Theca interna: the other side of bovine follicular atresia

Currently, histological classifications of ovarian follicular atresia are almost exclusively based on the morphology of the membrana granulosa without reference to the theca interna. Atresia in the bovine small antral ovarian follicle has been redefined into antral or basal atresia where cell death commences initially within antral or basal regions of the membrana granulosa, respectively. To examine cell death in the theca interna in the two types of atretic follicles, bovine ovaries were collected and processed for immunohistochemistry and light microscopy. Follicles were classified as healthy, antral atretic, or basal atretic. Follicle diameter was recorded and sections stained with lectin from Bandeiraea simplicifolia to identify endothelial cells or with an antibody to cytochrome P450 cholesterol side-chain cleavage to identify steroidogenic cells and combined with TUNEL labeling to identify dead cells. The numerical density of steroidogenic cells within the theca interna was significantly reduced (P < 0.001) in basal atretic follicles in comparison with other follicles. Cell death was greater in both endothelial cells (P < 0.05) and steroidogenic cells (P < 0.01) of the theca interna of basal atretic follicles compared with healthy and antral atretic follicles. Thus, we conclude that the theca interna is susceptible to cell death early in atresia, particularly in basal atretic follicles.     

Localization of apoptotic cells in the cystic ovarian follicles of cows: a DNA-end labeling histochemical study

We examined the frequency of apoptosis in cystic follicular cells to investigate the cause of the delay in regression of cystic follicles. Paraffin sections of healthy antral follicles, early and late atretic ones, and early and late cystic ones were stained using the terminal deoxynucleotidyl transferase (Tdt)-mediated biotinylated deoxyuridine triphosphates (dUTP) nick end-labeling (TUNEL) method to detect apoptotic cells. In the granulosa layer of early cystic and atretic follicles, TUNEL-positive cells were evident. In the theca interna of both early and late atresia, high frequencies of TUNEL-positive cells were observed. In the theca interna, a high frequency of TUNEL-positive cells was noted in the early cystic follicles, whereas their frequency decreased in late cystic follicles. These results suggest that apoptosis occurs in the granulosa and theca interna cells of cystic as well as atretic follicles, but the frequency of apoptosis in theca interna cells decreases in late cystic follicles, which may be responsible for the delay of follicular regression.     

Seasonal changes of the ovarian atretic follicles of the ground squirrel (Citellus citellus L.)

The ovaries of 84 ground squirrels (C. Citellus L.) were studied during the four seasons of the year. The ovarian atretic follicles were examined by histological methods and by electron microscopy. The histoenzyme activities of NAD.H2-tetrazolium reductase, glucose-6-phosphate dehydrogenase, and 3 beta-hydroxy-delta 5-steroid dehydrogenase were photometrically demonstrated. The steroid-producing atretic follicles were mainly described as they reached their highest enzyme activity during the lactation period in April. The atresia of the primordial and primary follicles was manifested by disappearance of the oocyte and preservation of the granulose cells surrounded by basal lamina. Atresia of follicles with two oocytes was a typical process for the ground squirrel. Later on the oocytes and the granulose cells around it disappeared. The remaining part of the follicle continued its development and reached maturity. Atresia was observed mainly in March, April, and May.     

DNA degradation in mural granulosa cells of non- and slightly atretic follicles of fresh and cold-stored domestic cat ovaries

