Effect of nitric oxide synthase inhabitors on ovulation in hCG-stimulated mares

Recent studies suggest that nitric oxide (NO) may have a role in regulating ovarian physiology. To investigate the role of NO during ovulation in mares, inhibitors of the nitric oxide synthase (NOS) were administered to estrous mares. Forty cycling mares (20 horses and 20 pony mares) were allotted to one of the three treatment groups. Once a follicle was at least 27 mm in diameter, but smaller than 35 mm, mares were given one of the following treatments: saline solution 0.9% (n = 20, w/v, i.v., every 12 h), Nomega-nitro-L-arginine methyl ester hydrochloride (L-NAME; n = 10, 148 micromol/kg, i.v., every 12 h), or aminoguanidine hemisulfate (AG; n = 10, 406 micromol/kg, i.v., every 12 h). When a follicle >30 mm was present on one of the ovaries, ovulation was induced with hCG (2,500 IU, i.v.). The median time of ovulation (+/-6 h) after hCG administration for the treatment groups was 42, 84 and 54 h for mares treated with saline solution, L-NAME and AG, respectively. There was no significant difference between the groups treated with AG or L-NAME (P = 0.06); however, these groups were different from the control group (P < 0.05). The delayed ovulation caused by the administration of NOS inhibitors suggests a role for NO in follicular growth and ovulation in horses.     

The effect of treatment with flunixin meglumine at different times relative to hCG administration on ovulation failure and luteal function in mares

Flunixin meglumine (FM), a prostaglandin synthetase inhibitor, causes ovulatory failure in the mare. However, the effect of the FM treatment relative to the time of hCG administration on the ovulation failure has not been determined nor has its effect on the luteal function of treated mares. Estrous mares with a follicle ≥32 mm (range of 32-38 mm) were treated with 1.7 mg/kg b.w. of FM iv at zero, 12, 24 and 36 h (n=6), at 24 and 36 h (n=6), at 28 and 36 h (n=6), at 24h (n=6) or at 30 h (n=6) after treatment with 1500 IU hCG. One group received no FM (control, n=6). Progesterone concentrations were determined using RIA. Mares treated with FM 0-36 h and 24-36 h had higher (P<0.05) incidence of ovulatory failure (83 and 80%, respectively) than mares treated twice at 28 and 36 h, or once at 24 or at 30 h after hCG (16.7, 0 and 0%, respectively). The anovulatory follicles of FM treated mares luteinized and produced progesterone (>2 ng/ml). The progesterone concentration was lower in mares treated with FM at zero to 36 h and at 24-36 h after hCG than in the other groups. In conclusion, the FM administration was effective in blocking ovulation only when the treatment began ≤24 h after hCG and was continued every 12 h until ≥36 h. In addition, the FM-induced anovulatory follicles underwent luteinization of follicular cells with active production of progesterone.     

Follicle and systemic hormone interrelationships during induction of luteinized unruptured follicles with a prostaglandin inhibitor in mares

The objective was to determine differences in follicle and reproductive hormone characteristics in mares with ovulatory and flunixin meglumine (FM)-induced anovulatory cycles. Estrous mares were given 1500 IU hCG when the follicle was ≥ 32 mm (0 h). In Experiment 1, control mares (n = 7) were not treated further. The remaining mares (n = 11) were given 1.7 mg/kg FM i.v. twice daily, from 0 to 36 h after hCG treatment. Blood samples and ultrasonographic examinations were performed every 12 h. All control mares ovulated normally between 36 and 48 h. In contrast, eight of 11 FM mares did not ovulate, but developed luteinized unruptured follicles (LUFs). Three FM-treated mares did not develop conventional LUFs. Plasma progesterone concentrations were lower (P < 0.05) in LUF mares at 96, 120, and 216 h than in controls, whereas plasma LH concentrations were higher (P < 0.05) between 108 and 120 h in LUF mares than in controls. Plasma concentrations of PGFM and estradiol did not differ significantly between groups. In Experiment 2, the three mares that did not develop LUFs were treated, during the consecutive cycle, with the same dose of FM but with increased frequency at zero, 12, 24, 30, 36, and 48 h after hCG. One mare formed a LUF, whereas the other two did not. These two mares had lower LH concentrations than LUF or control mares in the two consecutive cycles. In conclusion, systemic treatment with FM blocked ovulation in 73% of treated mares. Mares with LUFs had lower progesterone and higher LH concentrations than control mares.     

