Bicyclo octane systems

Intramolecular cycloadditions are among the most efficient methods for the synthesis of fused bicyclic ring systems [30]. From this perspective, the hetisine skeleton encompasses two key retro-cycloaddition key elements. (1) a bridging pyrrolidine ring accessible via a [3+2] azomethine dipolar cycloaddition and (2) a [2.2.2] bicyclo-octane accessible via a [4+2] Diels-Alder carbocyclic cycloaddition (Chart 1.4). While intramolecular [4+2] Diels—Alder cycloadditions to form [2.2.2] bicycle-octane systems have extensive precedence [3+2], azomethine dipolar cycloadditions to form highly fused aza systems are rare [31-33]. The staging of these two operations in sequence is critical to a unified synthetic plan. As the proposed [3+2] dipolar cycloaddition is expected to be the more challenging of the two transformations, it should be conducted in an early phase in the forward synthetic direction. As a result, a retrosynthetic analysis would entail initial consideration of the [4+2] cycloaddition to arrive at the optimal retrosynthetic C-C bond disconnections for this transformation. 

Two possible intramolecular disconnections are available for the [2.2.2] bicyclo-octane ring system (path A and path B, Scheme 1.4). The choice between the initial [4+2] disconnections A and B at first appears inconsequential leading to idealized intermediates of comparable complexity (54 and 57). However, when the [4+2] and [3+2] disconnections are considered in sequence, the difference becomes clear. For path A, retrosynthetic [3+2] disconnection of intermediate 54 leads to the conceptual precursor 56, which embodies a considerable simplification. In contrast, path B reveals a retrosynthetic [3+2] disconnection of intermediate 57 to provide the precursor 59, a considerably less simplified medium-ring bridged macrocycle. Thus, unification of the [3+2]/[4+2] dual cycloaddition strategy, using the staging... 

The last synthesis to evolve which is due to Ito and his coworkers is interesting in that it relies on a stereospecific skeletal rearrangement of a bicyclo[2.2.2]octane system which in turn was prepared by Diels-Alder methodology (Scheme XLVIII) Heating of a toluene solution of cyclopentene 1,2-dicarboxylic anhydride and 4-methylcyclohexa-l,4-dienyl methyl ether in the presence of a catalytic quantity of p-toluenesulfonic acid afforded 589. Demethylation was followed by reduction and cyclization to sulfide 590. Desulfurization set the stage for peracid oxidation and arrival at 591. Chromatography of this intermediate on alumina induced isomerization to keto alcohol 592. Jones oxidation afforded diketone 593 which had earlier been transformed into gymnomitrol. 

The palladium-catalysed intramolecular 3 + 2-cycloaddition of alk-5-enylidene-cyclopropanes produced a variety of bicyclo[3.3.0]octane systems with up to three stereocentres.62 The oxidative addition of cyclopropyl phenyl ketone to Ni(Pcy3) gave nickeladihydropyran, which is a key intermediate in the Ni(0)-catalysed homo-... 

Interestingly, zirconacyclopentane 246 formed by the reaction of 1,6-heptadiene with the Zr complex has the firms ring junction mainly [108]. It should be noted that the preparation of the trans ring junction in the bicyclo[3.3.0]octane system by other means is difficult. Carbonylation of 246 affords trans-fuzed bicyclo[3.3.0]octanone 247 [109,111]. The diacetoxy compound 248 is obtained by oxidative cleavage of 246. Protonation affords the frans-dimethylcyclopentane skeleton. Similar reactions occur with 1,6-enynes, and Pauson Khand-type cyclopentenone synthesis is possible by carbonylation. 

Die Bildung des Bicyclo [4,2,0]octan-Systems mit trans-Verknupfung der 4- und 6-Ringe ist nicht auf Isobutylen beschrankt, sondem wurde auch in den Reaktionen des 2-Cyclohexenons mit 1,1-Dimethoxyathylen, Methoxyathylen und Cyclopenten nachgewiesen. 

A tandem aldol condensation-radical cyclization sequence has been developed for the preparation of functionalized bicyclo[3.3.0]octane systems [116]. Conjugate addition of Me2AlSePh to dimethylcyclopentanone (118) followed by trapping of the resulting enolate with aldehyde gave predominantly the trans, erythro aldol 119 this then underwent radical cyclization with BusSnH and catalytic AIBN yielding the bicyclic ketol 120 stereospecifically (Sch. 80). 