Apoptosis of granulosa cells is associated with follicular atresia and may occur before atresia becomes morphologically evident. Detection of DNA fragmentation by in situ end-labeling (ISEL) with terminal transferase allows the histological assessment of apoptotic cells on conventional histological sections. Degradation of DNA also may occur after prolonged cold storage of ovaries caused by the release of lysosomal enzymes. The objectives of this study were to assess follicle atresia and the impact of cold storage for 8, 12, 24, and 48 hr after ovarian excision by assessing DNA degradation in mural granulosa cells of cat ovaries. Follicles were distinguished by morphological criteria as nonatretic (NA), slightly atretic (SA), or atretic, and the mean number (±SEM) of granulosa cells labeled by ISEL was determined. About 50% of follicles showed some sign of atresia independent from the stage of the reproductive cycle of the ovarian donor. Number of ISEL-stained granulosa cells for NA and SA, freshly collected follicles was 7.5 ± 0.6 and 9.3 ± 0.8 cells/field, respectively, compared to 16.2 ± 0.8 cells/field in the wall of atretic follicles (P < 0.001). Fresh NA follicles from luteal phase ovaries had more (P < 0.05) labeled granulosa cells (9.2 ± 0.7 cells/field) than measured in follicles of cats in a follicular phase (5.7 ± 0.7). During cold storage, DNA degradation began within 12 hr (NA, 12.2 ± 0.7 cells/field; SA, 13.3 ± 0.5), both values being different (P < 0.05) from fresh controls. By 24 hr, DNA degradation was at the level of a positive control subjected to DNAse treatment. In summary, results reveal that granulosa cell DNA degeneration precedes the loss of developmental capacity of cat oocytes during atresia and postexcision storage. Finding irreversible changes in granulosa cell DNA after storage of cat ovaries for >12 hr may be important for developing oocyte rescue protocols for rare felids in cases where prolonged storage and transport may be required. Mol. Reprod. Dev. 48:350–355, 1997. © 1997 Wiley-Liss, Inc.     

Histological and histochemical studies of post-ovulatory and pre-ovultory atretic follicles in Mustelus canis

The atresia of post-ovulatory and pre-ovulatory follicles of the viviparous smooth dogfish, Mustelus canis, is compared for approximately the first fourth of an 11 month gestation. A thick collagenous sheath and numerous tubules in the theca identify the large, folded stage A post-ovulatory follicle. In stage B the tubules have been filled by cells to form “islands.” In stage C the entire structure is greatly diminished, adjacent islands tend to fuse, the collagenous sheath is virtually gone and the granulosa is degenerating. Preovulatory follicles from large, yolky oocytes pass through four stages beginning with yolk phagocytosis by granulosa cells of the villi (stage I), which are long and granular in stage II; villi fuse, theca cells increase greatly, fill with granules (stage III), encroach on the granulosa and disperse it into small groups of cells which finally disappear (stage IV) leaving a mass of thecal cells. A special type of pre-ovulatory follicle from small non-yolky oocyte atresia exhibits prominent thecal tubules and an unusual arrangement of granulosa cells. This follicle appearrs to enlarge during the summer, becoming multilobed; few granules are present. The distribution of lipid in frozen sections, stained by Oil red O, is described for all types of follicles. Schultz and Lewis and Lobban tests for steroids were made on frozen sections with corresponding results. Positive green tests indicating the presence of steroids or possible steroidogenesis were limited to: (1) one post-ovulatory follicle, in the islands; (2) four stage III and seven late stage IV pre-ovulatory yolky atretic follicles; (3) two special atretic follicles. The special atretic follicle appears to be a unique feature of M. canis and it is suggested tentatively that it may be related to viviparity.     

Alteration of activation, growth, and atresia of bovine preantral follicles by long-term treatment of cows with estradiol and recombinant bovine somatotropin

The hypothesis was that long-term treatment of cattle with estradiol (E(2)) and bovine somatotropin (bST) would alter the earliest stages of folliculogenesis. Nonlactating Holstein cows (n = 26) were treated in a 2 x 2 arrangement with E(2) (2 x 24 mg implants, 67.1 +/- 1.4 days) and bST (Posilac, 63.6 +/- 1.5 days). At Day 67 +/- 1.3, one ovary was removed for morphometric and immunohistochemical analysis. For each ovary, 388 +/- 38 microscopic fields (2 x 2 mm) were examined and follicles within each field were classified by histological stage. Fields that contained no follicles were classified as empty. Empty fields (n = 100 per ovary) were further classified as containing no evidence of follicles or containing atretic remnants of follicles. Approximately 30 4-microm sections per ovary were stained for proliferating cell nuclear antigen (PCNA), and 150 fields per ovary were evaluated. Additional sections (n = 10 per ovary) were assessed immunohistochemically for apoptosis, and fluorescence intensity was determined for each follicle. Treatment with bST significantly decreased percentage of empty fields containing atretic remnants. Treatment with E(2) induced activation of follicles as shown by a decrease in percentage of primordial follicles and an increase in percentage of primary follicles as determined by PCNA staining. At the primary follicle stage the combination of bST + E(2) decreased apoptosis as shown by decreased fluorescence intensity. Thus, E(2) induced activation of follicles, bST enhanced survival, and the combination lowered atresia.     