Immunosuppressive properties of follicular fluid from preovulatory horse follicles

Fluid was aspirated from the preovulatory follicles of mares before and 12, 24 and 36 h after intravenous administration of hCG. Follicular fluid significantly (P less than 0.001) reduced lymphocyte blastogenesis in vitro and, at a dilution of 1:100, fluid collected at 36 h after administration of hCG was significantly more suppressive (P less than 0.01) than fluid collected before 36 h. Suppression of blastogenesis was reduced by extracting the follicular fluid with ether or by charcoal treatment (P less than 0.01) or by heating at 56 degrees C for 30 min (P less than 0.05). Preincubation of lymphocytes with 2 of 5 follicular fluid samples expressed subsequent blastogenesis. Follicular fluid inhibited blastogenesis of T-cell growth factor (TCGF)-dependent Con A lymphoblasts (P less than 0.05) and the degree of inhibition was related to time of addition of the TCGF and time of collection of the follicular fluid. These results indicate that preovulatory follicular fluid in the mare is increasingly suppressive to lymphocytes as time of ovulation approaches and that this immunosuppression is associated with an alteration of the response to lymphokine stimulation.     

Progesterone promotes oocyte maturation, but not ovulation, in nonhuman primate follicles without a gonadotropin surge

During the periovulatory interval, intrafollicular progesterone (P) prevents follicular atresia and promotes ovulation. Whether P influences oocyte quality or maturation and follicle rupture independent of the midcycle gonadotropin surge was examined. Rhesus monkeys underwent controlled ovarian stimulation with recombinant human gonadotropins followed by a) experiment 1: an ovulatory bolus of hCG alone or with a steroid synthesis inhibitor (trilostane, TRL), or TRL + the progestin R5020; or b) no hCG, but rather sesame oil (vehicle), R5020, or dihydrotestosterone (DHT). In experiment 1, the majority of oocytes remained immature (65% +/- 20%) by 12 h post-hCG. However, the percentage of degenerating oocytes increased (P < 0.05) with TRL (42% +/- 22% vs. 0% controls), but was reduced (P < 0.05) by progestin replacement (15% +/- 7%). By 36 h post-hCG, the majority of oocytes in all three groups reached metaphase II (MI). In experiment 2, no evidence of follicle rupture was observed in the vehicle, R5020, or DHT groups. Despite the absence of hCG, a significant (P < 0.05) percentage of oocytes resumed meiosis to metaphase I in R5020- (41 +/- 9) and DHT- (36 +/- 15) but not vehicle- (4 +/- 4) treated animals. Only oocytes from R5020-treated animals continued meiosis in vivo to MII. More (P < 0.05) oocytes fertilized in vitro with R5020 (40%) than with vehicle (20%) or DHT (22%). Thus, P is unable to elicit ovulation in the absence of an ovulatory gonadotropin surge; however, P and/or androgens may prevent oocyte atresia and promote oocyte nuclear maturation in primate follicles.     

