Chiral synthesis substrate control

In Ugi four-component reactions (for mechanism, see Section 1.4.4.1.) all four components may potentially serve as the stereodifferentiating tool65. However, neither the isocyanide component nor the carboxylic acid have pronounced effects on the overall stereodiscrimination60 66. As a consequence, the factors influencing the stereochemical course of Ugi reactions arc similar to those in Strecker syntheses. The use of chiral aldehydes is commonly found in substrate-controlled syntheses whereas the asymmetric synthesis of new enantiomerically pure compounds via Ugi s method is restricted to the application of optically active amines as the chiral auxiliary group. 

The latter work is a rare example in which a high stereoselectivity was reported for a substrate-controlled Ugi synthesis. In asymmetric Ugi reactions carried out with removable chiral auxiliaries, however, high diastei eoselections were achieved (see Section 1.4.4.3.1.). 

In principle, asymmetric synthesis involves the formation of a new stereogenic unit in the substrate under the influence of a chiral group ultimately derived from a naturally occurring chiral compound. These methods can be divided into four major classes, depending on how this influence is exerted (1) substrate-controlled methods (2) auxiliary-controlled methods (3) reagent-controlled methods, and (4) catalyst-controlled methods. 

The substrate-controlled reaction is often called the first generation of asymmetric synthesis (Fig. 1-30, 1). It is based on intramolecular contact with a stereogenic unit that already exists in the chiral substrate. Formation of the new stereogenic unit most often occurs by reaction of the substrate with an achiral reagent at a diastereotopic site controlled by a nearby stereogenic unit. 

The aldol reaction between a chiral a-amino aldehyde 16 and an acetate derived enolate 17 creates a new stereogenic center and two possible diastereomers. Several different methods for the synthesis of statine derivatives following an aldol reaction have been reported most of them lead to a mixture of the (35,45)- and (3/ ,45)-diastereomers 18 (Scheme 3), which have to be separated by laborious chromatographic methods.[17 211 Two distinct approaches for stereochemical control have been used substrate control and reagent control. 

Conversely, the addition of enantiomerically pure chiral dialkylboranes to enantiomerically pure chiral alkenes can also take place in such a way that substrate control and reagent control of diastereoselectivity act in the same direction. Then we have a matched pair. It reacts faster than the corresponding mismatched pair and with especially high diastereoselectivity. This approach to stereoselective synthesis is also referred to as double stereodifferentiation. 

We sought catalytic methods that would allow formation of chiral tethers that are asymmetric at the silicon center. Synthesis of the chiral tether by our method would be advantageous for the reasons we described in the Introduction. Chiral information could be transferred during an intramolecular reaction. This would be an example of substrate-controlled transformation. 

Chiral synthesis, also called asymmetric synthesis, is synthesis which preserves or introduces a desired chirality. Principally, there are three different methods to induce asymmetry in reactions. There can be either one or several stereogenic centres embedded in the substrate inducing chirality in the reaction (i.e. substrate control) or an external source providing the chiral induction (i.e. reagent control). In both cases the obtained stereoselectivity reflects the energy difference between the diastereomeric transition states. 

Asymmetric ylide reactions such as epoxidation, cyclopropanation, aziridination, [2,3]-sigmatropic rearrangement and alkenation can be carried out with chiral ylide (reagent-controlled asymmetric induction) or a chiral C=X compound (substrate-controlled asymmetric epoxidations). Non-racemic epoxides are significant intermediates in the synthesis of, for instance, pharmaceuticals and agrochemicals. 

Alkylations of acyclic enolates containing a collection of chiral auxiliary groups have been used successfully for the asymmetric synthesis of carboxylic acids. The chiral, nonracemic substrates that have been used include amides, imides, esters, imine derivatives of glycinates and acyl derivatives of chiral transition metals. In these systems either extraannular or chelate-enforced intraannular chirality transfer may control the sense of the alkylation step. 

The second total synthesis of swinholide A was completed by the Nicolaou group [51] and featured a titanium-mediated syn aldol reaction, followed by Tishchenko reduction, to control the C21-C24 stereocenters (Scheme 9-30). The small bias for anri-Felkin addition of the (Z)-titanium enolate derived from ketone 89 to aldehyde 90 presumably arises from the preference for (Z)-enolates to afford anti-Felkin products upon addition to a-chiral aldehydes [52], i.e. substrate control from the aldehyde component. 

