Construction of an advanced tetracyclic intermediate for total synthesis of the marine alkaloid sarain A

In work directed toward a total synthesis of the marine alkaloid sarain A (1), the advanced intermediate 54, containing all the key elements and the seven stereogenic centers of sarain A, has been successfully synthesized from bicyclic lactam 4, previously prepared via an intramolecular stereospecific [3 + 2]-azomethine ylide dipolar cycloaddition. Intermediate lactam 4 could be efficiently converted to N-Boc derivative 12. Introduction of a two-carbon fragment into lactam 12 which eventually becomes the C-7',8' syn diol of the "eastern" ring was then achieved by C-acylation of the corresponding enolate with methoxyacetyl chloride followed by a highly stereoselective ketone reduction with Zn(BH4)2 to afford alcohol 16. Intermediate 16 has the incorrect C-7' relative stereochemistry for sarain A, but this problem was conveniently remedied by inverting the C-7' center via an intramolecular Ohfune-type cyclization of the silyl carbamate derived from Boc mesylate 27 to produce the key cyclic carbamate 28. It was then possible to convert acetal 28 to allylsilane 32 followed by cyclization to the alkaloid tricyclic core 33 via an allylsilane/N-sulfonyliminium ion cyclization. Formation of the "western" macrocyclic ring has been successfully addressed using functional group handles at C-3' and N-1' on the tricyclic core via a ring-closing olefin metathesis (RCM) strategy with the second-generation Grubbs ruthenium catalyst to produce intermediate macrolactam 47. A chelation-controlled addition of ethynylmagnesium bromide to advanced aldehyde 51 afforded a single diastereomeric adduct 53 which is tentatively assigned to have the correct C-7',8' syn-diol stereochemistry. This adduct could be rearranged to the conveniently protected amino carbonate 54 which is set up for construction of the remainder of the eastern ring of sarain A.     

An intermediate for the total synthesis of guaianolides

A synthesis of an intermediate (5) for the construction of quaianolidesis described. The relative stereochemistry at C-1 and C-7 is established with complete stereocontrol.     

Synthesis of the shark repellent pavoninin-4

[reaction: see text] The first synthesis of the shark repellent pavoninin-4, 3, was achieved in 12 steps with 21% overall yield from diosgenin, 8. Key reactions involve an efficient synthesis of the C-15alpha hydroxyl steroid from a C-16beta hydroxyl steroid by an unexpected 1,2-transposition strategy, a stereospecific glycosylation of a hindered C-15alpha alcohol using glycosyl fluoride as a glycosyl donor and a highly chemoselective acetylation of the C-26 primary alcohol by catalytic transesterification.     

Stereocontrol in organic synthesis using silicon-containing compounds. Studies directed towards the synthesis of ebelactone A

Several approaches to the synthesis of ebelactone A 2 are described, culminating in the synthesis of the benzenesulfonate of 2-epi-ebelactone A 161. All the approaches were based on three fragments A, B and C, originally defined in general terms in, but eventually used as the aldehyde 72, the allenylsilane 3 and the aldehyde 139, respectively. They were joined, first B with C, and then B+C with A. In the main routes to fragments A and C, the relative stereochemistry was controlled by highly stereoselective enolate methylations 67-->67, 68-->69, and 135-->136, in each case anti to an adjacent silyl group, and by a highly stereoselective hydroboration of an allylsilane 137-->138, also anti to the silyl group. The hydroxyl groups destined to be on C-3 and C-11 were unmasked by silyl-to-hydroxy conversions 69-->70 and 138-->139 with retention of configuration. The stereochemistry created in the coupling of fragment B to C was controlled by the stereospecifically anti S(E)2' reaction between the enantiomerically enriched allenylsilane 3 and the aldehyde 139. The double bond geometry was controlled by syn stereospecific silylcupration 148-->151, and preserved by iododesilylation 151-->152 of the vinylsilane with retention of configuration, and Nozaki-Hiyama-Kishi coupling with the aldehyde 72 gave the whole carbon skeleton 153 of ebelactone A with the correct relative configuration, all of which had been controlled by organosilicon chemistry. In the steps to remove the superfluous allylic hydroxyl, an intermediate allyllithium species 156 abstracted the proton on C-2, and its reprotonation inverted the configuration at that atom. Other routes to the fragments A and C were also explored, both successful and unsuccessful, both silicon-based and conventional, and a number of unexpected side reactions were investigated.     

