Daniela Bebbere

Exogenous melatonin positively influences follicular dynamics, oocyte developmental competence and blastocyst output in a goat model

Abstract:  The role of melatonin in modulating mammalian reproduction is of particular interest; however, its effects on ovarian follicles and their oocytes still remain to be characterized. This study determined the influence of melatonin treatment on follicular growth patterns and on in vitro oocyte developmental competence. In a first experiment, the effects of melatonin supplementation on follicular dynamics were evaluated using daily transrectal ultrasonographies for 21 days, in 7 multiparous Sarda goats receiving a subcutaneous implant of 18 mg of melatonin and in 5 control untreated does. Melatonin caused more follicular waves (5.2 ± 0.2 versus 4 ± 0.3; P < 0.05) as the waves were shortened at around 2 days when compared with the non‐melatonin treated control goats (P < 0.001). Oocyte developmental competence was evaluated in a second experiment by applying procedures for in vitro embryo production. There were no significant differences in the total number of oocytes obtained from 6 control (n = 192) and 7 melatonin‐treated (n = 265) goats given follicle stimulating hormone to induce follicular development. Differences in oocyte developmental competence between the two groups became evident after in vitro fertilization and culture; melatonin increased the rate of cleaved oocytes in comparison with control animals (82.5 versus 63.4%; P < 0.001), advanced timing of embryo development and enhanced blastocyst output (31.5 versus 16.3%; P < 0.01). However, blastocyst quality, as evaluated by cryotolerance and gene expression analysis, was not found to be different between the groups. In conclusion, in vivo melatonin treatment is beneficial for increasing ovarian follicle turnover and improving oocyte developmental competence and kinetics of the blastocyst.

Expression pattern of zygote arrest 1 (ZAR1), maternal antigen that embryo requires (MATER), growth differentiation factor 9 (GDF9) and bone morphogenetic protein 15 (BMP15) genes in ovine oocytes and in vitro-produced preimplantation embryos

The expression patterns of four maternal effect genes (MEG), namely zygote arrest 1 (ZAR1), maternal antigen that embryo requires (MATER), growth differentiation factor 9 (GDF9) and bone morphogenetic protein 15 (BMP15), were determined in ovine oocytes and in vitro-produced preimplantation embryos. The existence of ZAR1 and MATER in ovine species has not been reported previously. Reverse transcription-polymerase chain reaction was performed on germinal vesicle and IVM MII oocytes, as well as in in vitro fertilised and cultured two-, four-, eight- and 12/16-cell embryos, morulae and blastocysts. Quantification of gene expression by real-time polymerase chain reaction showed the highest abundance of all transcripts analysed in the immature oocyte. During the following stages of preimplantation development, the mRNAs examined exhibited different patterns of expression, but often significant decreases were observed during maturation and maternal-embryonic transition. The transcription of the four genes did not resume with activation of the genome.

In vitro production and cryotolerance of prepubertal and adult goat blastocysts obtained from oocytes collected by laparoscopic oocyte-pick-up (LOPU) after FSH treatment

This study compares the developmental capacity and cryotolerance of embryos produced from oocytes of stimulated prepubertal and adult Sarda goats. Twelve prepubertal and 13 adult goats were each given 110 and 175 IU FSH, respectively, and cumulus-oocyte complexes (COCs) were collected by laparoscopic oocyte-pick-up (LOPU). After in vitro maturation, fertilisation and culture (IVMFC), blastocysts were vitrified, warmed and blastocoel re-expansion and gene expression were evaluated. Prepubertal goats produced a higher COCs number than adults (mean +/- s.e.m., 89.67 +/- 5.74 and 26.69 +/- 3.66, respectively; P < 0.01). Lower developmental competence was demonstrated in the prepubertal oocytes as shown by a higher number of COCs discarded before IVM (21.1% and 14.7% for prepubertals and adults, respectively; P < 0.01) and IVF (23.4% v. 9.1%; P < 0.01) and by the lower cleavage (55.6% and 70.3%, respectively; P < 0.01) and blastocyst rates (24.2% and 33.9%, respectively; P < 0.05). Compared with the adult, prepubertal vitrified/warmed blastocysts showed significantly (P < 0.05) lower in vitro viability, as determined by the re-expansion rate (62.5% and 40.3%). No differences were observed in the time required for blastocoel re-expansion or in cyclin B1, E-cadherin, Na/K ATPase, HSP90beta and aquaporin 3 messenger RNA quantity. These results show that in vitro-produced embryos produced from prepubertal goat oocytes have a lower developmental rate and cryotolerance compared with their adult counterparts. However, we can assume that the quality of re-expanded embryos does not differ between the two groups.

