Azadirachtin is a complex
tetranortriterpenoid limonoid natural product isolated from the neem tree Azadirachta indica, of the Meliaceae
family of flowering plants. The neem tree is evergreen and produces white and
fragrant flowers as well as a fruit that is smooth and olive-like. The neem is
native to India and the Indian subcontinent including Nepal, Pakistan,
Bangladesh and Sri Lanka. The azadirachtin content of neem oil pressed from
fruits and seeds varies from 300 to 2500 ppm, depending on the extraction
method and quality of the neem seeds used to produce the oil. Nimbin was the
first limonoid extracted from the neem tree. Subsequently, more than 150
bioactive chemical constituents were isolated from neem oil and various neem
tissues. Aside from triterpenoids, neem is known to contain sterols such as b-sitosterol and stigmasterol, as well as
polyunsaturated fatty acids.
Azadirachtin is a powerful insect repellent/anti-feedant with low mammalian toxicity (LD50 in rats is >3.5 g/kg). A 1.2% formulated solution of azadirachtin is marketed as Azatrol, an insecticide that provides broad-spectrum insect control and is non-toxic to honeybees. Azadirachtin is the active ingredient in a number of other pesticides including TreeAzin, AzaMax and AzaGuard. The enormous commercial potential of new azadirachtin analogues as safe anti-insect agents has inspired/funded organic chemists for decades. The sole chemical synthesis of azadirachtin, reported in 2007 by Steven Ley’s group at the University of Cambridge, relied on a relay approach and required >70 synthetic operations. Ley’s retrosynthetic disconnection of the crowded vicinal quaternary carbon atoms located at the C8 and C14 positions, a tactic that was adopted by numerous contemporary research groups (most notably, Nicolaou’s), generates two advanced synthetic intermediates: a highly oxygenated western decalin substructure and an eastern furopyran oxabicycle. Zhen Yang’s team in Shenzhen, China has recently disclosed remarkably concise protocols for the chemical synthesis of both of these fragments. A discussion of Yang’s synthetic studies of the azadirachtin-type limonoids is provided below.
Azadirachtin is a powerful insect repellent/anti-feedant with low mammalian toxicity (LD50 in rats is >3.5 g/kg). A 1.2% formulated solution of azadirachtin is marketed as Azatrol, an insecticide that provides broad-spectrum insect control and is non-toxic to honeybees. Azadirachtin is the active ingredient in a number of other pesticides including TreeAzin, AzaMax and AzaGuard. The enormous commercial potential of new azadirachtin analogues as safe anti-insect agents has inspired/funded organic chemists for decades. The sole chemical synthesis of azadirachtin, reported in 2007 by Steven Ley’s group at the University of Cambridge, relied on a relay approach and required >70 synthetic operations. Ley’s retrosynthetic disconnection of the crowded vicinal quaternary carbon atoms located at the C8 and C14 positions, a tactic that was adopted by numerous contemporary research groups (most notably, Nicolaou’s), generates two advanced synthetic intermediates: a highly oxygenated western decalin substructure and an eastern furopyran oxabicycle. Zhen Yang’s team in Shenzhen, China has recently disclosed remarkably concise protocols for the chemical synthesis of both of these fragments. A discussion of Yang’s synthetic studies of the azadirachtin-type limonoids is provided below.
Upon preliminary examination of the
molecular architecture of azadirachtin, the structural relationship between
this oxidatively rearranged tetranortriterpenoid and more simplified C13a/17-furyl-androstane limonoids is perhaps
not immediately intuitive (otherwise put, what does azadirachtin have to do
with a steroid?!). Identification of the genes and proteins involved in the neem
biosynthetic machinery is currently the subject of intense investigation due to
the impracticalities associated with commercial production of azadirachtin via
chemical synthesis. The prevailing biogenetic theory is that azadirachtin
arises from C-seco-limonoids derived from Norrish a-cleavage of an oxidation product of azadirone or azadiradione.