Nitric oxide inhibits oocyte meiotic maturation

Recently, we have found that the nitrate/nitrite concentrations in preovulatory follicles significantly decrease after hCG injection and that inducible nitric oxide synthase (iNOS) plays a main role in the decrease of the intrafollicular nitric oxide (NO) concentration. The purpose of the present study was to investigate the role of NO on oocyte meiotic maturation and to consider the physiological means of the decrease in intrafollicular NO concentration. Immature rats received 15 IU of eCG, and ovaries were removed under ether anesthesia 48 h later. Each ovary was bluntly divided into five or six pieces containing from four to seven preovulatory follicles under the microscope and then incubated with hCG, aminoguanidine (AG; an iNOS inhibitor), or S-nitroso-L-acetyl penicillamine (SNAP; an NO donor) for 5 h. After incubation, preovulatory follicles were punctured, and germinal vesicle breakdown (GVBD) was observed. Also, cGMP concentrations in these follicles were measured. Next, denuded oocytes were recovered from preovulatory follicles at 48 h after injection of 15 IU of eCG and incubated with SNAP with or without ferrous hemoglobin. Every 30 min up to 12 h, GVBD was observed. Both AG and hCG promoted GVBD, and SNAP prevented this effect. In addition, AG decreased intrafollicular cGMP levels, and the concomitant addition of SNAP prevented this decrease. Finally, SNAP dose-dependently inhibited GVBD in denuded oocyte, and this effect of SNAP was reversed by the addition of hemoglobin. We conclude that the iNOS-NO-(cGMP) axis may play an important role in oocyte meiotic maturation.     

Inverse relationships between steroid concentration and volume in preovulatory follicles of the golden hamster

In order to investigate variations in the microenvironment of oocytes within a cohort of maturing follicles the follicular volumes as well as the intrafollicular concentrations of oestradiol (E2) and progesterone (P) were measured in the golden hamster. At 10 h before ovulation the follicular volumes varied from 0.009 to 0.037 mm3 (mean +/- SD: 0.0187 +/- 0.0071 mm3; n = 36). Large follicles (greater than 0.025 mm3; n = 8) contained statistically significantly lower E2 and P levels (30.1 +/- 10.4 and 517 +/- 113 mumol/l, respectively) than the medium sized group (less than 0.025 and greater than 0.015 mm3; n =20): 46.9 +/- 16.0 (P less than 0.02) and 919 +/- 264 (P less than 0.0001) mumol/l, respectively. Small follicles (less than 0.015 mm3) showed the highest steroid levels: 97.0 +/- 33.3 and 1590 +/- 517 mumol/l for E2 and P (P less than 0.001 versus the medium sized group values). Correlation coefficients for the steroid concentrations and the follicular volumes appeared to be -0.674 for E2 and -0.612 for P (P less than 0.001). At the time studied a positive correlation between E2 and P concentrations in the follicles was found: r = 0.655 (P less than 0.001). The mean ratios of intrafollicular over serum steroid concentrations appeared to be approx 36 x 10(3) in the case of E2 and about 17 x 10(3) in the case of P. These results clearly show that there is an inverse relationship between follicular volume and intrafollicular steroid concentrations. The presence of a fine regulatory mechanism for a collective maturation of follicles is hypothesized.     

Characterization of cellular and vascular changes in equine follicles during hCG-induced ovulation

In contrast to other species, the histology of the equine follicle during ovulation has not been described. Preovulatory follicles were isolated during oestrus at 0, 12, 24, 30, 33, 36 and 39 h (n = 5-6 follicles per time point) after an ovulatory dose of hCG to characterize the cellular and vascular changes associated with ovulation in mares. Pieces of follicle wall were formalin-fixed and processed for light microscopy to evaluate the general follicular morphology and quantify selected parameters. Marked changes were observed in the histology of equine follicles in the hours before ovulation. The thickness of the granulosa cell layer doubled between 0 and 39 h after hCG (77.8 +/- 4.8 versus 158.8 +/- 4.8 microns, respectively; P < 0.01). This expansion was caused primarily by a pronounced accumulation of acid mucosubstances between granulosa cells, which was first detected at 12 h after hCG and peaked at 36-39 h. In contrast, a significant thinning of the theca interna was observed after hCG treatment. Fewer cell layers were present; theca interna cells appeared smaller than before hCG; and the presence of occasional pyknotic cells was noted at 36 and 39 h after hCG. In addition, the theca layers were invaded by numerous eosinophils. No eosinophils were observed in preovulatory follicles isolated between 0 and 24 h after hCG, but the number increased to 14.0 +/- 0.8 and 5.6 +/- 0.3 eosinophils per field (x 400) in theca interna and theca externa, respectively, 39 h after hCG treatment (P < 0.01). Severe oedema, hyperaemia and haemorrhages, and significant increases in the number of blood vessels in theca interna and externa were observed at 33, 36 and 39 h after hCG. This study provides the first in-depth characterization of the sequential cellular and vascular changes that occur in equine follicles before ovulation.     

