Radiation-induced chromosome aberrations in guinea-pig growing oocytes, and their relation to follicular atresia

The female guinea-pig has been shown to represent a good model to investigate the genetic hazard of ionizing radiation in humans. The sensitivity of the guinea-pig oocytes to radiation-induced chromosome aberrations was, therefore, studied at different stages of oocyte and follicular growth. The sensitivity of oocytes enclosed in small follicles (15 weeks before ovulation) was found to be low and comparable to that of immature oocytes present at birth. The sensitivity of growing oocytes remained low and almost constant until 3 weeks before ovulation, from which time it began to increase. The most dramatic increase of sensitivity occurred during the last week preceding ovulation: about 90% of oocytes X-irradiated with 4Gy, 2 days before ovulation showed one or more chromatid interchanges, as compared to 20% for those irradiated with the same dose 1 week earlier. A comparison of our results with those found by others in the mouse shows that considerable differences of sensitivity exist between oocytes of these two species irradiated at similar stages of development. The possible reasons for these differences are discussed.     

Hormonal dissociation of ovulation and maturation of oocytes: Ovulation of immature amphibian oocytes by prostaglandin

Prostaglandin involvement in ovulation and maturation of amphibian (Rana pipiens) ovarian follicular oocytes was investigated using in vitro-cultured ovarian follicles. Exposure of follicles to PGF₂α during culture stimulated variable but generally low levels of ovulation without concomitant induction of maturation. Addition of PGF₂α to cultured follicles markedly enhanced the incidence of ovulation in follicles exposed to progesterone or frog pituitary homogenate (FPH). Onset of the ovulatory process was further accelerated following addition of PGF₂α to FPH-treated follicles. PGE, in contrast to PGF₂α, exhibited no stimulatory effects on ovulation and consistently inhibited ovulation induction by FPH and progesterone. Cytological analysis of follicles undergoing ovulation revealed that ovulation of immature oocytes induced by PGF₂α varied markedly from that seen following FPH or progesterone stimulation of follicles in vivo or in vitro. Immature oocytes in contrast to maturing oocytes were typically ovlulated with follicle cells still attached to the vitelline membrane. The observations indicate that PGF₂α effected follicle rupture and contraction of the follicular epithelium and theca without prior separation of the follicle cells from the oocyte. Selective inhibitors of steroid synthesis (cyanoketone) and protein synthesis (cycloheximide) inhibited FPH-induced ovulation and maturation. PGF₂α reversed the inhibitory effects of cyanoketone and cycloheximide on FPH-induced ovulation but not maturation of oocytes. Neither prostaglandins alone or in combination with progesterone or FPH induced ovulation of oocytes following removal of the follicular epithelium. Ovulatory effects of PGF₂α appear to be mediated through the follicular epithelium. Results indicate that ovulation and maturation of amphibian oocytes can be induced independently of each other by separate classes of hormones. Normal synchronization of ovulation and maturation of oocytes may require the combined action of prostaglandins and steroids acting within different follicular compartments.     

Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: implications for blastocyst yield and blastocyst quality.

The aim of this study is to examine the effect of bovine oocyte maturation, fertilization or culture in vivo or in vitro on the proportion of oocytes reaching the blastocyst stage, and on blastocyst quality as measured by survival following vitrification. In Experiment 1, 4 groups of oocytes were used: (1) immature oocytes from 2-6 mm follicles; (2) immature oocytes from > 6 mm follicles; (3) immature oocytes recovered in vivo just before the LH surge; and (4) in vivo matured oocytes. Significantly more blastocysts developed from oocytes matured in vivo than those recovered just before the LH surge or than oocytes from 2-6 mm follicles. Results from > 6 mm follicles were intermediate. All blastocysts had low survival following vitrification. In Experiment 2, in vivo matured oocytes were either (1) fertilized in vitro or (2) fertilized in vivo by artificial insemination and the resulting presumptive zygotes recovered on day 1. Both groups were then cultured in vitro. In vivo fertilized oocytes had a significantly higher blastocyst yield than those fertilized in vitro. Blastocyst quality was similar between the groups. Both groups had low survival following vitrification. In Experiment 3a, presumptive zygotes produced by in vitro maturation (IVM)/fertilization (IVF) were cultured either in vitro in synthetic oviduct fluid, or in vivo in the ewe oviduct. In Experiment 3b, in vivo matured/in vivo fertilized zygotes were either surgically recovered on day 1 and cultured in vitro in synthetic oviduct fluid, or were nonsurgically recovered on day 7. There was no difference in blastocyst yields between groups of zygotes originating from the same source (in vivo or in vitro fertilization) irrespective of whether culture took place in vivo or in vitro. However, there was a dramatic effect on blastocyst quality with those blastocysts produced following in vivo culture surviving vitrification at significantly higher rates than their in vitro cultured counterparts. Collectively, these results indicate that the intrinsic quality of the oocyte is the main factor affecting blastocyst yields, while the conditions of embryo culture have a crucial role in determining blastocyst quality.     

