Insulin like growth factor 1 and regulation of ovarian function in mammals

Various growth factors have been proposed to play endocrine and/or paracrine role in mammalian ovarian follicular development. The insulin like growth factor 1 (IGF-1) is one such factor. More and more reports now support the existence of an intra-ovarian IGF system including receptors and binding proteins. The role of IGF-1 in ovary is to amplify gonadotropin hormone action in terms of increased steroidogenesis by ovarian granulosa cell and granulosa cell proliferation. The synthesis and proteolysis of insulin like growth factor binding proteins, under the control of follicle stimulating hormone, regulate the intra-follicular availability of IGF-1, which further determines the sensitivity of granulosa cells to gonadotropins. Besides gonadotropins, IGF-1 has been implicated in somatotropin hormone action in the ovarian function. Exact mechanism of IGF-1 action in the ovarian follicles needs to be worked out to elucidate whether or not IGF-1 is indispensable in addition to know endocrine factors like gonadotropic and ovarian steroid hormones. This will pave the way for better understanding of control(s) which ensure final development of dominant follicle(s) and atresia of other follicles of the cohort.     

Growth differentiation factor-9 stimulates proliferation but suppresses the follicle-stimulating hormone-induced differentiation of cultured granulosa cells from small antral and preovulatory rat follicles

In addition to pituitary gonadotropins and paracrine factors, ovarian follicle development is also modulated by oocyte factors capable of stimulating granulosa cell proliferation but suppressing their differentiation. The nature of these oocyte factors is unclear. Because growth differentiation factor-9 (GDF-9) enhanced preantral follicle growth and was detected in the oocytes of early antral and preovulatory follicles, we hypothesized that this oocyte hormone could regulate the proliferation and differentiation of granulosa cells from these advanced follicles. Treatment with recombinant GDF-9, but not FSH, stimulated thymidine incorporation into cultured granulosa cells from both early antral and preovulatory follicles, accompanied by increases in granulosa cell number. Although GDF-9 treatment alone stimulated basal steroidogenesis in granulosa cells, cotreatment with GDF-9 suppressed FSH-stimulated progesterone and estradiol production. In addition, GDF-9 cotreatment attentuated FSH-induced LH receptor formation. The inhibitory effects of GDF-9 on FSH-induced granulosa cell differentiation were accompanied by decreases in the FSH-induced cAMP production. These data suggested that GDF-9 is a proliferation factor for granulosa cells from early antral and preovulatory follicles but suppresses FSH-induced differentiation of the same cells. Thus, oocyte-derived GDF-9 could account, at least partially, for the oocyte factor(s) previously reported to control cumulus and granulosa cell differentiation.     

Influence of hormones on the inhibitory activity of oocyte maturation present in conditioned media of porcine granulosa cells

This study examines the influence of follicular maturation as well as the role of various hormones upon the secretion of an oocyte maturation inhibitor (OMI) from porcine granulosa cells incubated in vitro. The results demonstrate that the OMI substance, secreted into the media by granulosa cells, is present in a low molecular-weight fraction (< 10,000 daltons) similar to that found in follicular fluid of porcine antral follicles. Also, as follicular development progresses, the granulosa cells lose their ability to secrete OMI. More importantly, hormones appear to regulate OMI secretion: FSH stimulates OMI secretion and androgens inhibit OMI secretion. These data provide evidence for the proposal of the following hypothesis concerning hormonal regulation of oocyte, meiosis by OMI in the porcine follicle: Whether the oocyte resumes meiosis, either during atresia or ovulation, is dependent upon the proper milieu of gonadotropins, cyclic-AMP, and steroids within the microenvironment of the follicular compartment. The cellular interactions of these hormones, particularly FSH and androgens, control the amount of OMI (and possibly other intrafollicular factors) secreted in the follicle, which may be involved in either maintaining the immature state or permitting meiotic maturation.     

