Astaxanthin improves the developmental competence of in vitro-grown oocytes and modifies the steroidogenesis of granulosa cells derived from bovine early antral follicles

In this study we investigated the effect of astaxanthin (Ax), which exhibits strong antioxidant activity, during invitro growth (IVG) on the developmental competence of oocytes and steroidogenesis of granulosa cells derived from early antral follicles. Bovine oocyte–cumulus–granulosa complexes collected from early antral follicles were cultured for 12 days in the presence or absence (control) of 500µM Ax. The viability of oocytes and antrum formation in the granulosa cell layer during IVG culture were greater in the presence than absence of Ax (P<0.05). Regardless of Ax treatment, 17β-oestradiol production increased during IVG culture; however, progesterone production was significantly lower in the presence than absence of Ax (P<0.05). Reactive oxygen species levels were lower in Ax-treated oocytes than in controls after IVG (P<0.05). Although nuclear maturation and cleavage rates did not differ between the Ax-treated and control groups, Ax treatment led to weaker cathepsin B activity in oocytes and better blastocyst rates than in controls (P<0.05). Accordingly, Ax treatment during IVG increased the total number of cells in blastocysts (P<0.05). These results indicate that Ax supplementation of IVG medium improves the quality of bovine oocytes due to its antioxidative effects on growing oocytes and its suppression of the luteinisation of granulosa cells.

Intrafollicular oestradiol production, expression of the LH receptor (LHR) gene and its isoforms, and early follicular deviation in Bos indicus

The aim of the present study was to characterise the roles of intrafollicular oestradiol production and granulosa cell (GC) expression of the LH receptor (LHR) gene and its isoforms during follicular deviation in Bos indicus. Follicular wave emergence was synchronised in heifers from a Bos taurus dairy (Holstein; n = 10) and a B. indicus dairy breed (Gir; n = 10). Follicles were aspirated individually at sizes corresponding to the periods of predeviation, deviation and postdeviation. Intrafollicular oestradiol (IF-E2) and progesterone (IF-P4) concentrations were determined in the follicular fluid (FF) by radioimmunoassay, and relative expression of P450 aromatase (CYP19A1) and LHR forms was evaluated in GC using real-time quantitative–polymerase chain reaction. Despite differences in the size of the dominant follicle at deviation, changes in CYP19A1 expression and IF-E2 concentrations were similar in follicles of the same diameter in both breeds. A peak in total LHR expression occurred after follicular deviation in association with low expression of LHR isoforms. The results suggest that regulation of LHR function by sequential changes in the expression pattern of LHR isoforms may play a role in the early deviation of the dominant follicle, as observed in B. indicus breeds.

