Oxazoline enolates, chiral

Reagent control This involves the addition of a chiral enolate or allyl metal reagent to an achiral aldehyde. Chiral enolates are most commonly formed through the incorporation of chiral auxiliaries in the form of esters, acyl amides (oxazolines), imides (oxazolidinones) or boron enolates. Chiral allyl metal reagents are also typically joined with chiral ligands. 

The utility of chiral oxazoline enolates in asymmetric synthesis has elegantly been demonstrated by Myers (106,120). The stereoselective aldol condensations of these enolates have been examined in a hmited number of cases (eq. [107]) (32,121). Assuming that the enolate formed has the geometry indicated in 164 (120b), the diastereoselection observed for both the aldol condensation and the previously reported alkylations favors electrophile attack on the Re face as indicated. In contrast, the unsubstituted enolate 163b exhibits significantly poorer diastereoface selection with a range of aldehydes (eq. [108]) (121). 

In fact, the usefulness of chiral oxazoline enolates in asymmetric synthesis had been already demonstrated by Meyers [24]. Evans obtained enantiofacial selectivities (or enantiomeric excesses = e.e) equal to or greater than 99% (Table 9.4). 

Chiral oxazolines were the first ehiral auxiliaries used for asymmetrie enolate alkylations. Subsequent studies led to the development of a number of other ehiral auxiliaries (34-38) ineluding those reported by Evans, Myers, Enders, Sehollkopf, and others, whieh are now widely used in asymmetrie synthesis. Although these new auxiliaries frequently provide higher yields and enantioseleetivities than the oxazolines originally developed by Meyers, the pioneering work of Meyers laid the groundwork for these later studies. 

Optically active, a-branched lactams 30 have been built by means of Meyers chiral auxiliaries [ 10]. The key step included the diastereoselective a-alkylations of the initially formed co-i -sulfonamido oxazolines 26. The R or S configuration in the product 27 was obtained reacting the appropriately configured intermediate aza enolates with alkyl halides, high diastereoselectivities have been reported. Several attempts to achieve a complete ring closure to the lactams 30 (via 29) by an acidic cleavage of the oxazolines 27 failed. Varying mixtures of... 

Jorgensen s group44a carried out the reaction using the anhydrous form of chiral bis(oxazoline) coordinated copper complex. Complex 106 containing 83 as the chiral ligand was found to be the most effective. As shown in Scheme 5-32, the asymmetric hetero Diels-Alder reaction of //.y-unsaturated a-keto esters with acyclic enol ethers results in products with excellent yield and enantioselectivity. 

A new chiral proton source (111), based on an asymmetric 2-oxazoline ring, has been found to be capable of effecting asymmetric protonation of simple prochiral metal enolates (112) to give corresponding ketones (113) which need not bear polar groups. 

Since ketone R)-16 was prepared in a non-selective way when an achiral imino enolate was alkylated, it was considered whether alkylation of chiral enolates, such as that of oxazoline 18, with benzyl bromide 14, would provide stereoselective access to the corresponding alkylation product 19 with R-configuration at C(8) (Scheme 4). Indeed, alkylation of 18 with 14 gave the biaryl 19 and its diastereoisomer almost quantitatively, in a 14 1 ratio. However, reductive hydrolysis using the sequence 1. MeOTf, 2. NaBH4, and 3. H30", afforded hydroxy aldehyde 20 in 25% yield at best. Furthermore, partial epimerization at C(8) occurred (dr 7.7 1). An alternative route, using chiral hydrazones, was even less successful. 

Conversion of 2 to the highly crystalline oxazolidinone 3 with phosgene has been described by Thornton who has employed this substance as a chiral auxiliary in asymmetric aldol reactions of its N-propionyl derivative. Kelly has also used an oxazoline derived from 3 as a chiral auxiliary in asymmetric alkylation of a glycolate enolate. Oxazolidinone 3 has also been prepared from 2 with diethyl carbonate in the presence of potassium carbonate. The conversion of 2 to the oxazolidinone 3 is accomplished using triphosgene in this procedure because of the high toxicity of phosgene. 

The carbanion generated by ot-proton abstraction of a 2-alkyloxazoline is capable of typical enolate chemistry. Thus, the carbanion was found to react with nitriles to give an enamine, with formate esters to give an aldehyde that can be trapped,with chiral sulfinate esters to give chiral sulfoxides,and with alkylating agents. A carbamate-protected aminomethyl chiral oxazoline was deprotonated and alkylated with diastereoselectivities up to 92% de. ... 

Evans has reported that the cationic C2-symmetric chiral Lewis acid Cu(ll)bis(oxazoline) complex promotes the hetero-Diels-Alder reaction of 0 ,/3-unsaturated acyl phosphonates with enol ethers to give the cycloadducts with excellent ee (Scheme 52). As well as simple dihydropyrans, various fused bis-dihydropyrans are also reported <1998JA4895, 2000JA1635>. 

