Alterations in follicular fluid steroids and follicular hCG and FSH binding during atresia in hamster

Preovulatory follicles from hamsters treated on proestrus for 1-3 days with phenobarbital sodium exhibited early signs of atresia after 2-3 days of ovulatory delay. A significant increase in follicular fluid progesterone was evident by Day 1 of delay. Concentrations of androstenedione in follicular fluid were unaffected by ovulatory delay. Follicular fluid levels of estradiol in delayed follicles were either higher than proestrous values after 1 day of delay or lower after 2 and 3 days of delay. hCG binding was slightly higher than proestrous controls after ovulatory delay whereas FSH binding was significantly lower than controls after 2 and 3 days of ovulatory delay. These results indicate that in the barbiturate-treated hamster the elevated follicular fluid levels of progesterone precede by 1-2 days the previously reported increase in steroidogenic capability of delayed follicles to produce progesterone in vitro; this correlated with an increase in the ratio of hCG:FSH binding and this was mostly due to a decrease in FSH binding to whole follicles.     

Relationships between luteinizing hormone, follicle-stimulating hormone and prolactin secretion and ovarian follicular development in the weaned sow

Folliculogenesis was studied by assessing development of the largest 10 follicles obtained from 10 sows 48 h after weaning and by analyzing changes in plasma luteinizing hormone (LH), follicle-stimulating hormone (FSH) and prolactin (PRL) for 24 h before weaning until 48 h after weaning. Follicular diameter, follicular fluid volume, and concentrations of estradiol and testosterone and granulosa cell numbers were determined in all follicles, and 125I-hCG binding to theca and granulosa and maximal aromatase activity in vitro was determined in five follicles/sow. Overall, a significant rise in LH, but not in FSH, occurred at weaning, although in individual sows an increase in LH was not necessarily related to subsequent estrogenic activity of follicles. In 9/10 sows, PRL fell precipitously after weaning. In lactation, LH was negatively, and after weaning, positively, correlated with FSH and PRL. Marked variability in follicular development existed within and between sows. Overall, most follicular characteristics were positively correlated to follicular diameter; however, in larger follicles the number of granulosa cells was variable and unrelated to estrogenic activity, which--together with theca and granulosa binding of hCG--increased abruptly at particular stages of follicular development. Differences in maturation of similarly sized follicles from different sows were related to estrogenic activity of the dominant follicles but not to consistent differences in LH, FSH or PRL secretion. Both the dynamics and the control of folliculogenesis in the sow, therefore, appear to be complex.     

Alterations in follicular IGFBP mRNA expression and follicular fluid IGFBP concentrations during the first follicle wave in beef heifers

The objective was to determine the pattern of IGFBP-2, -3 and -4 gene expression and follicular fluid concentrations of IGFBP-2, -3, -4 and -5 during emergence, selection and dominance of the first follicle wave of the estrous cycle in cattle and during exogenous steroid treatment. Heifers (n = 35) were ovariectomized at 36 (n = 7), 66 (n = 8), 84 (n = 12) and 108 (n = 8) h after the onset of estrus. Heifers in the 84 h ovariectomy group were sub-divided to receive either no treatment (n = 6) or were treated with a progesterone-releasing intravaginal device (n = 6, PRID) and 0.75 mg estradiol benzoate i.m. at the approximate time of ovulation, 30 h post estrus until ovariectomy. Within heifers the four largest follicles recovered following ovariectomy were ranked on size (F1, F2, F3 and F4). At 36 h IGFBP gene expression and follicular fluid IGFBP concentrations were similar in all follicles (F1-F4). Mean diameter of the F1 follicle increased (P < 0.05) between 36 and 84 h with no difference between 84 and 108 h. The F1 follicle had the highest (P < 0.05) concentration of estradiol compared with the F2, F3 and F4 at 84 and 108 h. There was no granulosa cell IGFBP-2 mRNA in F1 follicles at 84 or 108 h. Intrafolliclar IGFBP-2 concentrations were lower (P < 0.05) in the F1 compared with F3 and F4 follicles at 108 h. There was no difference in theca cell IGFBP-4 mRNA expression at 108h, but amounts of follicular fluid IGFBP-4 were lower (P < 0.05) in F1 follicles compared with F3 and F4 follicles at 108 h. IGFBP-3 mRNA was localized in the theca layer of all follicles examined with no difference in expression or follicular fluid concentrations during emergence, selection and dominance of the first follicle wave. IGFBP-5 concentrations were higher (P < 0.05) in follicular fluid of F3 follicles at 108 h compared with the F3 at 36 h. In conclusion follicular dominance was associated with low or decreased follicular fluid concentrations of IGFBP-4 and -5, increased estradiol and differential regulation of IGFBP production.     