Follicular development, steroidogenesis and ovulation within ovaries exposed in vitro to hormone levels which mimic those of the rat estrous cycle

In order to more clearly define the hormonal factors responsible for follicular growth, ovulation and steroidogenesis, a perifusion culture system was developed. This culture system was capable of exposing the ovaries to hormonal levels which mimic the 4-day estrous cycle of the rat. Using this culture system, ovaries were exposed to the in vivo levels of luteinizing hormone (LH), follicle-stimulating hormone (FSH), estradiol-17 beta and progesterone to within the mean +/- one standard deviation of the values reported by Butcher et al. (1974a). During the 4-day culture period, the diameter of the follicles gradually increased in a manner similar to that of cycling rats. After 4 days in vitro, the ovaries ovulated 4.3 +/- 0.6 oocytes/ovary as assessed by the presence of ruptured-partially luteinized follicles. This in vitro ovulation rate was not significantly different from the in vivo ovulation rate of 5.0 +/- 0.8 oocytes/ovary (P greater than 0.05). The pattern of follicular growth within cultured ovaries was similar to that of the cycling rat, although the number of small follicles recruited to grow was reduced. The steroid secretory patterns also were slightly different in the cultured ovaries. These data indicate that physiological ovarian responses which are similar to those of cycling rats can be induced within cultured ovaries. With further utilization of this culture technique, the precise role of gonadotropins, ovarian steroids and other hormonal agents can be examined in order to define specific ovarian functions which are controlled by each hormonal agent.     

Timing of nuclear maturation and postovulatory aging in oocytes of in vitro-grown mouse follicles with or without oil overlay

Meiotic maturation of the oocyte is a timed sequence of events induced by the ovulatory LH surge. In vitro maturation of oocytes is known to alter the meiotic time course. This study documented the timing of meiosis in oocytes grown in vitro for 12 days, from the preantral follicle stage onward, and the influence of an oil overlay. In the oil-free culture, the stability of the metaphase II spindle was further explored to determine the postovulatory aging events. After the maturation stimulus, in vitro-grown oocytes were collected at 2-h intervals spanning the period of meiosis (0-18 h) and at 3-h intervals during early postovulatory aging (18-27 h). Stage of maturation was assessed both morphologically and by detailed spindle analysis and chromosome alignment. Results revealed that oil overlay did not impair the competence of cultured oocytes to proceed to meiosis II, but delayed meiosis I progression. Oil overlay during culture causes a different hormonal exposure of the follicles by a differential segregation into the oil overlay. The use of a progesterone receptor antagonist, however, did not induce a delay in meiotic progression. Aging effects in oil-free cultured follicles were detected 5 h after the establishment of the metaphase II spindle, comparable to their in vivo grown counterparts. The predominant effect of aging was an interphase-like appearance of the cytoskeleton. So an optimal time window for fertilization after in vitro follicular growth was determined to be 16-21 h after maturation induction.     