Reviews on stoichiometric asymmetric syntheses M. M. Midland, Reductions with Chiral Boron Reagents, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 2, Chap. 2, Academic Press, New York, 1983 E. R. Grandbois, S. I. Howard, and J. D. Morrison, Reductions with Chiral Modifications of Lithium Aluminum Hydride, in J. D. Morrison, ed.. Asymmetric Synthesis, Vol. 2, Chap. 3, Academic Press, New York, 1983 Y. Inouye, J. Oda, and N. Baba, Reductions with Chiral Dihydropyridine Reagents, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 2, Chap. 4, Academic Press, New York, 1983 T. Oishi and T. Nakata, Acc. Chem. Res., 17, 338 (1984) G. Solladie, Addition of Chiral Nucleophiles to Aldehydes and Ketones, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 2, Chap. 6, Academic Press, New York, 1983 D. A. Evans, Stereoselective Alkylation Reactions of Chiral Metal Enolates, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 3, Chap. 1, Academic Press, New York, 1984. C. H. Heathcock, The Aldol Addition Reaction, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 3, Chap. 2, Academic Press, New York, 1984 K. A. Lutomski and A. I. Meyers, Asymmetric Synthesis via Chiral Oxazolines, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 3, Chap. 

Masked chiral a-hetero substituted carboxylic acid enolates have also shown utility in dia-stereoselective additions to nitroalkenes. For example, derivatives of a-hydroxycarboxylic acids, e.g. l,3-dioxolan-4-ones (187) a-amino acids, e.g. 1,3-imidazolidin-4-ones (188) and a-amino-fi-hydroxy-carboxylic acids, e.g. methyl 1,3-oxazolidin-4-carboxylates (189) and methyl l,3-oxazolin-4-carboxy-lates (190), have been employed.1S0a Further, diastereoselective additions of chiral (3-hydroxyesters (191), via the enediolates, to nitroalkenes (40) afford predominant anr/ -P-hydroxyesters (192 Scheme... 

The chiral bis(oxazoline)/Cu(II) complex with OTf or SbFg as a counter anion effectively promotes the enantioselective hetero Diels-Alder reaction of enol ethers with acyl phosphonates to give chiral enol phosphonates as synthetically useful chiral building blocks [64] (Eq. 8A.40). 

Alkylation of chiral 2-(aminomediyl)oxazoline (105 Z = CH2Ph) at the exocychc carbon—using -butyllithium and an alkyl hahde—proceeds with negligible de. However, when the amine reactant is changed to a carbamate, e.g. (105 Z = C02Ph), the products exhibit up to 92% de.m This is ascribed to a preferred formation of an U-enolate-type intermediate during deprotonation, due to complexation of the lithium by the carbamate carbonyl. 

The structurally novel antimitotic agent curacin A (1) was prepared with an overall yield of 2.5 % for the longest linear synthesis. Three of the four stereogenic centers were built up using asymmetric transformations one was derived from a chiral pool substrate. Key steps of the total synthesis are a hydrozirconation - transmetalation protocol, the stereoselective formation of the acyclic triene segment via enol triflate chemistry and another hydrozirconation followed by an isocyanide insertion. For the preparation of the heterocyclic moiety of curacin A (1) the oxazoline - thiazoline conversion provides efficient access to the sensitive marine natural product. 

As shown below (Section IV), the lithium enolates are remarkable vectors of asymmetry. Indeed, the development of many chiral auxiliaries has been associated (in particular through their ester derivatives) with the enolate chemistry. We conclude this section with the contribution of a group of mathematical chemists who have tried to quantify the desymmetrization induced on enolate orbitals by common chiral auxiliaries219. This unusual viewpoint suggests that when the allylic stereogenic center is in the / position, the (Z) isomer has more chirality content than its (E) counterpart. This paper also concludes that in the enolates derived from Meyers oxazolines, the lithium cation distorts the structure but has little influence on its chirality. 

Double stereodifferentiation was effective in the protonation of the lithium enolate of (—)-menthone using chiral imides derived from Kemp s triacid. This protonating agent gathers both the chelation with the chiral oxazoline and a cumbersome protonating imide site. Moreover, a catalytic version was set up using 0.1 equivalent of the chiral imide in the presence of a non-chiral proton source (Scheme 73)357,358. 

Chiral bis(oxazolines) 51 with an oxalylic acid backbone were used for the Ru-catalyzed enantioselective epoxidation of tran5-stilbene yielding franx-l,2-diphenyloxirane in up to 69% ee [24]. The asymmetric addition of diethylzinc to several aldehydes has been examined with ferrocene-based oxazoline ligand 52 [25], resulting in optical yields from 78-93% ec. The imide 53 derived from Kemp s triacid containing a chiral oxazoline moiety was used for the asymmetric protonation of prochiral enolates [26]. Starting from racemic cyclopentanone- and cyclohexanone derivatives, the enantioenriched isomers were obtained in 77-98 % ee. 