Granulosa cell steroidogenesis before in vitro fertilization

Endocrine and gametogenic functions of the ovulatory follicle may be linked. To verify this, we studied granulosa cell steroidogenesis in relation to oocyte fertilization and preimplantation embryo development in vitro. Multiple follicles were stimulated in in vitro fertilization patients with clomiphene citrate and ovulation was induced with human chorionic gonadotropin (hCG). Oocytes were fertilized with husband's sperm and normal embryos were replaced 48 h later. Granulosa cells were separated from follicular fluid from 64 follicles and incubated for 3 h with and without aromatase substrate (1 microM testosterone). Progesterone and estradiol levels were measured in follicular fluid and incubation medium. Follicular fluid steroid levels and granulosa cell steroidogenesis showed no significant differences for oocytes which cleaved normally and those which did not. Granulosa cell aromatase activity was high in all follicles, suggesting that the low periovulatory follicular fluid estradiol level is not explained by a fall in granulosa cell aromatase after hCG. High granulosa cell progesterone production and follicular fluid progesterone were consistent with advanced granulosa cell luteinization. Oocytes undergoing polyspermic activation were from larger follicles with elevated follicular fluid progesterone levels, suggesting that follicular size and follicular fluid progesterone are correlated with "over-ripeness" and polyspermy. No simple relationship exists between oocyte function and the present indices of granulosa cell steroid metabolism.     

Development of codominant follicles in cattle is associated with a follicle-stimulating hormone-dependent insulin-like growth factor binding protein-4 protease.

Low molecular weight insulin-like growth factor binding proteins (IGFBPs), particularly IGFBP-4, are believed to inhibit the actions of insulin-like growth factors (IGFs). We showed previously that ovarian follicular dominance in cattle is associated with the presence of a protease that degrades IGFBP-4. To test the hypothesis that specific IGFBP-4 proteolysis is associated with selection of the dominant follicle, we induced codominant follicles (co-DFs) during the first follicular wave of the estrous cycle. The ovaries of Holstein heifers were examined twice daily by ultrasonography; when the largest follicle reached 6 mm in diameter, saline (control, n = 5) or 2 mg of recombinant bovine (rb) FSH (FSH, n = 5) was injected i.m. every 12 h for 48 h. Follicular fluid was collected by aspiration from the two largest follicles/heifer 12 h after the last injection. IGFBPs in follicular fluid were quantified by Western ligand blotting/phosphorimaging. IGFBP-4 protease activity was measured by incubating follicular fluid with recombinant human (rh) IGFBP-4 substrate, followed by ligand blotting/phosphorimaging to quantify the percent of substrate loss and Western immunoblotting to detect specific proteolytic fragments. Co-DFs of FSH heifers did not differ (P > 0.05) from the single dominant follicle of controls in size, or in concentration of progesterone or level of IGFBP-4 in follicular fluid. In contrast, the largest subordinate follicle of control heifers was smaller, with lower progesterone and higher IGFBP-4 in the follicular fluid (P < 0.05). Concentrations of estradiol in follicular fluid were high in dominant follicles, intermediate in co-DFs, and low in subordinate follicles (P < 0.05). IGFBP-4 protease activity in co-DFs was similar (P > 0.05) to that of dominant follicles, but fourfold higher (P < 0.05) than that of subordinate follicles. The results strongly suggest that an FSH-dependent IGFBP-4 protease is associated with selection of the dominant follicle in cattle.     

