Effects of Cisapride, Buprenorphine, and Their Combination on Gastrointestinal Transit in New Zealand White Rabbits.

Due to their effective analgesic properties, opioids are worthy of consideration for pain management in rabbits. However, this class of drugs causes undesirable effects including reduced gastrointestinal (GI) motility, reduced fecal output, and delays GI transit times and thus increases the risk of GI stasis. The risk of stasis discourages the use of opioids in rabbits, which could affect animal welfare. Gastroprokinetic agents such as cisapride are effective in promoting gastric emptying in many species, but whether this effect occurs in rabbits is unknown. This study assessed the efficacy of cisapride when administered as a single agent and in combination with buprenorphine in rabbits; efficacy was assessed by measuring GI transit times, fecal output, body weight, and food and water intake. Female New Zealand White rabbits (n = 10) were studied in a crossover, randomized design and received either vehicle and buprenorphine, cisapride and saline, cisapride and buprenorphine, or vehicle and saline (control) every 8 h for 2 d. Rabbits were anesthetized and administered radio-opaque, barium-filled spheres via orogastric tube. Feces was assessed via radiography for detection of the barium-spheres to determine GI transit time. GI transit time was significantly longer in buprenorphine groups than in control groups, regardless of the use of cisapride. Fecal output and food and water intake were lower for buprenorphine groups than control groups. Cisapride did not significantly alter GI transit, fecal output, or food and water intake. In addition, treatment group did not significantly affect body weight. In conclusion, buprenorphine treatment (0.03 mg/kg TID) prolonged GI transit time and reduced fecal output and food and water consumption in rabbits. Coadministration of buprenorphine and cisapride (0.5 mg/kg) did not ameliorate these effects, and the administration of cisapride at this dose did not appear to affect GI motility in female rabbits.

p53 Disruption Increases Uracil Accumulation in DNA of Murine Embryonic Fibroblasts and Leads to Folic Acid-Nonresponsive Neural Tube Defects in Mice.

BACKGROUND: Neural tube defects (NTDs) occur in nervous tissue during embryogenesis when the neural tube fails to close. Approximately 70% of all human NTDs can be prevented by folic acid (FA). Altered expression and/or function of the tumor suppressor protein p53 can lead to NTDs in mouse models. OBJECTIVES: The aim of this study was to determine if dietary FA could rescue p53-/--induced NTDs in mice, and to determine the effect loss of p53 has on pathways in folate 1-carbon metabolism. METHODS: p53+/- female mice were randomly allocated and weaned onto either an FA-sufficient diet (2 mg/kg folic acid; +FA), or an FA-deficient diet (-FA). After 8 wk, the females were time-mated to p53-/- males. Embryos were examined at E12.5 for NTDs. Folate enzyme concentrations, nucleotide synthesis, uracil accumulation in DNA, and proliferation were measured in primary murine embryonic fibroblasts (MEFs). The "n - 1" chi-square test was used to compare NTD percentages, whereas all other data were analyzed by Student t test, except where noted a multilevel-fit model was used. RESULTS: NTD rates of litters from dams consuming the +FA diet (20/46; 43%) did not differ from those of litters from dams consuming the -FA diet (14/35; 40%) (P > 0.05). p53-/- MEFs had 55% higher rates of folate-dependent de novo dTMP synthesis, a ∼2-fold higher accumulation of uracil in DNA, and a ∼30% higher rate of proliferation (P ≤ 0.05) than p53+/- MEFs independent of folate. CONCLUSIONS: p53-related NTDs are not FA responsive. Increased dTMP synthesis in p53-/- MEFs might not have been sufficient to meet the demands for thymidine triphosphate (dTTP) synthesis as evidenced by the elevated amounts of uracil in DNA. This study provides additional evidence that elevated uracil in DNA is a risk factor for NTDs.

Arsenic trioxide targets MTHFD1 and SUMO-dependent nuclear de novo thymidylate biosynthesis.

Arsenic exposure increases risk for cancers and is teratogenic in animal models. Here we demonstrate that small ubiquitin-like modifier (SUMO)- and folate-dependent nuclear de novo thymidylate (dTMP) biosynthesis is a sensitive target of arsenic trioxide (As2O3), leading to uracil misincorporation into DNA and genome instability. Methylenetetrahydrofolate dehydrogenase 1 (MTHFD1) and serine hydroxymethyltransferase (SHMT) generate 5,10-methylenetetrahydrofolate for de novo dTMP biosynthesis and translocate to the nucleus during S-phase, where they form a multienzyme complex with thymidylate synthase (TYMS) and dihydrofolate reductase (DHFR), as well as the components of the DNA replication machinery. As2O3 exposure increased MTHFD1 SUMOylation in cultured cells and in in vitro SUMOylation reactions, and increased MTHFD1 ubiquitination and MTHFD1 and SHMT1 degradation. As2O3 inhibited de novo dTMP biosynthesis in a dose-dependent manner, increased uracil levels in nuclear DNA, and increased genome instability. These results demonstrate that MTHFD1 and SHMT1, which are key enzymes providing one-carbon units for dTMP biosynthesis in the form of 5,10-methylenetetrahydrofolate, are direct targets of As2O3-induced proteolytic degradation, providing a mechanism for arsenic in the etiology of cancer and developmental anomalies.