Ruthenium-catalyzed alkene-alkyne coupling: synthesis of the proposed structure of amphidinolide A

The ruthenium-catalyzed alkene-alkyne coupling provides a powerful method for the synthesis of 1,4 dienes and a way to simplify synthetic strategy. The latter potential is explored in the context of a synthesis of the assigned structure of amphidinolide A, which also raises the question of the applicability of this reaction for macrocyclizations. Employing this reaction allows simplification of the target to three subunits corresponding to C-1 to C-6, C-7 to C-15, and C-16 to C-25. The C-7 to C-15 subunit involves introduction of chirality by an asymmetric dihydroxylation. The route to the C-16 to C-25 subunit introduces chirality by a Pd-catalyzed asymmetric allylic alkylation and an asymmetric epoxidation. Assembly of the three subunits employs the Ru-catalyzed addition inter- and intramolecularly. The synthesis culminated in the formation of the assigned structure and is identical to the synthetic samples prepared independently by two completely different routes. As noted by the other two groups, this structure appears to be a diastereomer of the natural product. Because this synthesis introduces all of the stereochemistry of the subunits by catalytic asymmetric processes, either enantiomer as well as diastereomers can be readily accessed to define the correct structure. Notably, the Ru-catalyzed macrocyclization to this macrolide proceeded in better yields than either a Pd-catalyzed cross-coupling or a Ru-catalyzed metathesis, macrocylization methods for the other two total synthesis.     

Synthesis of (±)-halipanicine, a marine sesquiterpene isothiocyanate isolated from an Okinawan marine sponge Halichondria panicea

(±)-Halipanicine, 4-isothiocyanato-1-cadinene, isolated from an Okinawan marine sponge Halichondria panicea was synthesized from (±)-cryptone in 21 steps in 7.7% total yield. The regio- and stereospecific synthesis esablished the relative stereochemistry of halipanicine.     

De novo asymmetric synthesis of milbemycin beta3 via an iterative asymmetric hydration approach

The enantioselective synthesis of the spiroketal/macrolide natural product milbemycin beta3 has been achieved in 22 steps and 2.8% overall yield from an achiral dienoate. The spiroketal ring system was installed by three sequential asymmetric hydrations followed by sprioketalization. Both the absolute and relative stereochemistry of milbemycin beta3 was introduced by two Sharpless asymmetric dihydroxylations, two pi-allylpalladium-catalyzed reductions, and an iridium-catalyzed hydrogen migration/Claisen rearrangement to install the C-12 stereocenter.     

De novo asymmetric synthesis of anamarine and its analogues

[reaction: see text] The enantioselective synthesis of anamarine has been achieved in 21 steps. The route relies on enantio- and regioselective Sharpless dihydroxylation of dienoate ester and zinc borohydride reduction to establish the C-8-C-11 stereochemistry. A diastereoselective Leighton allylation established the desired C-5 stereochemistry. The route has also been used to prepare two diastereoisomers of anamarine in 14 steps.     

The first total synthesis of (+/-)-ingenol

The first total synthesis of (+/-)-ingenol has been achieved. The key features of the synthesis include the use of a highly diastereoselective Michael reaction to fix the C-11 methyl stereochemistry and the incorporation of the dimethylcyclopropane via diastereoselective carbene addition to the Delta13,14 olefin. The intramolecular dioxenone photoaddition-fragmentation sequence leads to the establishment of the critical C-8/C-10 trans intrabridgehead stereochemistry, a central challenge in the synthesis of ingenanes. The completion of the synthesis proceeds using the C-6alpha hydroxymethyl group as the sole handle for oxidation of seven contiguous carbon centers.     