Critical role of insulin-like growth factor system in follicle selection and dominance in mares

The role of the insulin-like growth factor (IGF) system in the deviation in growth rates among follicles (follicle selection) was studied in mares using an IGF binding protein (BP) to reduce the follicular-fluid concentrations of IGFs. The future dominant follicle (F1) was treated by intrafollicular injection at the expected beginning of deviation (F1 > or = 20 mm; Day 0). The experimental groups were control (no injection, n = 8), vehicle (injection of vehicle; n = 6), and BP (injection of 250 microg of recombinant human IGFBP-3; n = 6). A sample of follicular fluid was taken from F1 on Day 1 in all groups. Compared with the control group, IGFBP-3 reduced (P < 0.05) the follicular-fluid concentration of free IGF-1 by 90%; lowered (P < 0.05) the concentrations of estradiol, activin-A, inhibin-A, and vascular endothelial growth factor; and increased (P < 0.05) the concentration of androstenedione. The diameter of F1 decreased and the diameter of F2 increased after Day 0 in the BP group, compared with the control and vehicle groups. A greater (P < 0.05) increase in circulating concentrations of FSH between Days 0 and 1 occurred in the BP group than in the other groups and accounted for the increased growth of F2. Dominance and ovulation from F1 occurred from fewer (P < 0.03) mares in the BP group (1 of 6) than from the control and vehicle groups combined (11 of 14); the remaining mares in the BP group ovulated from F2. Results indicated that the IGF system has a critical intrafollicular role in the differential changes in concentrations of follicular-fluid factors between the future dominant and subordinate follicles, leading to the development of follicle dominance (selection) and ovulation in mares.     

Stimulation of folliculogenesis in domestic cats with human FSH and LH

Folliculogenesis in response to exogenous stimulation by human urinary follicle stimulating hormone (huFSH) and human menopausal gonadotropin (hMG) was evaluated in the domestic queen (Felis catus). The role of LH and/or FSH in folliculogenesis was examined by measuring concentrations of estradiol 17beta (E(2)) and progesterone (P) in the serum. Additionally, changes in the number and size of follicles from before the administration of exogenous hormones to surgical oocyte collection were monitored. Findings indicated that in queens receiving huFSH or hMG followed by human chorionic gonadotropin (hCG) to induce ovulation, the numbers of follicles from 1 to 3 mm increase with statistical significance (P<0.005) from before the initiation of treatment to surgical collection of oocytes. Although E(2) concentrations in cats receiving hMG increased above baseline by the third exogenous hormone injection, mean E(2) concentrations did not increase in the groups that received both huFSH and hCG, or hCG only, until after the administration of hCG. This suggests that the exogenous administration of LH contained in both hMG and hCG was necessary for E(2) to rise to levels associated with estrus.     