Quantitative and qualitative cytochemical analysis of changes in polysaccharides-proteins in rat ovulable and atretic ovarian follicles during the estrous cycle

Summary The glycosaminoglycan (periodic acid — Schiff, PAS) and hyaluronic acid (alcian blue) content of the membrana granulosa, zona pellucida and antrum of rat ovarian follicles was analyzed qualitatively and quantitatively during the estrous cycle in three types of follicles: ovulable, early atretic and late atretic. The qualitative analysis consisted of the conjunctive localization of PAS-reactive, fluorescent granules within the membrana granulosa. The quantitative analysis consisted of microdensitometric measurements of PAS and alcian blue staining within the zona pellucida and antrum of the ovulable and atretic follicles. For the localization of PAS granules within the granulosa cells, ovaries were removed on the day of proestrus, fixed in 6% paraformaldehyde, embedded in methacrylate and sectioned. Following the examination of the cells for fluorescence, the same section was stained with PAS and lead-hematoxylin. In ovulable follicles there was no fluorescence in the membrana granulosa while PAS granules occurred exclusively within the cells of the cumulus and corona radiata. In late atretic follicles, fluorescent-PAS reactive granules were located in the granulosa cells at the periphery of the follicle. During early atresia no fluorescence and very few PAS granules were observed in the granulosa cells. Since fluorescence is a marker for some lysosomes, these observations suggest that the PAS granules in the ovulable follicles may not be a type of lysosome. The amount of stain in the zona pellucida and antrum of the three follicular types was quantified using a scanning and integrating microdensitometer. On all days of the estrous cycle, PAS intensity was higher in the zona pellucida than in the antrum of the three follicular types. PAS staining in the respective antra was the same on all days of the estrous cycle. Intrafollicular PAS staining in the zonae pellucidae differed during the cycle. With respect to the zonae pellucidae, staining intensity in the three follicles was identical on estrus. On diestrus-1, staining intensity was the same in the ovulable and early atretic follicles and less in the late atretic follicle. By diestrus-2 and on proestrus, PAS intensity was highest in the zona pellucida of the ovulable follicle and less in the zona pellucida of both types of atretic follicle. In contrast to this pattern of staining, alcian blue staining intensity was identical in the zona pellucida of all follicles throughout the cycle. There was no difference in intra-antral alcian blue staining intensity on estrus and diestrus-2. On diestrus-1 and proestrus, staining intensity was greater in the antrum of the late atretic follicle than in the antra of the other follicular types. These studies indicate that glycosaminoglycan content is greater in the zona pellucida of the ovulable follicle of the rat on the last two days preceding ovulation than in the zona pellucida of either the early or late atretic follicles. In contrast, hyaluronic acid content remains constant in the zona pellucida of the three follicular types throughout the estrous cycle. These studies also give the first indication that, in the rat, the localization of PAS granules exclusively in the cumulus oophorus and corona radiata may be used to identify ovulable follicles.This work was supported by a research grant from the National Institute of Child Health and Human Development, HD-12684     

Histological study of follicular atresia in the ovary of the domestic hen (Gallus domesticus)

Semi-serial (1 in 20) sections of ovaries were studied and only two types of atresia were identified--non-bursting and bursting. Smaller, non-yolky follicles (less than 1 mm diameter) showed non-bursting atresia. Atresia in follicles greater than 1 mm diameter was invariably of the bursting type which involved the rupture of the follicular wall, and the extrusion of yolk and cellular debris through the rupture site into the stroma. However, this rupture site was small and consequently was not visible in every section but it could always be seen when the follicle was followed in semi-serial sections. The mitotic index of granulosa cells in bursting atretic follicles was much lower than that for normal follicles. The most common criteria for distinguishing non-bursting atretic follicles were the extremely shrunken, irregularly shaped oocytes and the separation of the granulosa from the theca. In bursting atretic follicles, reliable indications were the presence in the ooplasm of some cells or cellular debris, and disorganization of the yolk and granulosa tissue. The presence of pycnotic nuclei in the granulosa cells was not a consistent feature of all atretic follicles of the hen.     

