Cyanohydrins natural

For the synthesis of cyanohydrins nature provides the chemist with R- and S-selective enzymes, the hydroxynitrile lyases (HNL) [4-7]. These HNLs are also known as oxynitrilases and their natural function is to catalyze the release of HCN from natural cyanohydrins like mandelonitrile and acetone cyanohydrin. This is a defense reaction of many plants. It occurs if a predator injures the plant cell. The reaction also takes place when we eat almonds. Ironically the benzaldhyde released together with the HCN from the almonds is actually the flavor that attracts us to eat them. 

A few cyanohydrins and ethers of cyanohydrins occur naturally One species of millipede stores benzaldehyde cyanohydrin along with an enzyme that catalyzes its cleavage to benzaldehyde and hydrogen cyanide m separate compartments above its legs When attacked the insect ejects a mixture of the cyanohydrin and the enzyme repelling the invader by spraying it with hydrogen cyanide... 

The reaction is used for the chain extension of aldoses in the synthesis of new or unusual sugars In this case the starting material l arabinose is an abundant natural product and possesses the correct configurations at its three chirality centers for elaboration to the relatively rare l enantiomers of glucose and mannose After cyanohydrin formation the cyano groups are converted to aldehyde functions by hydrogenation m aqueous solution Under these conditions —C=N is reduced to —CH=NH and hydrolyzes rapidly to —CH=0 Use of a poisoned palladium on barium sulfate catalyst prevents further reduction to the alditols... 

Naturally occurring compounds called cyanogenic glycosides, such as lotau-stralin, release hydrogen cyanide, HCN, when treated with aqueous acid. The reaction occurs by hydrolysis of the acetal linkage to form a cyanohydrin, which then expels HCN and gives a carbonyl compound-fa) Show the mechanism of the acetal hydrolysis and the structure of the cyanohydrin that results. 

The optical purities were determined solely from the optical rotations of the (/ -cyanohydrins thus obtained. Only for (/ )-a-hydroxybcnzeneacetonitrile, available from benzaldehyde, was an optical purity determined by comparison with the natural product. Variation of the reaction conditions (pH, temperature, concentration) in water/ethanol led to no appreciable improvementsl4. The use of organic solvents that are not miscible with water, but in which the enzyme-catalyzed reaction can still take place, resulted in suppression of the spontaneous addition to a significant extent, whereas the enzyme-catalyzed formation of cyanohydrins was only slightly slower (Figure l)13. 

Several reports on DKR of cyanohydrins have been developed using this methodology The unstable nature of cyanohydrins allows continuous racemization through reversible elimination/addition of HCN under basic conditions. The lipase-catalyzed KR in the presence of an acyl donor yields cyanohydrin acetates, which are not racemized under the reaction conditions. 

In 1992, Oda et al. reported a one-pot synthesis of optically active cyanohydrin acetates from aldehydes, which were converted to the corresponding racemic cyanohydrins through transhydrocyanation with acetone cyanohydrin, catalyzed by a a strongly basic anion-exchange resin [46]. The racemic cyanohydrins were acetylated by a lipase from P. cepacia (Amano) with isopropenyl acetate as the acyl donor. The reversible nature of the base-catalyzed transhydrocyanation enabled continuous racemization of the unreacted cyanohydrins, thereby effecting a total conversion (Figure 4.21). 

Alkylations of 4-cyano-l,3-dioxanes (cyanohydrin acetonides) represent a highly practical approach to syn-l,3-diol synthesis. Herein we present a comprehensive summary of cyanohydrin acetonide chemistry, with particular emphasis on practical aspects of couplings, as well as their utility in natural product synthesis. Both 4-acetoxy-l,3-dioxanes and 4-lithio-1,3-dioxanes have emerged as interesting anri-l,3-diol synthons. The preparation and utility of these two synthons are described. 

Stork first demonstrated the utility of protected cyanohydrins as acyl anion equivalents in 1971 [2]. The acetal-protected cyanohydrin 8 was transformed into the corresponding anion with LDA in THF/HMPA, which was then alkylated with a range of alkyl halides, including secondary bromides (Scheme 2). A mild acidic hydrolysis yielded a cyanohydrin, which provided the ketone after treatment with base. The Stork cyanohydrin alkylation and its variants have become important methods in natural product synthesis [3,4]. 

