Secretion Of Prostaglandin F2α Research Articles

Global gene expression in equine endometrium around the time of maternal recognition of pregnancy

The conceptus-maternal communication during the preimplantation period, also known as maternal recognition of pregnancy (MRP), is crucial for the establishment and maintenance of pregnancy. This communication affects the endometrial transcriptome and proteome with subsequent reduction of endometrial pulsatile prostaglandin F2α secretion and the consequent extension of the corpus luteum's lifespan during early pregnancy in the mare. Also, this communication results in the preparation of the uterine environment for implantation. Any alteration of these processes will result in early embryonic death. Therefore, a better understanding of the normal endometrial transcriptomic changes around the time of MRP might be the key to understanding and preventing early embryonic loss. This study aimed to evaluate the endometrial transcriptome from Day 14 (Day 0 = ovulation) of pregnant and non-pregnant (i.e. diestrus) mares. RNA was isolated from pregnant (n=5) and non-pregnant (n=4) endometrial tissue samples. RNA-Seq was performed using Illumina NovaSeq6000 and differentially expressed genes (DEGs) were evaluated using DESeq.2 based upon an FDR<0.05. Our study identified 1193 DEGs (570 upregulated DEGs and 623 downregulated DEGs) in the pregnant endometrium as compared to the non-pregnant endometrium. In the current study, the pregnant endometrium was associated with downregulation (9.6-fold change) of mRNA forprostaglandin-endoperoxide synthase 2 (PTGS2, also known as cyclooxygenase-2 enzyme; COX2), which encodes for the rate-limiting enzyme in prostaglandin production. Gene ontology analysis of DEGs revealed that these genes were associated with relevant biological processes such as immune response (TNFAIP1, TNF, CXCR2, TNFSF15, IL15, TGFBR3, IL1B, TNFSF9, TLR8), regulation of trophoblast cell proliferation and migration (BOK, LIF, RBM46, TIMP1, CALR, GJA1), embryo growth and development (PTCH1, PTCH2R, DH10, GLI3, SHOX2, ZDBF2, EVX1, GREM2, KLF2, TWIST1), cell adhesion (COL28A1, EGFL6, ITGA3, FN1, NEDD9, LAMC2, RGMB, THBS4, RHOB, SELP, CHL1, CDHR1, MXRA8, FOLR3, NECTIN3), embryo implantation (MMP9 and LIF), placenta development (ADAM19, MAPK14, BIRC3), amino acids transportation (SLC1A1, SLC25A29, SLC36A2, SLC38A2, SLC7A5), steroid biosynthesis and metabolism (SRD5A1, HSD11B2, HSD17B7, CYP20A1), and progesterone receptors (PAQR5, and PGRMC1). Several of the DEGs identified in the current study are known to play a role in controlling endometrial receptivity to the conceptus in species other than the equine. These findings improve our understanding of the molecular changes taking place in equine endometrium around the time of MRP which might help us to understand and forestall early embryonic loss in the future.

Piezo1 activation induces fibronectin reduction and PGF2α secretion via arachidonic acid cascade

Glaucoma is a neurodegenerative disease that leads to blindness, and lowering intraocular pressure (IOP) is very important in glaucoma treatment. The trabecular meshwork is responsible for aqueous humor outflow, and the accumulation of fibronectin in trabecular meshwork is known to cause ocular hypertension. We have already shown that Piezo1 activation has an IOP lowering effect in mice and suppresses fibronectin expression level in human trabecular meshwork cells (HTMC). In this study, we report the mechanism of the reduction of fibronectin caused by Piezo1 activation. Activation of Piezo1 in HTMC showed increased expression of matrix metalloproteinase-2 (MMP-2) and cyclooxygenase (COX)-2, and decreased fibronectin expression. In addition, Piezo1 activation enhanced phosphorylation of cytosolic phospholipase A2 (cPLA2), and inhibitors targeting cPLA2 and COX-2 suppressed Yoda 1, a Piezo1 agonist, induced fibronectin reduction. These results indicate that the arachidonic acid cascade underlies this reaction, and, in support of this hypothesis, activation of Piezo1 promoted secretion of prostaglandin F2α (PGF2α) in HTMC. These results indicate that the activation of Piezo1 in HTMC promotes the degrading of fibronectin by promoting the arachidonic acid cascade and increasing the expression of PGF2α and MMP-2.

