Thymidylate synthase (TS) is a major target in the chemotherapy of colorectal cancer and some other neoplasms. The emergence of resistance to the treatment is often related to the increased levels of TS in cancer cells, which have been linked to the elimination of TS binding to its own mRNA upon drug binding, a feedback regulatory mechanism, and/or to the increased stability to intracellular degradation of TS⅐drug complexes (versus unliganded TS). The active site loop of human TS (hTS) has a unique conformation resulted from a rotation by 180°relative to its orientation in bacterial TSs. In this conformation, the enzyme must be inactive, because the catalytic cysteine is no longer positioned in the ligandbinding pocket. The ordered solvent structure obtained from high resolution crystallographic data (2.0 Å) suggests that the inactive loop conformation promotes mRNA binding and intracellular degradation of the enzyme. This hypothesis is supported by fluorescence studies, which indicate that in solution both active and inactive forms of hTS are present. The binding of phosphate ion shifts the equilibrium toward the inactive conformation; subsequent dUMP binding reverses the equilibrium toward the active form. Thus, TS inhibition via stabilization of the inactive conformation should lead to less resistance than is observed with presently used drugs, which are analogs of its substrates, dUMP and CH 2 H 4 folate, and bind in the active site, promoting the active conformation. The presence of an extension at the N terminus of native hTS has no significant effect on kinetic properties or crystal structure.
Thymidylate synthase (TS)1 catalyzes the reductive methylation of 2Ј-deoxyuridine 5Ј-monophosphate (dUMP) to thymidine 5Ј-monophosphate (dTMP), using the co-substrate, 5,10-methylenetetrahydrofolate (CH 2 H 4 folate) as a 1-carbon donor and reductant. The physical structures of bacterial TSs have been relatively well defined, and crystallographic data, in concert with data derived from kinetic, spectroscopic, and sitedirected mutagenesis studies, have led to a detailed understanding of the catalytic mechanism of these enzymes (1). In contrast, relatively few investigations of mammalian TS structure and catalysis have been conducted. The three-dimensional structure of the native human TS (hTS) has been reported previously (2). The data showed a surprising feature not observed in TSs from other sources: loop 181-197 containing the catalytic cysteine, Cys-195, was in an inactive conformation, rotated ϳ180°with respect to its orientation in bacterial TSs, with the sulfhydryl of Cys-195 over 10 Å from the location of sulfhydryls of corresponding cysteine residues in bacterial enzymes. Subsequent determination of the structure of a ternary inhibitory complex between closely related ratTS (rTS) and dUMP and Tomudex (3) has shown that the ligands bind to the enzyme in the active conformation. Recently, it was found that also in the hTS⅐dUMP⅐Tomudex complex hTS is in the active conformation (4). The inactive conformation has...