Repair capacity of fertilized mouse eggs for X-ray damage induced in sperm and mature oocytes

To study the repair capacity of fertilized mouse eggs for X-ray damage induced in sperm and mature oocytes, the potentiating effects of 3 well-known repair inhibitors, arabinofuranosyl cytosine (ara-C), 3-aminobenzamide (3AB) and caffeine, on the frequency of induced chromosome aberrations were examined in eggs fertilized with X-irradiated sperm or in eggs irradiated with X-rays at the mature oocyte stage immediately before fertilization. Gametic treatment, fertilization and embryo culture were carried out in vitro. Ara-C treatment was done only in the pre-DNA replication period, while treatment with 3AB and caffeine was continuous from fertilization to the first-cleavage metaphase. The induction of chromosome aberrations by exposing sperm or oocytes to X-rays was remarkably potentiated by post-treatment incubation in the presence of each of the 3 inhibitors. This result indicates the possibility that X-ray damage induced in sperm or oocytes is reparable in the fertilized eggs and that various types of repair processes are involved.     

Trichlorfon-induced polyploidy and nondisjunction in mouse oocytes from preantral follicle culture

Trichlorfon (TCF), an organophosphate insecticide and potent inhibitor of choline esterases, was previously shown to induce first meiotic nondisjunction and spindle aberrations in isolated, follicle cell-denuded mouse oocytes maturing in vitro. To explore dose-response and direct and indirect, potentially synergistic effects of TCF on the somatic cells and the oocyte within a follicle, we presently employed preantral follicle culture. 100 microg/ml TCF added at the time of hormonally stimulated resumption of meiosis of follicle cell-enclosed mouse oocytes, 16 h before in vitro ovulation, induced significant rises in first meiotic nondisjunction in oocytes from preantral follicle culture. Lower concentrations (6 microg/ml TCF) disturbed polar body formation. Nuclear maturation to meiosis II in absence of cytokinesis resulted in significant increases in polyploidy. Oocytes maturing in follicles in the presence of TCF had aberrant second meiotic spindles. Influences of TCF on somatic cell function were evident by reduced follicular mucification in vitro and deceased progesterone production. In contrast to TCF, acetylcholine (0.1-100 microM) increased progesterone production. The observations therefore suggest that TCF influences oocyte maturation and folliculogenesis directly and indirectly. High TCF is aneugenic at first meiotic division in oocytes, irrespective of the presence or absence of follicle cells. At lower concentrations TCF interferes with spindle formation, chromosome congression at meiosis II, and coordination of nuclear and cytoplasmic maturation, posing risks for second meiotic errors. The observations suggest that chronic TCF exposure during maturation in the follicle may predispose oocytes to the formation of chromosomally unbalanced preimplantation embryos after fertilization.     

体外培养小鼠卵母细胞及其生长分化因子-9基因表达

体外培养小鼠的窦前卵泡以得到第二次减数分裂中期(MⅡ)卵母细胞,比较体外发育卵母细胞与体内生长的卵母细胞生长分化因子-9(GDF-9)的基因表达量,探讨GDF-9的表达对卵母细胞体外发育成熟的影响。选择体外培养第2天(D2)、D4、D6、D8、D10、D12卵母细胞作为体外发育组;同窝雌性小鼠出生后D12、D14、D16、D18、D20、D22卵母细胞作为体内发育组;半定量逆转录多聚酶链反应技术分别检测两组MⅠ卵母细胞GDF-9基因表达量。结果体外培养小鼠窦前卵泡可以得到MⅡ期卵母细胞,卵泡成活率、窦腔形成率、卵母细胞成熟率分别达到89·5%、51·8%和56·6%。小鼠卵母细胞GDF-9基因表达量随发育时间的改变而发生变化,而体外发育D8—12卵母细胞GDF-9表达量显著低于同期体内发育卵母细胞(P<0·05)。体外发育D8—12卵母细胞GDF-9基因表达量低于同期体内发育的卵母细胞的原因之一可能是其发育潜能较低。     

Recent achievements in in vitro culture and preservation of ovarian follicles in mammals

The mammalian ovary contains a large number of follicles that are in various developmental stages. The largest portion of them are primordial follicles. However, throughout the female reproductive lifespan only a small proportion of these follicles will produce oocytes competent to undergo successful maturation and ovulation. The rest of the ovarian oocytes (>99.9%) undergo atresia. It would be of great practical benefit to rescue some of these follicles by growing them in culture in order to provide an extra source of gametes. There is considerable interest in developing technologies that aim to produce fully-grown, developmentally competent oocytes from a pool of early developmental stages of follicles. Two methods have been used: 1/ long-term in vitro culture of either follicles or oocytes, and 2/ transplantation of ovarian tissue grafts. The development of efficient technologies may provide an additional source of oocytes for livestock production and reproduction in humans and rare or endangered species. The aim of this paper is to present a comprehensive review of recent achievements in the utilization of small ovarian follicles (primordial, preantral and early antral) by long-term in vitro culture and/or transplantation of ovarian tissue grafts (fresh and cryopreserved) in mammals including humans.     