Effects of cortisol on prostaglandin F2α secretion and expression of genes involved in the arachidonic acid metabolic pathway in equine endometrium - In vitro study

Glucocorticoids (GCs) are known to play an important role in maintaining basal and stress-related homeostasis by interacting with endocrine mediators and prostaglandins (PGs). Although a growing body of evidence shows that GCs exert their regulatory action at a multitude of sites in the reproductive axis through corticosteroid receptors, little is known about the direct role of cortisol, an active form of GCs, in the equine endometrium. Thus, the study aimed to determine the effect of cortisol on PGF2α synthesis in the endometrial tissue and cells in vitro. In Exp.1, the immunolocalization and the expression of the glucocorticoid receptor (GCR) in the endometrium throughout the estrous cycle were established. In Exp. 2 and 3, the effects of cortisol on PGF2α secretion and transcripts associated with the arachidonic acid (AA) cascade in endometrial tissues, and cells were defined. Endometrial tissues obtained from the early, mid, and late luteal phases and the follicular phase of the estrous cycle were exposed to cortisol (100, 200, and 400 nM) for 24 h. Endometrial epithelial and stromal cells (early phase of estrous cycle) were exposed to cortisol (100 nM) for 24 h. Then, PGF2α secretion and transcripts associated with the AA cascade (PLA2G2A, PLA2G4A, PTGS2, and PGFS) were assessed. GCR was expressed in the cytoplasm and the nucleus in the luminal and glandular epithelium as well as in the stroma. Endometrial GCR protein abundance was up-regulated at the late luteal phase compared to the mid-luteal phase of the estrous cycle. Cortisol dose-dependently decreased PGF2α secretion, PLA2G2A and PLA2G4A transcripts in endometrial tissues. Additionally, cortisol treatment decreased PGF2α secretion from endometrial epithelial and stromal cells. Moreover, it affected PLA2G2A, PLA2G4A, and PTGS2 transcripts in endometrial stromal cells. These findings suggest that cortisol suppresses the synthesis of PGF2α by affecting the AA cascade in the equine endometrium during the estrous cycle.

The role of embryo contact and focal adhesions during maternal recognition of pregnancy.

Maternal recognition of pregnancy (MRP) in the mare is an unknown process. In a non-pregnant mare on day 14 post-ovulation (PO), prostaglandin F2α (PGF) is secreted by the endometrium causing regression of the corpus luteum. Prior to day 14, MRP must occur in order to attenuate secretion of PGF. The embryo is mobile throughout the uterus due to uterine contractions from day of entry to day 14. It is unknown what signaling is occurring. Literature stated that infusing oil or placing a glass marble into the equine uterus prolongs luteal lifespan and that in non-pregnant mares, serum exosomes contain miRNA that are targeting the focal adhesion (FA) pathway. The hypothesis of this study is embryo contact with endometrium causes a change in abundance of focal adhesion molecules (FA) in the endometrium leading to decrease in PGF secretion. Mares (n = 3/day) were utilized in a cross-over design with each mare serving as a pregnant and non-pregnant (non-mated) control on days 9 and 11 PO. Mares were randomly assigned to collection day and endometrial samples and embryos were collected on the specified day. Biopsy samples were divided into five pieces, four for culture for 24 hours and one immediately snap frozen. Endometrial biopsies for culture were placed in an incubator with one of four treatments: [1] an embryo in contact on the luminal side of the endometrium, [2] beads in contact on the luminal side of the endometrium, [3] peanut oil in contact on the luminal side of the endometrium or [4] the endometrium by itself. Biopsies and culture medium were frozen for further analysis. RNA and protein were isolated from biopsies for PCR and Western blot analysis for FA. PGF assays were performed on culture medium to determine concentration of PGF. Statistics were performed using SAS (P ≤ 0.05 indicated significance). The presence of beads on day 9 impacted samples from pregnant mares more than non-pregnant mares and had very little impact on day 11. Presence of oil decreased FA in samples from pregnant mares on day 9. On day 11, oil decreased FA abundance in samples from non-pregnant mares. Embryo contact caused multiple changes in RNA and protein abundance in endometrium from both pregnant and non-pregnant mares. The PGF secretion after 24 hours with each treatment was also determined. On day 9, there was no change in PGF secretion compared to any treatments. On day 11, presence of peanut oil increased PGF secretion in samples from non-pregnant mares. In samples from non-pregnant mares, presence of an embryo decreased PGF secretion compared to control samples from non-pregnant mares. Results revealed that while beads and peanut oil may impact abundance of FA RNA and protein in endometrial samples, it does not appear to impact PGF secretion. Conversely, embryo contact for 24 hours with endometrium from a non-pregnant mare causes a decrease in PGF secretion. These results suggest that it is not just contact of any substance/object causing attenuation of PGF secretion, but the embryo itself is necessary to decrease PGF secretion.

