Synthesis of Three-Dimensionally Fascinating Diterpenoid Alkaloids and Related Diterpenes

Abstract: Conspectus Three-dimensional cage-like natural products represent astounding and long-term challenges in the research endeavors of total synthesis. A central issue that synthetic chemists need to address lies in how to efficiently construct the polycyclic frameworks as well as to install the requisite substituent groups. The diterpenoid alkaloids that biogenetically originate from amination of diterpenes and diversify through late-stage skeletal reorganization belong to such a natural product category. As the … Show more

“…Disassembly of the bicyclo[2.2.2]­octane motif in talassimidine and talassamine led back to 23 . Instead of the commonly used Diels–Alder cycloaddition strategy, formation of the C12–C13 bond of 23 would give the bicyclo[2.2.2]­octane motif and establish the hetidine core. Inspired by our previous success in constructing the B ring of hetisine through a dearomative free radical addition, we posited that addition of a ketyl radical to the arene moiety would yield the B ring and concurrently install a hydroxyl group.…”

“…Of the biosynthetically related atisine-, hetidine-, and hetisine-type C 20 -diterpenoid alkaloids, the hexacyclic hetidine core has a characteristic C14–C20 linkage; besides the C14–C20 linkage, the hetisine core has an additional C6–N linkage, forming a complex heptacyclic framework. The unique biological profiles and structural complexity of C 20 -diterpenoid alkaloids render them highly sought-after synthetic targets. − Successful total syntheses of hetisine-type alkaloids have been reported by the groups of Muratake/Natsume, Gin, and Sarpong, as well as our group, reflecting considerable achievements toward total synthesis of various C 20 -diterpenoid alkaloids in recent years. − However, there has been limited success in the synthesis of the seemingly less complex hetidine-type alkaloids, despite considerable efforts having been made toward this subtype. , Guided by network analysis, Sarpong’s group accomplished a unified total synthesis of C 18 -, C 19 -, and C 20 -diterpenoid alkaloids ,,, and developed an elegant approach of Ga-catalyzed cycloisomerization to synthesize dihydronavirine, a structurally very similar analogue of navirine. , Baran’s group applied a two-phase synthetic strategy to synthesize the atisine alkaloids and construct the hetidine skeleton from a readily available ent -kaurane . Qin and Liu developed an efficient biomimetic approach to access the denudatine- and atisine-type alkaloids and the hetidine skeleton from an atisine-type precursor .…”

“…The limited success in the synthesis of hetidine-type alkaloids can be attributed to the synthetic challenge associated with the rigid hexacyclic cage-shaped skeleton and more problematically, the different oxygen substitutions at various positions of the core frameworks. ,, To develop new synthetic strategies to access diterpenoid alkaloids with complex oxygen substitution patterns, we embarked on a synthetic program toward the synthesis of talassimidine ( 4 ) and talassamine ( 5 ), two hetidine-type alkaloids initially isolated from Aconitum talassicum M. Pop. by Nishanov and then reisolated from Delphinium campylocentrum Maxim.…”

Asymmetric Total Synthesis of Hetidine-Type C₂₀-Diterpenoid Alkaloids: (+)-Talassimidine and (+)-Talassamine

“…Disassembly of the bicyclo[2.2.2]­octane motif in talassimidine and talassamine led back to 23 . Instead of the commonly used Diels–Alder cycloaddition strategy, formation of the C12–C13 bond of 23 would give the bicyclo[2.2.2]­octane motif and establish the hetidine core. Inspired by our previous success in constructing the B ring of hetisine through a dearomative free radical addition, we posited that addition of a ketyl radical to the arene moiety would yield the B ring and concurrently install a hydroxyl group.…”

“…Of the biosynthetically related atisine-, hetidine-, and hetisine-type C 20 -diterpenoid alkaloids, the hexacyclic hetidine core has a characteristic C14–C20 linkage; besides the C14–C20 linkage, the hetisine core has an additional C6–N linkage, forming a complex heptacyclic framework. The unique biological profiles and structural complexity of C 20 -diterpenoid alkaloids render them highly sought-after synthetic targets. − Successful total syntheses of hetisine-type alkaloids have been reported by the groups of Muratake/Natsume, Gin, and Sarpong, as well as our group, reflecting considerable achievements toward total synthesis of various C 20 -diterpenoid alkaloids in recent years. − However, there has been limited success in the synthesis of the seemingly less complex hetidine-type alkaloids, despite considerable efforts having been made toward this subtype. , Guided by network analysis, Sarpong’s group accomplished a unified total synthesis of C 18 -, C 19 -, and C 20 -diterpenoid alkaloids ,,, and developed an elegant approach of Ga-catalyzed cycloisomerization to synthesize dihydronavirine, a structurally very similar analogue of navirine. , Baran’s group applied a two-phase synthetic strategy to synthesize the atisine alkaloids and construct the hetidine skeleton from a readily available ent -kaurane . Qin and Liu developed an efficient biomimetic approach to access the denudatine- and atisine-type alkaloids and the hetidine skeleton from an atisine-type precursor .…”

“…The limited success in the synthesis of hetidine-type alkaloids can be attributed to the synthetic challenge associated with the rigid hexacyclic cage-shaped skeleton and more problematically, the different oxygen substitutions at various positions of the core frameworks. ,, To develop new synthetic strategies to access diterpenoid alkaloids with complex oxygen substitution patterns, we embarked on a synthetic program toward the synthesis of talassimidine ( 4 ) and talassamine ( 5 ), two hetidine-type alkaloids initially isolated from Aconitum talassicum M. Pop. by Nishanov and then reisolated from Delphinium campylocentrum Maxim.…”

Asymmetric Total Synthesis of Hetidine-Type C₂₀-Diterpenoid Alkaloids: (+)-Talassimidine and (+)-Talassamine

“…The similar strained cage skeleton also exists in various ent -atisane diterpene-derived alkaloids. These intriguing structural features rendered these C 20 -diterpenoid alkaloids challenging and attractive targets for synthetic chemists . During the past decades, remarkable achievements have been accomplished toward accessing ent -atisane diterpene-derived alkaloids such as atisines, hetidines, hetisines, denudatines, and arcutines .…”

Divergent Total Syntheses of Napelline-Type C20-Diterpenoid Alkaloids: (−)-Napelline, (+)-Dehydronapelline, (−)-Songorine, (−)-Songoramine, (−)-Acoapetaldine D, and (−)-Liangshanone

“…23 Although the above studies on the synthesis of HHPs have their own merits, they mainly focus on the reaction of C]O bonds and primary amines. In 2017, Cui et al investigated the acid-catalyzed [2 + 2 + 2] system for HHPs, which overcame the challenge of insufficient nucleophilicity of the iminium species using the intermolecular aza-Prins reaction [24][25][26][27] and directly synthesizing the target product from the alkene precursor. 28 On the basis of this mechanism detection experiment, Fang et al calculated the possible reaction mechanisms, catalytic species, and regioselectivity in the cycloaddition reaction for this system using density functional theory.…”

Mechanism of the Fe(iii)-catalyzed synthesis of hexahydropyrimidine with α-phenylstyrene: a DFT study