Systemic treatment with high dose of flunixin-meglumine is able to block ovulation in mares by inducing hemorrhage and luteinisation of follicles

Prostaglandins play an obligatory role during the process of ovulation in mammals. Ovulation can be blocked by intrafollicular administration of non-steroidal anti-inflammatory drugs (NSAIDs) in several domestic species including the mare as well as by systemic administration of these drugs in women. In the mare, the effect of systemic NSAIDs treatment on ovulation has not been critically studied. The objectives of this study were: a) to determine whether high dose of flunixin-meglumine (FM) administered systemically to mares during the periovulatory period was able to block ovulation; and b) to study the follicular ultrasound characteristics of FM treated mares. Six mares were used in the study during two consecutive estrous cycles. Each mare received 2 mg FM/kg i.v. twice a day starting at the time of treatment with hCG when the follicle reached a diameter of ≥ 32 mm and continuing until ovulation. During the consecutive control cycle (CON) the mares received the same dose of hCG but were not administered FM. During the FM cycles five of six mares failed to ovulate and collapse the preovulatory follicle; but echoic specks were observed within the follicles, which continued to grow until a mean diameter of 55 mm. Eventually, the follicular contents were organised and luteinised. All CON mares ovulated normally. In conclusion, when mares were treated with FM, they had a higher incidence of ovulatory failure and development of luteinised unruptured follicles (83%, P = 0.015) compared with untreated mares.     

Aspiration of equine oocytes from immature follicles after treatment with equine pituitary extract (EPE) alone or in combination with hCG

This study examined the effect of treating mares with equine pituitary extract (EPE) alone or in combination with hCG on the recovery rate of immature follicles by transvaginal follicular aspiration (ovum pick-up; OPU). Ten normally cycling crossbred mares aged 3-15 years and weighing 350-400 kg were subjected to each of three treatments in a random sequence with each exposure to a new treatment separated by a rest cycle during which a spontaneous ovulation occurred. The treatments were (1) superovulated with 25mg EPE and treated with 2500 IU hCG, (2) superovulation with 25mg EPE, and (3) control (no exogenous treatment). Treatments 7 days after spontaneous ovulation; and all the follicles >10mm were aspirated 24h after the largest follicle achieved a diameter of 27-30 mm for control group, and most follicles reached 22-27 mm for the EPE alone treatment. To the group EPE+hCG, when the follicles reached 22-27 mm, hCG was administered, 24h before OPU. Superovulation increased the number of follicles available for aspiration. The total number of follicles available for aspiration was 61 in the EPE/hCG group, 63 in the EPE group and 42 in the control. The proportion of follicles aspirated varied from 63.5% to 73.8%. Oocyte recovery rate ranged from 15.0% to 16.7% and the proportion of mares that yielded at least one oocyte was 70% (7/10) in the EPE/hCG, 60% (6/10) in the EPE alone and 50% (5/10) in control group. The EPE/hCG treatment had a higher proportion of follicles with expanded granulose cells (64.4%) than the control (3.3%; p<0.05) and the EPE treatment (25.0%). The intervals from spontaneous ovulation to aspiration were similar for all treatments (11-12 days). However, superovulatory treatment significantly increased the aspiration to ovulation interval from 15+/-4 days for control to 27+/-15 days for EPE (p<0.05) and to 23+/-13 days for EPE/hCG treatment with commensurate increases in the time between spontaneous ovulations.     

Efficiency of superovulation and in vivo embryo production in eFSH-treated donor mares after estrus synchronization with progesterone and estradiol-17β