Alterations in intrafollicular regulatory factors and apoptosis during selection of follicles in the first follicular wave of the bovine estrous cycle

Changes in follicular fluid (FF) concentrations of estradiol, inhibin forms, and insulin-like growth factor binding proteins (IGFBPs), percentage of apoptotic granulosa cells (%A), and follicular size for individual follicles in a growing cohort were determined throughout the first wave of follicular development during the bovine estrous cycle and related to FSH decline. Four groups of heifers (n = 31) were ovariectomized between Days 1.5 and 4.5 of the estrous cycle at 5 +/- 1, 33 +/- 2, 53 +/- 1, and 84 +/- 2 h after the periovulatory peak in FSH concentrations. Follicles > or = 2.5 mm were dissected, measured, and FF aspirated. The five largest follicles were ranked based on their diameter (F1 to F5). Diameters of F1 to F5 were positively correlated with interval from FSH peak (r > or = 0.6, P < 0.05). Five hours after the FSH peak, follicular diameter and FF concentrations of estradiol, inhibins, and IGFBPs were similar for F1 to F5. From 5 to 33 h, amounts of the six precursor inhibin forms (> or = 48 kDa) increased (P < 0.05) in F1 follicles. The IGFBPs in F1 follicles remained low at all time periods. At 33 h, amounts of IGFBP-4 and -5 were higher (P < 0.05) in F4 and F5 compared with F1 follicles. At 84 h, IGFBP-2, -4, and -5 were increased (P < 0.05) in F3, F4, and F5 compared with F1. At 5, 33, or 53 h, %A was not different between follicles in any size class. At 84 h %A was increased (P < 0.05) in follicles <6 mm in diameter. However, at that time, %A did not differ between the selected DF and the largest subordinate follicle. For individual heifers, the selected DF at 84 h was largest in size, highest in estradiol, and lowest in IGFBP-2 and -4. The F1 follicle had highest estradiol in 23 of 27 heifers irrespective of stage of the wave and lowest IGFBP-4 in 19 of 21 heifers from 33 h. We concluded that the earliest intrafollicular changes that differentiate a dominant-like follicle from the growing cohort are enhanced capacity to produce estradiol and maintenance of low levels of IGFBPs.     

Oxytocin,prostaglandins E and F,estradiol, progesterone,sodium, and potassium in preovulatory bovine follicles either developed normally or stimulated by follicle stimulating hormone

To determine the differences between stimulation by follicle stimulating hormone (FSH) and normal development of follicles in heifers and the endocrinologic events associated with ovulatory development of follicles in heifers, follicular fluid was aspirated from follicles (n = 627) at 24, 48, and 72 h after estrus synchronization (via prostaglandin F_2α (PGF_2α)) from control animals (n = 10/time period) and a treatment group (n = 10/time period) that received FSH. No endocrinologic or ionic differences were noted between follicles harvested from control or FSH-stimulated animals within follicular size or time (24, 48, or 72 h). No interaction of treatment (FSH stimulation vs controls) by time was detected; thus the effect and timing of the LH surge was similar between treatments.At 48 h after PGF_2α administration, sodium from follicular fluid decreased and potassium increased, signifying a considerable physiologic change in the follicle. Follicular prostaglandins E and F increased ten-fold by 72 h, and these changes were primarily found in the estrogen-inactive follicles at 72 h. Though progesterone concentrations within follicular fluid tended to increase throughout the three periods and increased with enlargement of follicular size, a major increase was detected 72 h after PGF_2α injection. Estradiol concentrations tended to increase with enlargement of follicular size within a time period, but estradiol concentrations in the follicles greater than 10 mm in diameter decreased with time (24, 48, and 72 h) after PGF_2α. Concentrations of oxytocin increased with increases in follicular diameter, and the time trends were similar to changes in follicular progesterone. By 72 h after PGF_2α administration, follicular estradiol) was decreasing in concentration and progesterone and oxytocin were increasing, thus signifying a change in the secretory role of the granulosa cells.     

Changes in concentrations of follicular fluid factors during follicle selection in mares