Effects of in vitro culture of mouse fetal gonads on subsequent ovarian development in vivo and oocyte maturation in vitro

Under organ culture, female fetal gonads in mice cannot develop beyond the preantral follicle stage unless the follicles are individually isolated and cultured again. In this study, we investigated the effect of in vitro culture of female fetal gonads before transplantation on subsequent in vivo development. The gonads derived from female fetuses 12.5 days postcoitum were organ-cultured for 0, 7 and 14 days, and then were grafted underneath the kidney capsules of severe combined immunodeficient mice and recovered at 21, 14 and 7 days post-transplantation, respectively. The histological analysis of the grafts showed that the in vitro culture of the fetal gonads restricted follicular development to the antral follicle stage post-transplantation. In the grafts cultured for 14 days, particularly, no antral follicle was observed. However, the oocytes in these follicles had grown to around 65 µm in diameter and had competence to resume meiosis in vitro . When the fetal gonads were grafted after culture for 7 and 14 days, 13.0% and 6.8% of the oocytes progressed to the metaphase II stage, respectively. These data showed significant differences ( P  < 0.05) in comparison with the control group (25.3%). Our results indicate that the in vitro culture of female fetal gonads before transplantation affects the subsequent in vivo development of both follicular cells and oocytes, and in vitro oocyte maturation. However, this effect seems to be more severe in terms of follicular development when compared with oocyte growth and maturation.     

The influence of maternal age on radiation-induced chromosome aberrations in mouse oocytes

The relative sensitivities of dictyate oocytes from young and old female mice to radiation-induced chromosome damage were examined in 2 separate experiments. Firstly, females were given either 2 or 4 Gy of X-rays and metaphase I stage oocytes collected 16.5 days later. Analysis of these cells showed dose-related increases in chromosome aberrations in both age groups. The response was significantly greater in oocytes of older females. In the second experiment, females were given 4 Gy of X-rays and metaphase I stage oocytes collected 3.5 days later. Again, a significantly larger frequency of aberrations was present in cells from older animals. Overall, these 2 experiments provide unambiguous evidence that the radiosensitivity of mouse dictyate oocytes increases with advancing maternal age.     

Difference in types of radiation-induced structural chromosome aberrations and their incidences between Chinese and Syrian hamster spermatozoa

The effects of ionizing radiations on sperm chromosomes were studied in the Chinese hamster (Crisetulus griseus) and the Syrian (golden) hamster (Mesocrisetus auratus). Testes of mature male Chinese hamsters (CH) were irradiated with X-rays (0.91, 1.82 and 3.63 Gy) and γ-rays (1.10, 2.15, 2.95 and 4.01 Gy) at a single acute dosage, whereas the irradiation was done with lower doses of X-rays (0.45, 0.91 and 1.82 Gy) and γ-rays (0.49, 0.99 and 1.98 Gy) in mature male Syrian hamsters (SH), taking the higher radiosensitivity of this species into consideration. They were mated with normal females within 6 days of exposure. Sperm-derived chromosomes were analyzed in 1125 and 1966 fertilized ova of the CH and the SH, respectively. In both species, there was no great difference in the induction of structural chromosome aberrations between X-irradiated and γ-irradiated spermatozoa. Chromosome-type aberrations were predominantly induced. The incidence of breakage-type aberrations increased linearly, and that of exchange-type aberrations linear-quadratically with increase of dosage. A species-specific difference in chromosomal radiosensitivity of spermatozoa was clear. In spite of the same radiation dosage, the incidence of chromosomally abnormal spermatozoa in the SH was about twice as high as that in the CH (e.g., 27.0% vs. 14.7% at 0.91 Gy of X-rays). The incidences of breakage-type aberrations (69–89%) were far higher than those of exchange-type aberrations (11–31%) in the SH, while the disparity of the two incidences was much smaller in the CH (46–65% vs. 35–54%). Exchange-type aberrations consisted of both chromosome-type and chromatid-type in the SH, while almost all of them were of the chromosome-type in the CH. These results suggest that the DNA-repairing capacity of oocytes is much higher in the CH than in the SH. Moreover, it seems likely that radiation-induced sperm DNA damage is repaired with both pre-replication repair (excision repair) and post-replication repair systems in SH oocytes, whereas the excision repair system operate most exclusively in CH oocytes.     

