Polypropionate

Many examples of stereospecific allylation consistent with the above mechanism have been reported. As one example, the regioselective and highly diastereoselective allylation of the lactone 17 with the optically active allylic phosphate 16 proceeded with no appreciable racemization of the allylic part to give the lactones l8 and 19, and the reaction has been used for the synthesis of a polypropionate chain[26]. 

Stereoselective addition of cuprates to ji-alkoxy enoates of type 49 [17] isee Sdiemes 6.8 and 6.9) bas been used in die crrnstruction of polypropionate-type structures. Tlius, a sequence of diastereoselective cuprate addition, etiolate for-ruabon, and diastereoselective oxygenation widi Davis s reagent bas been applied iteratively to provide a Cio segment of Rifaruycin S i60) [ 17c, d]. 

Scli ir 6.9. Conctriictlon of the polypropionate cegment of Rlfamycln S through IteraHve dlactereocelectlve cuprate addition to ao/clic enoatec. a) Me Cn Li, TMSCI,... 

This highly convergent synthesis amply demonstrates the utility of Evans s asymmetric aldol and alkylation methodology for the synthesis of polypropionate-derived natural products. By virtue of the molecular complexity and pronounced lability of cytovaricin, this synthesis ranks among the most outstanding synthetic achievements in the macrolide field. 

A reiterative application of a two-carbon elongation reaction of a chiral carbonyl compound (Homer-Emmonds reaction), reduction (DIBAL) of the obtained trans unsaturated ester, asymmetric epoxidation (SAE or MCPBA) of the resulting allylic alcohol, and then C-2 regioselective addition of a cuprate (Me2CuLi) to the corresponding chiral epoxy alcohol has been utilized for the construction of the polypropionate-derived chain ]R-CH(Me)CH(OH)CH(Me)-R ], present as a partial structure in important natural products such as polyether, ansamycin, or macro-lide antibiotics [52]. A seminal application of this procedure is offered by Kishi s synthesis of the C19-C26 polyketide-type aliphatic segment of rifamycin S, starting from aldehyde 105 (Scheme 8.29) [53]. 

In some cases, if necessary, a C(3)-regioselective addition of cuprate can be accomplished by the use of a sterically demanding protecting group - such as an -OTr or -OMMTr group - on C(l), as described in the synthesis of the polypropionate segment present in (-)-amphidinolide P and (+)-amphidinolide K [54]. 

Polypropionate chains with alternating methyl and hydroxy substituents are structural elements of many natural products with a broad spectrum of biological activities (e.g. antibiotic, antitumor). The anti-anti stereotriad is symmetric but is the most elusive one. Harada and Oku described the synthesis and the chemical desymmetrization of meso-polypropionates [152]. More recently, the problem of enantiotopic group differentiation was solved by enzymatic transesterification. The synthesis of the acid moiety of the marine polypropionate dolabriferol (Figure 6.58a) and the elaboration of the C(19)-C(27) segment of the antibiotic rifamycin S (Figure 6.58b) involved desymmetrization of meso-polypropionates [153,154]. 

The sunuhaneous double Diels-Alder addition of l,l-bis(3,5-dimethylfur-2-yl)ethane (8) with a biS dienophile such as diethyl ( , )-4-oxohepta-2,5-diene-1,7-dioate was proposed as new, asymmetric synthesis of long-chain polypropionate fragments and analogues <96TL4149>. 

During the course of the development of our group s alkylation/reductive decyanation strategy, a very reliable method for distinguishing between syn-and anfz-l,3-diols was discovered [17,18]. The acetonide methyl groups reliably display diagnostic C-NMR chemical shifts, allowing for stereochemistry to be determined simply by inspection (Fig. 1). Evans later extended the C-NMR chemical correlation to polypropionate chains [19,20]. 

Entry 10 was used in conjunction with dihydroxylation in the enantiospecific synthesis of polyols. Entry 11 illustrates the use of SnCl2 with a protected polypropionate. Entries 12 and 13 result in the formation of lactones, after MgBr2-catalyzed additions to heterocyclic aldehyde having ester substituents. The stereochemistry of both of these reactions is consistent with approach to a chelate involving the aldehyde oxygen and oxazoline oxygen. 

Scheme 24) [38]. Chemoselective enolization of the less substituted enone moiety under hydrogenation conditions accompanied by subsequent aldol reaction provided the corresponding hydroxyl-enones, such as 87-89, which could be converted to various building blocks for polypropionate synthesis. p-Me2N styryl vinyl enone also was employed successfully as an enolate precursor, as demonstrated by the formation of hydroxy enone 90. 

Tridachiahydropyrone belongs to the family of marine polypropionates [69]. Efforts towards its total synthesis have recently led to a revision of the structure with the new proposal 2-147 [70]. The construction of the highly substituted cyclohex-enone moiety 2-146 which could be incorporated into this natural product [71] has been described by Perkins and coworkers (Scheme 2.33) [70, 72]. The conjugate addition/ Dieckmann-type cydization utilizing organocopper species as Michael donors afforded the enantiopure 2-145 in 68% yield. A further methylation of the (3-ketoester moiety in 2-145 followed by an elimination led to the desired cydohex-enone 2-146. 