128 THE ROLE OF ENDOTHELINS IN REGULATING BOVINE GRANULOSA CELLS STEROIDOGENESIS

Endothelins are a group of vasoactive 21 amino acid peptides reported to play roles in steroidogenesis, folliculogenesis, and ovulation (Bridges et al. 2012 Life Sci. 91, 501–506). Nevertheless, the role of endothelins in regulating steroidogenesis in the bovine species requires further investigation. Thus, the objective of this study was to investigate the effects of endothelin 1 (ET-1) and endothelin 2 (ET-2) on bovine granulosa cell (GC) steroidogenesis. Bovine ovaries were obtained from a local abattoir. Follicular fluid was aspirated from small (1–5 mm) follicles and GC were isolated and exposed to various treatments (ET-1, ET-2, or ET-1 plus ET-2 with FSH and with or without insulin-like growth factor-1). In replicated experiments, culture medium was removed and analysed for steroid production via radioimmunoassay. Granulosa cells were either harvested with trypsin and counted using a Coulter Counter or collected with Trizol for RNA extraction and quantification via real-time PCR (18S rRNA was used as a housekeeping gene). Steroid production was expressed as nanograms (in the case of progesterone) and picograms (in the case of oestradiol) per 105 cells per 24 h. Relative quantity of target gene mRNA was expressed as 2–ΔΔCt using the relative comparative threshold cycle (Ct) method. Data were analysed via ANOVA and the general linear models (GLM) procedure of SAS for Windows (SAS Institute Inc., Cary, NC). If a significant main effect was identified, differences among means were determined by Fisher’s protected least significant differences test. The values were reported as least squares means ± standard error of the mean. In the presence of insulin-like growth factor-1, ET-1 significantly inhibited oestradiol production at 300 ng mL–1 (100.30 ± 11.05; P < 0.05), but not at 30 ng mL–1 (114.47 ± 11.05; P > 0.05) in comparison to the control (141.21 ± 11.05), whereas no differences were observed for progesterone production at 300 ng mL–1 (60.11 ± 7.11; P > 0.05) or at 30 ng mL–1 (64.02 ± 7.11; P > 0.05) in comparison to control (76.75 ± 7.11). ET-2 also significantly inhibited oestradiol production at 300 ng mL–1 (91.08 ± 11.87; P < 0.01), but not at 30 ng mL–1 (112.77 ± 11.87; P > 0.05) in comparison to the control in the presence of insulin-like growth factor-1. No significant effect of ET-1 and ET-2 was observed on steroidogenesis of granulosa cells cultured without insulin-like growth factor-1. Consistent with steroids production data, real-time PCR results indicated that, in the presence of IGF-1, ET-1 (5.66 ± 1.05) and ET-2 (5.65 ± 1.05) inhibited (P < 0.05) aromatase gene expression compared to controls (11.33 + 1.05), and ET-1 plus ET-2 (2.42 ± 1.05) reduced (P < 0.05) expression below that observed with either alone. No effect of ET-1 (4.38 ± 0.95; P > 0.05), ET-2 (5.94 ± 0.95; P > 0.05), or ET-1 plus ET-2 (4.57 ± 0.95; P > 0.05) was observed for side-chain cleavage enzyme (CYP11A1) in comparison to controls (4.4 ± 1.07). Altogether, these results indicate that endothelins are involved in the regulation of steroidogenesis of bovine GC.

Endocrinology of the menopause and hormone replacement therapy

A major endocrine function of the human ovary is the production of oestradiol, a hormone essential for the development of the secondary sex characteristics, for normal reproduction, and for the integrity of the cardiovascular, skeletal, and central nervous systems in particular. Oestradiol is a product of the granulosa cells, and hence its secretion is dependent largely on the presence of ovarian follicles. The number of those follicles falls steeply in the last 10 years or so of reproductive life (1), to approach zero at around the time of final menses (Fig. 10.1.2.1). This results in a profound decline in oestradiol production, to levels less than 10% of those observed during reproductive life. The question of whether the consequences of this decline are to be regarded as ‘natural,’ or as giving rise to a pathological state of oestrogen deficiency, is a controversial one. This chapter describes the endocrine changes which take place from the mid-reproductive years through to the postmenopausal years, and addresses the consequences of these changes and their possible prevention.

Ovarian follicular cells have innate immune capabilities that modulate their endocrine function

Oestrogens are pivotal in ovarian follicular growth, development and function, with fundamental roles in steroidogenesis, nurturing the oocyte and ovulation. Infections with bacteria such as Escherichia coli cause infertility in mammals at least in part by perturbing ovarian follicle function, characterised by suppression of oestradiol production. Ovarian follicle granulosa cells produce oestradiol by aromatisation of androstenedione from the theca cells, under the regulation of gonadotrophins such as FSH. Many of the effects of E. coli are mediated by its surface molecule lipopolysaccharide (LPS) binding to the Toll-like receptor-4 (TLR4), CD14, MD-2 receptor complex on immune cells, but immune cells are not present inside ovarian follicles. The present study tested the hypothesis that granulosa cells express the TLR4 complex and LPS directly perturbs their secretion of oestradiol. Granulosa cells from recruited or dominant follicles are exposed to LPS in vivo and when they were cultured in the absence of immune cell contamination in vitro they produced less oestradiol when challenged with LPS, although theca cell androstenedione production was unchanged. The suppression of oestradiol production by LPS was associated with down-regulation of transcripts for aromatase in granulosa cells, and did not affect cell survival. Furthermore, these cells expressed TLR4, CD14 and MD-2 transcripts throughout the key stages of follicle growth and development. It appears that granulosa cells have an immune capability to detect bacterial infection, which perturbs follicle steroidogenesis, and this is a likely mechanism by which ovarian follicle growth and function is perturbed during bacterial infection.

