|Systematic (IUPAC) name|
|Half-life||1.0 to 4.5 hours.|
|Mol. mass||414.405 g/mol|
| (what is this?)
Podophyllotoxin (abbreviated as PPT), otherwise known as podofilox, is a non-alkaloid toxin lignan extracted from the roots and rhizomes of Podophyllum species. Under the trade name Condylox, a topical gel, it is used on the skin to treat external genital warts, caused by some types of the human papillomavirus (HPV). Under the trade name Wartec solution, it is used on the skin to treat external genital warts and other warts. PPT and its derivatives display a wide selection in medical applications such as purgative, vesicant, antirheumatic, antiviral, and antitumor agents. These derivatives include etoposide, teniposide, and etopophos. Their anticancer activity has been heavily under study and used in various chemotherapies, including lung cancer, lymphomas, and genital tumors.
Natural abundance 
It is present at concentrations of 0.3 to 1.0% by mass in the rhizome of American Mayapple (Podophyllum peltatum). Another common source of podophyllotoxin is the rhizomes of Podophyllum hexandrum Royle (Berberidaceae).
Structural characteristic 
The structure of podophyllotoxin was first elucidated in the 1930s. Podophyllotoxin bears a four consecutive chiral centers, labelled C-1 through C-4. The molecule also contains four almost planar fused rings. Four ends of podophyllotoxin have oxygen atoms at the functional groups dioxoles, methoxys, lactone, and secondary alcohol.
Derivatives of podophyllotoxin are synthesised as properties of the rings and carbon 1 through 4 are diversified. For example, ring A is not essential to antimitotic activity. Aromatization of ring C leads to loss of activity, possibly from ring E no longer being placed on the axial position. In addition, the stereochemistry at C-2 and C-3 configures a trans-lactone, which has more activity than the cis counterpart. Chirality at C-1 is also important as it implies an axial position for ring E.
Although the biosynthetic route of podophyllotoxin has yet to be completely elucidated, several studies have suggested a common pathway starting from coniferyl alcohol being converted to (+)-pinoresinol in the presence of a one-electron oxidant  through dimerization of stereospecific radical intermediate. Pinoresinol is subsequently reduced in the presence of co-factor NADPH to first lariciresinol, and ultimately secoisolariciresinol. Lactonization on secoisolariciresinol gives rise to matairesinol. Secoisolariciresinol is assumed to be converted to yatein through appropriate quinomethane intermediates, leading to podophyllotoxin.
Side effects 
Application can be immediately followed by burning or itching. Small sores, itching and peeling skin can also follow.
Usages and applications 
Podophyllotoxin displays a range of activities such as cathartic, purgative, antiviral, vesicant, and antihelminthic. Additionally, the lignan and its derivatives are exciting leads for anti-tumor agent. For instance, podophyllotoxin is the pharmacological precursor for the important anticancer drug etoposide.
Mechanism of action 
Podophyllotoxin's anticancer property can be attributed to the inhibition of tubulin polymerization. As podophyllotoxin binds to the tubulin, microtubule formation is prevented. Consequently, podophyllotoxin arrests the cell cycle in the metaphase.
Podophyllotoxin derivatives display binding activity to the enzyme topoisomerase II during the late S and early G2 stage. For instance, etoposide binds and stabilizes the temporary break caused by the enzyme, disrupts the reparation of the break through which the double-stranded DNA passes, and consequently stops DNA unwinding and replication. Mutants resistant to either podophyllotoxin, or to its topoisomerase II inhibitory derivatives such as etoposide (VP-16), have been described in Chinese hamster cells. The mutually exclusive cross-resistance patterns of these mutants provide a highly specific mean to distinguish the two kinds of podophyllotoxin derivatives. Mutant Chinese hamster cells resistant to podophyllotoxin are affected in a protein P1 that was later identified as the mammalian HSP60 or chaperonin protein.
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