Effects of combined administration of DPD-inhibitory oral fluoropyrimidine, S-1, plus paclitaxel on gene expressions of fluoropyrimidine metabolism-related enzymes in human gastric xenografts.

BACKGROUND: S-1 is the most effective oral fluoropyrimidine derivative widely used for patients with gastric carcinoma in Japan. Although S-1 plus taxane has been a promising candidate as an effective chemotherapeutic regimen, the mechanisms of its additive or synergistic anticancer effects and changes in gene expression after the administration of these agents have not yet been fully elucidated. METHODS: Experimental chemotherapy was performed using human gastric carcinoma xenografts, MKN-45 and TMK-1, to examine anticancer effects and gene expressions of fluoropyrimidine metabolism-related enzymes including thymidine phosphorylase (TP), thymidylate synthase (TS), dihydropyrimidine dehydrogenase (DPD), orotate phosphoribosyltransferase (OPRT), and uridine phosphorylase (UP). Nude mice were treated with S-1, paclitaxel, and their combination. After treatment, in vivo antitumor effects of S-1, paclitaxel alone, and their combination and the effects on gene expressions of enzymes involved in 5-fluorouracil metabolism were examined using the RT-PCR method. RESULTS: The combined use of S-1 and paclitaxel showed additive to synergistic antitumor effects on both gastric cancer xenografts. While consistent upregulation of dThPase and DPD gene expression was exhibited after administration of S-1, no further increase of dThPase gene expression after combined use of S-1 with paclitaxel was observed. There was no increase in TS gene expression after the administration of either S-1 alone or paclitaxel alone. CONCLUSION: These results provide some insight into the mechanism and/or rationale underlying the additive to synergistic effect of combined administration of S-1 and paclitaxel in gastric carcinoma.

Uridine protects cortical neurons from glucose deprivation-induced death: possible role of uridine phosphorylase.

We previously reported that uridine blocked glucose deprivation-induced death of immunostimulated astrocytes by preserving ATP levels. Uridine phosphorylase (UPase), an enzyme catalyzing the reversible phosphorylation of uridine, was involved in this effect. Here, we tried to expand our previous findings by investigating the uridine effect on the brain and neurons using in vivo and in vitro ischemic injury models. Orally administrated uridine (50-200 mg/kg) reduced middle cerebral artery occlusion (1.5 h)/reperfusion (22 h)-induced infarct in mouse brain. Additionally, in the rat brain subjected to the same ischemic condition, UPase mRNA and protein levels were up-regulated. Next, we employed glucose deprivation-induced hypoglycemia in mixed cortical cultures of neurons and astrocytes as an in vitro model. Cells were deprived of glucose and, two hours later, supplemented with 20 mM glucose. Under this condition, a significant ATP loss followed by death was observed in neurons but not in astrocytes, which were blocked by treatment with uridine in a concentration-dependent manner. Inhibition of cellular uptake of uridine by S-(4-nitrobenzyl)-6-thioinosine blocked the uridine effect. Similar to our in vivo data, UPase expression was up-regulated by glucose deprivation in mRNA as well as protein levels. Additionally, 5-(phenylthio)acyclouridine, a specific inhibitor of UPase, prevented the uridine effect. Finally, the uridine effect was shown only in the presence of astrocytes. Taken together, the present study provides the first evidence that uridine protects neurons against ischemic insult-induced neuronal death, possibly through the action of UPase.

Denaturation of uridine phosphorylase from Escherichia coli K-12 by guanidine hydrochloride.

Denaturation of uridine phosphorylase from Escherichia coli K-12 by guanidine hydrochloride results in red shift of the maximum in the protein fluorescence spectrum, dissociation of the hexameric enzyme molecule into monomers, and the loss of the enzymatic activity. The initial rate of the enzyme reactivation after the dilution of the enzyme preincubated with guanidine hydrochloride has the second order with respect to protein. It is assumed that the rate of the reactivation process is limited by the reassociation of monomers possessing low enzymatic activity to dimers followed by the rapid step of hexamer formation.

Effects of modifications in the pentose moiety and conformational changes on the binding of nucleoside ligands to uridine phosphorylase from Toxoplasma gondii.

One hundred and fifty analogues of uridine, with various modifications to the uracil and pentose moieties, have been tested and compared with uridine with respect to their potency to bind to uridine phosphorylase (UrdPase, EC 2.4.2.3) from Toxoplasma gondii. The effects of the alpha- and beta-anomers, the L- and D-enantiomers, as well as restricted syn and anti rotamers, on binding were examined. Pseudo-, lyxo-, 2,3'-anhydro-2'-deoxy-, 6,5'-cyclo-, 6,3'-methano-, O5',6-methano- and carbocyclic uridines did not bind to the enzyme. Ribosides bound better than the corresponding xylosides, which were better than the deoxyribosides. The binding of deoxyribosides was in the following manner: 2',3'-dideoxynucleosides > 2',5'-dideoxynucleosides > 2'-deoxyribosides > 3'- and 5'-deoxyribosides. alpha-2'-Deoxyribosides bound to the enzyme, albeit less tightly than the corresponding beta-anomers. The acyclo- and 2,2'-anhydrouridines bound strongly, with the 2,2'-anhydro-derivatives being the better ligands. 2,5'-Anhydrouridine bound to UrdPase less effectively than 2,2'-anhydrouridine and acyclouridine. Arabinosyluracil was at best a very poor ligand, but bound better if a benzyl group was present at the 5-position of the pyrimidine ring. This binding was enhanced further by adding a 5-benzyloxybenzyl group. A similar enhancement of the binding by increased hydrophobicity at the 5-position of the pyrimidine ring was observed with ribosides, alpha- and beta-anomers of the 2'-deoxyribosides, acyclonucleosides, and 2,2'-anhydronucleosides. Among all the compounds tested, 5-(benzyloxybenzyl)-2,2'-anhydrouridine was identified as the best ligand of T. gondii UrdPase with an apparent Ki value of 60 +/- 3 nM. It is concluded that the presence of an N-glycosyl bond is a prerequisite for a nucleoside ligand to bind to T. gondii UrdPase. On the other hand, the presence of a 2'-, 3'-, or 5'-hydroxyl group, or an N-glycosyl bond in the beta-configuration, enhanced but was not essential for binding. Furthermore, the potency of the binding of 2,2'-anhydrouridines (fixed high syn isomers) in contrast to the weaker binding of the 6,1'-anhydro- or 2,5'-anhydrouridines (fixed syn isomers), and the complete lack of binding of the 6,5'-cyclo, O5',6-methano- and 6,3'-methanouridines (fixed anti isomers) to T. gondii UrdPase indicate that the binding of ligands to this enzyme is in the syn/high syn conformation around the N-glycosyl bond. The results also indicate that the parasite but not the mammalian host UrdPase can participate in hydrogen bonding with N3 of the pyrimidine ring of nucleoside ligands. T. gondii UrdPase also has a larger hydrophobic pocket adjacent to the C5 of the pyrimidine moiety than the host enzyme, and can accommodate modifications in the pentose moiety which cannot be tolerated by the host enzyme. Most prominent among these modifications is the absence and/or lack of the ribo orientation of the 3'-hydroxyl group, which is a requirement for a ligand to bind to mammalian UrdPase. These differences between the parasite and host, enzymes can be useful in designing specific inhibitors or "subversive" substrates for T. gondii UrdPase.