GPR30 expression and function in breast cancer cells are induced through a cis­acting element targeted by ETS factors.

The capacity that G protein­coupled receptor 30 (GPR30) has demonstrated for triggering estrogen­dependent signaling pathways has attracted the interest of breast cancer researchers; however, the reported expression profiles and functions of GPR30 in breast cancer are inconsistent. The main purpose of the present investigation was to identify transcriptional mechanisms underlying the expression of GPR30 that allow a better understanding of its role in breast cancer progression. In the cell lines used as different polarity models in the present study, it was determined immunologically that GPR30 is expressed in normal mammary gland cells and that this expression decreased considerably during breast cancer development, where cell identity is lost. However, it was also determined that, in spite of low GPR30 expression levels in breast cancer cells with little differentiation, this membrane estrogen receptor (ER) is able to increase cell viability and suppress migration in cells that have acquired metastatic capacity. In addition, through transient expression assays in breast cancer cells, it was revealed that a transcriptional mechanism dependent on protein kinase A and susceptible to retinoic acid in ER­positive cells induces GPR30 expression through a cis­regulatory element for E26 transformation­specific transcription factors, located between ­631 and ­625 bp from the GPR30 translation start codon. Overall, these results suggested that in vitro transcriptional regulation of GPR30 expression in breast cancer cells may serve a relevant role in the conservation of an epithelial phenotype, and also may be important to avoid the transition to metastasis.

Co-culture with granulosa cells improve the in vitro maturation ability of porcine immature oocytes vitrified with cryolock.

This study was designed to evaluate the efficiency of two oocyte vitrification-warming procedures using two different devices: Superfine Open Pulled Straws (SOPS) and Cryolock, as well as the effect of the co-culture of vitrified immature oocytes with fresh granulosa cells to improve in vitro maturation (IVM). Immature oocytes were vitrified with two procedures: A) Oocytes were exposed to an increasing concentration of ethylene glycol (EG) from 4% to 35% with 0.5 M trehalose. They then, were loaded in SOPS or Cryolock. For warming, oocytes were exposed to decreasing concentrations of trehalose 0.3, 0.2 and 0.1 M for IVM. B) Oocytes were exposed to two mixtures of EG and dimethylsulfoxide (Me2SO), at 7.5% and 16%, both with 0.4 M of sucrose and then loaded in SOPS or Cryolock and stored in liquid nitrogen. For warming, oocytes were exposed to a single concentration of sucrose 0.5M. After warming, viability was determined; and after 44 h of IVM both viability and meiotic stages were evaluated. The results indicate no significant differences between procedures A and B with SOPS in all maturation stages, reaching a maximum maturation rate of 21%. As to Cryolock, significant differences were observed between both procedures, being procedure B, more efficient with a yield of 38% in MII stage and increased to 49% due to the co-culture with fresh granulosa cells. In conclusion, viability and maturation rates were improved with Cryolock and procedure B with the co-culture system in vitrified immature oocytes.

Sebox plays an important role during the early mouse oogenesis in vitro.

Oogenesis is a highly complex process that requires the exquisite temporal and spatial regulation of gene expression at multiple levels. Skin-embryo-brain-oocyte homeobox (Sebox) gene encodes a transcription factor that is highly expressed in germinal vesicle stage oocytes and that plays an essential role in early embryogenesis at the 2-cell stage in the mouse. As Sebox is also expressed in mouse fetal ovaries, the aim of the present study was to study its role during the early oogenesis in vitro. Expression of Sebox was low in 15.5 to 17.5 days post coitum (dpc) ovaries, showed a peak at 18.5 dpc and then its expression decreased dramatically in newborn ovaries. Sebox expression was efficiently knocked down (>80%) in fetal mouse ovary explants in culture using RNAi technology. When fetal ovary explants were transfected with Sebox-specific RNAi, the number of oocytes at germinal vesicle stage and showing a diameter of 40-70 µm was decreased significantly to 75% after 7 days of culture relative to the negative control, and to 22.4% after 10 days of culture, thus indicating that Sebox plays an important role in the early oogenesis in mice.