The temporal relationships in the changes in concentrations of follicular fluid factors during follicle selection were characterized in mares. All follicles > or =5 mm were ablated 10 days after ovulation, followed by follicular fluid collection from the three largest follicles (F1, F2, and F3) when F1 of the new wave reached a diameter of 8.0-11.9, 12.0-15.9, 16.0-19.9, 20.0-23.9, 24.0-27.9, or 28.0-31.9 mm (n = 4-8 mares/range). Diameter deviation between F1 and F2 began during the 20.0- to 23.9-mm range, as indicated by a greater difference in diameter between the two follicles at the 24.0- to 27.9-mm range than at the 20.0- to 23.9-mm range. Androstenedione concentrations increased in F1, F2, and F3 between the 16.0- to 19.9- and 20.0- to 23.9-mm ranges. In contrast, estradiol, free insulin-like growth factor (IGF)-1, activin-A, and inhibin-A concentrations increased only in F1 beginning at the 16.0- to 19.9-mm range. As a result, the concentrations of all four factors were higher in F1 than in F2 and F3 at all the later ranges, including the 20.0- to 23.9-mm range (beginning of diameter deviation). Concentrations of progesterone differentially increased in F1, concentrations of androstenedione and IGF-binding protein (IGFBP)-2 increased only in F2 and F3, and concentrations of inhibin-B differentially decreased in F2 and F3 simultaneous with the beginning of deviation. Concentrations of FSH, LH, pro-alphaC inhibin, and total inhibin did not change differentially among follicles. Results indicated that, on a temporal basis, estradiol, free IGF-1, activin-A, and inhibin-A may have played a role in the initiation of follicle deviation. In addition, these four factors as well as progesterone, androstenedione, IGFBP-2, and inhibin-B may have been involved in the subsequent differential development of the follicles.     

Identification of potential intrafollicular factors involved in selection of dominant follicles in heifers

A surgical procedure to aspirate follicular fluid concurrently from individual follicles from the same heifer was validated and used to determine if intrafollicular amounts of estradiol, progesterone, inhibins, activin-A, follistatins, and insulin-like growth factor binding proteins (IGFBP) differed for the future dominant compared with subordinate follicles during selection of the first wave dominant follicle. Heifers were subjected to surgery and aspiration of follicular fluid from the two or three largest follicles on Day 3 of the estrous cycle (approximately 1.5 days after emergence). Ultrasound was used to determine the fate of each aspirated follicle after surgery. At aspiration, diameter of the future dominant and largest subordinate follicle was similar in heifers. However, estradiol was higher, whereas IGFBP-4 was lower in the future dominant compared with the largest or next largest subordinate follicles. Also, the future dominant follicle in most cohorts had the highest estradiol and lowest IGFBP-4 compared with future subordinate follicles. We concluded that: IGFBP-4 and estradiol may have key roles in determining the physiological fate of follicles during selection of the first wave dominant follicle in heifers, and that both are reliable markers to predict which follicle in a growing cohort of 5- to 8.5-mm follicles becomes dominant.     

Follicular Development and Ovulation in Sows: Effect of hCG and GnRH Treatment

Follicular growth, chronology of ovulation and embryo morphology were compared in sows ovulating spontaneously and sows, in which the ovulation was attempted induced by hCG or GnRH. Indwelling catheters were placed on day 1 (weaning = day 0) in the ear veins of 18 sows, which were then randomly divided into 3 groups: a control group (N = 6), a group (N = 6) given 750 iu hCG (Physex®) im 76h after weaning (hCG group) and a group (N = 6) given 500 µg GnRH (Fertagyl®) im 76h (N = 3) or 100h after weaning (N = 3) (GnRH group). Follicular diameter and time of ovulation were monitored by ultrasonography every 4h from day 3 until ovulation or development of cysts by means of a sector scanner fitted with a 5.0/7.5 MHz multiangle probe. Heat detection was performed every 8h from day 3 until ovulation. On day 13, the sows were slaughtered, the number of corpora luteae (CL) was counted, and embryos were flushed from the uteri. The control group showed clear heat symptoms, and on day 3, the follicles were typically 3–7 mm and grew up to 7–10 mm over 2 days, where they remained for approximately 24h until ovulation took place 41h ± 9h after first sign of standing heat. The hCG group exhibited no signs of heat, and the follicles only reached 5–8 mm in diameter at time of ovulation, which occurred 40h ± lh after hCG-injection. The GnRH group exhibited inconsistent signs of heat, and the follicles reached a maximum size of 7–12 mm in diameter where they remained for more than 24h. Only 2 sows in this group ovulated within 84–92h after the GnRH injection, and development of bursa cysts and cystic follicles was a common finding. The average number of CL was 18.2 ±5.7 per sow (N = 16, range: 3–27) with no significant difference between the groups. Total embryo recovery was 79 ± 13 % with no significant difference between groups. The embryo diversity calculated as standard deviation of the maximum diameter was higher in the hCG group as compared with the control group. It is concluded that (1) transrectal ultrasonography can be used in sows for accurate assessment of follicular growth and ovulation; (2) the use of hCG results in lack of heat symptoms and reduced follicle size at the time of ovulation when injected 76h after weaning; (3) administration of a single injection of GnRH, if given before the first signs of heat, results in inconsistent heat symptoms and no or late ovulations.     