Regulation of ovarian follicular dynamics in farm animals. Implications for manipulation of reproduction

In this review, the main features of folliculogenesis are summarized and compared among species. In the past few years, ultrasonography has clarified follicle growth patterns, and our understanding of follicle maturation has improved considerably. As the follicles develop towards the ovulatory stage, three features appear to be highly conserved across all species: 1) the sequence of events (recruitment, selection and dominance); 2) the sequential need for gonadotropins (FSH for recruitment, LH for dominance) and 3) the large variability of numerical parameters (number of waves per cycle, number of follicles per wave) as well as temporal requirements (time of selection, duration of dominance). In addition, specific follicles may also have variable gonadotropin requirements (thresholds). When patterns of follicle development at different physiological states are compared across species, follicular waves were detected in cattle, sheep and horses and during the prepubertal period in swine, suggesting that ovaries of all species operate on a wave basis unless they are prevented from doing so. Efficient estrus control treatments should have the ability to affect 1) the wave pattern by preventing the development of persistent dominant follicles containing aging oocytes, and 2) the recruitment of the future ovulatory follicle whatever the stage of the wave at the time of treatment. This would allow synchronous ovulation of a growing dominant follicle. Manipulation of the luteal phase follicular waves after mating or AI may also optimize fertility. Superovulation is still an efficient technique to obtain progeny from genetically valuable females. Administration of exogenous gonadotropins acts to reveal the underlying ovarian variability. Ovarian response of each female depends on the number of gonado-sensitive follicles present at the time when treatment is initiated. Identification of the number of such follicles for each female would improve efficacy of superovulation, by allocating potential nonresponders to other techniques (OPU/FIV). One of the main components of the within female response to superovulation is the stage of the wave when gonadotropins are injected. Treatment in the absence of a dominant follicle ensures a response close to the female's specific maximum. The development of practical approaches to achieve this still requires further research.     

Activation of bovine and baboon primordial follicles in vitro

Mammalian ovaries contain a large pool of non-growing, primordial follicles. The ability to initiate growth of this pool of resting follicles in vitro and to maintain follicular growth to a stage when the oocyte could be matured and fertilized would increase the reproductive potential of valuable domestic animals, endangered species and infertile women. This paper summarizes our progress to date in activating primordial follicles of cattle and baboons. Pieces of ovarian cortex, rich in primordial follicles, were obtained from fetal bovine and baboon ovaries during late gestation. Pieces were maintained in organ culture in serum-free medium containing ITS+ (insulin-transferrin-selenium-linoleic acid-BSA) for up to 20 days and at various times during culture some pieces were fixed for histological morphometry. As early as 2 days of culture, the number of primordial follicles had decreased by 88% or 55%, whereas the number of primary follicles had increased 2.5- or 5-fold, compared to tissue freshly isolated from bovine or baboon ovaries, respectively (P < 0.01). In baboon cortical pieces a small number of secondary follicles developed during a 20-day culture period. The development of primary and secondary follicles was accompanied by an increase in diameter of both the granulosa cell layer and the oocyte. The addition of FSH (1, 10, or 100 ng/ml) had no effect on the development of follicles in bovine cortical pieces after 7 or 14 days of culture, relative to control cultures without FSH. These results show that a high percentage of primordial follicles from cattle and baboons can be activated to grow in serum-free medium in the absence of gonadotropins. Conditions that will support further growth in vitro of follicles from these species remain to be elucidated. The culture system we have developed could be used to develop such conditions and to explore factors that regulate the movement of primordial follicles into the pool of growing follicles.     

