Monique T. Rovani

Angiotensin II Signaling Promotes Follicle Growth and Dominance in Cattle

It is generally understood that angiotensin II (AngII) promotes follicle atresia in rats, although recent data suggested that this may not be true in cattle. In this study, we aimed to determine in vivo whether AngII alters follicle development in cattle, using intrafollicular injection of AngII or antagonist into the growing dominant follicle or the second largest subordinate follicle. Injection of saralasin, an AngII antagonist, into the growing dominant follicle inhibited follicular growth, and this inhibitory effect was overcome by systemic FSH supplementation. Injection of AngII into the dominant follicle did not affect follicular growth, whereas injection of AngII into the second largest follicle prevented the expected atresia of this subordinate follicle, and the treated follicle grew at the same rate as the dominant follicle for the next 24 h. Inhibition of AngII action in the dominant follicle decreased estradiol concentrations in follicular fluid and the abundance of mRNA encoding aromatase, 3β-hydroxysteroid dehydrogenase, LH receptor, and cyclinD2 in granulosa cells, with minimal effects on theca cells. The effect of AngII on aromatase mRNA levels was confirmed using an in vitro granulosa cell culture system. In conclusion, these data suggest that AngII signaling promotes follicle growth in cattle and does so by regulating genes involved in estradiol secretion and granulosa cell proliferation and differentiation.

Angiotensin II profile and mRNA encoding RAS proteins during bovine follicular wave

Angiotensin II (AngII) has a role in ovarian follicle development, ovulation, and oocyte meiotic resumption. The objective of the present study was to characterise the AngII profile and the mRNA encoding RAS proteins in a bovine follicular wave. Cows were ovariectomised when the size between the largest (F1) and the second largest follicle (F2) was not statistically different (day 2), slightly different (day 3), or markedly different (day 4). AngII was measured in the follicular fluid and the mRNA abundance of genes encoding angiotensin-converting enzyme (ACE), (pro)renin receptor, and renin-binding protein (RnBP) was evaluated in the follicular cells from F1 and F2. The AngII levels increased at the expected time of the follicular deviation in F1 but did not change in F2. However, the expression of the genes encoding ACE, (pro)renin receptor, and RnBP was not regulated in F1 but was upregulated during or after the follicular deviation in F2. Moreover, RnBP gene expression increased when the F1 was treated with the oestrogen receptor-antagonist in vivo. In conclusion, the AngII concentration increased in the follicular fluid of the dominant follicle during and after deviation and further supports our finding that RAS is present in the ovary regulating follicular dominance.

FGF10 inhibits dominant follicle growth and estradiol secretion in vivo in cattle.

Fibroblast growth factors (FGFs) are involved in paracrine control of follicle development. It was previously demonstrated that FGF10 decreases estradiol (E(2)) secretion in granulosa cell culture and that theca cell FGF10 mRNA expression is decreased in healthy follicles from abattoir ovaries. The main objectives of this study were to evaluate FGF10 and FGFR2b mRNA expression during follicular development in vivo, to evaluate the effect of FGF10 on follicle growth using Bos taurus taurus cows as a model, and to gain more insight into the mechanisms through which FGF10 inhibits steroidogenesis. Messenger RNA encoding both FGF10 and FGFR2b (main FGF10 receptor) was significantly more expressed in subordinate follicles (SFs) than in dominant follicles (DFs). The intrafollicular injection of FGF10 into the largest growing follicle at 7-8 mm in diameter interrupted the DF growth in a dose-dependent manner (11±0.4, 8.3±1 and 5.9±0.3 mm for 0, 0.1, and 1 μg/ml FGF10, respectively, at 72 h after treatment; P<0.05). In a third experiment, follicles were obtained 24 h after FGF10 (1 μg/ml) or PBS treatment through ovariectomy. In theca cells, FGF10 treatment did not affect mRNA encoding steroidogenic enzymes, LHCGR and IGFBPs, but significantly upregulated FGF10 mRNA expression. The expression of CYP19A1 mRNA in granulosa cells was downregulated by FGF10 treatment, which was accompanied by a 50-fold decrease in E(2) production, and decreased cyclin D2 mRNA. These results have shown that FGF10 and its receptor FGFR2b are more expressed in SFs and provide solid in vivo evidence that FGF10 acts as an important regulator of follicular growth in cattle.