Natural and endotoxin-induced atresia of preantral and early antral follicles is characterized by DNA internucleosomal cleavage

Preantral follicles (PAF) and early antral follicles (EAF) were isolated from bovine ovaries and classified under a stereomicroscope as atretic or healthy. The atretic follicles were all considered as group I (in vivo atresia), whereas healthy follicles were assigned to five groups (group II, in vivo normal control; group III, in vitro normal control; group IV, in vitro induced atresia; groups V and VI, Lipopolysaccharide (LPS)-induced atresia in vitro). Group I and II follicles were immediately snap-frozen (−70°C) until DNA extraction, whereas group III–VI follicles were incubated (39°C, 5% CO₂, 95% air) for periods up to 72 hr under various conditions. Group III follicles were maintained in complete medium (M199, bovine calf serum, sodium pyruvate, epidermal growth factor, insulin, transferrin, sodium selenite, penicillin, streptomycin, and amphotericin), whereas group IV follicles were incubated in the same medium, but without serum. Group V and VI follicles were maintained in complete medium, but in the presence of LPS (10 or 50 μ/ml, respectively). Results showed that follicles incubated in the absence of serum and those exposed to both doses of LPS became atretic. DNA isolated from all atretic follicles showed fragmentation typical of that described for apoptosis; this was also confirmed by in situ DNA labeling and histology. Atretic follicles did not produce estradiol (P < 0.001), but progesterone values increased with follicle size (P < 0.001) and time of incubation (P < 0.001). We concluded that in the absence of serum or in the presence of LPS, follicles undergo atresia via apoptosis. © 1996 Wiley-Liss, Inc.     

Follicular atresia and LH concentrations during the follicular phase of the estrous cycle in the goat (Capra hircus)

The objective of the study was to identify the effects of LH on the final follicle maturation process as well as the incidence of atresia during the follicular phase of the goat's estrous cycle. In Experiment 1, concentrations of the LH were measured during the follicular phase of a synchronized cycle in 8 Canary goats. In Experiment 2, the same animals were synchronized again. On each day of a 4-day experimental period (day 0=day of sponges withdrawal), 2 of the goats were bilaterally ovariectomized. Follicles with a diameter >1 mm were dissected out to obtain qualitative histological data in normal, early atretic I, early atretic II, advanced atretic I and advanced atretic II follicles. The total interval from sponge withdrawal to LH peak was 77.5±9.8 h. LH peak concentration averaged 44±5.3 ng/ml and the mean length of the preovulatory surge (amounts over 10 ng/ml) was 8.9±0.9 h. During the total follicular phase, there were more atretic follicles than normal follicles (58 vs. 30, P<0.05). The number of early and advanced atretic follicles was similar. There were more early atresia I than early atresia II follicles (23 vs. 6, P<0.05). On day 2, the number of advanced atretic follicles was greater than early atretic follicles (10 vs. 4, P<0.05). There was an increase in the number of early atretic follicles from day 2 to day 4 (4 vs. 9, P<0.05), which was consistent with the effects of the preovulatory LH surge.     

Quantification of ovarian follicles in bluefin tuna Thunnus thynnus by two stereological methods

The numbers of different types of ovarian follicles (developing, degenerating and postovulatory follicles) were estimated in bluefin tuna Thunnus thynnus using two stereological procedures: the model‐based method of Weibel & Gomez, which has become a tool of broad application in the quantification of oocytes in fishes, and the assumption‐free ‘disector’ (sic) method of Sterio. The estimates of developing follicles (follicles containing lipid‐stage, vitellogenic and migratory‐nucleus oocytes) made by the model‐based method tended to be lower than those obtained with the disector, though significant differences were not observed except for vitellogenic follicles. Counts of atretic follicles by the model‐based method were higher than those made using the disector, the differences being remarkable between both techniques, particularly in the case of β‐atresia, where the statistical analysis indicated significantly unequal estimations with the two methods. In contrast, the amount of postovulatory follicles estimated by the disector, which would stand for the realized batch fecundity, was somewhat larger than that calculated with the model‐based method.     