The early stages of follicular development: activation of primordial follicles and growth of preantral follicles

Although enormous progress has been made in understanding the events and regulation of the later stages of ovarian follicular development, the early stages of development, to a large extent and particularly in large mammals, remain a mystery. Mechanisms that regulate the initiation of follicular growth (follicle activation) and the ensuing growth and differentiation of preantral follicles are of considerable interest, since their elucidation is a prerequisite to use of the primordial pool to enhance reproductive efficiency in domestic animals, humans, and endangered species. This review is an attempt to summarize the approaches that have been taken to further this goal and the results thus far of these efforts. Preantral follicular development can be divided into three stages: activation of primordial follicles, the primary to secondary follicle transition, and the development of secondary follicles to the periantral stage. The activation of primordial follicles in vitro has been achieved thus far in rodents, cattle, and primates, where it occurs spontaneously without the addition of growth factors or hormones. The ovaries of rodents are small enough to be cultured intact and, in that experimental situation, some follicles activate, while many remain in the resting pool, and the addition of specific factors can increase or decrease the number of follicles that leave the resting pool in vitro. In contrast, follicular activation in cattle and primates has been studied by culturing small pieces of the ovarian cortex, rich in primordial follicles, and the great majority of the primordial follicles activate in that situation, suggesting the importance of inhibitory factors to the normal, gradual exit of follicles from the resting pool. In cultured rodent ovaries, follicles appear to pass easily and spontaneously from the primary to the secondary stage, whereas few of the activated follicles in cultured cortical pieces from cattle or primates progress from the primary to the secondary stage. Understanding the requirements for the primary to secondary transition is critical for growing follicles activated in vitro to the late preantral and antral stages. In contrast, the requirements for the continued growth of larger preantral follicles, which can be isolated for in vitro studies, have been extensively explored in rodents and to a lesser extent in domestic species. A number of hormones and factors have been implicated and will be discussed. Taken together, the results highlight the need for a better understanding of the earliest stages of follicular development in domestic ruminants, particularly follicle activation and the primary to secondary follicle transition.     

Influence of the dominant follicle on oocytes from subordinate follicles

As the oocyte grows within the follicle, a number of factors influence its health and developmental competence. These factors include follicle size, day of estrous cycle, level of atresia and influence of other follicles such as the dominant follicle. Follicles were dissected from ovaries of synchronized dairy cows on four days during the estrous cycle, and the oocyte from each follicle collected, matured, fertilized and cultured singly until Day 8. Development to blastocyst was greater in oocytes collected during phases of follicular growth than those collected during phases of follicular dominance (P<0.001) over all follicle size categories. Oocyte competence tended to increase with increasing follicle size (P<0.1). Follicular cells analyzed by flow cytometry showed an increase in proportion of apoptotic cells in subordinate follicles during the dominant phase compared to growth phase (P<0.05). Thus, the dominant follicle on both oocyte competence and levels of atresia. Further studies on the effect of dominance has shown that lactate production in cumulus-oocyte-complexes (COCs) from medium-sized follicles collected during a dominance phase and small follicles collected during a growth phase are no different from other follicles, despite having significantly lower uptake of glucose (P<0.1). Thus, COCs from different follicle subclasses differ in their nutrient requirements, and current IVM technology needs further improvement to better assist those oocytes that are developmentally challenged.     

Effects of gonadotrophin deficiency on follicular development in hypogonadal (hpg) mice

The rates of follicle growth and death in GnRH-deficient hypogonadal (hpg) mice and in normal mice were studied using the stochastic compartmental model of follicle dynamics. The rate estimates derived from this model suggest that in normal mice gonadotrophins act at several stages in the development of ovarian follicles. Gonadotrophins appear to regulate the number of follicles beginning to grow by controlling both the rate at which non-growing follicles enter the growing pool and the loss of non-growing follicles to atresia. They also appear to promote the growth of medium-sized follicles by reducing the rate of loss to atresia of these follicles rather than by stimulating growth per se. Furthermore, these data suggest that an intra-ovarian autoregulatory mechanism may exist to control the number of large follicles that are formed.     