Reliable methods of regulating estrus and stimulating superovulations in equine embryo transfer programs are desirable. Our objectives were to investigate the efficacy of a progesterone and estradiol-17β (P&E) estrus synchronization regimen in mares with and without subsequent equine follicle-stimulating hormone (eFSH) treatment and to examine the effects of eFSH on folliculogenesis and embryo production. Cycling mares were treated with P&E daily for 10 d. On the final P&E treatment day, prostaglandin F_2α was administered, and mares were randomly assigned to one of two treatment groups (n = 20 mares/group). In both groups, mares were examined daily by transrectal ultrasonography. In the eFSH group, twice-daily eFSH treatments were initiated at follicle diameter 20 to 25 mm and ceased at follicle ≥35 mm; human chorionic gonadotrophin (hCG) was administered after 36 h. In the control group, eFSH treatments were not given, but hCG was administered at follicle ≥35 mm. Mares were inseminated with fresh semen, and embryo recovery attempts were performed 8 d postovulation. Synchrony of ovulations within each group appeared to be similar. Six mares in the eFSH group failed to ovulate. The eFSH treatment resulted in higher (P < 0.05) numbers of preovulatory follicles and ovulations; however, embryo recovery rate did not increase (eFSH 1.0 ± 0.4 vs. control 0.95 ± 0.1 embryos/recovery attempt), and embryo per ovulation rate was significantly lower (36% vs. 73%). The eFSH-treated mares had significantly higher frequency of nonovulatory follicles (28% vs. 0) and higher periovulatory serum concentrations of estradiol-17β. Based on our findings, combined P&E and eFSH regimens cannot be recommended for cycling donor mares.     

Gonadotropin and steroid control of granulosa cell proliferation during the periovulatory interval in rhesus monkeys

Progesterone produced in response to the midcycle gonadotropin surge is essential for ovulation and luteinization of the primate follicle. Because cell-cycle arrest is associated with the initiation of luteinization, this study was designed to determine the dynamics and regulation of granulosa cell proliferation by gonadotropin and progesterone during the periovulatory interval in the primate follicle. Granulosa cells or ovaries were obtained from macaques undergoing controlled ovarian stimulation either before (0 h) or as long as 36 h following the administration of an ovulatory hCG bolus with or without a 3beta-hydroxysteroid dehydrogenase inhibitor with or without a nonmetabolizable progestin. The percentage of cells staining positive for Ki-67, a nuclear marker for cell proliferation, decreased (P < 0.05) within 12 h of hCG administration in a steroid-independent manner. Levels of cyclin D2 and E mRNA did not decline during the periovulatory interval; however, cyclin B1 mRNA was reduced significantly by 12 h. Steroid depletion increased (P < 0.05) cyclin B1 mRNA at both 12 and 36 h post-hCG and was reversible by progestin replacement at 36 h. The cyclin-dependent kinase inhibitor p21(Cip1) was transiently increased 12 h post-hCG, whereas p27(Kip1) mRNA levels increased at 36 h in a steroid-independent fashion. These data suggest that a gonadotropin bolus inhibits mitosis in granulosa cells early (12 h) in the periovulatory interval, whereas progesterone may play a later, antiproliferative role in luteinized cells of primates.     

Thecal cell 3-beta hydroxysteroid dehydrogenase activity: modulation by human chorionic gonadotropin, progesterone, estradiol-17 beta and dihydrotestosterone

Thecal cell steroidogenesis plays a major role in folliculogenesis within the porcine ovary. Accordingly, the effects of physiological concentrations of steroids on 3 beta-hydroxysteroid dehydrogenase activity (3 beta-HSD) were determined. Theca was excised from large porcine follicles and prepared in a monolayer culture in 1 ml of serum-free media. Cells were treated 24 h after culture as follows: (1) control, (2) hCG (5 IU); (3) progesterone (P, 3 micrograms); estradiol-17 beta (E, 4 micrograms); 5 beta-dihydrotestosterone (DHT, 1 microgram); (4) hCG + P or E or DHT. At 3, 6, 12, 24 and 48 h after treatment, media were assessed for P levels. For 3 beta-HSD activity, P formation by microsomal fractions incubated with 1 microM pregnenolone + 5 microM NAD+ for 1 h (37 degrees C) was monitored. Thecal cell P secretion increased from 27 to 72 h. hCG significantly (P less than 0.05) increased P levels after 36 h compared to controls. E or E + hCG decreased P levels at 36, 48, and 72 h and DHT prevented the hCG-induced increase in P secretion. 3 beta-HSD activity in thecal microsomes increased significantly from 27 to 72 h. hCG had little effect on 3 beta-HSD activity compared with controls from 27 to 36 h, but significantly (P less than 0.05) decreased 3 beta-HSD activity at 48 and 72 h. However, P or P + hCG significantly (P less than 0.05) decreased 3 beta-HSD activity at all times. In addition, E or E + hCG significantly (P less than 0.05) decreased 3 beta-HSD activity at 48 and 72 h. DHT prevented the hCG-induced decrease in 3 beta-HSD activity. In conclusion, porcine thecal secretion of P and microsomal 3 beta-HSD activity increased during 72 h of culture. Paradoxically, the addition of hCG to cultures enhanced media P concentrations but inhibited 3 beta-HSD activity. Further, the addition of E to cultures decreased media concentrations of P while P or E decreased 3 beta-HSD activity. Therefore, paracrine/autocrine effects of locally produced steroids may play a role in modulating thecal cell steroidogenesis.     