B. striata, its secondary metabolic pattern, consisting of a series of uncommon polypropionates, is almost identical to that of its prey [36,37], On the contrary, if the mollusc, under maintenance in an aquarium, feeds on Haminoea navicula, it discharges [5] in the form of a yellow secretion two Haminoea metabolites, the haminols (8,9), structurally related to navenone-A (I), which possess alarm pheromone properties [38] for H. navicula. Studies on a third Aglajidae mollusc [39, 40], Philinopsis speciosa, led to the characterization of a 2-alkyl-pyridine, pulo upone (10), as a minor constituent co-occurring with two polypropionates closely related to the metabolites from the pair P. depicta-B. striata. 

Fig, 3. Polypropionates from Cyerce cristallina (cyercenes) and from Cyerce nigricans (a, b)... 

Pulmonates are air-breathing molluscs that do not include many families and genera [68]. Siphonaria species from many distinct geographical areas possess a series of secondary metabolites with polypropionate skeletons characterized by the presence of ketal, pyrone and furanone moieties [47]. A rigorous biosynthetic experiment [69] proved that Siphonaria denticulata is able to... 

Biogenetic considerations [71], and a correlation of all polypropionates from pulmonate molluscs led to revision of the relative stereochemistry of pectinatone (20) and nor-pectinatone (21), metabolites of the pulmonate Siphonaria pectinata [72, 73] the point had already been questioned by Oppolzer s synthesis [74] and was definitively confirmed by two independent X-ray diffraction studies [71, 75] of pectinatone (20). 

Silyltitanation of 1,3-dienes with Cp2Ti(SiMe2Ph) selectively affords 4-silylated r 3-allyl-titanocenes, which can further react with carbonyl compounds, C02, or a proton source [26]. Hydrotitanation of acyclic and cyclic 1,3-dienes functionalized at C-2 with a silyloxy group has been achieved [27]. The complexes formed undergo highly stereoselective addition with aldehydes to produce, after basic work-up, anti diastereomeric (3-hydroxy enol silanes. These compounds have proved to be versatile building blocks for stereocontrolled polypropionate synthesis. Thus, the combination of allyltitanation and Mukayiama aldol or tandem aldol-Tishchenko reactions provides a short access to five- or six-carbon polypropionate stereosequences (Scheme 13.15) [28],... 

Scheme 13.15. Polypropionate building blocks via the stereoselective allyltitanation —Mukayiama aldol sequence.

An interesting pericyclic-anionic-pericyclic domino reaction showing a high stereoselectivity is the cycloaddition-aldol-retro-ene process depicted in scheme 20.1581 The procedure presumably starts with a [4+2]-cycloaddition of diene 98 and S02 in presence of a Lewis acid. After opening of the formed adduct reaction with (Z)-silyl vinyl ether 99 leads to a mixture of alk-2-enesulfinic acids 101. It follows a retro-ene reaction which affords a 7 3 mixture of the products 102 and 103. The reaction described by Vogel et al is a nice example for the efficient generation of polypropionate chains with the stereoselective formation of three stereogenic centers and one (0-double bond in a three-component domino reaction in its strict definition. 

Scheme 20. Stereoselective synthesis of polypropionate fragments by a three-component pericyclic domino reaction...

The addition of an enolsilane to an aldehyde, commonly referred to as the Mukaiyama aldol reaction, is readily promoted by Lewis acids and has been the subject of intense interest in the field of chiral Lewis acid catalysis. Copper-based Lewis acids have been applied to this process in an attempt to generate polyacetate and polypropionate synthons for natural product synthesis. Although the considerable Lewis acidity of many of these complexes is more than sufficient to activate a broad range of aldehydes, high selectivities have been observed predominantly with substrates capable of two-point coordination to the metal. Of these, benzy-loxyacetaldehyde and pyruvate esters have been most successful. 

Polypropionate synthesis, 20 138 Polypropylene (PP), 20 523-548 24 272. See also Olefin fibers Propylene polymer entries Spheripol technology Spherizone technology advanced material, 2 693 asbestos substitute, 3 314t, 315 can coatings, 26 39 catalyst systems for, 20 525-528 catalyst yield for, 20 531-532 coatings, 7 40 conducting, 7 525... 

Although the epothilones are structurally less complex that the taxanes, we foresaw several synthetic issues concerning this venture that would require careful attention. The structures of the epothilones invite retrosynthetic dissection into two regions. The polypropionate domain of the epothilones constitutes carbons C1-C8, while the... 

With the appropriate vinyl iodide in hand, we sought to prepare the polypropionate moiety suitable for eventual Suzuki merger. Thus, we envisioned merger of... 

Scheme 2.6 provides an overall view of our strategy towards solving this problem. As depicted, our late generation synthesis embraces three key discoveries that were crucial to its success. We anticipated that the difficult Cl-Cll polypropionate domain could be assembled through a double stereodifferentiating aldol condensation of the C5-C6 Z-metalloenolate system B and chiral aldehyde C. Two potentially serious problems are apparent upon examination of this strategy. First was the condition that the aldol reaction must afford the requisite syn connectivity between the emerging stereocenters at C6-C7 (by uk addition) concomitant with the necessary anti relationship relative to the resident chirality at C8 (by Ik diastereoface addition). Secondly, it would be necessary to steer the required aldol condensation to C6 in preference to the more readily enolizable center at C2. 

Dianion Equivalents Corresponding to the Polypropionate Domain of Epothilone B 119 2.9... 

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