哺乳动物腔前卵泡体外培养研究进展

哺乳动物卵巢中含有数以万计的腔前卵泡（preantral follicles）,仅不足1％能够发育至预排卵卵泡。建立哺乳动物腔前卵泡有效分离及体外培养技术体系,能够大量利用腔前卵泡,增加体外成熟卵母细胞数量,对哺乳动物胚胎体外生产、克隆及转基因动物生产等胚胎工程技术的研究与应用,以及在体外条件下揭示哺乳动物卵泡发育机理,都具有重要的理论意义和实用价值。鉴于卵巢质地与卵泡划、发生周期的固有差异,不同物种腔前卵泡分离方法与培养方式亦有所不同。同时,培养基类型、卵泡问相互作用、促性腺激素与细胞因子等因素均会对卵泡的体外发育产生影响。系统阐述了腔前卵泡的分离方法、培养方式以及相关因素对卵泡发育的影响,期望为从事相关研究的学者提供参考。     

Immunohistochemical localization of epidermal growth factor receptor (EGF-r) and transforming growth factor alpha (TGF-alpha) in developing human ovarian follicles

In this study, we aimed to detect the distribution of epidermal growth factor receptor (EGF-r) and transforming growth factor alpha in ovarian follicles at different stages. Indirect immunohistochemical methods and EGF-r polyclonal and TGF-alpha monoclonal antibodies were used; tissues were examined with light microscope. While dense collection of both growth factors were observed in primordial follicles, there was a strong reaction especially for EGF-r in follicles. Strong reactivity for EGF-r and moderate reactivity for TGF-alpha were observed in the nearby connective tissue. In examinations of primary follicles for EGF-r presence only, dye uptake was moderate in oocytes and dense in apical and basal cytoplasm of follicle cells. Reactivity was moderate in the nearby connective tissue. In the corpus luteum, there was weak reaction for both growth factors. But in stromal cells, reaction was strong. In degenerated follicle cells and in stroma of atretic follicles, reaction was positive for both growth factors; but EGF-r reactivity was more obvious. While strong staining was observed for both factors especially in granulosa cells surrounding the oocyte in Graafian follicle, moderate TGF-alpha reactivity was determined in oocyte cytoplasm. In conclusion, it is possible that EGF-r and TGF-alpha have ortocrine and paracrine effects on development and regression of human ovarian follicles.     

Effect of growth factors and co-culture with ovarian medulla on the activation of primordial follicles in explants of bovine ovarian cortex

It has been proposed that the ovarian medulla exerts an intra-ovarian inhibitory effect on primordial follicle activation in cattle. We tested this hypothesis using cortical ovarian explants and determined whether growth factors could alter follicle activation or primary follicle health. Ovaries were obtained from bovine fetuses, and cortical slices were cultured on Millicell culture inserts for up to 8 days. Within 2 d of culture, the proportion of primordial follicles decreased from 70.1 +/- 3.5 to 6.4 +/- 3.4% (P<0.05), and the proportion of primary follicles increased from 23.8 +/- 3.3 to 79.7 +/- 5.5% (P<0.05). The proportion of secondary follicles was relatively stable (6 to 13%). Morphological examination indicated that 91.9 +/- 3.7, 76.7 +/- 8.8, and 71.8 +/- 10.4% of primordial, primary, and secondary follicles, respectively, were considered to be healthy in slices of fresh tissue; these proportions were not altered by up to 8 d of culture (P>0.05). The proportion of all classes of follicles and their morphological health were not affected by the addition of medullary slices to the culture well, nor by the culture of corticomedullary slices (P>0.05). The addition of FSH, insulin-like growth factor-I, epidermal growth factor, basic fibroblast growth factor, or transforming growth factor-beta did not alter primordial follicle activation or the morphological health of primary or secondary follicles. The addition of transforming growth factor-alpha (TGFalpha) decreased the proportion of primary follicles that were healthy from 67.6 +/- 5.1 to 36.8 +/- 4.7% (P<0.05). In conclusion, these data do not support the existence of a medullary inhibitor of primary follicle activation but suggest a role for TGFalpha in the regulation of primary follicle development.     

The neuroendocrine regulation of the human ovarian cycle.

