Reproductive performance of heifers induced to oestrous asynchrony by suprabasal plasma progesterone levels

Suprabasal progesterone concentrations around oestrus have induced disturbances in oestrous behaviour and ovulation. To determine whether fertility in such an altered oestrus can be maintained at normal levels with additional inseminations (AI) until ovulation, fertility was compared in heifers (n = 11) inseminated in normal oestrous cycles and thereafter in cycles in which the animals were treated with progesterone in order to create suprabasal concentrations after luteolysis. The treatment consisted of silicone implants containing 10.6 mg kg⁻¹ of progesterone inserted subcutaneously on Day 8 of the oestrous cycle (day of ovulation designated Day 0) and removed on Day 25. Both in control oestrous cycles and oestrous cycles under progesterone treatment, growth of the ovulatory follicle and ovulation were determined by frequent ultrasound scanning. Blood was collected frequently for further analysis of progesterone, oestradiol-17β and luteinising hormone (LH). Insemination was performed 12 h after onset of standing oestrus. if ovulation did not occur 24 h after AI, heifers were inseminated again until ovulation. Pregnancy was diagnosed by ultrasound 25 days after ovulation.In control oestrous cycles, plasma progesterone decreased to 0.3 ± 0.3 nmol 1⁻¹. Duration of oestrus was 22.9 ± 2.0 h, the interval from onset of oestrus to ovulation was 32.4 ± 2.3 h and the interval from LH peak to ovulation was 28.6 ± 1.4 h. The interovulatory interval was 20.7 ± 0.6 days. In oestrous cycles in treated heifers, progesterone decreased to 1.0 ± 0.3 nmol l⁻¹ (P > 0.10) and the interovulatory interval was prolonged to 23.5 ± 1.0 days (P < 0.05). Standing oestrus lasted 47.2 ± 12.0 h (P = 0.09, n = 7). The interval from the onset of oestrus to ovulation was 59.4 ± 13.0 h (P = 0.08) and the interval from LH peak to ovulation 25.8 ± 1.3 h (P > 0.10). The prolonged oestrus was associated with increased (P < 0.05) growth of the ovulatory follicle and higher (P < 0.05) release of oestradiol-17β. Conception rates were 90% and 46% (P < 0.05), and the numbers of AI per heifer were 1.1 ± 0.1 and 3.4 ± 0.6 (P < 0.01) for control oestrous cycles and after treatment, respectively.The induction of suprabasal concentrations of progesterone caused asynchronies similar to those observed in cases of repeat breeding. The repeated AI did not maintain fertility at normal levels. It is suggested that the extended growth of the ovulatory follicle may cause impaired oocyte maturation or it may alter the maternal milieu owing to the prolonged release of oestradiol.     

Origin and fate of preovulatory follicles after induced luteolysis at different stages of the luteal phase of the oestrous cycle in goats

The effect of day of induced luteolysis on follicle dynamics, oestrus behaviour and ovulatory response in goats was studied by administering cloprostenol on Day 5 (n=10), Day 11 (n=10), or Day 16 (n=10) after detection of oestrus. Stage of the luteal phase affected the interval from cloprostenol injection to onset of oestrus, with behavioural oestrus being observed earlier in goats treated early in the luteal phase (43.4+/-3.2 h on Day 5 versus 57.0+/-2.6 h on Day 11 and 56.7+/-2.7 h on Day 16, P<0.01). The group treated on Day 5 also tended to have a higher proportion of does which exhibited oestrus behaviour (P=0.07) and ovulation (P=0.06). In all the cycles, at least one of the ovulatory follicles arose from antral follicles present in the ovary at cloprostenol injection. In 66.7% of monovular cycles, the ovulatory follicle was the largest follicle on the day of luteolysis. In 33.3% of polyovulatory cycles, one of the ovulatory follicles was the largest one present when cloprostenol was administered. In 80% of polyovulatory cycles, the second ovulatory follicle was present on the day of luteolysis; but in the three remaining cycles, the second ovulatory follicle emerged later. This shows that the largest follicle may not exert dominance over other follicles in the goat. Evaluation of follicular dynamics in different phases of luteal activity in current experiment showed an attenuation of dominance in the mid-luteal period. In does treated early or late in the luteal phase, the number of new growing follicles decreased with time (P<0.01 and 0.05, respectively), the mean number of follicles reaching 4-5mm in size also decreased (P<0.001 and 0.01, respectively) and the number of regressing follicles increased (P<0.05). These effects did not reach statistical significance in does treated in the mid-luteal phase.     