Revisión: El Ciclo Reproductivo de la Yegua

El ciclo estral, o intervalo interovulatorio en la yegua, permite monitorear y seleccionar el momento mas adecuado para la copula o la inseminacion artificial (IA). El ciclo estral se debe a la interaccion de hormonas de la glandula pineal, hipotalamo, hipofisis, gonada y endometrio, y dura 21 dias. La glandula pineal segrega melatonina durante las horas de obscuridad. En primavera-verano, existe menor secrecion de melatonina, y el hipotalamo secreta a la hormona liberadora de las gonadotropinas (GnRH) para inducir la secrecion de gonadotropinas: (FSH, hormona foliculo estimulante y LH, hormona luteinizante) en la adenohipofisis y estimular la funcion ovulatoria. La FSH promueve el crecimiento folicular y la LH, la maduracion folicular y la ovulacion. Ambas estimulan la produccion de estradiol en los foliculos ovaricos. El estradiol causa las manifestaciones de estro. Despues de la ovulacion, se forma el cuerpo luteo que produce progesterona (P4), para la gestacion. La P4 bloquea al hipotalamo y reduce la secrecion de GnRH, interrumpiendo el ciclo estral. El hipotalamo, produce oxitocina, que se almacena en neurohipofisis y actua en endometrio, estimulando a la prostaglandina F2α, para que ejerza luteolisis, y el inicio de un nuevo ciclo estral. En otono e invierno se interrumpe la actividad ovulatoria

Physiological mechanisms involved in maintaining the corpus luteum during the first two months of pregnancy.

Maintenance of the corpus luteum (CL) during pregnancy is essential for continuing the elevated circulating progesterone (P4) that is required to maintain pregnancy. The mechanisms that protect the CL during early pregnancy when the non-pregnant animal would typically undergo CL regression have been extensively investigated. It is clear uterine prostaglandin F2α (PGF) causes regression of the CL in non-pregnant ruminants and that maintenance of the CL during early pregnancy is dependent upon secretion of interferon-tau (IFNT) from the elongating embryo. A number of specific mechanisms appear to be activated by IFNT. Most studies indicate that there is an inhibition of oxytocin-induced secretion of uterine PGF. There is also evidence for increased resistance to PGF action, perhaps due to secretion of PGE2 and PGE1 or direct endocrine actions of circulating IFNT. These mechanisms occur concurrently and each may help to maintain the CL during the first month of pregnancy. However, during the second month of pregnancy, IFNT is no longer secreted by the embryo. Attachment of the embryo to the uterus and subsequent placentome development have been linked to silencing of expression from the IFNT gene. In addition, there is some evidence that oxytocin responsiveness of the uterus returns during the second month of pregnancy leading to substantial basal secretion of PGF and perhaps PGF pulses. There is also no evidence that the CL during the second month of pregnancy is resistant to the actions of PGF as observed during the first month. Thus, this manuscript attempts to compare the mechanisms that maintain the CL during the first and second months of pregnancy in ruminants and provides a new, speculative, physiological model for maintenance of the CL during month two of pregnancy that is distinct from the previously-described mechanisms that maintain the CL during the first month of pregnancy.

Interferon-tau and fertility in ruminants.

Establishment of pregnancy in domestic ruminants includes pregnancy recognition signalling by the conceptus, implantation and placentation. Despite the high fertilisation success rate in ruminants, a significant amount of embryo loss occurs, primarily during early gestation. Interferon-tau (IFNT), a type I interferon that is exclusively secreted by the cells of the trophectoderm of the ruminant conceptus, has been recognised as the primary agent for maternal recognition of pregnancy in ruminants. It produces its antiluteolytic effect on the corpus luteum by inhibiting the expression of oxytocin receptors in the uterine epithelial cells, which prevents pulsatile, luteolytic secretion of prostaglandin F2α by the uterine endometrium. While the importance of IFNT in maternal recognition of pregnancy and prevention of luteolysis in ruminants is unequivocal, important questions, for example, relating to the threshold level of IFNT required for pregnancy maintenance, remain unanswered. This paper reviews data linking IFNT with measures of fertility in ruminants.