Effect of porcine follicular fluid proteins and peptides on oocyte maturation and their subsequent effect on in vitro fertilization.

The follicular fluid (FF) is a microenvironment that contains molecules involved in oocyte maturation, ovulation, and fertilization. Characterizing the proteins and peptides present in the FF could be useful for determining which proteins and peptides to use as a supplement for culture media. Biologically active peptides produced during the maturation or degradation of functional proteins are called cryptides. The aim of this study was to identify the proteins and cryptides in porcine FF that could stimulate porcine oocyte in vitro maturation (IVM) and in vitro fertilization (IVF) when added to culture maturation medium. Five FF protein fractions (F1-F5) were obtained by ionic exchange chromatography, resolved by SDS-PAGE, and identified by tandem mass spectrometry. These fractions had effects on IVM and/or IVF. The F1 fraction, which was composed of immunoglobulin fragments, cytokeratin, transferrin, and plasminogen precursor increased IVM and IVF. The F2, F3, and F4 fractions reduced the percentage of oocytes in first metaphase. Additionally, the F3 fraction, which was composed of immunoglobulins and transthyretin, interfered with germinal vesicle breakdown. The F5 fraction, which was mainly composed of serum albumin and keratin, favored germinal vesicle breakdown and promoted IVM. Most of the 31 proteins which were associated with the immune response and inflammatory processes could be related to oocyte maturation and fertilization. Some of the identified proteins were present in more than one fraction; this could be explained by a change in their isoelectric points, because of the loss of part of the amino acid sequence or a change in the glycosylation status of the protein. Improved oocyte IVM and IVF will increase embryo production, which in turn will contribute to the efficiency of assisted reproduction in various mammalian species.

Viability, maturation and embryo development in vitro of immature porcine and ovine oocytes vitrified in different devices.

This study was designed to evaluate the effects of vitrification on immature porcine and ovine oocytes, collected at a slaughterhouse, by performing vitrification in devices with different volumes. Viability was evaluated both before and after vitrification and maturation. Immediately after warming, the percentage of viable pig oocytes was 81% regardless the type of device, while in the control (after oocyte selection) was 95%. The viability of matured pig oocytes after warming, vitrified in beveled edge open straws (BES) was 6%, in small-open-pulled-straw (SOPS) was 17% and in cryotop was 4%, while the viability of the control group was 86%. The viability and maturation results were similar with all devices. Embryo development (ED) was observed in fresh porcine oocytes with 15% 2-8 cell embryos, 7% morulae and 3% blastocysts, and non-embryo cleavage was observed in warmed oocytes. The viability of sheep oocytes immediately after warming averaged 90% in all devices, while that of the control (after oocyte selection) averaged 95%. The viability of warmed oocytes after maturation was: BES 21%, SOPS 30%, cryotop 21% and control group 86%; while maturation values were 11, 21, 34 and 70%, respectively. After vitrification, the highest ED was achieved with ovine oocytes vitrified in SOPS, with 17% morulae development and it was the only device in which blastocysts developed. A direct relationship was observed between viability and actin filament integrity in both species.

Gene expression analysis on the early development of pig embryos exposed to malathion.

Malathion is a widely used pesticide and there is evidence that it could alter mammal's germ and somatic cells, as well as cell lines. There are not enough studies showing how the nonacute malathion doses affect gene expression. This study analyzes gene expression alterations in pig morular embryos exposed in vitro, for 96 h, to several malathion concentrations after in vitro fertilization. cDNA libraries of isolated morular embryos were created and differential screenings performed to identify target genes. Seven clones were certainly identified. Genes related to mitochondrial metabolism as cytochrome c subunits I and III, nuclear genes such as major histocompatibility complex I (MHC I), and a hypothetical protein related with a splicing factor were the target of malathion's deregulation effect. The widespread use of malathion as a pesticide should be regarded with reproductive implications and more detailed analysis would yield more about molecular mechanisms of malathion injury on embryo cells.