Expression of receptors for BMP15 is differentially regulated in dominant and subordinate follicles during follicle deviation in cattle

Bone morphogenetic proteins are known to be involved in determining ovulation rate in mammals. The mechanisms through which these proteins determine follicle fate are incompletely understood. In the present study, we used cattle as a model to evaluate the regulation of BMP15 and GDF9 receptors in granulosa cells during dominant follicle (DF) selection. Before follicular deviation (day 2 of the follicular wave), BMPR2 mRNA abundance tended to be higher in the second largest follicles (F2; P<0.1) compared to the future dominant follicle (F1). At the expected time of follicular deviation (day 3), BMPR2 and BMPR1B mRNA levels were higher in subordinate follicles (SFs; P<0.05) compared to dominant follicles (DFs). After deviation (on day 4), BMPR1B mRNA and protein were significantly more abundant in atretic SFs (as assessed by cleaved caspase 3) than in DFs. The fact that BMPR1B is more expressed in atretic follicles was further confirmed by using intrafollicular treatment with two agents known to induce atresia, namely an estradiol receptor antagonist (fulvestrant) and FGF10. In conclusion, the fact that BMPR-1B and -2 are more expressed in the second largest follicles before and at the expected time of follicular deviation is indicative of their inhibitory role in follicle differentiation and steroidogenesis. BMPR1B also seems to have a pivotal role during follicle regression since it is upregulated in advanced atretic follicles.

Lack of FSH support enhances LIF–STAT3 signaling in granulosa cells of atretic follicles in cattle

Subordinate follicles (SFs) of bovine follicular waves undergo atresia due to declining FSH concentrations; however, the signalling mechanisms have not been fully deciphered. We used an FSH-induced co-dominance model to determine the effect of FSH on signalling pathways in granulosa cells of the second-largest follicles (SF in control cows and co-dominant follicle (co-DF2) in FSH-treated cows). The SF was smaller than DF in control cows while diameters of co-DF1 and co-DF2 in FSH-treated cows were similar. The presence of cleaved CASP3 protein confirmed that granulosa cells of SFs, but not of DFs and co-DFs, were apoptotic. To determine the effect of FSH on molecular characteristics of the second-largest follicles, we generated relative variables for the second largest follicle in each cow. For this, variables of SF or co-DF2 were divided by the variables of the largest follicle DF or co-DF1 in each cow. There was higher transcript abundance of MAPK1/3 and AKT1/2/3 but lower abundance of phosphorylated MAPK3/1 in SF than co-DF2 granulosa cells. Abundance of mRNA and phosphorylated protein of STAT3 was higher in granulosa cells of control SF than FSH-treated co-DF2. SF granulosa cells had higher levels of LIFR and IL6ST transcripts, the two receptors involved in STAT3 activation. Further, lower transcript abundance of interleukin 6 receptor (IL6R), another receptor involved in STAT3 activation, indicated that STAT3 activation in SF granulosa cells could be mainly due to leukemia inhibitory factor (LIF) signalling. These results indicate that atresia due to lack of FSH is associated with activated LIF-STAT3 signalling in SF granulosa cells, as FSH treatment reversed such activation.

Effects of estradiol and progestins on follicular regression before, during, and after follicular deviation in postpartum beef cows

The objective was to evaluate the effect of estradiol benzoate (EB), in association with three progestin protocols, on ovarian follicular regression of suckled beef cows treated at three stages of follicular development (pre-deviation, deviation, or post-deviation). Thirty-six suckled beef cows (60-90 d postpartum, given 125 microg cloprostenol on two occassions, 12h apart). Forty-eight hours after the first cloprostenol treatment, all follicles >5mm were ablated and transrectal ultrasound scanning (8 MHz) was performed every 24h until Day 7 (Day 0=treatment). When the largest follicle reached a designated diameter of 5-7, 8-10 or >10mm, cows were randomly allocated to receive 2mg of EB im in association with an intravaginal device containing 250 mg of medroxyprogesterone acetate (MPA) with or without 100mg of progesterone (P(4)) given im, or an intravaginal device containing P(4) (3 x 3 factorial design). Treatments induced follicular regression in all cows, independent of follicular stage or treatment. There was no interaction between progestin treatment and follicular stage, nor was there any difference in the time of follicular regression or new wave emergence among follicular stages. Treatment with MPA plus P(4) delayed follicular regression. In conclusion, EB in association with various progestins induced regression of growing follicles and emergence of a new follicular wave in postpartum beef cows, regardless of the stage of follicular development.

Dietary supplementation of ginger and turmeric improves reproductive function in hypertensive male rats

Ginger [Zingiber officinale Roscoe (Zingiberaceae)] and turmeric [Curcuma longa Linn (Zingiberaceae)] rhizomes have been reportedly used in folk medicine for the treatment of hypertension. However, the prevention of its complication such as male infertility remains unexplored. Hence, the aim of the present study was to investigate the preventive effects of ginger and turmeric rhizomes on some biomarkers of male reproductive function in L-NAME-induced hypertensive rats. Male Wistar rats were divided into seven groups (n = 10): normotensive control rats; induced (L-NAME hypertensive) rats; hypertensive rats treated with atenolol (10 mg/kg/day); normotensive and hypertensive rats treated with 4% supplementation of turmeric or ginger, respectively. After 14 days of pre-treatment, the animals were induced with hypertension by oral administration of L-NAME (40 mg/kg/day). The results revealed significant decrease in serum total testosterone and epididymal sperm progressive motility without affecting sperm viability in hypertensive rats. Moreover, increased oxidative stress in the testes and epididymides of hypertensive rats was evidenced by significant decrease in total and non-protein thiol levels, glutathione S-transferase (GST) activity with concomitant increase in 2′,7′-dichlorofluorescein (DFCH) oxidation and thiobarbituric acid reactive substances (TBARS) production. Similarly, decreased testicular and epididymal NO level with concomitant elevation in arginase activity was observed in hypertensive rats. However, dietary supplementation with turmeric or ginger efficiently prevented these alterations in biomarkers of reproductive function in hypertensive rats. The inhibition of arginase activity and increase in NO and testosterone levels by both rhizomes could suggest possible mechanism of action for the prevention of male infertility in hypertension. Therefore, both rhizomes could be harnessed as functional foods to prevent hypertension-mediated male reproductive dysfunction.