Effect of GnRH antagonist-induced prolonged follicular phase on follicular atresia and oocyte developmental competence in vitro in superovulated heifers

A GnRH antagonist (Antarelix) was used to suppress endogenous pulsatile secretion of LH and delay the preovulatory LH surge in superovulated heifers to study the effect of a prolonged follicular phase on both follicle and oocyte quality. Oestrous cycles were synchronized in 12 heifers with progestagen (norgestomet) implants for 10 days. On day 4 (day 0 = day of oestrus), heifers were stimulated with 24 mg pFSH for 4 days and luteolysis was induced at day 6 with PGF2 alpha (2 ml Estrumate). Animals in the control group (n = 4) were killed 24 h after the last FSH injection. At this time, heifers in group A36h (n = 4) and group A60h (n = 4) were treated with 1.6 mg of Antarelix every 12 h for 36 and 60 h, respectively, and then killed. After dissection of ovarian follicles, oocytes were collected for individual in vitro maturation, fertilization and culture; follicular fluid was collected for determination of steroid concentrations, and granulosa cells were smeared, fixed and stained for evaluation of pycnosis rates. Granulosa cell smears showed that 90% of follicles were healthy in the control group. In contrast, 36 and 58% of the follicles in group A36h showed signs of early or advanced atresia, respectively, while 90% of the follicles in group A60h showed signs of late atresia. Intrafollicular concentrations of oestradiol decreased (P < 0.0001) from healthy follicles (799.14 +/- 40.65 ng ml-1) to late atretic follicles (3.96 +/- 0.59 ng ml-1). Progesterone concentrations were higher (P < 0.0001) in healthy follicles compared with atretic follicles, irrespective of degree of atresia. Oestradiol:progesterone ratios decreased (P < 0.0001) from healthy (4.58 +/- 0.25) to late atretic follicles (0.07 +/- 0.009). The intrafollicular concentrations of oestradiol and progesterone were significantly higher (P < 0.0001) in the control than in the treated groups. The oestradiol:progesterone ratio was higher (P < 0.0001) in the control (4.55 +/- 0.25) than in the A36h (0.40 +/- 0.05) and A60h (0.07 +/- 0.009) groups. Unexpectedly, the cleavage rate of fertilized oocytes, blastocyst rate and number of cells per blastocyst were not significantly different among control (85%, 41% and 95 +/- 8), A36h (86%, 56% and 93 +/- 5) and A60h (88%, 58% and 79 +/- 4) groups. In addition, there were no significant differences in the blastocyst rates from oocytes derived from healthy (45%), early atretic (54%), advanced atretic (57%) and late atretic follicles (53%). In conclusion, the maintenance of the preovulatory follicles in superovulated heifers with a GnRH antagonist induced more atresia and a decrease in oestradiol and progesterone concentrations. However, the developmental potential in vitro to day 8 of the oocytes recovered from these atretic follicles was not affected.     

Histogenesis of atretic ovarian follicles in a seasonally breeding bird

Histologic examination of ovaries from a non-migratory population of scrub jays (Aphelocoma coerulescens) disclosed a marked annual cycle in the incidence of atresia. Atretic follicles became more common as the nesting season progressed and were most abundant immediately after the cessation of breeding. Atresia involved a dissociation of granulosa cells and movement of these cells into the follicle. Subsequently, granulosa cells showed steatogenesis and ultimately disappeared simultaneously with the invasion of the follicle by ex-thecal gland cells. The data suggest that the diverse histology of avian atretic follicles reflects different stages in the process of atresia rather than multiple origins. Ovarian stromal glands apparently arise both from ex-thecal gland cells of atretic follicles and stromal connective tissue. A possible secretory role of atretic follicles is considered.     