Influence of perioestrous suprabasal progesterone levels on cycle length,oestrous behaviour and ovulation in heifers

In order to induce suprabasal plasma concentrations of progesterone after luteolysis and to determine their effect on oestrous behaviour and ovulation, heifers subcutaneously received silicone implants containing 2.5 (n = 4), 5 (n = 4), 6 (n = 3), 7.5 (n = 3) or 10 (n = 4) g of progesterone, or an empty implant (controls, n = 5) between days 8 and 25 of the cycle (ovulation designated Day 0). Growth of dominant follicles and time of ovulation were determined by ultrasound, and signs of oestrus were recorded and scored. Blood was collected at 2–4 h intervals from Days 15 to 27 and assayed for progesterone concentration. In all heifers, plasma concentrations of progesterone sharply decreased during Days 16–18. Control heifers had their lowest progesterone levels on Days 20.5 and 21, standing oestrus on Day 19.5 ± 0.4 (mean ± SEM), and ovulated on Day 20.7 ± 0.4. A similar pattern was observed in heifers treated with 2.5 and 5 g progesterone. Heifers treated with 6, 7.5 and 10 g of progesterone showed an extended (P < 0.05) interovulatory interval. Onset of prooestrus and time of maximum expression of signs of oestrus were not significantly different from those in controls. However, there was an absence of standing oestrus in most of the cases, signs of oestrus lasted longer (P < 0.05) and were weaker in intensity when doses increased. In these groups, the lowest progesterone concentrations were attained shortly after implant removal. Some heifers treated with 6 and 7.5 g of progesterone had standing oestrus and post oestrous bleeding as seen in the controls but ovulation occurred from Days 24.5 to 27. When plasma progesterone concentrations were over 1 nmol 1⁻¹, disturbed oestrus and delayed ovulation occurred. The extended period of prooestrus and oestrus and delayed ovulation were similar to that described in cases of repeat breeding. It is suggested that suprabasal plasma concentrations of progesterone, after luteolysis, may lead to asynchrony between onset of oestrus and ovulation and consequently be a cause of repeat breeding in cattle.     

Regulation of the proliferative activity of ovarian surface epithelial cells by follicular fluid

Despite critical roles of the ovarian surface epithelium (OSE) in ovulation and post-ovulatory wound repair, little is known about the physiological mechanism regulating OSE proliferation. A role of follicles and corpora lutea in locally regulating the proliferative activity of OSE has been suggested. In this study, the effects of follicular and luteal products on proliferation of cultured OSE cells were tested using cells obtained from seasonally anoestrous ewes. Follicular fluid but not luteal extracts induced OSE cell proliferation (2.5-fold relative to untreated controls; P < 0.0001). The response of OSE cells was not affected by follicle size or previous charcoal-extraction of follicular fluid (P > 0.1). Treatment with IGF-1 (2.2-fold; P < 0.01), EGF (1.9-fold; P < 0.01) and, to a lesser extent, FSH (P < 0.05) also induced OSE cell proliferation. In contrast, oestradiol or progesterone did not induce cell proliferation or enhance the effects of FSH on proliferation (P > 0.1). It was concluded that follicular fluid can directly stimulate ovine OSE cell proliferation and that this effect is attributable to non-steroidal mitogens.     

Ovarian and endocrine responses in tropical sheep treated with reduced doses of cloprostenol

The present study aimed to assess the efficacy of reduced doses of cloprostenol for synchronizing estrus and ovulation in hair sheep. With the aim to evaluate the luteolytic activity of reduced cloprostenol doses, a first experiment was performed using a relatively large (group H: 126 μg; n = 8), medium (group M: 68.25 μg; n = 6) and small (group L: 38.5 μg; n = 6) cloprostenol dose. Luteolysis was assessed at Days 3 and 6 after injection (Day 0) by progesterone concentrations (P₄) and transrectal ultrasonography (US). In Experiment 2, sheep were randomly assigned to the same three doses to evaluate a protocol for estrous synchronization using two injections administered 9 days apart. A third trial was performed with ewes treated (9 days apart) with the large dose (H = 126 μg; n = 12) and with a small dose adjusted for facilitating volume management (LA = 43.75 μg; n = 12). Presence of estrous cycling was determined in all the ewes by US and P₄ assay, at Days −9, −6, −2, 0 (Day of second cloprostenol injection), 8 and 11. Bleeding and US were done every 4 h from 16 h of the beginning of the estrus during the third trial to assess the preovulatory LH surge and timing of ovulation. Additionally, blood samples were drawn at Days 0, 1, 2 and 3 to assess estradiol (Experiments 2 and 3) and P₄ (Experiment 2) concentrations during the ovarian follicular phase. In all experiments, percentage of animals showing luteolysis, preovulatory follicular dynamics and function and percentage of ewes showing behavioral estrus in response to treatment was similar among groups. Timing of estrus for group H was earlier than group L (28.6 ± 1.8 h compared with 37.1 ± 2.4 h; P < 0.05). In the third trial, the preovulatory LH peak was higher in the LA group than group H, in terms of maximum mean concentration during the surge (27.7 ± 1.8 ng/mL compared with 21.3 ± 2.2 ng/mL; P < 0.05) and area under the curve (AUC; 183.4 ± 12.7 ng/mL compared with 127.7 ± 10.9 ng/mL; P < 0.01). However, timing of ovulation was similar for H and LA groups. Thereafter, ovulation rate and luteal function at Day 11 were similar. Current results demonstrate that reduced doses of cloprostenol may be applied in a practical manner for reproductive management of sheep, with the additional advantage of reducing treatment costs.     

