Drug-resistant variants of Escherichia coli thymidylate synthase: effects of substitutions at Pro-254.

Drug-resistant variants of thymidylate synthase (TS) can potentially be used in gene therapy applications to decrease the myelosuppressive side effects of TS-directed anticancer agents or to select genetically modified cells in vivo. Mutations of proline 303 of human TS confer resistance to TS-directed fluoropyrimidines and antifolates (). We generated the corresponding variants in Escherichia coli TS (ecTS), position 254, to better understand the mechanism by which mutations at this residue confer resistance. In addition, because ecTS is intrinsically resistant to several antifolates when compared with human TS, we suspected that greater resistance could be achieved with the bacterial enzyme. The P254L enzyme conferred >100-fold resistance to both raltitrexed and 5-fluoro-2'-deoxyuridine (FdUrd) compared with wild-type ecTS. Four additional mutants (P254F, P254S, P254G, and P254D), each of which complemented growth of a TS-deficient cell line, were generated, isolated, and characterized. Steady-state values of K(m) for dUMP and k(cat) were not substantially different among the variants and were comparable with the wild-type values, but K(m) for methylenetetrahydrofolate (CH(2)H(4)PteGlu) was >10-fold higher for P254D. Values of k(on) and k(off) for nucleotide binding, which were obtained by stopped-flow spectroscopy, were virtually unchanged among the mutants. Drastic differences were observed for CH(2)H(4)PteGlu binding, with K(d) values >15-fold higher than observed with the wild-type enzyme; surprisingly, the proposed isomerization reaction that is very evident for the wild-type enzyme is not observed with P254S. The decrease in affinity for CH(2)H(4)PteGlu correlates well with K(i) values obtained for three TS-directed inhibitors. These results show that mutations at Pro-254 specifically affect the initial binding interactions between enzyme and cofactor and also alter the ability of the mutant enzymes to undergo conformational changes that occur on ternary complex formation. The crystal structure of P254S was determined at 1.5 A resolution and is the most precise structure of TS available. When compared with wild-type TS, the structure shows local conformational changes affecting mostly Asp-253; its carbonyl is rotated approximately 40 degrees, and the side chain forms an ion pair with Arg-225.

Thyroid function during pregnancy.

BACKGROUND: This Case Conference reviews the normal changes in thyroid activity that occur during pregnancy and the proper use of laboratory tests for the diagnosis of thyroid dysfunction in the pregnant patient. CASE: A woman in the 18th week of pregnancy presented with tachycardia, increased blood pressure, severe vomiting, increased total and free thyroid hormone concentrations, a thyroid-stimulating hormone (TSH) concentration within the reference interval, and an increased human chorionic gonadotropin (hCG) beta-subunit concentration. ISSUES: During pregnancy, normal thyroid activity undergoes significant changes, including a two- to threefold increase in thyroxine-binding globulin concentrations, a 30-100% increase in total triiodothyronine and thyroxine concentrations, increased serum thyroglobulin, and increased renal iodide clearance. Furthermore, hCG has mild thyroid stimulating activity. Pregnancy produces an overall increase in thyroid activity, which allows the healthy individual to remain in a net euthyroid state. However, both hyper- and hypothyroidism can occur in pregnant patients. In addition, two pregnancy-specific conditions, hyperemesis gravidarum and gestational trophoblastic disease, can lead to clinical hyperthyroidism. The normal changes in thyroid activity and the association of pregnancy with conditions that can cause hyperthyroidism necessitates careful interpretation of thyroid function tests during pregnancy. CONCLUSION: Assessment of thyroid function during pregnancy should be done with a careful clinical evaluation of the patient's symptoms as well as measurement of TSH and free, not total, thyroid hormones. Measurement of thyroid autoantibodies may also be useful in selected cases to detect maternal Graves disease or Hashimoto thyroiditis and to assess risk of fetal or neonatal consequences of maternal thyroid dysfunction.

Retroviral coexpression of thymidylate synthase and dihydrofolate reductase confers fluoropyrimidine and antifolate resistance.

Retroviral gene transfer of dominant selectable markers into hematopoietic cells can be used to select genetically modified cells in vivo or to attenuate the toxic effects of chemotherapeutic agents. We show that retroviral gene transfer of thymidylate synthase (TS) confers resistance to TS directed anticancer agents and that co-expression of TS and dihydrofolate reductase (DHFR) confers resistance to TS and DHFR cytotoxic agents. Retroviral vectors encoding Escherichia coli TS, human TS, and the Tyr-to-His at residue 33 variant of human TS (Y33HhTS) were constructed and fibroblasts transfected with these vectors conferred comparable resistance to the TS-directed agent fluorodeoxyuridine (FdUrd, approximately 4-fold). Retroviral vectors that encode dual expression of Y33HhTS and the human L22Y DHFR (L22YhDHFR) variants conferred resistance to FdUrd (3- to 5-fold) and trimetrexate (30- to 140-fold). A L22YhDHFR-Y33HhTS chimeric retroviral vector was also constructed and transduced cells were resistant to FdUrd (3-fold), AG337 (3-fold), trimetrexate (100-fold) and methotrexate (5-fold). These results show that recombinant retroviruses can be used to transfer the cDNA that encodes both TS and DHFR and dual expression in transduced cells is sufficiently high to confer resistance to TS and DHFR directed anticancer agents.