Raman microspectroscopy as a non-invasive tool to assess the vitrification-induced changes of ovine oocyte zona pellucida

Cryopreservation-induced modifications of zona pellucida (ZP) have been explored to a lesser extent compared to other oocyte compartments. Different methods have been applied to identify ZP changes, but most of them are invasive and measure only few properties of ZP. Raman microspectroscopy (RMS) is a powerful technique for studying the molecular composition of cells but to date few studies have been performed on the oocytes using this method. The aim of the present study is to investigate the structural modifications of ZP of vitrified/warmed in vitro matured ovine oocytes by means of RMS. Cumulus-oocyte complexes were recovered from the ovaries of slaughtered adult sheep, matured in vitro and vitrified following the Minimum Essential Volume method using cryotops. ZPs of vitrified/warmed oocytes (VITRI), were exposed to vitrification solutions but not cryopreserved (CPA-exp) and untreated oocytes (CTR) were analyzed by RMS. We focused our analysis on the ZP protein and carbohydrate components by analyzing the 1230-1300 cm(-1) amide III region and the 1020-1140 cm(-1) spectral range in RMS spectra, respectively. The spectral profiles in the ranges of proteins and carbohydrates were comparable between CTR and CPA-exp ZPs, whereas VITRI ZPs showed a significantly altered protein secondary structure characterized by an increase in β-sheet content and a decrease in the α-helix content. A significant modification of the carbohydrate components was also observed. This study demonstrates that vitrification of ovine oocytes induces biochemical changes of ZP related to the secondary structure of proteins and carbohydrate residues. Cryoprotectants do not strongly alter the molecular composition of ZP which is affected mainly by cooling. Raman technology offers a powerful and non-invasive tool to assess molecular modifications induced by cryopreservation in oocytes.

High hydrostatic pressure treatment improves the quality of in vitro-produced ovine blastocysts

Exposure to sub-lethal hydrostatic pressure (HP) treatment is emerging as an approach to improve the general resistance of gametes and embryos to in vitro conditions. The present study was aimed to evaluate the effect of HP treatment on in vitro-produced ovine blastocysts. Experiment 1 was aimed to define optimal treatment parameters: two different HP treatments were applied to blastocysts and embryo survival was evaluated. In Experiment 2, HP parameters (40 MPa, 70 min, 38 °C) selected in Experiment 1 were used to treat blastocysts. Embryo quality was assessed and compared with untreated controls by counting total cell number, the inner cell mass (ICM) and trophectoderm (TE) cells and by evaluating nuclear picnosis. HP-treated blastocysts were processed for gene expression analysis (AQP3, ATP1A1, BAX, CDH1, HSP90β, NANOG, OCT4 and TP53) 1, 5h after the end of HP exposure. Results showed that the hatching rate of embryos treated at 40 MPa was significantly higher than that of the 60 MPa-treated group (P<0.01) and similar to untreated embryos. Blastocysts exposed at 40 MPa showed higher ICM (P<0.05) and TE (P<0.01) cell number and a lower percentage of picnotic nuclei (P<0.05) compared with the control group. Significantly lower abundance for BAX (P<0.01) and OCT4 (P<0.05) transcripts were observed in HP embryos than in the control group. In conclusion, treatment with HP improved the quality of in vitro-produced ovine blastocysts by increasing their cell number and reducing the proportion of nuclear picnosis.