Relationship between concentrations of cortisol in ovarian follicular fluid and various biochemical markers of follicular differentiation in cyclic and anovulatory cattle

Concentrations of cortisol were determined in pooled fluid of small (less than 10 mm) and large (greater than or equal to 10 mm) follicles of cyclic cattle (Exp. 1), and in fluid of the largest follicle of 17 post-partum anovulatory cows (Exp. 2). In Exp. 1, concentrations of cortisol in small follicles were greater (P less than 0.05) than in large follicles (14.7 versus 13.2 ng/ml), and varied significantly with stages of the cycle; small and large follicles had the highest cortisol concentration during the early luteal phase of the cycle. Large follicles had 2-fold greater concentrations of oestradiol than did small follicles, whereas small follicles had 2-fold greater concentrations of androstenedione than did large follicles. Across pools of follicular fluid, cortisol concentrations were correlated only to androstenedione concentrations (r = 0.65, P = 0.07). In Exp. 2, concentrations of cortisol did not significantly differ between oestrogen-active (oestradiol greater than progesterone in follicular fluid) and oestrogen-inactive (progesterone greater than oestradiol) follicles, although oestrogen-active follicles had a 24-fold greater concentration of oestradiol than did oestrogen-inactive follicles. Cortisol concentrations were correlated to hCG binding capacity of thecal cells (r = -0.35, P = 0.08) and to follicular diameter (r = 0.45, P less than 0.05). These results suggest that normally fluctuating concentrations of cortisol in follicular fluid of cattle play little or no active role in follicular differentiation in vivo.     

Follicular dynamics around the recruitment of the first follicular wave in the cow

The present study aimed to test the generally accepted view that a follicular wave starts with follicles newly recruited from the population smaller than 3 mm, which later compete for dominance. According to this view, subordinate follicles are expected to be too atretic to join the next follicular wave. Ten cows were ovariectomized shortly prior to the LH surge, thus around the start of the first follicular wave of the cycle. Per cow, on average, 14.4 follicles of >/=3 mm were dissected. Follicular health was determined on the basis of four parameters: 1) judgment of the degree of atresia by stereomicroscope, 2) incidence of apoptotic nuclei among the granulosa cells, 3) estradiol and progesterone concentrations, and 4) insulin-like growth factor-I (IGF-I) binding proteins (IGFBPs)-2, -4, and -5 concentrations in the follicular fluid. In addition to the preovulatory follicle, 3.1 other follicles, mainly sized 3-4.5 mm, were found to be healthy based on the proportion of apoptotic nuclei, and concentrations of estradiol/progesterone, and IGFBPs. The ability of these follicles to respond with growth on the preovulatory and periovulatory FSH surges was supported by a comparison to the follicular population of four cows 31-68 h after the LH surge. The present results point to an alteration of the view on the follicular wave. The larger follicles during the first days of the follicular wave are, in general, derived from follicles that also joined the previous wave. A portion of these growing follicles are estradiol active and compete for dominance. Other growing follicles lack estradiol production and are probably derived from rather atretic follicles. The first newly recruited follicles do not reach the size of 3 mm before 31 h after the preovulatory FSH surge. At that time, the larger follicles are already competing for dominance.     

Steroid hormone formation in human ovarian follicles in vitro.

Ovarian follicles of 5 to 15 mm in diameter were isolated from 45 ovaries of 34 patients in the follicular and luteal phases of the cycle. Three experiments were done. In the first, follicles were minced and incubated in Krebs-Ringer bicarbonate buffer containing 1 to 2muCi of testosterone-4-14C in the presence or absence of 100 IU human chorionic gonadotropan (hCG). In the second, minced follicles were incubated with 100 muCi of sodium acetate-I-14C under identical conditions. In the third, ten follicles from a single patient in the late proliferative stage of endometrial dating were cut in halves and incubated with 100 muCi of acetate-I-14C under identical conditions. The minced follicle preparation was capable of aromatizing testosterone-4-14C into radioactive estrone and estradiol in significant amounts. Incorporation of radioactive acetate into pregenolone, progesterone, 17-hydroxypregnenolone, 17-hydroxyprogesterone, dehydroepiandrosterone, androstenedione, testosterone, estradiol and estrone was assessed by reverse dilution analysis with recrystallization to constant specific activity. The major radioactive products formed were androstenedione and 17-hydroxyprogesterone in the latter two experiments. Dehydroepiandrosterone was one of the major steroids in the second experiment. The minor products were testosterone, progesterone and pregnenolone. Smaller, but definite incorporations of radioactive acetate into estradiol and estrone occurred in the second experiment. On histological examination, the follicles were characterized by atretic changes. This distribution pattern of radioactive acetate among the steroids was considered to represent the steroidogenic profile of unstimulated or atretic follicles.     