Only a few possibilities of evolution are open to this intermediate. One of these would be its equilibration with the other possible enolate XVII by way of proton transfer from the solvent followed by cyclization on the ester (route E) to give the bicyclo[2.2.2]octane system XVIII (see Scheme 39.4). One of the two keto functions would keep the labeled caibon if the other undergoes attack by the alkoxy anion followed by fragmentation as indicated. The end result of this would be the right compound—III. 

Similar procedures are also successful in the construction of cyclobutane rings in other stereochemical environments, including the formation of bicyclo[3.1.1]heptane (67)and bridged tricyclic systems such as (68), (69) ° and (70). ° A variety of annelated cyclobutanes have been prepared by the photochemical procedure as above, yields are sometimes poor or only moderate. Examples include bicy-clo[2.1.0]pentanes (71), °° bicyclo[2.2.0]hexanes (72)"° and cyclobuteno aromatics (e.g, 73), " o-nor-steroids e.g. 74)," A-bisnorsteroids" and triterpenes" as well as the highly strained tricyclo[4.2.0.0 ]octane system (75)," and the [4.4.4.5]fenestrane (76)." ... 

The tricyclo[3.3.0.0 ]octane system usually undergoes ring opening to give bicyclo[3.3.0]octane derivatives by cleavage of the C2-C8 bond when treated with lithium in liquid ammonia. In the case of tricyclo[3.3.0.0 ]octan-3-one (31, R = = H), a small amount (5%) of the... 

The labelling studies described above provide definitive evidence for the mixed polyketide-terpenoid biogenesis of the andibenins, andilesins, andi-tomins, austin and terretonin. The formation of the bicyclo [2.2.2] octane system in the first two classes of metabolite provides a rare example of a biosynthetic Diels-Alder reaction. The biosynthetic relationship of austin and andibenin was supported by the isolation of austin from another mutant strain of A. variecolor [81]. Further metabolites related to austin have been isolated from Emericella dentata [82] and Penicillium diversum [81]. Other complex metabolites which are almost certainly further products of the meroterpenoid pathway are fumiga-tonin (102) and paraherquonin (103) which have been isolated from Aspergillus... 

A simple route to a bicyclo[2.2.2]octanone system was achieved by Michael reaction under microwave irradiation of a mixture of cyclohexenones and ethyl acetoacetate adsorbed on the surface of solid lithium (5)-( )-prolinate followed by intramolecular aldolization on a column of basic Al2O3 5 (Scheme 5.31). The bicyclo[2.2.2]octane system is the core unit of several biologically active natural products and a useful intermediate for synthetic manipulation. ... 

The squalestatins, e.g. 6.28, also known as the zaragozic adds, have attracted considerable interest as inhibitors of squalene synthase and hence of cholesterol biosynthesis and lipid deposition in the circulatory system. They are also inhibitors of farnesyl protein transferase and thus they may have other potentially useful biological applications. They are formed by Phoma spedes and also by Setosphaeria khartoumensis. The squalestatins are characterized by a dioxabicyclo-octane core bearing three carboxyl groups and two polyketide chains, one of which is attached as an ester. The biosynthetic incorporation of succinic acid into part of the bicyclo-octane, together with its oxygenation pattern, indicate that it may be derived via oxaloacetic acid. Both the polyketide chains have several pendant methyl groups attached to them, which arise from methionine, whilst benzoic add ads as a starter unit for one of the chains. These complex structures are thus the summation of several biosynthetic pathways. 

The remaining structural inference depended considerably on interpretation of spectroscopic anomalies. These will be discussed later. The location of the carbonyl on the bicyclo[2,2,2]octane system is of biosynthetic interest (see Section 2E). 

Kobusine (C20H27NO2) and Pseudokobusine (C20H27NO3). The structure of kobusine seemed reasonably secure on chemical and spectroscopic grounds. However, the configuration of the hydroxy-groups on the bicyclo[2,2,2]octane system was uncertain. An X-ray analysis of kobusine methiodide has now shown it to have structure (9). It follows that pseudokobusine has structure (10) (ref. 1, pp. 182—185). 

A simple route to the tetracarbocyclic skeleton of the gibberellins which possesses the advantage of generating both the bridgehead hydroxy-group and the terminal methylene of the bicyclo[3,2,l]octane system has been described. ... 

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