The effects of spermatozoal irradiation with X-rays on chromosome abnormalities and on development of mouse zygotes after delayed fertilization

The chromosome complements of zygotes derived from oocytes aged post ovulation and fertilized in vivo with X-ray-irradiated sperm were studied. Ovulation was induced by an injection of luteinizing hormone-releasing hormone (LHRH) at pro-estrus and fertilization was achieved by artificial insemination at 13 h and 24 h after LHRH in order to obtain embryos from unaged and aged (12 h post-ovulation) oocytes respectively. Post-ovulatory aging prior to fertilization did not significantly affect the percentage of zygotes with irradiation-induced chromosome abnormalities. However, post-ovulatory aging had a negative effect on the morphology of male as well as female pronuclear chromosomes of the first cleavage metaphase. When fertilized with control spermatozoa this effect was apparent in both the male and the female pronucleus. When unaged oocytes were fertilized with X-irradiated spermatozoa chromosome morphology was also adversely affected in both pronuclei. In zygotes from aged oocytes, there was an extra negative effect of X-rays on the male pronuclear chromosomes only. After fertilization with X-irradiated sperm 27% of zygotes from aged oocytes were arrested at interphase compared to 7% from unaged oocytes. We suggest that post-ovulatory aging and X-rays affect the male and female pronuclear chromatin structure after fertilization. These chromatin alterations could interact with DNA lesions induced in the spermatozoa prior to fertilization, such that development to first cleavage can be blocked.     

Hormonal stimulation of maturation and Ovulation,egg quality,and development of larvae of <Emphasis Type="Italic">Abudefduf sexfasciatus</Emphasis> (Pomacentridae)

Experiments on the hormonal stimulation of oocyte maturation and ovulation of Abudefduf sexfasciatus (Pomacentridae) have been conducted. Both single and double injections of surfagon (LH-RH-a) are applied. Ovulation is registered more often 40–48 h after injection I. The morphological changes of oocytes during final maturation are followed. The egg quality is assessed after the storage of ovulated oocytes inside of the female’s body (in vivo) and in the external medium (in vitro) at 25 and 5°C. The development of free embryos and larvae is described.     

In vitro and in vivo maturation of oocytes from gonadotrophin-treated brushtail possums

The time course of nuclear maturation of oocytes was examined in brushtail possums, Trichosurus vulpecula. Oocytes were recovered from ovarian follicles > 2 mm in diameter after pregnant mares' serum gonadotrophin/porcine luteinizing hormone (PMSG/LH) treatment (in vivo matured) or 72 hr after PMSG treatment (in vitro matured). Oocytes recovered from small (< 2 mm) and large (> 2 mm) follicles were also assessed for their ability to mature in vitro. Staining with the DNA-specific dye Hoechst 33342 was used to assess the stage of nuclear development by fluorescence microscopy. The process of nuclear maturation progressed rapidly in vivo, as oocytes collected at 20-27 hr post-LH all had a GV, but by 28-29.5 hr post-LH approximately a third of eggs were MII. By 30-hr post-LH, more than 70% of oocytes had reached MII stage and all ovulated eggs were MII. In vitro, all oocytes were at germinal vesicle stage at the start of culture. After 24 hr of culture, 67% of oocytes had progressed to metaphase I/anaphase I of meiosis. After 36 hr, 25% of oocytes had completed maturation to metaphase II, increasing to 52% after 48 hr. Maturation of oocytes after 48 hr in culture was unaffected by the presence or absence of granulosa cells, PMSG or LH/porcine follicle stimulating hormone (FSH). More oocytes from large follicles (55%) completed maturation by 48 hr than from small follicles (15%). The potential of oocytes to mature after 48 hr in culture was dependent on the follicle harvested having reaching a critical diameter of 1.5 mm.     