Characterization, isolation and culture of primordial germ cells in domestic animals: recent progress and insights from the ovine species

Primordial germ cell (PGC) allocation, characterization, lineage restriction, and differentiation have been extensively studied in the mouse. Murine PGC can be easily identified using markers as alkaline phosphatase content or the expression of pluripotent markers such as Pou5f1, Nanog, Sox2, Kit, SSEA1, and SSEA4. These tools allowed us to clarify certain aspects of the complex interactions of somatic and germinal cells in the establishment of the germ cell lineage, its segregation from the neighbouring somatic tissue, and the guidance mechanisms during migration that direct most of the germ cells into the genital ridges. Few data are available from other domestic animals and here we reported our preliminary studies on the isolation, characterization, and in vitro culture of sheep PGCs. Sheep PGCs can be identified with the markers previously used in mouse, but, in some cases, these markers are not coherently expressed in the same cell depending on the grade of differentiation and on technical problems related to commercial antibodies used. Pluripotency of PGCs in culture (EGCs) from domestic animals also needs further evaluation even though the derivation of embryonic pluripotent cell lines from large mammals may be an advantage as they are more physiologically similar to the human and perhaps more relevant for clinical translation studies. Comprehensive epigenetic reprogramming of the genome in early germ cells, and derived EGCs including extensive erasure of epigenetic modifications, may be relevant for gaining insight into events that lead to reprogramming and establishment of totipotency. EGCs can differentiate in vitro in a various range of tissues, form embryonic bodies, but in many cases failed to generate tumours when transplanted into immunodeficient mice and are not able to generate germline chimeric animals after their transfer. Such incomplete information clearly indicates the urge to improve the studies on derivation of stem cells in farm animals and shows the need for a multidisciplinary investigation in order to create farm animal models to set up suitable ethical and technical systems for cell regenerative therapies in humans.

Calcium concentration in vitrification medium affects the developmental competence of in vitro matured ovine oocytes

The present study was designed to determine whether different calcium concentrations in the vitrification solutions could improve the developmental competence of in vitro matured ovine oocytes after cryopreservation. In vitro matured oocytes were vitrified with 16.5% ethylene glycol (EG) + 16.5% dimethylsulfoxide (DMSO) vitrification media. The base media contain different calcium concentrations, so that five experimental groups were obtained: TCM/FCS (TCM 199 + 20% fetal calf serum (FCS), [Ca(2+)] 9.9 mg/dl); PBS/FCS (Dulbecco Phosphate Buffered Saline (PBS) + 20% FCS, [Ca(2+)] 4.4 mg/dl); PBS(CaMg free)/FCS (PBS without Ca(2+) and Mg(2+) + 20% FCS [Ca(2+)] 2.2 mg/dl); PBS/BSA (PBS + 0.4% bovine serum albumin (BSA), [Ca(2+)] 3.2 mg/dl) and PBS(CaMg free)/BSA (PBS without Ca(2+) and Mg(2+) +0.4% BSA, [Ca(2+)] 0.4 mg/dl). After warming, the oocytes from the five experimental groups were assessed for survival, spontaneous parthenogenetic activation and developmental capacity via in vitro fertilization. Oocyte survival after vitrification procedures was better preserved in group PBS(CaMg free)/FCS compared to the others (P < 0.05). In addition, a positive correlation was found between calcium concentration in vitrification solutions and spontaneous parthenogenetic activation (correlation index 0,82; P < 0.001). Development of vitrified oocytes was significantly affected by vitrification media composition (P < 0.01). In particular, oocytes from group PBS(CaMg free)/FCS led to higher cleavage rates and blastocyst rate compared to the others. Our data showed that lowering calcium concentration in the vitrification medium improves the blastocyst rate of vitrified ovine oocytes, probably reducing the effect of EG + DMSO during vitrification. On the contrary, the replacement of FCS with BSA dramatically reduces the developmental potential of these oocytes.