Ultrasound-monitored ovarian responses in normal and superovulated cattle given exogenous progesterone at different stages of the oestrous cycle

In two experiments with female cattle, responses to synchronisation and superovulation were monitored by transrectal ultrasonography and embryo recovery. Each experiment had both a synchronisation phase to establish a reference oestrus and a superovulatory phase with the oestrous cycle controlled by exogenous progesterone commencing at two specific times. The reference oestrus was controlled using a progesterone releasing intravaginal device (PRID) applied for 12 days with prostaglandin F_2α given 1 day before removal. Experiment 1 had two treatments which differed by the absence (A) or presence (P) of a 10mg oestradiol benzoate capsule on the PRID, while in Experiment 2 all animals were on treatment P. In the superovulatory phase of both experiments treatment P commenced on Day 7 (PRID 7 treatment) or Day 14 (PRID 14 treatment) of the oestrous cycle (oestrus designated Day 0). Superovulation, using equine chorionic gonadotrophin in Experiment 1 and oFSH in Experiment 2, commenced 3 days before PRID removal. Treatment P caused rapid regression of the dominant follicle and corpus luteum (CL) irrespective of when treatment commenced. A second wave of follicular growth was detected after 6–8 days and the dominant follicle grew at 1.1 mm day⁻¹ in the 7 days before oestrus. In contrast, in treatment A of Experiment 1, the dominant follicle either grew slowly and eventually ovulated for cows in the mid-luteal phase, or the dominant follicle regressed and a second wave follicle ovulated if cows were early luteal at PRID insertion. In the superovulatory phase of both experiments the dominant follicle of PRID 7 animals increased in size and then regressed, but in PRID 14 cows, the dominant follicle was regressing before PRID insertion. During superovulation, the number of 7–10 mm follicles was significantly (P<0.001) greater in PRID 7 animals in Experiment 2. In both experiments, half the animals on the PRID 14 treatment maintained a large follicle during the superovulatory phase in contrast to the even sized follicles in animals on PRID 7 treatment. In Experiment 1, the number of grade 1 embryos recovered was significantly (P<0.05) higher for PRID 7 than PRID 14 treatments. In Experiment 2, there were significant differences (P<0.001) in the number of corpora lutea, total ova plus embryos and grade 1 embryos in favour of PRID 7 animals following superovulation. We conclude that the initiation of control of the oestrous cycle with a PRID and subsequent superovulating regime should take account of normal follicular wave status for effective superstimulation and production of viable embryos, and that ultrasonography may usefully be applied to the process.     

Glucose uptake and lactate production by the autotransplanted ovary of the ewe during the luteal and follicular phases of the oestrous cycle

Two experiments were carried out on ewes with ovarian autotransplants to estimate the ovarian uptake of glucose and production of lactate. The first was carried out in the luteal phase of the oestrous cycle. Samples of carotid arterial, ovarian venous and jugular venous blood were collected simultaneously for glucose analysis. The arterial concentration of glucose (58.0 ± 5.0 mg/dL; Mean ± SEM) was significantly higher than the ovarian venous concentration (42.3 ± 2.4 mg/dL; P < 0.001). Next, a second more complete experiment was carried out in the luteal and follicular phases of the oestrous cycle. The oestrous cycle was synchronised and samples of carotid arterial, ovarian venous and jugular venous blood were collected simultaneously for glucose and lactate analysis. There were significant positive arterio-venous differences in the concentration of glucose in the luteal (5.6 ± 1.2 mg/dL, mean ± SEM; P = 0.001), early (3.1 ± 0.82 mg/d; P = 0.003) and late follicular (6.4 ± 1.3 mg/dL; P = 0.001) phases of the oestrous cycle. There was a significant negative arterio-ovarian venous difference in the concentration of lactate in only the luteal phase (-2.2 ± 0.96 mg/dL; P = 0.043).The results show significant removal of glucose from the arterial circulation during its passage through the ovary in the luteal, early follicular and late follicular phases of the oestrous cycle. Furthermore, there was lactate production in the luteal phase but not in the follicular phase suggesting that in the luteal phase of the oestrous cycle, ovarian metabolism can be anaerobic.     