Most often, the application of cyanohydrin acetonide couplings to a natural product synthesis calls for coupling with a primary alkyl halide. This has proven successful in every instance. However, on occasion, alkylations of more hindered epoxides or hindered alkyl halides are desirable. These reactions are less dependable. 

The cyanohydrin acetonide method has been a valuable tool in natural product synthesis. The first reported demonstration of this strategy was the total synthesis of (-)-roxaticin [29]. In this approach, treatment of cyanohydrin 57 with an excess of the C2-symmetrical dibromide 58 provided 59, without overalkylation (Scheme 6). A second alkylation involving cyanohydrin 60 gave 61 in excellent yield. (-)-Roxaticin was accessed in ca. 10 steps from tetraacetonide 62. 

New synthetic methods are the lifeblood of organic chemistry. Synthetic efforts toward natural products often provide the impetus for the development of novel methodology. Reactive synthons derived from 1,3-dioxanes have proven to be valuable intermediates for both syn- and anfz-1,3-diols found in many complex natural products. Coupling reactions at the 4-position of 1,3-dioxanes exploit anomeric effects to generate syu-1,3-diols (cyanohydrin acetonides), autz-1,3-diols (4-acetoxy-1,3-dioxanes), and either syn- or azztz-1,3-diols (4-lithio-1,3-dioxanes). In the future, as biologically active polyol-containing natural products continue to be discovered, the methods described above should see much use. 

For successful DKR two reactions an in situ racemization (krac) and kinetic resolution [k(R) k(S)] must be carefully chosen. The detailed description of all parameters can be found in the literature [26], but in all cases, the racemization reaction must be much faster than the kinetic resolution. It is also important to note that both reactions must proceed under identical conditions. This methodology is highly attractive because the enantiomeric excess of the product is often higher than in the original kinetic resolution. Moreover, the work-up of the reaction is simpler since in an ideal case only the desired enantiomeric product is present in the reaction mixture. This concept is used for preparation of many important classes of organic compounds like natural and nonnatural a-amino acids, a-substituted nitriles and esters, cyanohydrins, 5-alkyl hydantoins, and thiazoUn-5-ones. 

In contrast to 2-amino acids, only a few non-racemic 2-hydroxy acids are found in nature. Hydrolysis of non-racemic cyanohydrins offers an interesting general route to (R)- as well as (5 )-2-hydroxy carboxylic acids. 

Both enzymes belong to the family of a,p-hydrolases." The active site of MeHNL is located inside the protein and connected to the outside through a small channel, which is covered by the bulky amino acid tryptophane 128." It was possible to obtain the crystal structure of the complex with the natural substrate acetone cyanohydrin with the mutant SerSOAla of MeHNL. This complex allowed the determination of the mode of substrate binding in the active site." A summary of 3D structures of known HNLs was published recently." " ... 

S (2)-hydroxy-3-butenenitrile from acrolein and HCN trans hydrocyanation using, for instance, acetone cyanohydrin Hydrolysis of nitriles to amides, e.g. acrylonitrile to acrylamide Isomerization of glucose to fructose Esterifications and transesterifications Interesterify positions 1 and 3 of natural glycerides Oxidation of glucose to gluconic acid, glycolic acid to glyoxalic acid... 

Hydroxynitrile lyases (HNLs or oxynitrilases) catalyze C—C bond-forming reactions between an aldehyde or ketone and cyanide to form enantiopure cyanohydrins (Figure 1.15), which are versatile building blocks for the chiral synthesis of amino acids, hydroxy ketones, hydroxy acids, amines and so on [68], Screening of natural sources has led to the discovery of both... 

This example (the cyanohydrin reaction) appears to me to provide a simple solution for the natural asymmetric synthesis. The formation of the sugar, as the plant physiologists assume, occurs in the chlorophyll grain, which itself is composed of optically active substances.. . . The prepared sugar is released and later on used by the plant, as is known, for the preparation of other organic components. Their asymmetry is thus explainedfrom the nature of the building material. Of course, they also provide material for new chlorophyll... 

