Dehydratase polyketide

All polyketides use the same general mechanism for chain elongation. Acetyl coenzyme A provides acetate (C2) units, which are condensed by a ketosynthase (KS). This in turn catalyzes condensation of the growing chain onto an acyl carrier protein (ACP), as generalized in Fig. 1.4. Enzymes such as ketoreductase (KR), enoyl reductase (ER), and dehydratase (DH) establish the oxidation state of caibon during translation, imparting structural diversity. Successive translation of each module leads to a chain of the required length that is eventually passed to thioeste-rase (TE), which releases the chain as a free acid or lactone. 

DJ Bevitt, J Staunton, PF Leadlay. Mutagenesis of the dehydratase active site in the erythromycin-producing polyketide synthase. Biochem Soc Trans 21 30S, 1992. 

Figure 1 Polyketide biosynthesis. Polyketide backbones are formed via condensations from acyl-CoA thioesters of carboxylic acids. The (3-ketone which results from each condensation can undergo a series of reductive steps analogous to fatty acid biosynthesis. However, either none or only some of the reductive activities may occur in a given cycle. This allows PKSs to generate diversity through selection of priming and extender units, variation of the reductive cycle, and stereoselectivity. (ACP, acyl carrier protein AT, acyl transferase KS, ketosynthase DH, dehydratase ER, enoylreductase KR, ketoreductase TE, thioesterase.) The structure depicted in the lower right-hand corner is representative of the possible structural variations that can arise during polyketide biosynthesis.

Figure 4 (a) The aromatic polyketide biosynthetic cycle (ACP, acyl carrier protein KS, P-ketoacyl synthase KR, P-ketoacyl reductase DH, dehydratase ER, enoyl reductase), (b) The complex polyketide biosynthetic cycle. 

Figure 2 Conventional modular type I PKS paradigm, (a) Individual domains in a full type I polyketide synthase extension module. Homodimeric contacts are made in the N-terminal docking, ketosynthase, dehydratase, enoyi reductase, and C-terminal docking domains, (b) PKS system for 10-deoxymethynolide and narbonolide generation.

DH Dehydratase, found in fatty acid syntheases and polyketide syntheases, dehydrates the 3-OH of acyl thioester... 

Figure 3. Relationship between polyketide and fatty acid biosynthesis. The simplest ( minimaV) PKSs possess ketosynthase activity and produce linear polyketide products. In contrast, FASs also catalyze successive ketoreduction-dehydration-enoyl reduction reactions following each condensation. Diverse PKSs may perform none, part, or all of this reductive sequence. KS, ketosynthase KR, ketoreductase DH, dehydratase ER, enoyl reductase.

Figure 4. Organization of representative type 1, II, and III polyketide synthases. Upper modular arrangement of DEBS 1,2,3 subunits Center orientation and arrangement of open reading frames in actinorhodin gene cluster Lower chalcone synthase subunit. AT, acyltransferase ACP, acyl carrier protein KS, ketosynthase KR, ketoreductase DH, dehydratase ER, enoyl reductase TE, thioesterase TA, tailoring enzyme R/T, regulatory/transport related AR aromatase CY, cyclase.

Many of the above studies have given invaluable information on the stereochemical outcome of the ketoreductase and dehydratase catalysed reactions occurring during polyketide assembly in fungi. A number of studies of incorporation of [2H3]acetate have provided indirect information on the stereochemistry of the final enoyl reductase reaction. Thus 2H label is found at the pro-... 

Figure 1 Hypothetical pentaketide biosynthetic system, which illustrates the enzymatic logic of type I modular polyketide synthases (PKSs) and the catalytic role of acyl transferase (AT) domains. Each AT domain selects substrates from the cellular pool and tethers them as thioesters to acyl carrier protein (ACP) domains. In a typical PKS module, the AT and ACP domains are present in all modules. The ketosynthase (KS) domain is present in all chain extension modules. The dehydratase (DH), enoyl reductase (ER), and ketoreductase (KR) domains are optional domains. The final thioesterase (TE) domain catalyzes the release of the product from the PKS.

Since the PKS (polyketide synthase) gene cluster for actinorhodin (act), an antibiotic produced by Streptomyces coelicolor[ 109], was cloned, more than 20 different gene clusters encoding polyketide biosynthetic enzymes have been isolated from various organisms, mostly actinomycetes, and characterized [98, 100]. Bacterial PKSs are classified into two broad types based on gene organization and biosynthetic mechanisms [98, 100, 102]. In modular PKSs (or type I), discrete multifunctional enzymes control the sequential addition of thioester units and their subsequent modification to produce macrocyclic compounds (or complex polyketides). Type I PKSs are exemplified by 6-deoxyerythronolide B synthase (DEBS), which catalyzes the formation of the macrolactone portion of erythromycin A, an antibiotic produced by Saccharopolyspora erythraea. There are 7 different active-site domains in DEBS, but a given module contains only 3 to 6 active sites. Three domains, acyl carrier protein (ACP), acyltransferase (AT), and P-ketoacyl-ACP synthase (KS), constitute a minimum module. Some modules contain additional domains for reduction of p-carbons, e.g., P-ketoacyl-ACP reductase (KR), dehydratase (DH), and enoyl reductase (ER). The thioesterase-cyclase (TE) protein is present only at the end of module 6. 

Modular PKSs are large multifunctional enzymes. Active sites (domains) within these enzymes ketosynthases (KS), acyltransferases (AT), dehydratases (DH), enoyl reductases (ER), ketoreductases (KR), acyl carrier proteins (AGP) and thioesterases (TE) are organized into modules such that each module catalyzes the stereospecific addition of a new monomer onto a growing polyketide chain and also sets the reduction level of the carbon atoms of the resulting intermediate [70]. In 1994, the heterologous expression of the complete erythromycin polyketide synthase was accomplished. The recombinant... 

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