Cytotoxic methylthioadenosine analogues

Doerksen, Thomas

09 September 2016

The gene for methylthioadenosine phosphorylase (MTAP) is absent in almost 30% of cancers, opening a door for selective chemotherapy. One strategy to target the absence of MTAP involves the design of a cytotoxic methylthioadenosine (MTA) analogue. Non-cancerous cells would break down the cytotoxic analogue, since they contain MTAP, but cancerous cells would not, since they do not have MTAP. However, before such a compound can be made, we need to better understand the types of substrates accommodated by MTAP. The purpose of this thesis was therefore to explore a series of MTA analogues, probing the structure-function relationships between MTAP and specific structural modifications of MTA. Nine phenylthioadenosine (PTA) derivatives bearing ortho-, meta-, or para- methyl carboxylate, carboxylate, and hydroxymethyl substituents were synthesized and tested for cytotoxicity and as substrates for MTAP. The biological results of these nine compounds suggested that addition of substituents to the ortho-position was not tolerated by MTAP, and substituents similar to the hydroxymethyl might be accommodated by MTAP. None of the compounds were cytotoxic. This informed the design of ten more PTA derivatives, most of which were synthesized and tested for cytotoxicity and as substrates for MTAP. The range of functionalities included an amine, an acetamide, a urea, an isovaleramide, and an N-nitrosourea group inspired by the known anticancer agent lomustine. The amine derivatives of PTA were the best substrates of all MTA analogues tested (including PTA). The meta-amine derivative and the meta-isovaleramide showed minor cytotoxicity. Finally, the urea derivatives were moderate substrates of MTAP, and this pointed towards the future creation of other nitrosoureas as potential cytotoxic MTAP substrates. / Graduate / 2017-08-25

Drug discovery

Chemotherapy

Methylthioadenosine phosphorylase

Chemical synthesis

Methylthioadenosine

Methylthioadenosine analogue

Cytotoxicity

MTAP