Assignment of the liposidomycin diazepanone stereochemistry

The liposidomycins comprise a family of complex nucleoside antibiotics that inhibit bacterial peptidoglycan synthesis. Their structures (1, 2) feature nucleoside, ribofuranoside, diazepanone, and lipid regions. Several stereogenic centers remain unassigned, including three within the diazepanone region: C-6', C-2'", and C-3'". An intramolecular reductive amination reaction has been used to prepare model diazepanones. Analysis of 40 and two of its diastereomers by NMR spectroscopy, X-ray crystallography, and molecular modeling indicates a close relative configurational and conformational match between 40 and the liposidomycin diazepanone degradation product 43 and allows the assignment of stereochemistry of the natural products as either [C-6'(R), C-2'"(R), C-3'"(R)] or [C-6'(S), C-2'"(S), C-3'"(S)].     

Stereospecific synthesis of hydroxylated steroid side chains. Synthesis of 25,28-dihydroxy-7,8-dihydroergosterol and its c-24 epimer via [2,3] sigmatropic rearrangement.

An efficient, stereospecific synthesis of hydroxylated ergosterol and C-24 epi-ergosterol side chains has been developed using a C-20 keto-steroid as starting material. The side chain is elaborated via stereoselective hydroboration, asymmetric reduction and a stereospecific [2, 3] sigmatropic rearrangement.     

Structure Determination and Total Synthesis of (+)‐16‐Hydroxy‐16,22‐dihydroapparicine

Herein, we describe the first asymmetric total synthesis and determination of the relative and absolute stereochemistry of naturally occurring 16‐hydroxy‐16,22‐dihydroapparicine. The key steps include 1) a novel phosphinimine‐mediated cascade reaction to construct the unique 1‐azabicyclo[4.2.2]decane core, including a pseudo‐aminal‐type moiety; 2) a highly stereospecific 1,2‐addition of 2‐acylindole or a methylketone through a Felkin–Anh transition state for the construction of a tetrasubstituted carbon center; and 3) an intramolecular chirality‐transferring Michael reaction of the ketoester, with neighboring‐group participation, to introduce a chiral center at C15 in the target molecule. In addition, we evaluated the antimalarial activity of synthetic (+)‐(15S,16R)‐16‐hydroxy‐16,22‐dihydroapparicine and its intermediate against chloroquine‐resistant Plasmodium falciparum (K1 strain) parasites.     

Synthesis of PPAR agonist via asymmetric hydrogenation of a cinnamic acid derivative and stereospecific displacement of (S)-2-chloropropionic acid

The synthesis of the peroxime proliferator activated receptor (PPAR) alpha,gamma-agonist (1) was accomplished with high enantio- and diastereoselectivity by employing an asymmetric hydrogenation strategy, of an alpha-alkoxy cinnamic acid derivative, to set the C-2 chiral center. A diastereospecific S(N)2 displacement under mild basic conditions established the C-10 stereochemistry without any detectable racemization of the two epimerizable chiral centers.     

Ring-opening Sn2'' reactions of 7-oxanorbornenes by organolithium reagents. Regio- and stereospecific synthesis of substituted cyclohexenediols

The nucleophilic Sn2' bridge opening of 7-oxabicyclo[2.2.1] hept-5-en-2-ols with organolithium reagents occurs in a regio- and stereospecific fashion to produce 6-substituted-cyclohex-4-en-1,3-diols, regardless of the stereochemistry at C-2. A free alcohol functionality is necessary to attain complete regiocontrol of the process. The methodology is utilized to prepare an optically pure cyclohexene derivative, (+)-(1S,3S,6R)-6-n-butyl-3-methyl-cyclohex-4-en-1,3-diol (5b), as a model system.     

