User:Chemistryluvr/sandbox

Taxol is a tetracyclic diterpene, and the biosynthesis of diterpenes starts with a FPP molecule being elongated by the addition of an IPP molecule in order to form geranylgeranyl diphosphate (GGPP). The biosynthesis of Taxol contains nineteen steps. These 19 steps can be considered in several steps, with the first step being the formation of the taxane skeleton, which then undergoes a series of oxygenations. Following the oxygenations, two acetylations and a benzoylation occur on the intermediate. The oxygenation of the taxane core is believed to occur on C5 and C10, C2 and C9, C13 followed by C7, and a C1 hydroxylation later on in the pathway. Later in the pathway, an oxidation at C9 forms a ketone functional group and an oxetane, forming the intermediate baccatin III. The final steps of the pathway include the formation of a C13-side chain which is attached to baccatin III. The biosynthesis of Taxol is illustrated in more detail in the figure, with steps 1-7 all occurring in one enzyme, taxadiene synthase (TS on the figure). Taxol's biosynthesis begins with E,E,E-GGPP losing pyrophosphate via an SN1 mechanism (step 1 in the figure). The double-bond attacks the cation via electrophilic addition, yielding a tertiary cation and creating the first ring closure (step 2). Another electrophilic attack occurs, further cyclizing the structure by creating the first 6-membered ring and creating another tertiary cation (step 3). An intramolecular proton transfer occurs, attacking the verticillyl cation (step 4) and creating a double bond, yielding a tertiary cation. An electrophilic cyclization occurs in step 5, and an intramolecular proton transfer attacks the taxenyl cation (step 6). This forms the fused ring structure intermediate known as taxadiene. Taxadiene then undergoes a series of 10 oxidations via NADPH, forming the intermediate taxadiene-5α-acetoxy-10β-ol (several steps later in the figure). A series of hydroxylations and esterficiations occur, forming the intermediate 10-deacetyl-baccatin III, which undergoes a further series of esterifications and side-chain hydroxylation. This finally yields the product taxol.