Intratesticular hypertonic sodium chloride solution treatment as a method of chemical castration in cattle

Castration of male calves is necessary for trading to facilitate handling and prevent reproduction. However, some methods of castration are traumatic and lead to economic losses because of infection and myiasis. The objective of the present study was to evaluate the efficiency of intratesticular injection (ITI) of hypertonic sodium chloride (NaCl; 20%) solution in male calf castration during the first weeks of life. Forty male calves were allocated to one of the following experimental groups: negative control-surgically castrated immediately after birth; positive control -intact males; G1-ITI from 1- to 5-day old; G2-ITI from 15- to 20-day old; and G3-ITI from 25- to 30-day old. Intratesticular injection induced coagulative necrosis of Leydig cells and seminiferous tubules leading to extensive fibrosis. Testosterone secretion and testicular development were severely impaired in 12-month-old animals from G1 and G2 groups (P<0.05), in which no testicular structure and sperm cells were observed during breeding soundness evaluation. Rectal and scrotal temperatures were not affected by different procedures. In conclusion, ITI of hypertonic NaCl solution induces sterility and completely suppresses testosterone secretion when performed during the first 20 days of life.

The components of the angiotensin-(1-7) system are differentially expressed during follicular wave in cattle:

Introduction: This study was based on the hypothesis that some components of the angiotensin-(1-7) (Ang-(1-7)) system are differentially expressed during follicular development and can be involved in the follicular health/atresia transition in bovine. Material and methods: The largest (F1) and second largest follicles (F2) were collected from cows before (Day 2), during (Day 3), or after (Day 4) the expected moment of follicular deviation. In the second experiment, F1 was induced to atresia through intrafollicular injection of fulvestrant (estrogen receptor-antagonist) and, in both experiments, mRNA expression of the Mas receptor, ACE2, NEP, and PEP was evaluated in the granulosa and theca cells. Results: The mRNA expression of Mas receptor was upregulated in the granulosa cells of F2 after the establishment of follicular deviation, while PEP mRNA increased during and after the deviation process. The mRNA expression of ACE2 was upregulated in the granulosa cells of F1 during and after the follicular deviation. The mRNA expression of NEP was not regulated in F1 and F2. Mas receptor expression increased in the F1 induced to atresia. Conclusions: mRNA for Mas receptor, ACE2, and PEP are differentially expressed in granulosa cells throughout follicular development and the Mas receptor can be involved with the establishment of follicular dominance.

Expression of growth and differentiation Factor 9 and cognate receptors during final follicular growth in cattle

Mutations in growth and differentiation factor 9 (GDF9) gene are associated to sterility or, paradoxically, increased ovulation rate in ewes. Despite its importance, the exact function of GDF9 in ovarian physiology is still poorly understood. This study aimed to investigate GDF9 function during dominant follicle growth and its regulation in follicular fluid. The regulation of GDF9 receptors in GnRH/LH-stimulated granulosa cells was also investigated. In a first experiment, a new follicular wave was induced and the intrafollicular GDF9 treatment into the largest growing follicle (8.5-9.5 mm) at both 100 (n = 3) and 1000ng/ml (n = 4) had no effect on follicular growth, estrus manifestation and ovulation compared to control (PBSinjected) follicles (n = 3). In a second experiment, follicles were obtained just after follicular deviation (day 4 after follicular emergence) and the abundance of GDF9 in follicular fluid did not differ between healthy dominant (n = 4) and atretic subordinate follicles (n = 4), as assessed by western blot analysis. Finally, mRNA expression of BMPR2 and TGFBR1 receptors was evaluated in granulosa cells obtained from preovulatory follicles (>12 mm diameter) obtained 0, 3, 6, 12 or 24 h after i.m. GnRH administration (n = 4-5 follicles/moment). Both receptors were significantly up regulated 12 h after GnRH treatment. Present results do not confirm the hypothesis that GDF9 inhibits dominant follicle growth and suggests a minor role in determining follicle fate. In the other hand, GDF9 receptors regulation in GnRH/LH-stimulated granulosa cells provides the first in vivo evidence of its involvement in the complex cascade of events that culminates in ovulation and luteinization in cattle.