Enhancement of 5-fluorouracil sensitivity by an rTS signaling mimic in H630 colon cancer cells.

The rTSbeta protein has been hypothesized to synthesize signaling molecules that can down-regulate thymidylate synthase. These molecules share biological and chemical properties with acyl-homoserine lactones (AHL), suggesting some AHLs might act as rTS signaling mimics and down-regulate thymidylate synthase. We have determined that the AHL, 3-oxododecanoyl homoserine lactone (3-oxo-C12-(L)-HSL) can down-regulate thymidylate synthase protein at 10 micromol/L and reduce H630 (human colorectal cancer) growth by 50% at 23 micromol/L (IC50) in cell culture. At its IC50 concentration, 3-oxo-C12-(L)-HSL reduces the apparent IC50 of 5-fluorouracil (5-FU) from 1 micromol/L to 80 nmol/L (12-fold) in a colony formation assay. 3-Oxo-C12-(L)-HSL enhances the activity of 5-fluorodeoxyuridine, tomudex, and taxol but not the activity of 5-fluorouridine, methotrexate or Adriamycin. The unexpected interaction with taxol probably results from effects of the AHL on tubulin expression. Differences in taxol sensitivity, tubulin, and cellular morphology between H630 and the thymidylate synthase and rTSbeta-overproducing, 5-FU-resistant H630-1 cell line as determined by colony formation assays, Western analysis of one-dimensional and two-dimensional gels, and photomicroscopy confirm that cytoskeletal changes are induced by the AHL or by rTS signaling. Isozyme differences in thymidylate synthase and rTSbeta also exist in the two cell lines. Phosphorylation of rTSbeta amino acid S121 is shown to occur and is decreased at least 10-fold in the drug-resistant cells. The data presented provide support for further investigations of rTS signaling mimics as enhancers to thymidylate synthase-directed chemotherapy, evidence that the phosphorylation state of rTSbeta may be a marker for 5-FU resistance and a previously unrealized relationship between rTS signaling and the cytoskeleton.

A novel function for the rTS gene.

The rTS gene codes for a naturally occurring antisense RNA to thymidylate synthase (TS) mRNA and two proteins (rTSalpha and rTSbeta). The role of the major protein product of rTS, rTSbeta has been linked to alterations in TS protein expression, but the precise function of rTSbeta is unknown. In this report we demonstrate that increased expression of rTSbeta is associated with the decrease in TS protein expression due to production of novel, diffusible signal molecules. These signal molecules are produced more abundantly when rTSbeta amounts are elevated. This hypothesis is supported by the demonstration that the rTSbeta-overproducing cell line H630-1 can downregulate TS protein in other cells without direct cellular contact. These cells are shown to secrete significant amounts of lipophilic metabolites derived from methionine, in contrast to cells that do not overproduce rTSbeta. In support of the hypothesis that rTSbeta is essential for the generation of these compounds, we demonstrate that rTSbeta can catalyze the transfer of the carboxyl carbon of methionine from S-adenosylmethionine to a lipophilic acceptor molecule in vitro. We propose rTS is involved in regulation of TS through a novel methionine-based signaling pathway.