Ex-Chiral-Pool Synthesis of Optically Active 4-Alkylidene-Tetrahydro­isoquinolines – Key Intermediates for Crinane Alkaloid Total Syntheses

 

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Dedicated to Prof. Dr. Johann Mulzer on the occasion of his 80^th birthday

Abstract

A seven-step ex-chiral-pool synthesis of optically active 4-alkylidenetetrahydroisoquinolines was developed. Starting from 6-bromopiperonal and (S)-serine esters, N-benzylation via reductive amination gave enantiopure N-piperonyl serine esters. Subsequent NH and OH protection delivered defined (S)-serine building blocks. The best results to achieve the conversion into the corresponding serinal were obtained via a two-step sequence of NaBH₄/LiCl reduction and subsequent TEMPO oxidation. Then, chain elongation using the Masamune–Roush variant of the Horner olefination afforded ethyl (E)-4-(N-6-bromopiperonyl)-substituted pentenoates in high yields. Intramolecular Heck cyclization employing the Herrmann–Beller catalyst enabled generation of enantiopure 4-(2-ethoxycarbonylmethylidene)tetrahydroisoquinoline building blocks in high Z-selectivity. Subsequent selected functional group transformations gave carbinols and lactones, which can be used as key intermediates in crinane alkaloid total syntheses.

Publication History

Received: 20 March 2024

Accepted after revision: 15 May 2024

Accepted Manuscript online:
15 May 2024

Article published online:
06 June 2024

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• 44 In contrast, the aryl iodide series required lower reaction temperatures and less intensive microwave support. Starting from iodoaryl alkenyl ester (E)-11-(I), the Z-configured 4-alkylidene tetrahydroisoquinoline (Z)-12 was generated stereoselectively in 66% yield. The analogous reaction involving the Z-starting material (Z)-11-(I) gave the corresponding (E)-alkylidene tetrahydroisoquinoline (E)-14 in 64% yield as a single isomer. For reaction details, see the SI.
• 45 Because of difficult reaction control, the yield varied between about 50% and 80%. Prolonged reaction times partly induced thermal removal of the Boc protecting group. Furthermore, the very low optical rotation values of both isomers indicated a significant percentage of racemization. See also: Yokoyama Y, Kondo K, Mitsuhashi M, Murakami Y. Tetrahedron Lett. 1996; 37: 9309
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• 47 The separation of the tetrahydroisoquinolines (Z)-12 and (E)-12 proved laborious and need to be run after a transformation (for examples, see Scheme 5). For data of a dihydroisoquinoline side product, see the SI (exo to endo double-bond isomerization).
• 48 CCDC 2338529 contains the supplementary crystallographic data for ester rac-(Z)-12 of this paper. The data can be obtained free of charge from The Cambridge Crystallographic Data Centre via www.ccdc.cam.ac.uk/structures.
• 49 In most runs, complete removal of residual (E)-12 and optically inactive 1,2-dihydroisoquinoline succeeded after the next step, resulting a reduced [α]_D value (material including small amounts of remaining side products). For details, see the SI.

The 1,2-dihydroisoquinoline could be described as a side product involving two successive 1,5-H shifts: a C1→exo alkylidene H shift might have formed an o-quinodimethide intermediate, which immediately undergoes re-aromatization via a C3→C1 H shift delivering the product. Alternatively, C3→ester C=O 1,5-H shift for a dienol intermediate and a subsequent enol/C=O tautomerization (1,3-H shift). For data, see the SI. See also:
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• 52 Since amine 16 was labile in the presence of oxidizing reagents/O₂, the material should be stored as hydrochloride 16 (HCl).
• 53 Still, removal of the dihydroquinoline lactone (double-bond-positional isomer) side product remained problematic (laborious HPLC). In contrast to the major isomer 16, dehydrogenation of the dihydroquinoline forming the isoquinoline enabled a more facile separation. If necessary, remaining dihydroquinoline side products (traces) definitely were removed upon generating the quaternary stereocenters. Here, the dihydroisoquinolines remained as reactants.

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• 55 For dihydropyranone in diol, see: Tomooka K, Miyasaka S, Motomura S, Igawa K. Chem. Eur. J. 2014; 20: 7598
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For Luche reduction of lactone, see:
• 56a Kirsch SF, Klahn P, Menz H. Synthesis 2011; 3592
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• 57 Long reaction times and more acidic conditions (predominantly upon workup) gave some dihydropyran as a side product. For data, see SI.
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• 58b Reymond S, Cossy J. Eur. J. Org. Chem. 2006; 4800
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• 58d Kim S, Ahn KH. J. Org. Chem. 1984; 49: 1717
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• Supplementary Material