Substrates to study the mechanism of vitamin D hydroxylation: synthesis of [24R-2H]-25-hydroxyprovitamin D3

[24R-²H]-25-Hydroxyprovitamin D₃ has been synthesised, in order that the corresponding vitamin may be used to study the stereochemistry of hydroxylation in production of the metabolite 24R,25-dihydroxycholecalciferol. The stereospecific introduction of deuterium at C-24 is effected by means of a Claisen rearrangement.     

A synthesis of (+/-)-sparteine

In a synthesis of racemic sparteine, Diels-Alder reaction between dimethyl bromomesaconate 14 and dicyclopentenyl 4, followed by cyclopropane formation, set up the stereochemistry at C-1 and C-5 as S and R, respectively, in a meso intermediate 8. The stereochemistry at C-2 and C-4 was then secured by a moderately diastereoselective protonation of the bis-enolate 17 derived from the diester 8 by reductive cleavage with lithium in liquid ammonia. The C=C in the racemic diester 19 was ozonolysed and the diketone converted by Beckmann rearrangement into the bis-lactam . Reduction of the bis-lactam with lithium aluminium hydride and intramolecular nucleophilic displacement gave racemic sparteine 1. Some ideas for making this synthesis amenable to a synthesis of enantiomerically enriched sparteine are presented.     

Asymmetric total synthesis of (-)-saframycin A from L-tyrosine

The asymmetric total synthesis of (-)-saframycin A, a natural antitumor product of the tetrahydroisoquinoline antitumor antibiotics family, has been accomplished by employing L-tyrosine as the starting chiral building block in 24 steps for the longest linear sequence in an overall yield of 9.7%. The key steps in the synthesis involve stereoselective intermolecular and intramolecular Pictet-Spengler reactions, which induced the correct stereochemistry at C-1 and C-11, respectively. The selective protection-deprotection protocol of an amino group in the two-step transformation from intermediate 10 to 12 and a hydroxyl group in the first two steps resulted in both high selectivity and efficiency of the synthetic route.     

Synthesis and antiviral activity of scopadulcic acids analogues

The synthesis and antiviral properties of several scopadulcic acid analogues functionalized at C-6/C-7 and C-13 is reported. The preparation of advanced intermediates for the synthesis of scopadulcic acid B/scopadulciol analogues is also described. The biological study revealed the importance of polar groups at C-13, while the stereochemistry at C-8 was not critical for activity.     

Regiospecific,enantiospecific total synthesis of the alkoxy-substituted indole bases, 16-epi-N(a)-methylgardneral, 11-methoxyaffinisine,and 11-methoxymacroline as well as the indole alkaloids alstophylline and macralstonine

A regiospecific, enantiospecific approach to the synthesis of ring-A-substituted indole alkaloids was developed via a doubly convergent strategy. The asymmetric Pictet-Spengler reaction and enolate-driven palladium cross-coupling processes were both executed in stereospecific fashion and served as the stereochemical basis of this approach. The synthesis of 16-epi-N(a)-methylgardneral (15), 11-methoxyaffinisine (16), and 11-methoxymacroline (22) has been accomplished in high yield and in enantiospecific fashion. Moreover, the key C-19 ketosarpagine system (borane adducts) 19a,b employed for the construction of 11-methoxymacroline (22) was also transformed into alstophylline 25, which resulted in completion of the total synthesis of the bisindole macralstonine (1). [reaction: see text]     

Efficient synthesis of the κ-opioid receptor agonist CJ-15,161: four stereospecific inversions at a single aziridinium stereogenic center

An efficient four-step sequence has been developed for the synthesis of the κ-opioid receptor agonist CJ-15,161. The process features four consecutive regioselective and stereospecific inversions at a single aziridinium stereogenic center, which leads to overall retention of stereochemistry, in a single operation. The chemistry is straightforward, practical and amenable to large-scale synthesis.