Substrate protection strategy

Na+-coupled glucose transporters have also been tentatively identified using substrate protection strategies with protein modifying reagents (Peerce and Wright, 1984) and by monoclonal antibodies raised against brush-border membrane extracts (Wu and Lever, 1987). 

Hbhne et al. reported a substrate protection strategy that enhanced both the rate and the enantioselectivity of transaminase catalyzed kinetic resolution reactions [32]. The co transaminase catalyzed resolution of the pharmaceutically important syn thons 3 amino pyrrolidine 53 and 3 aminopiperidine 54 was imp roved by the addition of protecting groups to the substrate amines. Reaction rates were improved by up to 50 fold, and product ee was improved from 86 to 99% (Figure 14.23). 

Bridged bicycloketones are attractive substrates due to the structural complexity of the scaffolds. The high chemoselectivity of the biotransformation for the carbonyl oxygenation allows for a functional decoration without the need for elaborate protection strategies. Subsequent chemical elaboration of the biooxidation products opens up rapid and efficient novel synthetic pathways towards various target compounds. 

Furthermore, multicomponent reactions can also be performed under fluorous-phase conditions, as shown for the Ugi four-component reaction [96], To improve the efficiency of a recently reported Ugi/de-Boc/cyclization strategy, Zhang and Tempest introduced a fluorous Boc group for amine protection and carried out the Ugi multicomponent condensation under microwave irradiation (Scheme 7.84). The desired fluorous condensation products were easily separated by fluorous solid-phase extraction (F-SPE) and deprotected by treatment with trifluoroacetic acid/tet-rahydrofuran under microwave irradiation. The resulting quinoxalinones were purified by a second F-SPE to furnish the products in excellent purity. This methodology was also applied in a benzimidazole synthesis, employing benzoic acid as a substrate. 

This clever strategy is illustrated in Scheme 10.5. Selective cleavage of short N -protected peptide substrates with chymotrypsin from the surface area of TentaGel-... 

The skeleton of 47 is a heterocyclic tricyclo[6.2.0.0 ]decane and the similarity to the tricyclic kelsoene is obvious. In the course of the above-mentioned studies we had become curious whether the high facial diastereocontrol in the photocycloaddition reaction could be extended to other bridged 1,6-hexadienes. Kelsoene was an ideal test case. The retrosynthetic strategy for kelsoene along an intramolecular [2+2]-photocycloaddition pathway appeared straightforward. To avoid chemoselectivity problems the precursor to kelsoene should not contain additional double bonds. Alcohol 48, the hydroxy group of which was possibly to be protected, seemed to be a suitable substrate for the photocycloaddition (Scheme 14). Access to the 1,2,3-substi-... 

Palladium-catalyzed, Wacker-type oxidative cycHzation of alkenes represents an attractive strategy for the synthesis of heterocycles [139]. Early examples of these reactions typically employed stoichiometric Pd and, later, cocat-alytic palladium/copper [140-142]. In the late 1970s, Hegedus and coworkers demonstrated that Pd-catalyzed methods could be used to prepare nitrogen heterocyles from unprotected 2-allylanilines and tosyl-protected amino olefins with BQ as the terminal oxidant (Eqs. 23-24) [143,144]. Concurrently, Hosokawa and Murahashi reported that the cyclization of allylphenol substrates can be accomplished by using a palladium catalyst with dioxygen as the sole stoichiometric reoxidant (Eq. 25) [145]. 

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