Abstract
Thymidylate synthase from Pneumocystis carinii (PcTS) is an especially important drug target, since P. carinii is a fungus that causes opportunistic pneumonia infections in immune-compromised patients and is among the leading causes of death of AIDS patients. Thymidylate synthase (TS) is the sole enzyme responsible for the de novo production of deoxythymidine monophosphate and hence is crucial for DNA replication in every organism. Inhibitors selective for P. carinii TS over human TS would be greatly beneficial in combating this disease. The crystal structure of TS from P. carinii bound to its substrate, dUMP, and a cofactor mimic, CB3717, was determined to 2.6 A resolution. A comparison with other species of TS shows that the volume of the closed PcTS active-site is 20 % larger than that of five other TS closed active-sites. A two-residue proline insert that is strictly conserved among all fungal species of TS, and a novel C-terminal closing interaction involving a P. carinii-specific tyrosine residue are primarily responsible for this increase in volume. The structure suggests several options for designing an inhibitor specific to PcTS and avoiding interactions with human TS. Taking advantage of the residue substitutions of P. carinii TS over human TS enables the design of a selective inhibitor. Additionally, the larger volume of the active-site of PcTS is an important advantage for designing de novo inhibitors that will exclude the human TS active-site through steric hindrance.
PDB: 1CI7
Comment
This work from the Stroud lab at UCSF reflected the more or less collaborative efforts of three postdocs who committed a lot of time trying to figure out how best to process a remarkably poor dataset from the only crystal of 'PCTS'. Amy published a second paper from the same structure as well.