Concentrations of inhibins and steroids in follicular fluid during development of dominant follicules in heifers

The objective of this study was to examine changes in intrafollicular concentrations of inhibins and steroids in heifers during growth of dominant follicles. To obtain dominant ovulatory follicles, heifers received injections of prostaglandin (PG) on Day 9 of an estrous cycle and were ovariectomized (OVX) 0, 24, 48, 60, or 72 h after injection. To obtain dominant nonovulatory follicles, heifers were OVX on Day 3, 6, or 9 of a cycle. Follicular size was determined, follicular fluid (FF) was collected from follicles 6 mm or greater in diameter, and RIA was used to quantify concentrations of inhibins, estradiol, and progesterone in FF. During growth of dominant ovulatory follicles, concentrations of estradiol and progesterone increased, whereas inhibins decreased when compared with dominant follicles on Day 9 before PG treatment. Concentrations of inhibins were inversely correlated with size and concentrations of estradiol in dominant ovulatory follicles. As dominant nonovulatory follicles increased in size, concentrations of inhibins, estradiol, and progesterone increased. Concentrations of inhibins were positively correlated with size and with progesterone concentrations in dominant nonovulatory follicles. Concentrations of inhibins were greater in dominant nonovulatory follicles than in atretic follicles. In summary, intrafollicular concentrations of inhibins decreased during growth of dominant ovulatory follicles, but increased during growth of dominant nonovulatory follicles. Because of the well-known suppressive action of inhibins on FSH secretion, we hypothesize that inhibins are involved in growth and atresia of dominant follicles during the bovine estrous cycle.     

Follicular Development in Lactating,Post Weaning and Anoestrous Primiparous Sows

The ovarian follicular system was studied in 4 lactating sows (6 or 8 weeks lactation period), 4 post weaning sows (2 or 4 days after weaning) and 5 post weaning anoestrous sows (22 days after weaning) by macroscopical and microscopical examinations. Blood sampling was performed daily in the post weaning anoestrous sows. The results showed that none of the sows had ovulated during lactation and after weaning. Only small and medium sized follicles were present in the ovaries of the sows. The blood levels of oestradiol-17β and progesterone were low throughout the post weaning period in the anoestrous sows. Microscopical examination showed that all sows had more normal than atretic follicles. In the lactating sows all follicles were below 5 mm in size, the majority being small (1.00–2.99 mm in diameter). The post weaning sows had follicles up to 5.00–5.99 mm and 23–24% of the follicles were medium sized (3.00–5.99 mm in diameter). The post weaning anoestrous sows had no follicles above 5 mm in diameter but many normal medium sized follicles.     

Changes in the hypothalamic-hypophyseal-ovarian axis of primiparous sows following weaning or pulsatile gonadotropin releasing homrone administration and weaning

Lactating primiparous sows were used to examine relationships among hypothalamic gonadotropin releasing hormone (GnRH), serum, and anterior pituitary gonadotropins and follicular development after weaning or after administering GnRH pulses (1.5 ug) once hourly for 72 h before weaning. Control sows were either slaughtered at 0 or 72 h after weaning or were cannulated for collection of blood samples until 24 h after estrus. Sows pulsed with GnRH were either slaughtered 72 h after beginning of GnRH treatment or were cannulated for collection of blood samples until 24 h after estrus. Exogenous GnRH pulsed hourly during 72 h prior to weaning stimulated follicular growth as demonstrated by an increase in number of surface follicles >5 mm in diameter and a decrease in number of follicles <5 mm in diameter. Interval (h) from weaning to an increase in estradiol (>16 pg/ml) was less in GnRH-pulsed than in control sows (P < 0.05), but hours from weaning to estrus were similar between groups. Amounts of GnRH in the medial basal hypothalamus (MBH), stalk median eminence (SME), and hypophyseal portal area (HPA) were similar among control sows killed at 0 or 72 h and sows pulsed with GnRH. Serum concentrations of luteinizing hormone (LH) and frequency of release of LH were similar between GnRH-pulsed and control sows, but concentrations of LH and follicle stimulating hormone (FSH) in anterior pituitary were lower in GnRH-pulsed sows than control sows. Administration of GnRH for 72 h prior to weaning in primiparous sows stimulated follicular growth as manifested by increased secretion of estrogen; however, the amount of follicular growth was apparently inadequate to hasten the onset of estrus after weaning.     