Rapid conceptus elongation in the pig: An interleukin 1 beta 2 and estrogen-regulated phenomenon.

Establishment and maintenance of pregnancy in the pig involves activating many physiological, cellular, and molecular signaling pathways between the developing conceptus and hormonally regulated maternal endometrium. Rapid elongation of the pig trophoblast allows for the establishment of sufficient placental surface area for the transport of nutrients to the fetus throughout pregnancy. Estrogens secreted by the conceptus during elongation act on uterine epithelia to induce secretion of uterine factors required for conceptus development and for preventing endocrine secretion of prostaglandin F2α, which would cause luteolysis. Thus, trophoblast expansion within the uterine lumen during early gestation is an essential process for implantation and maintenance of pregnancy in species with an epitheliochorial form of placentation. In the pig, rapid conceptus elongation involves the unique expression of interleukin-1 beta 2 (IL1B2), which establishes pro-inflammatory effects that may be tempered by the spatiotemporal secretion of estrogen from the conceptuses. The present review provides current information on pig conceptus remodeling and signaling via estrogen and IL1B2 pathways, as well as endometrial responses to those conceptus factors leading to establishment of pregnancy.

The effect of aspirin on prostaglandin F2α secretion in lactating dairy cows

Early embryonic loss may be related to untimely secretion of prostaglandin F2α. The objective of this study was to examine the effect of aspirin, a nonsteroidal anti-inflammatory drug (NSAID), on prostaglandin F2α secretion and luteal function in lactating dairy cows by characterizing plasma prostaglandin metabolites (PGFM) and progesterone (P4) during the luteal phase. Estrous cycles were synchronized in 23 lactating Holstein cows using a 5-d CIDR-Ovsynch protocol. Transrectal ultrasonography was performed to confirm ovulation and formation of a corpus luteum. On d 14, after after the second injection of gonadotropin-releasing hormone, cows were assigned randomly to receive aspirin (n = 11, 46.65 g/dose) orally on d 14 (2×) and d 15 (1×), 12 h apart, or no aspirin (n = 12, control). On d 15, hourly blood samples were collected for PGFM, and daily blood samples were collected (d 14 to 22) for P4 concentrations. Mean P4 concentrations before treatment (d 14) did not differ between groups. There was an effect of treatment and treatment × time on PGFM (P < 0.05). Mean PGFM concentrations decreased (P < 0.05) after treatment and remained low for 11 h after last aspirin dose, whereas in the control PGFM remained unchanged. For cows that underwent luteolysis (n = 16), P4 concentrations were greater (P = 0.05), and the days to luteolysis tended (P = 0.09) to be longer for the aspirin compared with the control. This study indicated that oral administration of aspirin may suppress prostaglandin F2α secretion during d 14 to 15 after estrus and may prevent early luteal tissue regression.

Maintenance or regression of the corpus luteum during multiple decisive periods of bovinepregnancy