The menstrual cycle is now thought to be mainly determined by the ovary itself, which sends various signals to the pituitary and the hypothalamus. The hypothalamus is an autonomous pacemaker, with a pulse frequency that is modulated by ovarian signals; in turn, it is indispensable to ovarian function. In women, the ovarian cycle produces a single mature oocyte each month from puberty to menopause. This follicle is rescued from atresia, the genetically controlled ovarian apoptosis (or "programmed cell death"), involving 99.9% of the follicles. Follicular growth and maturation are mostly independent of gonadotropins from the stage of primordial to antral follicles. A complete intraovarian paracrine system is implied in this gonadotropin-independent follicular growth and in the modulation of the action of gonadotropins in the ovary. Follicle-stimulating hormone (FSH) allows the rescue of a minority of follicles from atresia and is indispensable only for the final maturation of the preovulatory follicle during the follicular phase of the cycle. Luteinizing hormone (LH) is responsible for the final growth of the dominant follicle in the late follicular phase. the induction of ovulation during the LH peak, and the survival of the corpus luteum during the luteal phase. The cyclical variations of gonadotropins are under the control of ovarian steroids (estradiol and progesterone) and peptides (inhibins). The cycle length is determined by the duration of terminal follicular growth and by the fixed life span of the corpus luteum. The ovarian cycle can be monitored as well at the level of target tissues of steroids, such as the endometrium. In fact, the endometrial maturation is synchronized to follicular development, and this synchronization is indispensable for successful implantation of the embryo. The improving knowledge of follicular and endometrial physiology will allow the development of new treatments of infertility, the design of new contraceptive techniques, and a better tolerance of treatments using sex steroids.     

Increased beta-oxidation and improved oocyte developmental competence in response to l-carnitine during ovarian in vitro follicle development in mice

Oocyte developmental competence is acquired throughout folliculogenesis and is associated with appropriate differentiation and responsiveness to the luteinizing hormone (LH) surge. The recent development of a novel system for culturing ovarian follicles in a three-dimensional alginate matrix shows promise in phenocopying in vivo folliculogenesis. However, oocytes from follicles grown in vitro have a reduced capacity to complete nuclear maturation and be fertilized compared to oocytes matured in vivo. Oocyte metabolism is closely linked with oocyte quality, and we have recently shown that beta-oxidation of lipids is essential for oocyte developmental competence. Thus we investigated whether upregulation of beta-oxidation by treatment with the fatty acid transport cofactor l-carnitine could improve folliculogenesis and developmental competence of mouse follicles following three-dimensional culture. Ovarian hormones (androstenedione, estradiol, and progesterone) and the induction of cumulus matrix proteins (hyaluronan and ADAMTS1) were similar to in vivo follicles, indicating that appropriate differentiation of follicular cells occurs in cultured follicles after an LH/human chorionic gonadotropin (hCG) stimulus. l-carnitine did not alter survival, growth, or differentiation of follicles. However, l-carnitine supplementation significantly increased beta-oxidation, and markedly improved both fertilization rate and blastocyst development. Together, these results show that appropriate responsiveness of the follicle to the LH/hCG surge occurs following three-dimensional follicle culture but limitations on key metabolic requirements remain. l-carnitine supplementation during in vitro follicle culture increased lipid metabolism and improved oocyte developmental competence.     

Activin promotes oocyte development in ovine preantral follicles <Emphasis Type="Italic">in vitro</Emphasis>

Activins have been implicated as important regulating factors for many reproductive processes. The aim of this study was to determine the effect of activin A on the development of ovine preantral follicles in vitro. Mechanically isolated preantral follicles (161 ± 2 microm) were cultured for 6 days in the presence of human recombinant activin A (0, 10 and 100 ng/ml). Half of the medium was replaced every second day and follicle diameters were measured. Conditioned medium was subsequently analysed for oestradiol content using a delayed enhancement lanthanide fluorometric immunoassay (DELFIA). At the end of the culture period, follicles were fixed and processed for histology, after which oocyte diameter and granulosa cell death were measured. There was significant follicle growth over 6 days in all groups (p < 0.001). Activin, at both concentrations, increased follicle growth over control levels by Day 6 (p < 0.05). Oocyte diameters were also significantly increased by Day 6 of culture in all groups (p < 0.05), with 100 ng/ml activin increasing oocyte diameter over control levels (p < 0.05). Activin, at both concentrations, increased oestradiol production on Day 2 of culture, but this increase was not sustained during the culture period. Moreover, activin did not have any effect on antrum formation or follicle survival. In conclusion, activin promoted ovine preantral follicle and oocyte growth in vitro, but did not accelerate follicle differentiation over a six-day culture period. These results support a paracrine role for activin A during early oocyte and follicular development.     