Ovarian stimulation with follicle-stimulating hormone under increasing or minimal concentration of progesterone in dairy cows

The objective of this study was to investigate the effect of the presence or absence of Corpus luteum (CL) on the follicular population during superstimulation in dairy cows (Holstein-Friesian cattle). Animals were divided into two groups as follows: (1) Growing CL group (G1): Cows (n = 7) received a total dose of 28 Armour units (AU) follicle-stimulating hormone (FSH) through the first 4 d (twice daily) after spontaneous ovulation (Day 0). (2) CL Absence group (G2): Cows (n = 10) received prostaglandin F_2α (PGF_2α) at 9 or 10 d after ovulation. After 36 h, all the follicles (larger than 5 mm) were aspirated (Day 0). The FSH treatment started 24 h after aspiration and continued for 4 d. The number of small (3 to <5 mm), medium (5 to <8 mm), and large (≥8 mm) follicles was examined on Days 1, 3, and 5 in all groups. Blood samples were collected daily for 5 d, and progesterone (P₄), estradiol (E₂), insulin-like growth factor-1 (IGF-1), and growth hormone (GH) in plasma were measured by enzyme immunoassays. The results showed that in G1, the P₄ level increased gradually from 0.5 ng/mL at Day 1 to 2 ng/mL at Day 5, whereas in G2, the P₄ level was completely below 0.5 ng/mL. All cows of the G2 group showed an increase of E₂ at Day 3 or Day 4 followed by an increase of IGF-1 within 24 h, while GH increased concomitantly with the E₂ increase in 8 of 10 trials. On the other hand, cows of the G1 group showed neither E₂ nor IGF-1 increase. Moreover, at the end of the treatment, the number of follicles in the G2 group was significantly increased compared with that of the G1 group (22.8 ± 2.0 vs. 11.6 ± 2.0). In conclusion, low P₄ level during FSH treatment enhanced multiple follicular growth and E₂ secretion, which was followed by increase of IGF-1 and GH. Therefore, the absence of the CL may play a critical role in the superovulation response by controlling the number of growing follicles.     

Growth and regression of ovarian follicles during the follicular phase of the oestrous cycle in heifers undergoing spontaneous and PGF-2 alpha-induced luteolysis

Ultrasonography was used to monitor the growth, ovulation and regression of individual ovarian follicles greater than or equal to 5 mm during the late luteal and follicular phases of the oestrous cycle in heifers treated with injections of PGF-2 alpha to induce luteolysis and in heifers undergoing spontaneous luteolysis. Six heifers were given a single injection of PGF-2 alpha between Day 12 and 15 of the oestrous cycle and their ovaries were examined daily by transrectal ultrasonography until ovulation occurred. Another group of 5 heifers was examined daily by ultrasound from Day 14 or 15 of the cycle through spontaneous luteolysis and ovulation. Blood samples were taken twice daily from this group and analysed for progesterone to determine when luteolysis occurred. All heifers were checked for oestrous behaviour twice daily. Mean diameters of ovulatory follicles on each of the 3 days before oestrus were not different between PGF-2 alpha-treated and untreated heifers. In both groups there was large variation among heifers in the sizes and growth rates of the ovulatory follicles. At 3 days before oestrus the diameters of ovulatory follicles were between 7.5 and 11 mm in PGF-2 alpha-treated heifers and between 6 and 11.5 mm in untreated heifers. Non-ovulatory follicles decreased in size during the 3 days before oestrus and the number of non-ovulatory follicles within the size ranges of ovulatory follicles decreased. The ovulatory follicle was not consistently the largest follicle on the ovaries until the day of oestrus but was always one of the 2 largest follicles during the 3 days before oestrus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Follicle populations,ovulation rates and plasma profiles of LH,FSH and prolactin in Scottish Blackface ewes in high and low levels of body condition