Changes in germinal vesicle (GV) chromatin configurations during growth and maturation of porcine oocytes

Changes in germinal vesicle (GV) chromatin configurations during growth and maturation of porcine oocytes were studied using a new method that allows a clearer visualization of both nucleolus and chromatin after Hoechst staining. The GV chromatin of porcine oocytes was classified into five configurations, based on the degree of chromatin condensation, and on nucleolus and nuclear membrane disappearance. While the GV1 to 4 configurations were similar to those reported by previous studies, the GV0 configuration was distinct by the diffuse, filamentous pattern of chromatin in the whole nuclear area. Most of the oocytes were at the GV0 stage in the <1 and 1-1.9 mm follicles, but the GV0 pattern disappeared completely in the 2-2.9 and 3-6 mm follicles. As follicles grew, the number of oocytes with GV1 configurations increased and reached a maximum in the preovulatory follicles 4 hr post-hCG injection. During maturation in vivo, the number of GV1 oocytes decreased while oocytes undergoing GVBD increased. The percentage of oocytes with GV3 and GV4 configurations was constant during oocyte growth except at the 2-2.9 mm follicle stage, but these configurations disappeared completely after hCG injection. On the contrary, the in vitro maturing oocytes showed a large proportion of GV3 and GV4 configurations. There was no significant difference in distribution of chromatin configurations between the nonatretic and atretic follicles, and between oocytes with more than two layers of cumulus cells and those with less than one layer or no cumulus cells. Overall, our results suggested that (i) the GV0 configuration in porcine oocytes corresponded to the "nonsurrounded nucleolus" pattern in mice and other species; (ii) all the oocytes were synchronized at the GV1 stage before GVBD and this pattern might, therefore, represent a nonatretic state; (iii) the GV3 and GV4 configurations might represent stages toward atresia, or transient events prior to GVBD that could be switched toward either ovulation or atresia, depending upon circumstances; (iv) the in vitro systems currently used were not favorable for oocytes to switch toward ovulation (or final maturation); (v) the number of cumulus cells was not correlated with the chromatin configuration of oocytes, indicating that the beneficial effect of cumulus cells on oocyte maturation and development may simply be attributed to their presence during in vitro culture.     

Stimulation of parthenogenesis in mouse ovarian follicles by inhibitors of inosine monophosphate dehydrogenase

The effects of hormonal priming and inosine monophosphate (IMP) dehydrogenase inhibitors on the meiotic maturation and parthenogenetic activation of mouse oocytes were examined in this study. In the first series of experiments, unprimed mice or mice primed 24 h with equine chorionic gonadotropin (eCG) received injections of the IMP dehydrogenase inhibitors, bredinin (Br) or mycophenolic acid (MA), followed by histological examination at 24 h, 48 h, and 72 h after drug administration. In both treatment groups, oocytes from nonatretic antral follicles were stimulated to undergo germinal vesicle breakdown by 24 h and became parthenogenetically activated as manifested by pronuclear formation and early cleavage divisions. The parthenotes underwent degeneration by 72 h. In the second part of this study, the effects of priming and drug treatment on parthenogenetic activation and subsequent developmental potential in vitro were examined. Mice were primed with eCG, and 24 or 48 h later received injections of Br or MA. Cumulus cell-enclosed oocytes were isolated 21-22 h later and assessed for maturation; those having undergone germinal vesicle breakdown were cultured and subsequently examined for embryonic development. In mice primed for 24 h, but not 48 h, Br and MA stimulated a significant number of oocytes to resume maturation in vivo; these subsequently underwent activation and developed to blastocysts in vitro. In another series of experiments, germinal vesicle-stage oocytes were isolated from primed or unprimed mice and cultured in vitro to permit spontaneous meiotic maturation. Nine percent of mature ova from 24-h-primed mice developed to 2-cell parthenotes; activation in ova from unprimed and 48-h-primed mice was considerably lower. A time-course experiment demonstrated that the extent of parthenogenetic activation in vivo following Br treatment was related to the period of time between drug injection and isolation of ova, the optimal period being 12 h. Neither Br nor MA had a direct activating effect on the oocytes as evidenced by an inability to induce parthenogenesis in vitro. Simultaneous injection of hCG with either Br or MA stimulated ovulation and prevented the parthenogenetic response. These data are consistent with the idea that conditions within the follicle promote parthenogenetic activation when the oocyte matures in the absence of gonadotropin stimulation.     