Unexpected oocyte growth after follicular antrum formation in four marsupial species.

During examination of maturing preovulatory marsupial oocytes we noted that oocyte diameters were invariably about 50% greater than the figures reported in earlier histological studies. As all previous investigations were limited to small follicles (at most 25% the size of the ovulating follicle), the present study was initiated to examine oocyte growth during the whole period of follicular development. Oocyte and follicle diameters were measured for three Australian (Trichosurus vulpecula, Macropus eugenii and Bettongia penicillata--fresh nonfixed material) and one American marsupial species (Monodelphis domestica--histological sections) in which multiple follicle development had been induced by exogenous gonadotrophin treatment. In all species oocytes were obtained from follicles ranging from pre-antral to immediately pre-ovulatory (maximum follicle sizes obtained were: T. vulpecula, 4.5 mm; M. eugenii, 4.3 mm; B. penicillata, 2.5 mm; M. domestica, 0.7 mm). In two of the species (T. vulpecula and B. penicillata) ovulated oocytes were also examined. In T. vulpecula and M. eugenii oocytes were found to achieve much greater diameters than previously reported from histological studies of small follicles (< 0.8 mm) and similar patterns of growth were found in the other two species. In the four species oocytes reached diameters about two to three times that found for eutherian mammals. It was concluded that the marsupial oocyte continued to grow after formation of the follicular antrum and that, although the rate of oocyte growth slowed in larger follicles, it continued into the period immediately before ovulation. In B. penicillata the largest oocytes were obtained after ovulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endocrine regulation of ovarian antral follicle development in cattle

Antral follicle growth in cattle occurs in two distinct phases; the first 'slow' growth phase spans the time from antrum acquisition to a size of approximately 3 mm detectable by transrectal ultrasound, and the second 'fast' phase is gondadotrophin-dependent and includes cohort growth, dominant follicle (DF) selection, and DF growth. This review summarises current concepts of the relative roles FSH and LH, ovarian and metabolic hormones play mainly in the second phase of antral follicle growth in animals of different reproductive and nutritional states. It is proposed that differential FSH response may enable one cohort follicle to become selected, and that follicular secretions, particularly inhibin, suppress FSH and thus are responsible for DF selection and dominance. Acute dependence of the DF on LH pulses will determine DF lifespan, and the LH pulse profile can be influenced by metabolic hormones such as leptin, providing one possible link for nutritional state and reproduction. Direct ovarian effects of acute and chronic changes in growth hormone, insulin and insulin-like growth factor (IGF)-I have been described on cohort follicles, DF oestrogen activity and on DF growth. Influences of metabolic hormones on early antral follicles undergoing their first 'slow' growth phase are less well described, yet metabolic hormones appear to enhance growth into the cohort available for FSH-induced emergence, and may influence subsequent developmental competence of oocytes.     