So, yes, azadirachtin is likely a biosynthetic descendant of azadirone, which
bears an androstane/steroidal core carbon skeleton. Cyclization of a
cyclopentenol precursor (bracketed intermediate shown above) onto the heteroaryl
furan system likely forges the eastern, bridged hydroxyfuran acetal motif.
Evidence for this type of biogenetic pathway is found in the chemical
composition of neem oil, which is known to contain relatively high levels of
putative biosynthetic intermediates including azadirone, azadiradione, nimbin,
nimbidinin, salannin, salannol, along with trace amounts of other structurally
related limonoids.
Yang’s synthesis of azadirachtin’s
western A/B decalin fragment begins from the spearmint oil-derived enantiomer
of carvone, which was converted in two steps into the substituted cyclohexene
derivative depicted in the Scheme above. This early-stage intermediate was subjected
to palladium-catalyzed oxyalkynylation, furnishing the requisite [6,5]-oxabicycle
in good yield under optimized conditions. The reaction is completely regio- and
diastereoselective, with the relative stereochemical outcome presumably
dictated by minimization of steric interactions between the methyl and vinyl
substituents. Subsequent ozonolysis of the propenyl group then delivers an
allylic acetate intermediate bearing an intact endocyclic olefin. This latter
reaction was developed in the early 1980s by Stuart Schreiber’s group, then at
Yale University. Schreiber showed that the intermediary carbonyl oxide derived
from retro-[3+2] of the initially formed molozonide could be trapped by
1,3-addition of methanol to generate an a-methoxy
hydroperoxide species. Upon acylation of the hydroperoxide in the presence of
base, a Criegee rearrangement involving alkyl migration (similar to the
Baeyer-Villiger mechanism) ensues to provide the acetate as an inconsequential
mixture of diastereomers. Seven additional operations were required to eventually
produce the critical 1,7-diyne that was designed to serve as the substrate for
a remarkable gold-catalyzed tandem cyclization reaction, described below.
The gold-catalyzed cascade reaction
proceeded under mild reaction conditions, generating the densely functionalized
trans-decalin product as a single
stereoisomer in 49% yield. This stereocontrolled alkyne metathesis-type
cyclization reaction forms two rings and two new stereocenters in a single
operation. The fully intact azadirachtin western decalin substructure was
synthesized from the cascade cyclization product in eight additional steps. The
overall route to Yang’s decalin requires 20 total synthetic operations,
starting from (-)-carvone. It should be
noted that a similar advanced decalin intermediate was synthesized in the early
2000’s by Nicolaou’s group by a sequence involving a total of 47 linear
operations.
Yang’s synthesis of the eastern furo[2,3b]pyran azadirachtin fragment
relies on silylglyoxylate-based synthetic technology developed by Jeff
Johnson’s group at UNC Chapel Hill. Yang’s recent limonoid work extends
Johnson’s methodology to accommodate the use of allylzinc bromide in place of
Reformatsky’s reagent in the diastereoselective three-component coupling process
(see Scheme above). The reaction proceeds by addition of the allylzinc reagent
to the silylglyoxylate benzyl ester, followed by [1,2]-Brook rearrangement to
afford a zinc-chelated enolate. The latter nucleophile approaches the b-lactone coupling partner from its less
hindered convex side to furnish the condensation product with exquisite
1,4-stereoinduction. The remaining stages of the route involve initial g-lactonization followed by ozonolysis of a
lactol intermediate to construct the oxabicyclic ring system. A
bis-TBS-protected furo[2,3b]pyran building block was prepared in a total of nine steps and a differentially protected system,
similar to Ley’s advanced intermediate, was generated in 15 steps. Those
familiar with the Ley group’s endgame know all too well that the completion of
azadirachtin from the advanced intermediates described above is far from trivial.
It will be interesting to see the extent to which Yang’s expedited syntheses of
the eastern and western fragments will enable methodological improvements in critical
aspects of the azadirachtin endgame strategy, such as construction of the
notoriously challenging C8-C14 bond which links the two substructural
hemispheres of the natural product.