Comparison of three in vitro culture systems for maturation of early preantral mouse ovarian follicles

The aim of this study was to compare three different culture systems for in vitro follicular growth and oocyte maturation in ovarian follicles of mice in order to assess the technique with the optimal growth and improved rate of meiotic maturation. The three systems tested were culture under oil, on a hydrophobic membrane and on agar respectively. Early preantral follicles were cultured for 12 days in alpha-MEM GlutaMAX medium. Follicular growth, oocyte meiotic maturation, oocyte extrusion, atresia and estradiol production were analysed. Follicular development showed two phases in the three systems, with slow growth before day 5 and subsequent acceleration. The percentage of follicles transferred into oocyte maturation medium was significantly higher after culture under oil. The proportion of oocytes that achieved nuclear maturation (metaphase II) was higher when follicles were cultured under oil or on a hydrophobic membrane than on agar. Our results support the use of culture under oil for in vitro follicular growth from the early preantral stage in order to obtain metaphase II oocytes. Fertilization ability of these oocytes and the capacity to obtain healthy mice in a reproducible manner warrants further investigation.     

Effect of 5-Hydroxytryptamine on Steroidogenesis and Oocyte Maturation in Pre-ovulatory Follicles of the Medaka Oryzias latipes

The effect of 5-hydroxytryptamine (5-HT) on steroidogenesis and oocyte maturation in pre-ovulatory follicles of the medaka Oryzias lalipes was examined using in vitro culture system. The earliest breakdown of the germinal vesicle of intrafollicular oocytes occurred about 17 hr after the beginning of incubation in the presence of 5-HT at concentration of 10 ng/ml or more. 5-HT induced oocyte maturation in a dose-dependent manner. Cyanoketone inhibited this stimulation. The concentration of 5-HT required to induce oocyte maturation corresponded to that required to enhance the production (secretion) of estradiol-17β and 17α,20β-dihydroxy-4-pregnen-3-one by pre-ovulatory follicle cells. At a concentration of 1 μg/ml, the follicle had to be exposed to 5-HT for at least 4 hr for oocyte maturation accompanied by ovulation to occur. These results indicate that 5-HT induces in vitro maturation of medaka oocytes by stimulating 17α,20β-dihydroxy-4-pregnen-3-one production by pre-ovulatory follicular cells.     

Oocyte Ca2+ spike acquisition during in vitro development of early preantral follicles: influence of age and hormonal supplementation

Calcium signalling is involved in important events in oocytes, such as meiotic competence acquisition. We have previously demonstrated the positive influence of animal age and gonadotropin stimulation in vivo regarding the ability of oocytes recovered from preantral follicles to exhibit calcium spikes. In the present work we determined whether preantral follicle development in vitro also allows oocytes to acquire calcium signalling activity. We also aimed to verify the influence of animal age, FSH + LH and/or insulin on oocyte calcium spike acquisition during preantral follicle culture. Early preantral follicles were isolated from 12-day-old and 1- to 3-month-old F1 hybrid mice and cultured individually for either 2 or 6 days. At the end of the culture period the oocytes were processed for calcium imaging by confocal microscopy. We show that oocytes recovered from cultured preantral follicles exhibit variable calcium spike activity rates, depending on animal age, culture duration and hormonal supplementation. Oocytes recovered from adult animals continue to exhibit calcium spikes, and those recovered from juveniles acquire that activity after culture. Insulin and gonadotropins in combination account for an early and maintained inhibitory effect on calcium signalling acquisition by oocytes. Insulin alone also leads to an early inhibitory effect, which, however, disappears with longer culture periods. Contrary to the complex in vivo situation, the acquisition of calcium signalling by oocytes in a controlled in vitro environment does not seem to be dependent on gonadotropins alone.