Oral misoprostol does not hasten oviductal transport of day-5 horse embryos.

In horses, prostaglandin E2 (PGE2) is produced by embryos around Day 5 post-ovulation; PGE2 functions directly at the oviduct promoting embryo transport into the uterus. Non-surgical collection of horse embryos for cryopreservation is recommended at Day 6.5-7 post-ovulation. It was proposed that misoprostol administered orally will hasten oviductal transport of horse embryos. In Experiment 1 (n = 15) there was comparison of time of embryo recovery (Day 6 and 6.5 post-ovulation) from mares administered misoprostol (Day 5 and 5.5) orally to that of untreated mares. On Day 6, embryo collections were attempted; if no embryo was collected, there was a second attempt on Day 6.5. In Experiment 2, (n = 16) misoprostol treatment was initiated on Day 4.5; there was the first embryo collection attempt on Day 5.5, followed by Day 6 and 6.5 if no embryo was collected. Blood samples were collected at 12 h intervals on Day 4.5 or 5, to Day 6.5. In Experiment 1, on days 6 and 6.5, respectively, there was collection of seven and one of a total of eight embryos detected at the time of collection per group (P = 1). In Experiment 2, 12 embryos were collected during 15 cycles with there being a total of three, two, and one collected from mares of both groups on Day 5.5, 6, and 6.5 post-ovulation, respectively (P = 1). Serum progesterone concentrations were not different (P ≥ 0.05). In conclusion, misoprostol, when administered orally, does not hasten oviductal transport of horse embryos.

Stretch induction of cyclooxygenase-2 expression in human urothelial cells is calcium- and protein kinase C zeta-dependent.

Prostanoid synthesis via cyclooxygenase (COX)-2 induction during urothelial stretch is central to nociception, inflammation, contractility, and proliferation caused by urinary tract obstruction. We used our primary human urothelial cell stretch model published previously to evaluate the signaling mechanisms responsible for stretch-induced COX-2 expression in urothelial cells. To determine intracytosolic calcium concentrations ([Ca(2+)](i)), primary human urothelial cells were grown on flexible membranes and loaded with Fura-2 acetoxymethyl ester (AM). We determined [Ca(2+)](i) using a fluorescent scope during stretch. Additional cells were treated with 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA)-AM, stretched, and COX-2 mRNA and protein were evaluated by real-time polymerase chain reaction and immunoblotting. To evaluate protein kinase C (PKC) in this system, cells were stretched and fractionated into membrane, cytosol, and nucleus. Fractions were immunoblotted for PKCalpha, beta1, and zeta, the predominant isoforms in urothelial cells. We treated additional cells with increasing concentrations of either bisindolylmaleimide-I or a peptide PKC pseudosubstrate inhibitor, and COX-2 mRNA and protein were evaluated after stretching. Furthermore, we transfected urothelial cells with siRNA against each of the inducible PKC isoforms in these cells and evaluated the stretch-induced COX-2 response. Stretch of urothelial cells activated calcium flux and PKC translocation to membrane and nucleus. Pharmacological inhibition indicated that stretch-induced COX-2 expression is dependent on calcium and PKC, and biochemical knockdown experiments indicated that PKCzeta is the predominant isoform mediating stretch-induced COX-2 expression. Elucidating the signaling mechanism of stretch-induced COX-2 expression may identify therapeutic targets.