Canine placenta: a source of prepartal prostaglandins during normal and antiprogestin-induced parturition

Clinical protocol for pregnancy termination in bitches using prostaglandin F2 alpha.

Sixty-seven pregnant bitches were given atropine sulphate (0.025 mg kg-1), prifinium bromide (0.1 ml kg-1) and metopimazine (0.5 mg kg-1) and 15 min later 2.5 micrograms cloprostenol kg-1 s.c., three times at 48 h intervals (day 1, day 3, day 5). After one treatment, 53 of the 67 bitches had aborted, and after a second treatment, 62 of the 67 bitches had aborted. In 18 bitches, progesteronemia kinetics were followed-up: the first injection of cloprostenol resulted in a significant (P < 0.01) fall in progesteronemia. In 12 of the 18 bitches that had aborted following the first protocol, this rapid fall in progesterone was noteworthy as it decreased progesterone concentration on average from 17.07 +/- 8.20 ng ml-1 on day 1 to 1.31 +/- 0.34 ng ml-1 on day 3. The premedication administered 15 min before the injection of prostaglandins, prevented the appearance of side effects in 39 of the 67 bitches (58.2%).

Canine placenta: a source of prepartal prostaglandins during normal and antiprogestin-induced parturition.

Expression of cyclooxygenase 2 (COX2, now known as PTGS2), prostaglandin E2 synthase (PTGES, PGES), and prostaglandin F2A synthase (PGFS), of the respective receptors PTGFR (FP), PTGER2 (EP2), and PTGER4 (EP4) and of the progesterone receptor (PGR, PR) was assessed by real-time PCR, immunohistochemistry (IHC), or in situ hybridization (ISH) in utero/placental tissue samples collected from three to five bitches on days 8–12 (pre-implantation), 18–25 (post-implantation), and 35–40 (mid-gestation) of pregnancy and during the prepartal luteolysis. Additionally, ten mid-pregnant bitches were treated with the antiprogestin aglepristone (10 mg/kg bw (2x/24 h)); ovariohysterectomy was 24 and 72 h after the second treatment. Plasma progesterone and 15-ketodihydro-PGF2A (PGFM) concentrations were determined by RIA. Expression of the PGR was highest before implantation and primarily located to the endometrium; expression in the placenta was restricted to the decidual cells. PTGS2 was constantly low expressed until mid-gestation; a strong upregulation occurred at prepartal luteolysis concomitant with an increase in PGFM. PGFS was upregulated after implantation and significantly elevated through early and mid-gestation. PTGES showed a gradual increase and a strong prepartal upregulation. PTGFR, PTGER2, and PTGER4 were downregulated after implantation; a gradual upregulation of PTGFR and PTGER2 occurred towards parturition. ISH and IHC co-localized PGFS, PTGFR, PTGES, and PTGS2 in the trophoblast and endometrium. The changes following application of aglepristone were in the same direction as those observed from mid-gestation to prepartal luteolysis. These data suggest that the prepartal increase of PGF2A results from a strong upregulation of PTGS2 in the fetal trophoblast with the withdrawal of progesterone having a signalling function and the decidual cells playing a key role in the underlying cell-to-cell crosstalk.

Effects of prostaglandins on ovarian blood flow in the bitch.

Oestrous and anoestrous mongrel dogs were anaesthetized with chloralose–urethane. In one group, the ovaries were isolated in situ and the effects of a 15-min infusion of PGF-2 or PGE-2 on perfusion pressure were measured. In the other group, heated thermocouples were introduced into the stroma of each ovary to measure the changes of local blood flow in response to PGF-2 and PGE-2 infused into the ovarian bursa for 15 min. Intra-arterial infusion of 25,50,100 or 200ng PGF-2 /kg/min did not affect perfusion pressure; PGE-2 doses of 3·1, 6·2, 12·5 or 25 ng/kg/min caused reductions in proportion to the dose. All doses of PGF-2 (50·0, 100or 200 ng/kg/min) or PGE-2 (25, 50 or 100 ng/kg/min) increased blood flow in the ovarian stroma in proportion to the dose when administered by infusion into the ovarian bursa. There were no differences in the results from oestrous and anoestrous dogs. It is concluded that PGF-2 changes intraovarian blood distribution without interfering with the total blood flow while PGE-2 increases both the total and local ovarian blood flow.