Antibiotics different functions

The compatibility with different functional groups, the remarkable regio-and stereoselectivity, and the development of asymmetric procedures have made benzannulation an attractive methodology for the synthesis of natural products with densely functionalized quinoid or fused phenolic substructures [13-20], Some pertinent examples are the syntheses of vitamins K and E [17], and the production of anthracyclinones or naphtoquinone antibiotics [13, 14a, 15, 21]. 

The generation of hydroxy ketones by the brominolysis of stannylenes has been used several times in total synthesis. Experiment G [see Eq. (15)] describes a key step in the total synthesis of the antibiotic (+)-spectinomycin [12,13]. It is remarkable that the two oxygen atoms bound to the tin atom originate from hydroxyl groups, which are port of different functions, a hemiketal and a secondary alcohol. The oxidation is selective for one alcoholic function ont of three. The same product was obtained by W-bromosuccinimide oxidation of the tributylstarmyl ether. 

Antibiotics are an extremely important class of human and veterinary drugs. Chemically, they constitute a widely diverse group with different functions and modes of operation. They can be derived from living organisms or obtained synthetically. However, all of them exhibit antibacterial properties (i.e., either inhibit the growth of, or kill, bacteria). 

An example of how different functional groups can yield compounds with similar physicochemical properties is shown with sulfanilamide antibiotics. In Figure 2.3, the structures of sulfanilamide... 

The Sonogashira reaction provides an important way to make the ene-diyne antibiotics. Symmetrical ene-diynes may be synthesized in one step from two moiecuiesofa terminai aikyne and Z-dihaloethylene. The ene-diyne part of the molecule does the remarkable Bergmann cyclization to give a benzene diradical the ene-diyne is able to penetrate DNA and the diradical is able to react with it, giving the compounds anticancer activity. To make the most biologically active compounds, however, the reaction is performed sequentially, allowing different functionality on each of the aikyne units. 

Important members of this toxin family are Clostridium difficile toxins A and B, which are implicated in antibiotics-associated diarrhea and pseudomembranous colitis. The large clostridial cytotoxins are single-chain toxins with molecular masses of 250-308 kDa. The enzyme domain is located at the N terminus. The toxins are taken up from an acidic endosomal compartment. They glucosylate RhoA at Thr37 also, Rac and Cdc42 are substrates. Other members of this toxin family such as Clostridium sordellii lethal toxin possess a different substrate specificity and modify Rac but not Rho. In addition, Ras subfamily proteins (e.g., Ras, Ral, and Rap) are modified. As for C3, they are widely used as tools to study Rho functions [2] [4]. 

Nanaomycin A 103 and deoxyfrenolicin 108 are members of a group of naphthoquinone antibiotics based on the isochroman skeleton. The therapeutic potential of these natural products has attracted considerable attention, and different approaches towards their synthesis have been reported [65,66]. The key step in the total synthesis of racemic nanaomycin A 103 is the chemo-and regioselective benzannulation reaction of carbene complex 101 and allylacety-lene 100 to give allyl-substituted naphthoquinone 102 after oxidative workup in 52% yield [65] (Scheme 47). The allyl functionality is crucial for a subsequent intramolecular alkoxycarbonylation to build up the isochroman structure. However, modest yields and the long sequence required to introduce the... 

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