The ovarian expression of mRNAs for aromatase, IGF-I receptor, IGF-binding protein-2, -4 and -5, leptin and leptin receptor in cycling ewes after three days of leptin infusion

An experiment was carried out to determine the pattern of follicular expression of mRNAs for aromatase, IGF-I receptor (IGF-IR), IGF-binding protein (IGFBP)-2, -4 and -5, leptin and the long form of the leptin receptor (Ob-Rb) in ten ewes infused with human recombinant leptin (n= 5; 1 μg/h) or saline (n= 5) for 72 h in the luteal phase of the oestrous cycle. At the end of infusion a follicular phase was induced with a luteolytic dose of a prostaglandin F2α analogue and the ovaries were collected 32 h later. One ovary from each ewe was serially sectioned at 10 μm using a cryostat at −20 °C. All follicles >1 mm in diameter were counted and probed with specific oligoprobes for aromatase, IGF-IR and IGFBP-2, -4 and -5 and specific riboprobes for leptin and Ob-Rb. Leptin mRNA was detected in theca and granulosa cells and Ob-Rb mRNA was detected only in granulosa cells, of some, but not all antral follicles. Leptin doubled the number of follicles with a diameter ≥3.5 mm (1.0 ± 0.36 (s.e.m.) vs 2.4 ± 0.24; control vs leptin;P< 0.02) but had no effect on the number of ≥1 < 3.5 mm follicles. Leptin had no effect on the number of follicles expressing aromatase mRNA but it decreased significantly the number of follicles expressing mRNA for IGF-IR (10.7 ± 0.79 vs 7.4 ± 0.81; control vs leptin;P< 0.05), IGFBP-2 (10.0 ± 0.82 vs 5.2 ± 0.87; control vs leptin;P< 0.05) and IGFBP-5 (5.2 ± 1.60 vs 1.2 ± 0.30; control vs leptin;P< 0.05). Leptin increased the diameter of IGFBP-2 mRNA-positive follicles (1.5 ± 0.15 vs 2.2 ± 0.31 mm; control vs leptin;P< 0.05) and increased follicular mRNA expression for IGFBP-2 (0.30 ± 0.021 vs 0.39 ± 0.027 arbitrary units; control vs leptin;P< 0.05) and IGFBP-5 (0.46 ± 0.019 vs 0.25 ± 0.053 arbitary units; control vs leptin;P< 0.05). The mRNA for IGFBP-4 was detected in the theca of only two follicles from the control group. Leptin increased the number of follicles expressing Ob-Rb mRNA (0.25 ± 0.25 vs 1.40 ± 1.17; control vs leptin;P< 0.05) but had no effect on the number expressing leptin mRNA. Leptin decreased plasma concentrations of oestradiol (P< 0.05) and increased concentrations of FSH (P< 0.001) and insulin (P< 0.001), with no effect on glucose concentrations. These data show that: (i) ovine granulosa cells express mRNA for Ob-Rb and leptin and (ii) leptin increased the number of follicles ≥3.5 mm. Furthermore, the data suggest that suppression of oestradiol production by leptin is not mediated by inhibition of aromatase gene expression. Finally, the data indicate that the action of leptin in ovarian follicles is mediated by the IGF system, because leptin increased mRNA expression of IGFBP-2 and -5. Leptin also decreased the number of follicles expressing IGF-IR and IGFBP-2 and -5. We suggest that these actions of leptin on the IGF system decrease the bioavailability of IGF-I, resulting in decreased oestradiol production.

Distribution of aromatase activity in brain and peripheral tissues of male sheep: effect of nutrition

Conversion of testosterone to oestradiol plays a major role in the feedback inhibition of gonadotrophin secretion in male sheep but little is known of the distribution or control of aromatase activity among central and peripheral tissues. Changes in activity at those sites may mediate alterations in the effectiveness of negative feedback following, for example, a change in nutrition. Using a tritiated-water assay, we quantified aromatase in several tissues in mature male sheep, assessed their contribution to oestradiol production, and tested whether activity at each site was affected by a nutritional treatment that stimulates gonadotrophin secretion. Among the brain tissues, the preoptic area had the highest concentration of activity, followed by the hypothalamus, amygdala and cortex. Among the peripheral tissues, liver and testis had the highest activity and, due to their mass, they are the major sources of circulating oestradiol. Pituitary, muscle, kidney and adipose tissues had very low aromatase levels. The nutritional stimulus increased activity in testis but not in liver or brain. We conclude that changes in aromatase activity do not mediate the effects of nutrition on steroid feedback, but aromatisation in testis, liver and brain is important in the endocrine regulation of reproduction in the mature ram.