In ruminants, there are specific times during the estrous cycle or pregnancy when the corpus luteum (CL) may undergo regression. This review has attempted to summarize the physiological and cellular mechanisms involved in CL regression or maintenance during four distinct periods. The first period is near day 7 when animals that are ovulating after a period of low circulating progesterone (P4), such as first pubertal ovulation or first postpartum ovulation, are at risk of having a premature increase in Prostaglandin F2α (PGF) secreted from the uterus resulting in early CL regression and a short estrous cycle. The second period is when normal luteolysis occurs at day 18-25 of the cycle or when the CL is rescued by interferon-tau secreted by the elongating embryo. The uterine mechanisms that determine the timing of this luteolysis or the prevention of luteolysis have been generally defined. Induction and activation of endometrial E2 receptors result in induction of endometrial oxytocin receptors that can now be activated by normal pulses of oxytocin. Of particular importance is the observation that the primary mechanisms are only activated through local (ipsilateral) and not a systemic route due to transfer of PGF from the uterine vein to the ovarian artery. In addition at the CL level, studies are providing definition to the cellular and molecular mechanisms that are activated in response to uterine PGF pulses or pregnancy. The third period that is discussed occurs in the second month of pregnancy (day 28-60) when undefined mechanisms result in CL maintenance of an ipsilateral CL but regression of a contralateral (opposite side from pregnancy) CL. The final period that is discussed is regression of the CL just prior to parturition. Although, cortisol from the fetus appears to be the primary initiator of luteolysis, PGF seems to be the final signal that causes regression of the CL. Thus, in all four periods, regression of the CL is likely to be caused by the direct actions of PGF that is secreted from the uterus. The uterine mechanisms that result in secretion of PGF seem to be normally inhibited during the early luteal phase, making short luteal phases not a normal event, and are altered during early pregnancy (day 18-25) resulting in prevention of luteolysis. During much of pregnancy, the mechanisms that cause PGF secretion from the uterus in response to oxytocin are intact but luteolysis does not normally occur, perhaps due to lack of efficient utero-ovarian transfer of PGF.

Defective secretion of Prostaglandin F2α during development of idiopathic persistent corpus luteum in mares

Five mares that developed idiopathic persistent corpus luteum (PCL) were compared with 5 mares with apparently normal interovulatory intervals (IOIs). Progesterone (P4) and a metabolite of prostaglandin F2α (PGFM) were assayed daily beginning on the day of ovulation (Day 0). Transition between the end of an initial progressive P4 increase and the beginning of a gradual decrease in P4 occurred on mean Day 6. The gradual decrease in P4 between Days 6 and 12 was less (approached significance, P < 0.06) in the PCL group than in the IOI group. The P4 concentration on Day 12 (before luteolysis in IOI group) was greater (P < 0.05) in the PCL group than in the IOI group. In a post hoc comparison, an interaction (P < 0.04) of group by day for Days 4 to 7 indicated that the end of the progressive increase in P4 was temporally associated with a transient increase in concentration of PGFM in IOI mares but not in PCL mares. Complete luteolysis (P4 < 1 ng/mL) occurred in the IOI mares on Days 13 to 15. Partial luteolysis (mean P4 decrease, 62%) occurred in 3 of the 5 PCL mares. Normalization to the day at the end of the most pronounced P4 decrease in the IOI mares and in the 3 PCL mares with partial luteolysis resulted in a day-by-group interaction (P < 0.05) for PGFM concentration. The interaction was partly from lower PGFM concentration on the day at the end of the pronounced P4 decrease in the 3 PCL mares than in the IOI mares. The peak of a transient PGFM increase and the day at the end of the most pronounced decrease in P4 were synchronized in each IOI mare but not in any of the 3 PCL mares. In the other 2 PCL mares, partial luteolysis did not occur, and a transient increase in PGFM was not apparent. Results tentatively indicated that the relationship between P4 and PGFM may be altered as early as Day 6 in PCL mares and supported the hypothesis that prostaglandin F2α secretion is defective in mares with idiopathic PCL.

REV-ERBα Inhibits the &lt;i&gt;PTGS2&lt;/i&gt; Expression in Bovine Uterus Endometrium Stromal and Epithelial Cells Exposed to Ovarian Steroids

The nuclear receptor REV-ERBα (encoded by NR1D1) has a critical role in metabolism and physiology as well as circadian rhythm. Here, we investigated the possible contribution of clock genes including NR1D1 to the secretion of prostaglandin F2α (PGF2α) from bovine uterine stromal (USCs) and epithelial cells (UECs) by modulating the expression of PTGS2. The circadian oscillation of clock genes in the cells was weak compared with that reported in rodents, but the expression of BMAL1, PER1, and NR1D1 was changed temporally by treatment with ovarian steroids. Significant expression of clock genes including NR1D1 was detected in USCs exposed to progesterone. NR1D1 was also significantly expressed in UECs exposed to estradiol. The expression of PTGS2 was suppressed in USCs exposed to progesterone, while the expression was initially suppressed in UECs exposed to estradiol and then increased after long-term exposure to estradiol. BMAL1 knockdown with specific siRNA caused a significant decrease in the transcript levels of NR1D1 and PTGS2 in USCs, but not in UECs. The production of PGF2α also decreased in USCs after BMAL1 knockdown, while its level did not significantly change in UECs. The transcript level of PTGS2 was increased by treatment with the antagonist of REV-ERBα in both cell types, but the agonist was ineffective. In these two cell types treated with the agonist or antagonist, the PGF2α production coincided well with the PTGS2 expression. Collectively, these results indicate that REV-ERBα plays an inhibitory role in the expression of PTGS2 in both bovine USCs and UECs treated with ovarian steroids.