In vitro steroidogenesis by dissociated rat follicles, primary to antral, before and after injection of equine chorionic gonadotropin.

Prepubertal female rats were injected s.c. with 5.0 IU eCG, and ovaries were collected 24 and 48 h post-eCG, on Day 25, as well as from an untreated group also on Day 25. Large antral follicles were manually dissected, and the ovarian remnants were incubated with collagenase overnight to liberate preantral follicles from adhering stromal cells. The viability of the follicles was established by normal histology and lack of pyknotic granulosa cells (GCs) and by their ability to secrete steroids. After a 1-h baseline incubation, either 10 ng LH or 100 ng FSH was added for an additional hour, and the media-before and after gonadotropin administration-were used to measure progesterone, androstenedione, and estradiol by RIA. A distinct hierarchy existed in steroid synthesis, with the maximal production by the largest (700 microm) antral follicles. The major steroid that had accumulated after addition of LH at 48 h post-eCG was androstenedione (1099 pg/follicle per hour), followed by equal amounts of progesterone (155 pg/follicle per hour) and estradiol (191 pg/follicle per hour). There was a precipitous drop in steroid production by 550-microm and 400-microm antral follicles, especially in estradiol for the latter-sized follicles (0.08 pg/follicle per hour). Preantral follicles also produced progesterone and androstenedione after addition of LH. For example, follicles 222 microm in diameter with 4-5 layers of GCs and well-developed theca responded to LH at 48 h post-eCG by accumulating androstenedione (37 pg/follicle per hour) and progesterone (6 pg/follicle per hour) but negligible estradiol. The smallest follicles secreting steroids, 110-148 microm in diameter, had 2-4 layers of GCs. However, primary follicles (1 layer of GCs and no theca) did not synthesize appreciable amounts of any steroid. Although small preantral follicles were consistently stimulated by LH, FSH was ineffective. This result differs from findings in the hamster showing that intact preantral follicles with 1-4 layers of GCs and no theca respond to FSH by secreting progesterone in vitro (Roy and Greenwald, Biol Reprod 1987; 31:39-46). The technique developed to collect intact rat follicles should be useful for numerous investigations.     

Decline in circulating estradiol during the periovulatory period is correlated with decreases in estradiol and androgen, and in messenger RNA for p450 aromatase and p450 17alpha-hydroxylase, in bovine preovulatory follicles

The preovulatory surge of gonadotropins induces meiotic maturation of the oocyte, the follicular/luteal phase shift in hormone production, and ovulation. This complex and rapid series of developmental changes is difficult to study in large mammals, such as primates and ruminants, because variability in the length of individual reproductive cycles makes it virtually impossible to predict the time of the LH surge. We have validated an experimental model for inducing the LH surge and ovulation in cattle and used it to study the sequence of changes in hormone secretion and some of the mechanisms of these changes. Luteolysis and a follicular phase were induced by injection of prostaglandin F(2alpha); injection of a GnRH analogue 36 h later induced an LH surge and ovulation. The LH surge peaked 2 h after GnRH and ovulation followed 22-31 h after the surge, consistent with the periovulatory interval in natural cycles. The ensuing luteal phase was normal, both in length and in concentrations of circulating progesterone. In experiment I, the uteroovarian effluent was collected, via cannulation of the vena cava, at frequent intervals relative to GnRH injection. Circulating estradiol declined progressively after GnRH, reaching a nadir by 8-10 h before ovulation, whereas concentrations of androstenedione and testosterone remained constant. In experiment II, preovulatory follicles were obtained at 0, 3.5, 6, 12, 18, or 24 h after GNRH: Concentrations of androgens and estradiol were measured in follicular fluid and medium from cultures of follicle wall (theca + granulosa cells); steady-state levels of mRNA for 17alpha-hydroxylase (17alphaOH) and P450 aromatase were measured in follicular tissue. Shortly after the LH surge (3.5 h post-GnRH) there was an acute increase in the capacity of follicular tissue to secrete androstenedione, but not estradiol, in vitro. Thereafter, both androgens and estradiol declined, both in follicular fluid and in medium collected from cultures of follicle wall. Levels of mRNA for 17alphaOH and aromatase in follicle wall decreased significantly by 6 h after GnRH, suggesting that declining levels of these enzymes underlie the decreases in steroid production by follicular cells. These results show that in cattle the preovulatory decrease in follicular estradiol production is mediated by redundant mechanisms, because androgen production and the capacity of granulosa cells to convert androgens to estradiol decline coordinately, in concert with decreases in mRNA for 17alphaOH and P450 aromatase.     