Expression of maternally derived KHDC3, NLRP5, OOEP and TLE6 is associated with oocyte developmental competence in the ovine species

BackgroundThe sub-cortical maternal complex (SCMC), located in the subcortex of mouse oocytes and preimplantation embryos, is composed of at least four proteins encoded by maternal effect genes: OOEP, NLRP5/MATER, TLE6 and KHDC3/FILIA. The SCMC assembles during oocyte growth and was seen to be essential for murine zygote progression beyond the first embryonic cell divisions; although roles in chromatin reprogramming and embryonic genome activation were hypothesized, the full range of functions of the complex in preimplantation development remains largely unknown.ResultsHere we report the expression of the SCMC genes in ovine oocytes and pre-implantation embryos, describing for the first time its expression in a large mammalian species.We report sheep-specific patterns of expression and a relationship with the oocyte developmental potential in terms of delayed degradation of maternal SCMC transcripts in pre-implantation embryos derived from developmentally incompetent oocytes.In addition, by determining OOEP full length cDNA by Rapid Amplification of cDNA Ends (RACE) we identified two different transcript variants (OOEP1 and OOEP2), both expressed in oocytes and early embryos, but with different somatic tissue distributions.In silico translation showed that 140 aminoacid peptide OOEP1 shares an identity with orthologous proteins ranging from 95% with the bovine to 45% with mouse. Conversely, OOEP2 contains a premature termination codon, thus representing an alternative noncoding transcript and supporting the existence of aberrant splicing during ovine oogenesis.ConclusionsThese findings confirm the existence of the SCMC in sheep and its key role for the oocyte developmental potential, deepening our understanding on the molecular differences underlying cytoplasmic vs nuclear maturation of the oocytes.Describing differences and overlaps in transcriptome composition between model organisms advance our comprehension of the diversity/uniformity between mammalian species during early embryonic development and provide information on genes that play important regulatory roles in fertility in nonmurine models, including the human.

Different temporal gene expression patterns for ovine pre-implantation embryos produced by parthenogenesis or in vitro fertilization

Parthenogenetic activation of the mammalian oocyte constitutes an essential step to a number of oocyte- or embryo-related technologies. Mammalian parthenotes are useful tools for studying the roles of paternal and maternal genomes in early mammalian development and are considered potential candidates for an ethical source of embryonic stem cells. We investigated the in vitro developmental competence of pre-implantation ovine embryos derived from in vitro fertilization (IVF) and parthenogenetic activation (PA) together with the expression of a panel of fourteen genes at different times of development. IVF and PA embryos showed similar developmental competence. No differences in gene expression were observed between PA and IVF two cell-stage embryos, while PA morulae showed a significantly higher expression of IGF2. At the blastocyst stage, parthenotes exhibited up-regulation of TP-1, CDC2, and IGF2 transcripts and significantly lower levels of AQP3, ATP1A1, H2A.Z, hsp90beta, and OCT4, while NANOG, BAX, CCNB1, CDH1, GAPDH, and IGF2R displayed similar expression patterns in the two groups. Our study indicates that oocyte parthenogenetic activation does not impair in vitro pre-implantation development to the blastocyst stage, but affects the gene expression status of the embryo after the activation of its own genome.

The subcortical maternal complex: multiple functions for one biological structure?

The subcortical maternal complex (SCMC) is a multiprotein complex uniquely expressed in mammalian oocytes and early embryos, essential for zygote progression beyond the first embryonic cell divisions. Similiar to other factors encoded by maternal effect genes, the physiological role of SCMC remains unclear, although recent evidence has provided important molecular insights into different possible functions. Its potential involvement in human fertility is attracting increasing attention; however, the complete story is far from being told. The present mini review provides an overview of recent findings related to the SCMC and discusses its potential physiological role/s with the aim of inspiring new directions for future research.