylation

Scheme II.II Indole borylation toward a synthesis of asperazine by Movassaghi and Miller...

One year later Van der Eycken and Dehaen described the smooth microwave-assisted borylation of 4, 5, 6 and 7-bromo-lff-indole using PdCl2(dppf) as a precatalyst and KOAc as a base (Scheme 30) [48]. With 5, 6, and 7-bromo-lH-indole, DMSO was used as solvent at a temperature of 150 °C (with a set power of 150 W) for 17-27 min, resulting in the corresponding boronate esters in good yields. For 4-bromo-lH-indole, DME gave a better result at the same temperature (with a set power of 250 W). 

The Ir-catalyzed borylation of the indole nucleus is another important development that promises to find widespread use in complex molecule synthesis. Early reports include the functionalization of C(7) and also of C(2), reported by Malezcka and Smith and by Hartwig, respectively [39, 40]. In a report in 2011, Movassaghi, Miller, and coworkers demonstrated the borylation of tryptamine derivative 61 to afford 62 in 70 % yield [41]. This material was subjected to Suzuki-Miyaura cross coupling with 7-bromoindole (63) to set the stage for studying the oxidative rearrangement of 64, which would eventually provide diketopiperazine indole alkaloids such as asperazine (Scheme 11.11). 

The [Ir(OMe)(COD)]2/dtbpy catalytic system borylates indole selectively at the 2-position (Scheme 6). Smith and coworkers reported that borylation of N-unprotected 2-substituted indoles exclusively occurs at 7-position (Scheme 6) [85, 86]. It has been suggested that nitrogen interaction with the iridium center or possibly the empty p-orbital of boron in a boryl ligand induces the observed regioselectivity. Borylation of other heteroarenes have been reported using the same or similar Ir(I) and bipyridine combination [85, 87-90]. 

Iridium-catalyzed borylation has also proved to develop the first general approach to functionalized unprotected indoles at the 7-position [67]. This selectivity can be explained by the nitrogen-directed aromatic borylation pathway in the mechanistic steps (Scheme 7.34). 

Although not fitting exactly into the scope of this book, the iridium catalyzed borylation of five membered heterocycles through C-H bond activation also deserves mentioning. A recent report by Miyaura disclosed the reaction of bis(pinacolato)diboron with heteroaromatic systems, where thiophene, fiirane and pyrrole were converted to their 2-boryl derivatives with good selectivity (6.86.), The yields presented refer to the diboron compound since the heterocycles were used in excess in all cases. Indole, benzofurane and benzothiophene were monoborylated with similar efficiency.116... 

Indole-fused, or indole-benzo-fused azepinone derivatives have attracted synthetic attention and examples include the preparation of 85 in 84% yield from 84 by intramolecular Heck coupling [01SL848], as well as the preparation of paullone 87 (a CDK inhibitor) by cyclisation of 86 under basic conditions borylation/Suzuki coupling technology was used to access 86 [02JOC1199]. Acid-catalysed cyclisation with polyphosphoric acid was used to prepare the racemic reduced azepino[4,5-6]indoles 92a,b from the precursors 91, which were obtained in turn from CDl-mediated coupling of 88 and 89, followed by reduction of the amide with lithium aluminium hydride [01H1455]. 

Iridium complexes generated from [IrCl(COD)]2 and 2,2 -bipyridine (bpy) catalyze the borylation of pyrrole and indole derivatives to yield the borylated products 788 in moderate to good yields (Equation 190) <2004JM021>. 

Coupling of borylated indoles with readily available chloropyrazine proceeded smoothly... 

Although not a palladium-catalyzed reaction, the Ir(I)-catalyzed C-H borylation reaction developed independently by Smith and Malezcka [58] and Hartwig and Miyaura [59] deserves some mention in the context of indole and pyrrole functionalization. Based on the original studies, indoles and pyrroles can be borylated (and hence cross coupled under Suzuki conditions) to form either the C2 or C3 functionalised products (Scheme 35) [60, 61]. Free (NH)-indoles and pyrroles react exclusively at the C2, whereas /V-TIPS indole and pyrroles are borylated at the C3 positions. Interestingly, Smith, Maleczka and co-workers also demonstrated that when the C2 position of indole is blocked, then the borylation reaction takes place at the C7-position of the indole nucleus [62]. They propose that an A-chelation to Ir (or B) is responsible for the observed selectivity. 

Scheme 35 Regioselective Ir(I)-catalyzed C-H borylation of indoles and pyrroles...

Paul S, Chotana GA, Holmes D, Reichle RC, Maleczka RE Jr, Smith MR III (2006) Ir-catalyzed functionalization of 2-substituted indoles at the 7-position Nitrogen-directed aromatic borylation. J Am Chem Soc 128 15552... 

As mentioned in a previous section, the iridium-catalyzed borylation of 2-(substituted)indoles gave 7-(borylated)indoles [291]. 

C—H borylation of indoles has been reported by a number of groups. Chirik and coworkers utilized pincer-ligated cobalt complexes with N-methyhndole and recorded the C-2 borylated indole (133) as the major product (2014JAC4133). The catalysts employed demonstrated high catalysis turnover and low catalytic loading and also demonstrated efficacy with other electron-rich heteroarenes (furan, thiophene, benzofuran) as well as electron-deficient pyridines. More recendy, platinum-NHC complexes have been used in the selective C—H borylation of indoles (2015JAC12211). The authors reported higher isolated yields with this... 

Scheme 29 Ir-catalyzed C2-borylation and C3-borylation of IH-indole via a traceless Bpin directing group.

The reactive boronium ion (88) has been prepared from l,8-bis(dimethylamino) naphthalene and has been shown to be effective in the borylation of pyrrole and indole derivatives. Catechol-ligated borenium cations, such as (89), have also been used in the borylation of a range of anilines, thiophenes, and (V-heterocycles. ... 

Borylated pyrrole 88 was prepared by Oestreich by treatment of the corresponding pyrrole with pinacolborane and a ruthenium(II) thiolate complex. The direct synthesis of 88 promises to find wide utility in medicinal chemistry and was applied to a variety of substituted indoles (13JA10978). N-Methylpyrrole was directly arylated at room temperature by photoredox catalysis with diaryliodonium salts to furnish 89 in 84% yield (13SL507). 

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