Developmental changes in the ovarian follicular basal lamina detected by immunofluorescence and electron microscopy

Alterations in the basal lamina (BL) of developing follicles were studied by immunofluorescent microscopy using antibodies against type IV collagen, laminin, and fibronectin, and by electron microscopy. Ovarian development was induced in immature rats by sequential administration of estradiol, follicle-stimulating hormone (FSH) and human chorionic gonadotropin (hCG). A continuous BL was observed in healthy follicles treated with estradiol and FSH. As determined by immunofluorescence, laminin, type IV collagen, and fibronectin were restricted to the BL and the theca but not to the granulosa. When follicles were allowed to undergo atresia or induced to ovulate with hCG, the BL became fragmented. This was confirmed by electron microscopy of healthy, atretic, and luteinizing follicles which showed that in healthy follicles the BL was continuous, whereas in both atretic and luteinizing follicles, it was fragmented. Atresia was also associated with the penetration of thecal cells into the follicles. These observations indicate that the intact BL present in healthy follicles undergo extensive changes during atresia and ovulation.     

Morphological and biochemical correlates of equine ovarian follicles as a function of their state of viability or atresia.

The histological features and hormonal content of follicular fluid of antral follicles during oestrus were correlated. As a result it was possible to characterize several categories of viable and atretic follicles. A seemingly important stage in maturation appeared to be at 3 cm in diameter since follicular oestrogens and androgens underwent a 3-fold increase in concentration at that size. Evidence was obtained to suggest that oestrogens are anti-atretogenic. However, a drop in oestrogens was not the cause of atresia since degeneration commenced when levels were high. Contrary to the concept that androgens are atretogenic in some species, it was also evident that elevated androgens did not precipitate spontaneous atresia. Theca epithelioid cells not only underwent histological luteinization in viable follicles as they matured toward ovulation but occasionally in atretic follicles as well. Elevated prostaglandin F levels were associated with follicles in the transitory states of either luteinization or atresia. Granulosa cells of viable follicles only were capable of specifically binding hCG. It was not determined whether loss of binding capacity or atresia occurred first. Follicular atresia in the mare appears to be a gradual process of which the initiating cause remains unknown.     

Mechanism of granulosa cell death during follicular atresia depends on follicular size

Changes in granulosa cell lysosomal and mitochondrial functions in relation to follicular size and to the stage of atresia were studied by fluorescent emission spectra and intensity using flow cytometry. Antral follicles were grouped by size in two groups: small, 3-6 mm and large, >6mm in diameter, and classified into three stages of atresia: non-atretic, initially atretic and advanced atretic. Differences in Rhodamine 123 (Rh123) and Acridine Orange (AO) fluorescent intensity indicated that changes in mitochondrial function are the primary mechanism of granulosa cell death in atretic follicles 3-6 mm in diameter, while its role in granulosa cell death in >6 mm atretic follicles seemed to be less important. However, modifications in lysosomal function (shown by a decrease in fluorometric intensity of AO incubated granulosa cells) were mainly associated with cell death in large atretic follicles. Our results support the hypothesis that the pathway of granulosa cell death during follicular atresia depends on the state of energy metabolism or on the production of hypoxic conditions related to follicular size. Changes in mitochondrial membrane potential and production of permeability transition pores were the main changes found in small follicles, while lysosomal function destabilization seemed to be the major cause of granulosa cell death during atresia in large follicles.     

Multiparametric study of atresia in ewe antral follicles: histology, flow cytometry, internucleosomal DNA fragmentation, and lysosomal enzyme activities in granulosa cells and follicular fluid

The differential quantitative participation of apoptosis and necrosis in ewe antral follicles of two different sizes, separated in four stages of atresia using macroscopic, histologic, and esteroid quantification methods was assessed. Annexin V binding and propidium iodide (PI) uptake was used to detect healthy live cells (Annexin V negative/PI negative), early apoptotic cells (Annexin V+/PI-), and necrotic or late apoptotic cells (PI+). Additionally we used internucleosomal DNA fragmentation as a quantitative estimate of apoptosis. Presence and distribution of lysosomal enzymes in follicular fluid and granulosa cells was used as a measure of necrotic cell death. DNA flow cytometry and gel electrophoresis were positively correlated with the progression of atresia, small atretic follicles tend to have higher percentages of internucleosomal cleaved DNA than follicles >6 mm. Annexin/PI binding also indicates that apoptosis and necrosis increase with atresia progression, generally apoptosis outweighs necrosis in small follicles. Acid phosphatase and glucosaminidase in follicular fluid of 3-6 mm follicles showed no significant modifications between healthy and initially atretic follicles, and only a small, but significant increase in activity in advancedly atretic follicles. On the contrary, lysosomal enzyme activity in follicles >6 mm showed positive correlation between atresia stages and the activities of acid phosphatase and glucosaminidase in follicular fluid. A similar size-differential behavior was found in free or membrane-bound lysosomal enzyme activity of granulosa cells. Necrosis, but principally apoptosis, were present during all stages of follicular maturation indicating that growth and maturation of ovarian follicles involves a continuous renewal of granulosa cells, regulated by apoptosis. Mechanisms regulating this equilibrium may participate in the final destiny, whether ovulation or atresia of ovarian follicles.     