Secretion of prostaglandins and leukotrienes by endometrial cells in cows with subclinical and clinical endometritis

The aims of this study were (1) to measure the secretion of prostaglandin F2α (PGF2α), prostaglandin E2 (PGE2), leukotriene B4 (LTB4), and leukotriene C4 (LTC4) by endometrial cells collected by a cytobrush from healthy cows and cows with subclinical and clinical endometritis in the fourth week postpartum, and (2) to evaluate the relationship between the mediators' levels of secretion and the number of polymorphonuclear neutrophils (PMNs) in the uterine smears of cows with subclinical endometritis. The study included cows without any signs of clinical endometritis (n = 63) and cows with clinical endometritis as a positive control (ENDOM, n = 12). Two different threshold ratios (>5% and >18% of PMNs) were used to categorize the cows without clinical signs as with or without cytologic endometritis (CE). Considering the first or second threshold, the animals with CE were included in group CE POS I or CE POS II, whereas the healthy cows were assigned to group CE NEG I or CE NEG II, respectively.The prevalence of CE was 68.25% (42/63) and 57.14% (36/63) according to the first and second thresholds, respectively. The highest level of secretion of all of the measured mediators occurred in the ENDOM group and differed significantly (P < 0.05) from the CE POS and CE NEG groups, regardless of the threshold. PGF2α secretion in the CE POS II group (1629 pg/mL) was significantly lower (P < 0.05) when compared with the CE NEG II group (2797 pg/mL), whereas there was no significant difference between the CE POS I and CE NEG I groups. PGE2 secretion differed between both groups with CE; higher concentrations were measured in the CE POS II group (6.68 ng/mL) when compared with the CE POS I (2.4 ng/mL) and CE NEG II (2.37 ng/mL) groups (P < 0.05). No significant differences were observed in the LTB4 and LTC4 secretion between the CE POS and CE NEG groups, considering both thresholds. It seems that CE does not fully mimic the inflammatory cascade associated with clinical signs. The response in the subclinical cases was limited to enhanced production of PGE2, which was particularly well-pronounced in cows with high numbers of PMNs (>18%) in the endometrial scrapings.

Effects of oxytocin, lipopolysaccharide (LPS), and polyunsaturated fatty acids on prostaglandin secretion and gene expression in equine endometrial explant cultures

Increased secretion of prostaglandin F2α (PGF2α) within the uterus because of uterine inflammation can cause luteolysis and result in early embryonic loss. Supplementation with polyunsaturated fatty acids (PUFAs) has been shown to influence PG production in many species, although the effects on the mare remain unknown. The present study aimed to determine fatty acid uptake in equine endometrial explants and evaluate their influence on PG secretion and expression of enzymes involved in PG synthesis in vitro. Equine endometrial explants were treated with 100 μM arachidonic acid, eicosapentaenoic acid, or docosahexaenoic acid and then challenged with oxytocin (250 nM) or lipopolysaccharide (LPS; 1 μg/mL). Production of PGF2α and PG E2 (PGE2) was measured, and mRNA expression of enzymes involved in PG synthesis was determined with quantitative real-time PCR. Media concentrations of PGF2α and PGE2 were higher (P < 0.0001) from endometrial explants challenged with oxytocin or LPS compared with controls despite which fatty acid was added. Only DHA lowered (P < 0.0001) media concentrations of PGF2α and PGE2 from explants. Endometrial explants stimulated with oxytocin had increased expression of PG-endoperoxide synthase 1 (PTGS1; P < 0.02), PG-endoperoxide synthase 2 (PTGS2; P < 0.001), PG F2α synthase (PGFS; P < 0.01), PG E2 synthase (PGES; P < 0.01), and phospholipase A2 (PLA2; P < 0.005) compared with controls and regardless of fatty acid treatment; whereas stimulation with LPS increased expression of PTGS2 (P < 0.004), PGFS (P < 0.03), PGES (P < 0.01), and PLA2 (P < 0.01) compared with controls and regardless of fatty acid treatment. Treatment with PUFAs, specifically DHA, can influence PG secretion in vitro through mechanisms other than enzyme expression.