Asymmetric addition to chiral oxazolines.1 The chiral 1-oxazolinylnaphthalene 2, obtained by the reaction of ( + )-l with a-naphthylamide, reacts with an organolithium to form an intermediate enolate that is trapped on the opposite face by an electrophile to give 3 as a mixture of diastereomers in the ratio 83 17. The major product results from attack of the organolithium at the p-face. The diastereomers are separable by flash chro-... 

The chiral ferrocenylphosphine.gold(I)-catalyzed aldol reaction of a-alkyl a-isocya-nocarboxylates 92 with paraformaldehyde gives optically active 4-alkyl-2-oxazoline-4-carboxylates 93 with moderate to good enantioselectivity [46], The absolute configuration (S) of the product indicates that the reaction occurs selectively at the si face of the enolate as illustrated in Fig. 2. These oxazolines 93 can be converted into a-alkyl-serine derivatives 94 (Sch. 24). 

On alkylation of 2-(aminomethyl)oxazolines (42) and (43), stereochemical induction is evident for the tertiary carbamates (43), but not the tertiary amines (42) this is apparently a consequence of prior complexation of the carbamate carbonyl group to the base and kinetic preference for ( )-enolate formation on deprotonation. 4-Alkenylamides (44) having a )S-chiral centre have been found to undergo syn-selective a-iodination with iodine to give syn-a-iodoalkenamides, via an intermediate... 

Catalytic enantioselective versions of the inverse electron demand cycloaddition have also been reported. For example, the C-(diisopropylamino)carbonyl A -phenyl nitrone reacted with 7-substituted allylic alcohols in the presence of diethylzinc, iodine, pyridine A -oxide, and a catalytic amount of enantiopure DIPT to afford 3,5-m-disubstituted isoxazolidines with high enantioselectivity (Scheme 124) <2002CL302>. Enantioselective cycloaddition of nitrones to enol ethers was achieved in the presence of chiral binaphthol-aluminium and chiral copper-bis(oxazoline) catalysts <1999JA3845, 1999CC811, 1999JOC2353, 2000JOC9080>. 

After the screening of chiral Lewis acids which could be used in aqueous solvents, the combination of Cu(II) triflate and bis(oxazoline) ligands [30] was found to give good enantioselectivities. Several examples of the catalytic asymmetric al-dol reactions of aldehydes with silyl enol ethers are summarized in Table 14-5 [31]. 

Addition of diethyl aluminum chloride at — 78 °C to a,/ -unsaturated oxazolidinone (154) affords an aluminum enolate that, on hydroxylation with (63a), gives the / -ethyl-a-hydroxy amide (155) with high anti selectivity (Equation (38)) <91AG(E)694>. Formation of the enolate of oxazoline thiol ester (156) under chelation (NaHMDS) and stereoelectronic (NaHMDS/HMPA) control gives the syn and anti alcohols (157), respectively, on hydroxylation with (63a) in good to excellent yield and better than 95% diastereoselectivity (Scheme 28) <93JOC6180>. A counterion dependent reversal in stereochemistry has also been reported for the hydroxylation of chiral amide enolates where the auxiliary was 2-pyrrolidinemethanol <85TL3539>. 

The oxazoline 184 provides an attractive approach to lactacystin as it is a protected form of 3-hydroxyleucine. The other half of the molecule was made in the LeukoSite synthesis by a very different method the alkylation of an Evans chiral auxiliary. This was chosen partly because they wished to vary the alkyl group on the pyrrolidone ring and we use the propyl compound as example. The phenylalanine derived oxazolidinone 193 (chapter 27) was acylated and then the titanium enolate of 194 was alkylated to give 195 with very high selectivity and the chiral auxiliary removed to give the simple acid 196. 

Our research group independently found a catalytic enantioselective proto-nation of preformed enolate 47 with (S,S)-imide 30 founded on a similar concept (Scheme 5) [51]. The chiral imide 30, which has an asymmetric 2-oxazoline ring and is easily prepared from Kemp s triacid and optically active amino alcohol, is an efficient chiral proton source for asymmetric transformation of simple metal enolates into the corresponding optically active ketones [50]. When the lithium enolate 47 was treated with a stoichiometric amount of the imide 30, (K)-en-riched ketone 48 was produced with 87% ee. By a H-NMR experiment of a mixture of (S,S)-imide 30 and lithium bromide, the chiral imide 30 was found to form a complex rapidly with the lithium salt. We envisaged that a catalytic asym-... 

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