Scottish Blackface ewes in high body condition (mean score = 2.86) had a higher mean ovulation rate (1.8 v. 0.9; P < 0.05) and more large (⪖ 4 mm diameter) follicles (4.6 v 2.2; P < 0.05) than ewes in low condition (mean score = 1.84) but similar numbers of small (1–4 mm diameter) follicles (6.3 v 6.0; NS). There was little difference in LH profiles with body condition but FSH and prolactin concentrations were significantly greater, during both luteal and follicular phases of the cycle, in ewes in high condition.Despite the relationships between body condition and ovulation rate and between condition and hormone concentrations, within the high condition groups, there was no significant difference in FSH levels with ovulation rate. Prolactin levels were higher in ewes with a single ovulation than in ewes with two or three ovulations. There was a trend towards a higher mean LH pulse frequency in the luteal phase and a higher mean LH pulse amplitude in the follicular phase in ewes with multiple ovulations compared with ewes with a single ovulation. During oestrus, only circulating prolactin concentrations differed with body condition, being significantly higher in ewes in high condition, but mean LH concentrations were higher and FSH concentrations lower in ewes with multiple ovulations. Subsequent luteal function, as measured by circulating progesterone concentrations, was normal in all ewes. It is concluded that body condition affected the size of the large follicle (⪖ 4 mm diameter) population through changes in FSH and possibly pulsatile LH secretion and prolactin secretion during the luteal and follicular phases of the cycle and that the number of follicles that were potentially ovulatory was probably determined during the luteal phase of the cycle. However, their ability to undergo the final stages of development and to ovulate may be related to the amount of LH secreted during the follicular phase.     

Corpus luteum function following single and double ovulation during estrous cycle in Sanjabi ewes

This study compared the effect of double and single ovulation on serum progesterone concentrations and luteal characteristics in Sanjabi ewes at different days of the estrous cycle. The estrous cycles of 197 Sanjabi ewes were synchronized by a 12-day treatment with intravaginal sponges (Chronogest^®). Estrus was detected in 144 ewes 27–39 h after sponge removal. Daily blood samples were taken every morning and analyzed for serum progesterone (P4). Ewes were then transported to a local abattoir, where nine ewes were slaughtered on each experimental day (days 1–16 after estrus) for ovary collection. The ovarian follicles were measured and categorized by size (very small <2 mm; small 2–3.5 mm; medium 3.5–5 mm; large >5 mm). On each slaughter day, the number of corpora lutea per ewe was classified as single and double ovulation. The results show that the effect of dominant follicles was less during the mid-luteal phase. Ovulation rate of right, left and both ovaries were (54.9%), (23.6%) and (21.5%), respectively. The incidence of double ovulations was 40.2%. In the case of ewes exhibiting double ovulation, 46.6% occurred unilateral (ewes exhibited both ovulations on the right ovary); whereas 53.4% occurred bilateral (ewes exhibited ovulations on the right and left ovaries). Unilateral double ovulation was not observed in the left ovary. The right ovary appeared to play a significantly greater role in ewes showing single and double ovulations than the left ovary (P < 0.05). Serum progesterone concentration showed minimum and maximum levels of 0.29 ± 0.15 and 5.51 ± 0.75 ng/ml on days 16 and 11 post-estrous, respectively (P < 0.001). The mean volume of individual corpus lutea in ewes with single ovulations was significantly higher than in ewes with double ovulations (P < 0.01). However, the total volume of corpus lutea in ewes with single ovulation was significantly lower than in ewes with double ovulations in some days of estrous cycle (P < 0.01). The serum progesterone concentration was significantly higher in double than single ovulating animals on days 1–16 of the estrous cycle (P < 0.001). These results indicated a relatively high incidence of double ovulation in ewes associated with increasing total luteal volume and high circulating concentrations of progesterone.     

Effect of nutritionally induced liveweight differences on ovulation rates and the population of ovarian follicles in ewes

Differential feeding prior to the onset of the breeding season resulted in mean liveweight differences of 12 kg in two groups of Romney ewes. This difference was maintained while ovulation rates and the population of externally visible ovarian follicles were measured. The ovulation rate at first oestrus was significantly higher in the high liveweight group but there was no difference between groups thereafter. High liveweight ewes had consistently higher mean follicle scores at all stages of the oestrous cycle. Mean follicle score was lower following the third oestrus than following first oestrus (P < 0.01).     