Gene profiling of inflammatory genes in day 18 endometria from pregnant and non‐pregnant mares

Maternal recognition of pregnancy is a physiological process that primarily describes endometrial responses to a conceptus. Recognition of a conceptus prevents the release of prostaglandin F(2α) , thereby ensuring survival of the corpus luteum and continued progesterone production. Exactly how this occurs in the mare is poorly understood. Because prostaglandin F(2α) is a pro-inflammatory hormone, we hypothesized that differential gene expression in the endometrium at the time of maternal recognition reflects an anti-inflammatory event leading to decreased prostaglandin F(2α) secretion. Mares were inseminated, and endometrial biopsies were recovered from pregnant mares on Day 18 post-ovulation. In subsequent estrous cycles, mares were not inseminated and Day 18 post-ovulation endometrial biopsies were collected (non-pregnant control, matched per individual). Endometrial gene expression profiles were examined by screening an Affymetrix equine GeneChip containing probes specific for genes related to inflammatory processes. Microarray analysis revealed 118 genes that were up-regulated and 93 genes that were down-regulated (P < 0.001) at least 1.5-fold in the endometrium of pregnant versus non-pregnant mares. Quantitative, real-time RT-PCR confirmed the microarray results for three up-regulated genes homologous to TSC22D3, PPAPDC2, and KLF6, and three down-regulated genes homologous to ESR1, MARCKSL1, and EPSTI1 (P < 0.05). It is concluded that the presence of the equine embryo induces differential gene expression in the endometrium of Day 18 pregnant mares, and that these genes are associated with inflammatory processes and pathways involving cellular growth and proliferation. The results from this study provide important new insights into endometrial gene expression in response to early equine pregnancy.

Maternal recognition of pregnancy in the horse: a mystery still to be solved

Maternal recognition of pregnancy in the horse is the sum of events leading to maintenance of pregnancy; in a narrow sense, maternal recognition of pregnancy refers to the physiological process by which the lifespan of the corpus luteum is prolonged. The horse is one of the few domestic species in which the conceptus-derived pregnancy recognition signal has not been identified. The presence of the conceptus reduces pulsatile prostaglandin F(2α) secretion by the endometrium during early gestation in the mare, partly attributed to the reduced expression of cyclooxygenase-2. Cyclooxygenase-2 has therefore been suggested as one of the regulators of endometrial prostaglandin F(2α) release modified by the antiluteolytic factor secreted by the conceptus. In addition, altered oxytocin responsiveness has been implicated in the adjustment of prostaglandin release in pregnant mares. While conceptus mobility has proven to be essential for establishment of pregnancy, conceptus-derived oestrogens and prostaglandins, principally prostaglandin E(2), have not been confirmed as the critical antiluteolytic factor. Various ways to induce prolonged luteal function in the non-pregnant mare will be highlighted in the current review, specifically, how they may pertain to the process of maternal recognition of pregnancy. Furthermore, recently published microarray experiments comparing the transcriptome of pregnant and non-pregnant endometria and different stages of conceptus development will be reviewed. Findings include the prevention of conceptus adhesion, the provision of nutrients to the conceptus and the avoidance of immunological rejection, among others.

ORIGINAL ARTICLE: Endometrial Explant Culture for Characterizing Equine Endometritis

Problem Endometritis after insemination is ubiquitous in the horse and is associated with semen and/or bacteria in the uterus. In up to 40% of horses, inflammation persists causing infertility. An endometrial explant culture was developed to study uterine secretion of prostaglandin F2α(PGF2α) in response to physiological and pathological challenge.Method of study Uteri were collected from mares, the endometrium dissected and explants from the uterine body or horn cultured in William’s or RPMI medium. The response of explants to oxytocin, semen or bacteria compared to untreated tissue was tested by collecting medium after 24 and 72 hr and measuring PGF2αby radioimmunoassay.Results Explants from the uterine horn and cultured in William’s medium secreted the most PGF2αafter challenge with oxytocin. Explants treated with semen produced a PGF2αresponse after 72 hr. Explants collected from mares in the transition season treated with killedS. zooepidemicusorE. colilipopolysaccharide (LPS) secreted increased concentrations of PGF2αafter 24 and 72 hr. The response to LPS was inhibited by polymyxin B. Follicular and luteal phase explants did not respond to treatments.Conclusions An endometrial explant culture was developed that measured PGF2αand may be used to study endometritis.