Potential role of bone morphogenetic protein-15 in zebrafish follicle development and oocyte maturation

Bone morphogenetic protein (BMP)-15 is a member of the transforming growth factor beta (TGF-beta) superfamily and is closely related to growth and differentiation factor (GDF)-9, both structurally and functionally. In mammals, BMP-15 is predominantly produced by oocytes and exerts important regulatory functions within the ovary, such as promoting early folliculogenesis, preventing premature luteinization and enhancing cumulus cell expansion. The role of BMP-15 in mammalian ovary differs between monoovulatory and polyovulatory species. Recent studies in zebrafish have provided initial evidence that BMP-15 is also an important regulator of ovarian functions. BMP-15 is produced by the zebrafish ovary throughout follicle development and maturation. In vitro studies using zebrafish follicles have revealed that incubation with recombinant human BMP-15 or over-expression of BMP-15 in oocytes results in an inhibition of gonadotropin- and maturation inducing hormone (MIH)-induced oocyte maturation. Conversely, immnunoneutralization with BMP-15 antiserum or silencing of BMP-15 expression using morpholino antisense oligonueclotides enhances oocyte maturation. A key step in BMP-15 action is the sensitivity of follicles to MIH. In vivo injection of BMP-15 antiserum causes a significant decrease in maturation-incompetent (insensitive to MIH) small early growth phase follicles and a concomitant increase in mature follicles. These findings support a role in BMP-15 in preventing precocious oocyte maturation in zebrafish. We propose that the suppression of premature oocyte maturation by BMP-15 may be important to maintain oocyte quality and subsequent ovulation and fertilization.     

Maturation of pig and rat oocytes transplanted into surrogate pig follicles in vitro

Pig oocytes obtained from slaughterhouse material and rat oocytes obtained from PMSG-treated immature females were incubated as isolated oocytes or injected into explanted pig follicles (5–8 mm). Free oocytes of both species, with or without their cumulus investment or gonadotropins during culture, matured at high rates after 30 hr or 9–10 hr of culture, respectively. Gonadotropic stimulation was necessary for maturation of both the native and injected cumulus-intact pig oocytes in follicle culture. Cumulus-free pig oocytes injected into follicle failed to mature in response to gonadotropic stimulation, suggesting an inability to perceive or respond to stimulation. Injected rat oocytes, however, matured irrespective of cumulus investment or gonadotropic stimulation. Their maturation was delayed and reduced at 9 hr. These results in the rat suggest that the pig follicular environment is incapable of regulating rat oocyte maturation but rather presents a permissive or supportive environment for their maturation. The explanted surrogate follicles from the pig or other species may provide a useful model for the study of oocyte-follicle interactions in oocyte maturation within or between species.     

Growth and antrum formation of bovine preantral follicles in long-term culture in vitro

Culture of preantral follicles has important biotechnological implications through its potential to produce large quantities of oocytes for embryo production and transfer. A long-term culture system for bovine preantral follicles is described. Bovine preantral follicles (166 +/- 2.15 micrometer), surrounded by theca cells, were isolated from ovarian cortical slices. Follicles were cultured under conditions known to maintain granulosa cell viability in vitro. The effects of epidermal growth factor (EGF), insulin-like growth factor (IGF)-I, FSH, and coculture with bovine granulosa cells on preantral follicle growth were analyzed. Follicle and oocyte diameter increased significantly (P < 0.05) with time in culture. FSH, IGF-I, and EGF stimulated (P < 0.05) follicle growth rate but had no effect on oocyte growth. Coculture with granulosa cells inhibited FSH/IGF-I-stimulated growth. Most follicles maintained their morphology throughout culture, with the presence of a thecal layer and basement membrane surrounding the granulosa cells. Antrum formation, confirmed by confocal microscopy, occurred between Days 10 and 28 of culture. The probability of follicles reaching antrum development was 0.19 for control follicles. The addition of growth factors or FSH increased (P < 0.05) the probability of antrum development to 0.55. Follicular growth appeared to be halted by slower growth of the basement membrane, as growing follicles occasionally burst the basement membrane, extruding their granulosa cells. In conclusion, a preantral follicle culture system in which follicle morphology can be maintained for up to 28 days has been developed. In this system, FSH, EGF, and IGF-I stimulated follicle growth and enhanced antrum formation. This culture system may provide a valuable approach for studying the regulation of early follicular development and for production of oocytes for nuclear/embryo transfer, but further work is required.