Evans synthesis of bryostatin 2 (113) also relied upon asymmetric aldol reactions for the introduction of most of the 11 stereocenters [58], At different points, the synthesis used control from an auxiliary, a chiral Lewis acid, chiral ligands on the enolate metal and substrate control from a chiral aldehyde. Indeed, this represents the current state of the art in the aldol construction of complex polyketide natural products. 

In the previous synthesis, two asymmetric aldol reactions using dienyl silyl ethers were described, one using a chiral Lewis acid for stereoinduction while the other used substrate control from a chiral aldehyde. This can be compared with the use of chiral dienolate 131 in the synthesis of a Ci-Cie fragment of the bryo-statins (Scheme 9-41) [59J. Here, the menthyl-derived auxiliary is covalently attached to the enolate, and again an excellent level of asymmetric induction was achieved on addition to aldehyde 132 to give adduct 133. 

An alternative strategy has been used by ourselves in the synthesis of the aply-ronine macrocycle 166, whereby chiral ketones 167 and 168 were used in two substrate-controlled aldol reactions (Scheme 9-49) [67]. Following reduction, this... 

Our synthesis of the C1-C7 fragment 227 of oleandolide started with a substrate-controlled tin-mediated aldol reaction of a-chiral ketone (5)-18 which afforded syn adduct 52 with 93% ds. This same transformation could also be achieved using reagent control with (Ipc)2BOTf, albeit with lower selectivity (90% ds). In a key step, treatment of the aldol adduct 52 with (-i-)-(Ipc)2BH led to controlled reduction of the C3 carbonyl together with stereoselective hydrobora-tion of the C -Cv olefin, affording the desired triol 228 with 90% ds. 

Substrate-Controlled Chiral Amine Synthesis via C H Amination... 

The use of substrate control in rhodium catalyzed C H aminations is covered in detail in Espino and Du Bois recent review of rhodium catalyzed oxidative amina tion [51]. A brief summary of relevant material is provided here, leading to a discussion of recent advances in the synthesis of chiral amines from achiral substrates. Rhodium catalyzed C H amination proceeds via a concerted insertion process rendering it a stereospecific transformation. Thus, the appropriate choice of an enantioenriched starting material can facilitate the synthesis of enantioenriched amines, which would often be particularly difficult to access in any other manner. As exemplified in Scheme 12.9, the C H insertion reaction of enantiomerically pure carbamate 9 was accomplished with complete retention of configuration providing the chiral oxazolidinone 10 in greater than 98% ee [13]. 

In a separate, elegant use of 165, Rychnovsky and coworkers have carried out a diastereoselective addition of methyl acetate-derived silyl ketene acetal to aldehyde 174 to afford adduct 175 in high diastereomeric purity (Scheme 15) [102]. Hydroxy ester 175 was subsequently employed as an intermediate in the total synthesis of the polyene macrolide antibiotic Roflamycoin. This work highlights a novel application of the chiral catalyst system in reagent-controlled coupling of chiral functionahzed substrates which by themselves display only mod-... 

According to the general principles of asymmetric synthesis, chiral induction can be effected via substrate, reagent, or external (catalyst) control. Effective substrate control in the sense of induced diastereoselectivity requires a preformed stereogenic center within the substrate. For organometallic catalytic conversions a stereospecific reaction course and simple diastereoselectivity, as outlined above, is prerequisite. 

In terms of versatility in asymmetric synthesis, chiral auxiliary methodology is often favored over a substrate-controlled process, since the preexisting stereogenicity can be removed (and recovered) subsequent to reaction. This leads, in end effect, to an enantioselective rather than diastereoselective transformation. This section discusses the advances achieved in chiral auxiliary technology for metal-mediated [3 + 2] cycloadditions to electron-deficient olefins68,69. 

Schreiber et al. have described the first synthesis of (+)-discodermolide and of its (-)-antipode by using the same strategy. The synthesis of (+)-discodermolide was achieved by the coupling of three fragments 6, 8, 11 of approximately equal complexity (Schema 1, 2, 3) which were synthesized from (S)-(+)-3-hydroxy-2-methylpropionate 1 by using Roush s chiral boronates, allowing the control of nine of discodermolide s thirteen stereocenters. All the other stereocenters were set by substrate-controlled reactions. 

This implies all chiral centers are created at the time of the Diels-Alder reaction, but some are formed prior to the Diels-Alder and some after. It is important to specify the timing of the reactions and their sequence. If chiral centers are created from prochiral substrates, control of the geometry of diene and alkene is important. If chiral centers are incorporated into the diene and alkene, an asymmetric synthesis is required, possibly using a chiral starting material. 

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