Improving ovine peri-conception diets by feeding an algal source of omega-3 fatty acids

The UK dairy industry currently suffers huge losses due to declining fertility. Although fertility in the sheep industry is good overall, the use of multiple ovulation and embryo transfer techniques would benefit from improved conception and embryo survival rates. Studies suggest that omega-3 supplementation may bring about a reduction in the secretion of prostaglandin F2α (PGF2α), which would favour the maintenance of the corpora lutea (CL) and hence, a successful pregnancy. Feeding fish meal to dairy cows has been found to improve pregnancy rates by 10% (Burke et al., 1997). Using sheep as a model, this study aimed to evaluate whether reproductive performance in ruminants is improved by feeding an algal source of omega-3 fatty acids, particularly docosahexaenoic acid (DHA, C22:6 n-3). The study was also structured to determine whether prostaglandin production is affected by supplementing diets with omega-3.

Mechanisms for Establishment of Pregnancy in Mammalian Species

Cross-talk between the embryo and mother is necessary for the establishment of successful pregnancy. In the mouse, cervical stimuli during mating induce prolactin secretion from the pituitary and formation of the corpus luteum (CL) of pregnancy. Placental lactogen supports the maintenance of pregnancy after implantation. In the human, the embryo secretes chorionic gonadotropin (hCG), which has lenbinizing hormone (LH) activity and maintains pregnancy before the luteal-placental shift occurs. In cattle and sheep, the mechanism underlying the establishment of pregnancy is unique. Their embryos secrete interferon (IFN)-τ, which is related to type I IFNs. IFN-τ prevents the secretion of prostaglandin F2α(PGF2α) from the uterine endometrium by suppressing the expression of estrogen and oxytocin receptor. In the pig, estrogen secreted from the conceptus is a factor for maternal recognition of pregnancy. Estrogen leads to a shift in the direction of PGF2α secretion from endocrine to exocrine and inhibits the regression of CL. Thus, each species has specific mechanisms for the establishment of pregnancy.

Conceptus signals for establishment and maintenance of pregnancy

Establishment and maintenance of pregnancy results from signaling by the conceptus (embryo/fetus and associated extraembryonic membranes) and requires progesterone produced by the corpus luteum. In most mammals, hormones produced by the trophoblast maintain progesterone production by acting directly or indirectly to maintain the corpus luteum. In domestic animals (ruminants and pigs), hormones from the trophoblast are antiluteolytic in that they act on the endometrium to prevent uterine release of luteolytic prostaglandin F2α. In cyclic and pregnant sheep, progesterone negatively autoregulates progesterone receptor gene expression in the endometrial luminal and superficial glandular epithelium. In cyclic sheep, loss of the progesterone receptor is closely followed by increases in epithelial estrogen receptors and then oxytocin receptors, allowing oxytocin to induce uterine release of luteolytic prostaglandin F2α pulses. In pregnant sheep, the conceptus trophoblast produces interferon tau that acts on the endometrium to inhibit transcription of the estrogen receptor alpha gene directly and the oxytocin receptor gene indirectly to abrogate development of the endometrial luteolytic mechanism. Subsequently, sequential, overlapping actions of progesterone, interferon tau, placental lactogen, and growth hormone comprise a hormonal servomechanism that regulates endometrial gland morphogenesis and terminal differentiated function to maintain pregnancy in sheep. In pigs, the conceptus trophoblast produces estrogen that alters the direction of prostaglandin F2α secretion from an endocrine to exocrine direction, thereby sequestering luteolytic prostaglandin F2α within the uterine lumen. Conceptus estrogen also increases expression of fibroblast growth factor 7 in the endometrial lumenal epithelium that, in turn, stimulates proliferation and differentiated functions of the trophectoderm, which expresses the fibroblast growth factor 7 receptor. Strategic manipulation of these physiological mechanisms may improve uterine capacity, conceptus survival, and reproductive health.