The GnRH antagonist acyline prevented ovulation, but did not affect ovarian follicular development or gestational corpora lutea in the domestic cat

Two experiments were conducted to investigate the effects of the GnRH antagonist acyline (330 μg/kg, given sc) on ovarian follicular development and ovulation, as well as on pregnancy maintenance in domestic cats. In the first experiment, seven queens in proestrus (total of 24 proestrus periods), were randomly assigned to treatment with either acyline (ACY; n = 17) or a placebo (PLC; n = 7). All queens were mated with a fertile tomcat. In the ACY and PLC groups, cessation of estrus occurred (mean ± SEM) 7.0 ± 1.3 and 7.0 ± 1.7 d after treatment (P > 0.1), ovulation occurred in 2 of 17 and all seven estrus periods (P < 0.05), and pregnancy rates were 1 of 16 and 7 of 7 (P < 0.05), respectively. In the ACY and PLC groups, intervals from treatment to the onset of the ensuing proestrus were 18.4 ± 1.7 and 120 ± 17.2 d. In the second experiment, 14 pregnant queens were randomly allocated, according to their mating date, to treatment with acyline in early pregnancy (from 20 to 25 d, n = 3), mid pregnancy (from 26 to 45 d; n = 4), late pregnancy (> 45 d; n = 3), or injection of a placebo in early (n = 1), mid (n = 2), or late pregnancy (n = 1). Ultrasonographic assessments of the uterus were done every second day for 2 wk post treatment, and serum progesterone (P₄) concentrations were determined before treatment, and at 7 and 14 d after treatment. No pregnancies were prematurely terminated and post-treatment P₄ concentrations did not differ among treatment groups (P > 0.1). In conclusion, in the domestic cat, GnRH withdrawal by acyline prevented ovulation when given in early follicular phase (proestrus), but did not significantly affect luteal function during pregnancy.     

Low peripheral progesterone and late embryonic/early fetal loss in suckled beef and lactating dairy cows

Pregnancy failure during placentation in lactating dairy cows was associated with low concentrations of serum progesterone. Beef cows have greater serum progesterone and less pregnancy failure. Experiment 1 determined that reduction of serum progesterone affected late embryonic/early fetal loss in suckled beef cows. Cows (n = 40) received progesterone from two new or used controlled internal drug releasing devices, replaced every 5 d, beginning on Day 28 of gestation (mating = Day 0); CL were enucleated on Day 29. Retention of pregnancy was 77% in treated cows and 97% in 78 control cows (P < 0.05). Experiment 2 determined how pregnant, lactating dairy cows with high or low progesterone concentrations during Days 28-34 differed in luteal function or in serum progesterone during replacement therapy. Luteal tissue from such cows was assayed for progesterone and expression of mRNA for genes of endothelin and prostaglandin (PG) systems. Secretion of progesterone and prostaglandins by dispersed luteal cells was determined during incubation with LH, endothelin-1, or arachidonic acid. Neither luteal progesterone nor mRNAs for endothelin or prostaglandin systems differed. Endothelin-1 inhibited secretion of progesterone more (P < 0.05) in luteal cells from cows with low versus high serum progesterone, when incubated with arachidonic acid. Secretion of prostaglandin F₂α was increased and that of 6-keto-PGF₁α decreased by endothelin-1 in vitro. Serum progesterone during replacement was lower (P < 0.05) for cows with low than high serum progesterone at lutectomy. Thus, clearance, more than luteal production, determined peripheral progesterone in pregnant, lactating dairy cows.     

Ovarian follicular dynamics and plasma steroid concentrations are not significantly different in ewes given intravaginal sponges containing either 20 or 40 mg of fluorogestone acetate

Although various progestagens are often used to induce and synchronize estrus and ovulation in ruminants, concerns regarding residues are the impetus to develop alternative approaches, including reduced doses of progestagens. Therefore, the objective was to determine whether ovarian function was affected by halving the dose of fluorogestone acetate in intravaginal sponges for synchronizing ovulation in sheep during the physiologic breeding season. Twenty Manchega ewes, 4-6-year-old, were randomly allocated to receive an intravaginal sponge containing either 20 mg (P20, n = 10) or 40 mg of fluorogestone acetate (P40, n = 10). Cloprostenol (125 μg) was given at sponge insertion, and all sponges were removed after 6 d. Ovarian follicular dynamics (monitored by daily ultrasonography) and other aspects of ovarian function did not differ significantly between the two groups. Ovulatory follicles (OF) grew at a similar growth rate (r = 0.62; P < 0.001), with comparable initial and maximum diameters (4.2 ± 0.4 to 6.0 ± 0.3 mm in P20 vs. 4.6 ± 0.6 to 5.7 ± 0.2 mm in P40, mean ± S.E.M.). Plasma estradiol concentrations (determined once daily) increased linearly during the 72 h interval after sponge removal (1.3 ± 0.1 to 3.3 ± 0.1 pg/mL for P20, P < 0.005 and 1.4 ± 0.1 to 3.1 ± 0.2 pg/mL for P40, P < 0.005). Ten days after sponge removal, ovulation rates (1.2 ± 0.2 for P20 and 1.4 ± 0.3 for P40), and plasma progesterone concentrations (3.8 ± 0.35 ng/mL for P20 and 3.9 ± 0.38 ng/mL for P40) were similar. In conclusion, reducing the dose of fluorogestone acetate from 40 to 20 mg did not affect significantly ovarian follicular dynamics or other aspects of ovarian function.     