Since the reaction has been reviewed recently (12) only a few additional facts will be mentioned. Many optically active cyanohydrins can be prepared (33) with e.e. s of 84 to 100% by the use of the flavopnotein D-oxynitrilase adsorbed on special (34) cellulose ion-exchange resins. Although the enzyme is stable, permitting the use of a continuously operating column, naturally only one enantiomer, usually the R isomer, is produced in excess. This (reversible) enzyme-catalyzed reaction is very rapid (34). Nonenzymic catalysts, such as the cinchona alkaloids, permit either enantiomer to be prepared in excess. 

Gregory, Cyanohydrins in nature and the laboratory biology, preparations, and synthetic... 

The two established Hnls, those from L. usitatissimum and P. amygdalus, have found biocatalytic applications for the production of (i )-cyanohydrins. The former of these Hnls is the least widely applied, the natural substrates being acetone cyanohydrin or (i )-2-butanone cyanohydrin (Table 1) [28]. Although an improved procedure for the purification of this enzyme has been reported [27] it is still only available in limited quantities (from 100 g of seedlings approximately 350 U of enzyme are obtained). It was found that this enzyme transforms a range of aliphatic aldehyde and ketone substrates [27], the latter of which included five-membered cyclic (e.g. 2-methylcyclopentanone) and chlorinated ketone substrates. In contrast, attempts to transform substituted cyclohexanones and 3-methylcyclopentanone failed and it was even found that benzaldehyde deactivated the enzyme. 

Therefore, the chiral cyanohydrins are valuable and versatile synthons as their single hydroxyl asymmetric centre is accompanied by at least one other chemical functionality. Thus with careful functional group protection, differential and selective chemical transformations can be performed. Such synthetic techniques lead to production of interesting bioactive compounds and natural products. These products include intermediates of j3-blockers 15 1117], j3-hydroxy-a-amino acids 16 [118],chiral crown ethers 17 [lll],coriolic acid 18 [120], sphingosines 19 [121], and bronchodilators such as salbutamol 20 [122] (Fig. 3). 

These features, together with the reversible, thermoneutral nature of the cyanohydrin formation, make the reaction potentially useful for applications in dynamic chemistry. This was also recently shown in a DCR study [4],... 

Salicin is an (9-glycoside of a phenol, namely salicyl alcohol. Salicin is a natural antipyretic and analgesic found in willow bark, and is the template from which aspirin (acetylsalicylic acid, see Box 7.13) was developed. Prunasin from cherry laurel is an example of a cyanogenic glycoside, hydrolysis of which leads to release of toxic HCN (see Box 7.7). It is the (9-glucoside of the alcohol mandelonitrile, the trivial name for the cyanohydrin of benzaldehyde. It is the further hydrolysis of mandelonitrile that liberates HCN. 

A very popular alternative to aspirin and acetaminophen is ibuprofen, which has tradenames such as Motrin and Advil . It can be synthesized from isobutylbenzene by a Friedel-Crafts acylation with acetyl chloride, followed by formation of a cyanohydrin. Treatment with H2/Pd reduces the benzylic hydroxyl to a hydrogen and hydrolysis of the nitrile gives the carboxylic acid. There are at least six published syntheses of ibuprofen. This illustrates the difficulty of knowing which technology a particular company is using. At the other extreme is the proprietary nature of some syntheses, where they have not yet been published. 

L-Mannitol does not occur naturally but is obtained by the reduction of L-mannose or L-mannonic acid lactone (80). It can be synthesized from the relatively abundant L-arabinose through the L-mannose and L-glucose cyanohydrins, conversion to the phenylhydrazines which are separated, liberation of L-mannose, and reduction with sodium borohydride (81). Another synthesis is from L-inositol (obtained from its monomethyl ether, quebrachitol) through the diacetonate, periodate oxidation to the blocked dialdehyde, reduction, and removal of the acetone blocking groups (82). 

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