Fecundity regulation by atresia in turbot Scophthalmus maximus in the Baltic Sea

Down‐regulation of fecundity through oocyte resorption was assessed in Baltic Sea turbot Scophthalmus maximus at three locations in the period from late vitellogenesis in April to spawning during June to July. The mean ± s.d . total length of the sampled fish was 32·7 ± 3·1 cm and mean ± s.d . age was 6·2 ± 1·5 years. Measurements of atresia were performed using the ‘profile method’ with the intensity of atresia adjusted according to the ‘dissector method’ (10·6% adjustment; coefficient of determination was 0·675 between methods). Both prevalence (portion of fish with atresia) and intensity (calculated as the average proportion of atretic cells in fish displaying atresia) of atresia were low in prespawning fish, but high from onset of spawning throughout the spawning period. Atretic oocytes categorized as in early alpha and in late alpha state occurred irrespective of maturity stage from late prespawning individuals up to late spawning fish, showing that oocytes may become atretic throughout the spawning period. Observed prevalence of atresia throughout the spawning period was almost 40% with an intensity of c. 20%. This indicates extensive down‐regulation, i.e. considerably lower realized (number of eggs spawned) v. potential fecundity (number of developing oocytes), suggesting significant variability in reproductive potential. The extent of fecundity regulation in relation to fish condition (Fulton's condition factor) is discussed, suggesting an association between levels of atresia and fish condition.     

Cholesterol side-chain cleavage cytochrome P450 and 3beta-hydroxysteroid dehydrogenase expression and the concentrations of steroid hormones in the follicular fluids of different phenotypes of healthy and atretic bovine ovarian follicles

Bovine ovarian antral follicles exhibit either one or the other of two patterns of granulosa cell death in atresia. Death can commence either from the antrum and progress toward the basal lamina (antral atresia) or the converse (basal atresia). In basal atresia, the remaining live antrally situated cells appeared to continue maturing. Beyond that, little is known about these distinct patterns of atresia. Healthy (nonatretic) follicles also exhibit either one or the other of two patterns of granulosa cell shape, follicular basal lamina ultrastructure or location of younger cells within the membrana granulosa. To examine these different phenotypes, the expression of the steroidogenic enzymes cholesterol side-chain cleavage cytochrome P450 (SCC) and 3beta-hydroxysteroid dehydrogenase (3beta-HSD) in granulosa cells and concentrations of steroid hormones in follicular fluid were measured in individual histologically classified bovine antral follicles. Healthy follicles first expressed SCC and 3beta-HSD in granulosa cells only when the follicles reached an approximate threshold of 10 mm in diameter. The pattern of expression in antral atretic follicles was the same as healthy follicles. Basal atretic follicles were all <5 mm. In these, the surviving antral granulosa cells expressed SCC and 3beta-HSD. In examining follicles of 3-5 mm, basal atretic follicles were found to have substantially elevated progesterone (P < 0.001) and decreased androstenedione and testosterone compared to healthy and antral atretic follicles. Estradiol was highest in the large healthy follicles, lower in the small healthy follicles, lower still in the antral atretic follicles, and lowest in the basal atretic follicles. Our findings have two major implications. First, the traditional method of identifying atretic follicles by measurement of steroid hormone concentrations may be less valid with small bovine follicles. Second, features of the two forms of follicular atresia are so different as to imply different mechanisms of initiation and regulation.