Factors affecting the incidence of postpartum oestrus, ovarian activity and reproductive performance in Thoroughbred mares bred at foal heat under Indian subtropical conditions

Decreased reproductive performance due to summer stress is a well known phenomenon in farm livestock. Whether this occurs in the mare and specifically how this might affect postpartum reproductive activity and performance, especially at Foal Heat (FH), is unknown. This study, therefore, aims to investigate this and the factors that might affect postpartum reproductive activity. Reproductive records of 228 Thoroughbred mares (694 mare years) bred in subtropical north-western India were retrospectively analysed. Overt oestrous activity occurred within 21 d postpartum in 92.94% (645/694) of mares. Significantly (p < 0.001) more April foaling mares (97.37%, 185/190) expressed postpartum oestrous activity than those foaling in January (83.61%; 51/61) and February (88.49; 123/139). Similarly significantly (p < 0.01) fewer multiparous mares failed to demonstrate oestrous activity than primiparous mares (6.12% vs.15.07%; 38/621 vs. 11/73, respectively). 190 of these 694 mares were additionally monitored to confirm ovulation; in these mares onset of FH (oestrus plus confirmed ovulation) occurred 8.42 ± 0.17 d and first ovulation 13.64 ± 0.20 d postpartum. Month, stud farm, year, and parity did not affect interval from parturition to FH onset or to first ovulation; or FH onset to ovulation. In FH bred mares Day 16 pregnancy rate and overall foaling rate were 53.76% (100/186) and 46.24% (86/186) respectively and were similar to those of mares bred later postpartum. FH pregnancy rates were not affected by stud, season, month, year, number of matings, or day of ovulation but were significantly (p < 0.008) lowered by increasing mare age. Significantly (p < 0.01) lower Day 16 pregnancy rates were observed in uterine treated mares compared to untreated mares (31.09% vs. 57.96%; 9/29 vs. 91/157, respectively), this difference was not evident during the rest of pregnancy. In conclusion, postpartum reproductive and ovarian activity appears to be affected by environment, i.e., delayed in subtropical kept Thoroughbred mares compared to those kept in temperate climates. However, resulting reproductive performance at FH and the factors affecting postpartum reproductive activity are similar.     

Intermittent suckling enables estrus and pregnancy during lactation in sows: effects of stage of lactation and lactation during early pregnancy

Previously we demonstrated that pre-ovulatory LH and post-ovulatory progesterone (P4) concentrations in plasma were low and embryo development was retarded when sows were induced to ovulate during lactation by submitting them to intermittent suckling (IS). The present study investigated whether this was due to: (1) stage of lactation when IS was initiated, and (2) continuation of IS post-ovulation. Multiparous Topigs40 sows were studied under three conditions: conventional weaning at Day 21 of lactation (C21; n = 30), intermittent suckling from Day 14 of lactation (IS14; n = 32), and intermittent suckling from Day 21 of lactation (IS21; n = 33). Sows were separated from piglets for 12 h daily during IS. IS sows were either weaned at ovulation or 20 d following ovulation. One-third (21/63) of the IS21 and C21 sows had already ovulated or had large pre-ovulatory follicles at Day 21 and were excluded from further study. Initiation of IS at Day 14 instead of Day 21 of lactation tended to reduce P4 at 7 d post-ovulation (P = 0.07), did not affect pregnancy rate, and tended to reduce embryo survival (P = 0.06). Continuation of IS during pregnancy resulted in lower P4 at 7 and 12 d post-ovulation, tended to reduce embryo weight and pregnancy rate (P < 0.10), whereas embryo survival was not affected. This study presents data for a population of sows in which follicle growth and ovulation are easily triggered under suckling conditions. Further, when these sows are bred during lactation, initiation of IS at 21 rather than 14 d of lactation with weaning at ovulation yields the most desirable reproductive performance.     