Effects of weaning on concentrations of inhibin in follicular fluid and plasma of sows.

Changes in plasma and follicular fluid concentrations of inhibin were examined in sows after weaning at 28-32 days post partum. From 0 to 48 h after weaning, inhibin concentrations were 200-300 times higher in follicular fluid from small (less than 4 mm) and medium-large (greater than or equal to 4 mm) follicles than in ovarian venous plasma. Inhibin concentrations increased in follicular fluid from medium-large follicles at 24 and 48 h after weaning; concentrations in ovarian venous plasma were positively correlated with the number of medium-large follicles (r = 0.40) and with ovarian venous plasma concentrations of oestradiol (r = 0.61). Blood samples were collected for 30 days from sows (n = 6) that exhibited oestrus within 5 days after weaning and from sows (n = 5) that remained anoestrous for 11 days after weaning. Plasma inhibin concentrations rose in oestrous and anoestrous sows by 12 h and continued to rise for 60 h after weaning. Plasma inhibin concentrations rose further and were higher at 3.5-4.5 days after weaning in oestrous sows than in sows that remained anoestrous. After oestrus, plasma inhibin concentrations declined. At weaning, plasma concentrations of follicle-stimulating hormone (FSH) were higher in sows that subsequently exhibited oestrus than in sows that remained anoestrous. After weaning, plasma concentrations of FSH declined in both groups, reached a nadir at 2.5 days, and increased gradually in anoestrous sows; oestrous sows exhibited an FSH surge at oestrus. Plasma FSH returned to preweaning concentrations in both groups of sows at Days 7-8.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of short-term nutritional supplementation of ewes with lupin grain (Lupinus luteus), during the luteal phase of the estrous cycle on the number of ovarian follicles and the concentrations of hormones and glucose in plasma and follicular fluid

An experiment was conducted using 16 cyclic, Welsh Mountain ewes during the luteal phase of the estrous cycle to determine the effect of a 5-day period of feeding a high-energy high-protein diet (lupin grain; 500 g/day) on folliculogenesis and on the plasma concentrations of glucose, insulin, follicle stimulating hormone (FSH) and estradiol-17beta, and on the follicular fluid concentrations of glucose, inhibin A, estradiol-17beta, androstenedione and progesterone. Average weight did not differ between lupin-fed and control groups during the experiment. There was a trend for the number of small and large follicles to increase in the lupin-fed group. The plasma concentrations of glucose (P=0.012) and insulin (P=0.007) were higher during the feeding period in lupin-fed ewes. The plasma concentrations of FSH and estradiol-17beta were not significantly different. The mean follicular fluid concentration of glucose (small follicles; <3.5 mm) from lupin-fed ewes was elevated (P=0.010) and progesterone lowered (P=0.034) compared to controls. The follicular fluid concentrations of estradiol-17beta, androstenedione and inhibin A were not significantly different. The follicular fluid concentration of estradiol-17beta was positively correlated with androstenedione (r=-0.241; P=0.001) and inhibin A (r=0.734; P< or =0.001) and glucose was negatively correlated with inhibin (r=-0.241; P=0.01), but not estradiol (r=0.075; P=0.410) or androstenedione (r=0.050; P=0.564). The lupin grain supplement increased the number of follicles as expected, but this increase was not significant. These changes were reflected in follicular fluid where lupin feeding increased the concentration of glucose and decreased the concentration of progesterone in follicles less than 3.5mm in diameter. These data suggest that the local ovarian actions of nutrients have a role in the mediation of nutritional influences on folliculogenesis.