Mitochondrial aggregation patterns and activity in porcine oocytes and apoptosis in surrounding cumulus cells depends on the stage of pre-ovulatory maturation

In this study, we evaluated the distribution and oxidative activity of mitochondria in ex vivo pre-ovulatory porcine oocytes using the fluorescence probe MitoTracker CMTM Ros Orange. Cumulus-oocyte complexes (COCs) were classified according to cumulus morphology and time from hCG administration. The meiotic configuration of the oocytes and the degree of apoptosis in the surrounding cumulus cells were also evaluated. Estrus was synchronized in 45 crossbred Landrace gilts by feeding altrenogest for 15 days and administering 1000 IU PMSG on Day 16. The LH peak was simulated by treatment with 500 IU hCG, given 80 h after PMSG. Endoscopic oocyte recovery was carried out 2 h before or 10, 22, or 34 h after hCG administration. Altogether 454 COCs were aspirated from follicles with a diameter of more than 5 mm. Cumulus morphology in the majority of COCs recovered 2 h before and 10 h after hCG was compact (60.4 and 52.7%, respectively; P<0.05). At 22 h after hCG, COC morphology changed significantly from 10 h dramatically: 74% of COCs had an expanded cumulus (P<0.01). At 34 h after hCG, 100% of recovered COCs had an expanded cumulus. The percentage of oocytes with a mature meiotic configuration differed among COC morphologies and increased as the interval after hCG administration increased (P<0.05). The type of mitochondrial distribution in the oocytes (n=336) changed from homogeneous to heterogeneous as the interval after hCG administration increased (P<0.01) and was associated with the cumulus morphology. Representative mitochondrial distributions were found as follows: -2 h: fine homogeneous in compact and dispersed COCs; 10 h: granulated homogeneous in compact and dispersed COCs; 22 h: granulated homogeneous in expanded COCs; and 34 h: granulated heterogeneous and clustered heterogeneous in expanded COCs (P<0.01). The oxidative activity of mitochondria measured by fluorescence intensity (Em: 570 nm) per oocyte after Mitotracker CMTM Ros Orange labeling increased in the oocyte as the post-hCG interval increased (P<0.01) and depended on the type of mitochondrial distribution. Lowest oxidative activity of mitochondria was found in oocytes with fine homogeneous distribution (253.1+/-9.4 microA). The oxidative activity increased (334.4+/-10.3 microA) in oocytes with granulated homogeneous distribution of mitochondria, and reached highest level in oocytes with granulated heterogeneous (400.9+/-13.0 microA) and clustered heterogeneous distributions (492.8+/-13.9 microA) (P<0.01). Mitochondrial activity in oocytes coincided with apoptosis in surrounding cumulus cells which increased in a time-dependent manner during pre-ovulatory maturation in vivo (P<0.01). These results indicate that there is a relationship between meiotic progression, cumulus expansion and mitochondrial redistribution and their oxidative activity during final pre-ovulatory maturation in pig oocytes. It appears that increased levels of mitochondrial activities in oocytes are correlated to increased levels of apoptosis in surrounding cumulus cells, in which mitochondria may play a role.