Influence of somatic cell count, body condition and lameness on follicular growth and ovulation in dairy cows

The objective of this study was to investigate the effect of somatic cell count (SCC), body condition score (BCS) or lameness score on ovarian follicular growth and ovulation in dairy cows. Seventy four animals 30-80 days post-partum were monitored for all three conditions before synchronization of ovarian follicular phases by administration of gonadotrophin releasing hormone (GnRH) followed seven days later with prostaglandin F2alpha (PG). Ultrasonography of both ovaries twice daily throughout the follicular phase revealed that fewer animals with combined high SCC and lameness (4/9) ovulated compared to healthy animals (19/21; P = 0.006) or animals with only high SCC (11/11; P = 0.004) or only lameness (21/27; P = 0.06). Overall, regardless of the presence of other concurrent conditions, fewer lame cows ovulated than Non Lame animals (30/42 and 30/32; P = 0.015). Mean follicular growth and maximum follicular diameter were unaffected by any of the three conditions. However, dominant follicle growth and maximum diameter were greater in the 60 animals that ovulated compared to the 14 that did not; 1.83 ± 0.16 versus 0.96 ± 0.26 mm/day (P = 0.014) and 19.4 ± 0.4 versus 16.4 ± 1.2 mm (P = 0.003), respectively. In conclusion, lameness reduced the proportion of cows that ovulated and the synergistic effect of high SCC and lameness reduced that proportion further. However, follicular growth and maximum follicular diameter were unaffected by high SCC, low BCS or lameness.     

The effect of porcine luteinizing hormone in the synchronization of ovulation and corpus luteum development in nonlactating cows

The objective of this study was to determine the effects of different doses of porcine luteinizing hormone (pLH) versus 100 μg gonadotropin-releasing hormone (GnRH) on ovulatory response (during diestrus and proestrus) and corpus luteum (CL) development in nonlactating cows. In Experiment 1, 75 cows received an intravaginal insert containing 1.9 g progesterone (P4) for 10 d to synchronize estrus (Day 0), with prostaglandin F_2α (PGF) at insert removal. On Day 5, all follicles ≥8 mm were ablated, and on Day 12, cows received 8, 12.5, or 25 mg pLH or 100 μg GnRH. Mean (±SEM) plasma P4 concentrations on Day 12 did not differ among treatments (5.6 ± 0.2 ng/mL). Mean plasma LH concentration was greatest (P < 0.01) in cows given 25 mg pLH (4.3 ± 0.4 ng/mL). The ovulatory response to 25 mg pLH (84%) or 100 μg GnRH (72%) was greater (P < 0.05) than that to 8 mg pLH (32%), but not different from that of 12.5 mg pLH (58%). In Experiment 2, 68 cows were given two injections of PGF 10 d apart to synchronize estrus (Day 0). On Day 7, cows received PGF, and, 36 h later, pLH or GnRH (as in Experiment 1). The interval from treatment to ovulation was most variable in cows given 8 mg pLH; only 65% of these cows ovulated during the initial 27 h versus 88% of cows given 25 mg pLH (P < 0.05). Cows given 25 mg pLH or 100 μg GnRH had larger CL area and greater plasma P4 concentrations (P < 0.05) than that of those given 8 mg pLH. In summary, diestrous cows given 25 mg pLH had the greatest plasma luteinizing hormone concentrations, but ovulatory response did not differ from that of those given 100 μg GnRH. Proestrous cows given 25 mg pLH or 100 μg GnRH had greater CL area and P4 concentrations than that of those given 8 mg pLH.     

Age-related dynamics of follicles and hormones during an induced ovulatory follicular wave in mares

An ovulatory follicular wave was induced by ablation of follicles ≥6 mm and treatment with prostaglandin F2α (PGF) on Day 10 (ovulation = Day 0). Follicle and hormone dynamics of the induced waves were compared among three age groups: young (5-6 y, n = 14 waves), intermediate (10-14 y, n = 16), and old (≥18 y, n = 15). During the common-growth phase of the induced wave (Days 12-17), diameter of the future ovulatory follicle was not different among ages, but the young group had more (P < 0.05) follicles that reached ≥10 mm. The number was correlated (r = +0.7; P < 0.0001) within mares between consecutive interovulatory intervals, indicating repeatability. Concentrations of LH increased in all age groups during Days 12-17, but were greatest (P < 0.002) in the young group and continued to be greater (P < 0.0001) throughout the ovulatory LH surge. During several days before Day −1, there were no age-related effects on systemic estradiol concentrations, diameter of the preovulatory follicle, or B-mode echo texture or color-Doppler signals of blood flow in the follicle wall. Interpretations were: (1) greater number of follicles in the young group reflected a greater follicle reserve, (2) greater LH concentrations throughout the ovulatory surge in the young group reflected a more positive response to an extraovarian/environmental influence after removal of the negative effect of progesterone, and (3) lower LH concentrations in the older groups were adequate for the preovulatory changes in the follicle.