Domino enzymatic

For the reason of comparison and the development of new domino processes, we have created a classification of these transformations. As an obvious characteristic, we used the mechanism of the different bond-forming steps. In this classification, we differentiate between cationic, anionic, radical, pericyclic, photochemical, transition metal-catalyzed, oxidative or reductive, and enzymatic reactions. For this type... 

Such an inter-type difference will not be utilized in this book, mainly because it complicates the classification and is not necessary as tbe focus is placed on the substrates and the products. The argument is also valid for enzymatic transformations [12d, 14], where one enzymatic system with one enzyme or different independent enzymatic systems with one or more enzymes may be used. In Nature, as well as in several artificial enzymatic domino reactions, a mixture of different enzymes catalyzing independent cycles is employed. 

During the past few years, increasing numbers of reports have been published on the subject of domino reactions initiated by oxidation or reduction processes. This was in stark contrast to the period before our first comprehensive review of this topic was published in 1993 [1], when the use of this type of transformation was indeed rare. The benefits of employing oxidation or reduction processes in domino sequences are clear, as they offer easy access to reactive functionalities such as nucleophiles (e. g., alcohols and amines) or electrophiles (e. g., aldehydes or ketones), with their ability to participate in further reactions. For that reason, apart from combinations with photochemically induced, transition metal-catalyzed and enzymatically induced processes, all other possible constellations have been embedded in the concept of domino synthesis. 

Enzymatic trigger reaction Effect of trigger reaction Domino process... 

In 1996, the first successful combination of an enzymatic with a nonenzymatic transformation within a domino process was reported by Waldmann and coworkers [6]. These authors described a reaction in which functionalized bicy-clo[2.2.2]octenediones were produced by a tyrosinase (from Agaricus bisporus) -catalyzed oxidation of para-substituted phenols, followed by a Diels-Alder reaction with an alkene or enol ether as dienophile. Hence, treatment of phenols such as 8-1 and an electron-rich alkene 8-4 in chloroform with tyrosinase in the presence of oxygen led to the bicyclic cycloadducts 8-5 and 8-6 in moderate to good yield (Scheme 8.1). It can be assumed that, in the first step, the phenol 8-1 is hydroxylated by tyrosinase, generating the catechol intermediate 8-2, which is then again oxidized enzy-... 

The application of enzymes for the mild hydrolysis of esters has been well established as a convenient method, and hence can be regarded as a standard methodology in organic synthesis. Accordingly, the expectation is met that such enzymatic ester cleavage reactions are included in domino processes. In this context, a number of publications describe enzyme-initiated fragmentation reactions. 

A similar domino process involving the opening of two epoxide moieties after an enzymatic ester hydrolysis has been described by Robinson and coworkers [16]. Treatment of 8-32 with PLE in an aqueous buffer solution at pH 7.5-8 led to 8-34 in 70% yield after formation of 8-33 (Scheme 8.8). 

The Shen group has devised a domino process wherein after an enzymatic cleavage of a glycoside a rearrangement sequence takes place [18]. Subjecting multifloroside 8-38 to P-glucosidase in acetate buffer (Scheme 8.10) afforded jasmolac-tone analogues such as 8-39 in a rather low yield. 

A combination of an enzymatic kinetic resolution and an intramolecular Diels-Alder has recently been described by Kita and coworkers [23]. In the first step of this domino process, the racemic alcohols ( )-8-55 are esterified in the presence of a Candida antarctica lipase (CALB) by using the functionalized alkenyl ester 8-56 to give (R)-8-57, which in the subsequent Diels-Alder reaction led to 8-58 in high enantioselectivity of 95 and 91 % ee, respectively and 81 % yield (Scheme 8.15). In-... 

Another very recent development in the field of enzymatic domino reactions is a biocatalytic hydrogen-transfer reduction of halo ketones into enantiopure epoxides, which has been developed by Faber, Bornscheuer and Kroutil. Interestingly, the reaction was carried out with whole lyophilized microbial cells at pH ca. 13. Investigations using isolated enzymes were not successful, as they lost their activity under these conditions [26]. 

Waldmann et al. used tyrosinase which is obtained from Agaricus bisporus for the oxidation of phenols to give ortho-quinones via the corresponding catechols in the presence of oxygen (scheme 33).1881 A combination of this enzymatic-initiated domino process with a Diels-Alder reaction yields the functionalized bicyclic components 164 and 165 as a 33 1 mixture starting from simple p-methyl-phenol 160 in the presence of ethyl vinyl ether 163 as an electron rich dienophile via the intermediates 161 and 162 in an overall yield of 77%. 

Enzymatic DKRs have also been applied in domino one-pot processes [97]. The combination of a lipase-catalyzed resolution with an intramolecular Diels-Alder reaction led to interesting building blocks for the synthesis of natural products such as compactin [98,99] or forskolin [100-102], A ruthenium catalyst is employed for the racemization of the slow reacting enantiomer of the starting material. The DKR with lipase B from C. antarctica delivered high enantiomeric excesses which could mainly be contained through the Diels-Alder reaction (Fig. 12). 

The question of oxidative cyclization versus a polyepoxide cascade in the biosynthesis of polyether natural products has been reviewed <1995AGE298>. Enzymatic domino reactions involving epoxide intermediates have been reviewed <2001CSR332>. The DNA-damaging activity of epoxides and other oxidized species has been examined using chemical models <1995ACR289>. 

Scheme 8.28 Enzymatic domino DKR-Diels-Alder reaction with a diruthenium...

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