Project description:In cattle, the in vitro production (IVP) of embryos is becoming more relevant than embryos produced in vivo, i.e., after ovarian stimulation and embryo transfer (MOET). However, the effects of IVP on the developmental programming of specific organs in the postnatal calves are yet unknown. The objective of this study was to compare the hepatic and muscular transcriptomic modifications between IVP and MOET male calves of three months of age (n=4 per group). Tissue samples from liver and semitendinosus muscle were obtained at 3 months of age, and the extracted RNA was sequenced through RNAseq to determine differentially expressed genes (DEG; FDR<0.05). KEGG pathways enrichment analysis showed that DEG up-regulated in the liver and the muscle of the IVP calves were involved in oxidative phosphorylation and the tricarboxylic acid cycle. In contrast, ribosome and translation were up-regulated in the liver but down-regulated in the muscle of the IVP calves compared to the MOET calves (FDR<0.05). In conclusion, our findings indicated an altered hepatic and muscular energy regulation in phenotypically normal IVP calves compared to MOET calves.

Project description:In cattle, two of the most common technologies for embryo production are “in vivo”, after multiple ovulation and embryo transfer (MOET), or “in vitro” (IVP). IVP can sometimes impact fetal growth, resulting in large offspring, although most IVP calves are born apparently healthy. However, gene regulation changes in the organs involved in the developmental process in phenotypically normal postnatal calves are unknown and could indicate physiological programming. The objective was to compare the epigenomic and transcriptomic modifications in the liver, muscle, and organs of the hypothalamus-pituitary-gonadal and adrenal (HPGA) axes between IVP and MOET male calves of three months of age. Pregnancies were monitored until delivery. Male calves were maintained in similar conditions during the postnatal period until euthanasia at around 100 days of age. There were no differences regarding body weight at birth and growth rate among the animals in both groups at this age.

Project description:In cattle, two of the most common technologies for embryo production are “in vivo” (MOET) or “in vitro” (IVP). IVP can sometimes impact fetal growth, resulting in large offspring, although most IVP calves are born apparently healthy. However, gene regulation changes in the organs involved in the developmental process in phenotypically normal postnatal calves are unknown and could indicate physiological programming. The objective of this study was to compare the transcriptomic modifications in organs of the hypothalamus-pituitary-gonadal and adrenal (HPGA) axes between IVP and MOET male calves of three months of age. RNA extracted from the HPGA organs samples (n=4 per group) were sequenced through RNAseq. The raw files were subjected to a bioinformatic pipeline to determine differentially expressed genes (FDR<0.05) in IVP versus MOET samples and the KEGG pathways enriched by these genes (FDR < 0.1). Pathways related to the reproductive process (GnRH secretion in hypothalamus, GnRH signaling in pituitary and steroidogenesis in testicle) were stimulated in IVP calves, suggesting an early activation of the HPG axis in male IVP calves when compared to MOET counterparts.

Project description:This study compared the gene expression of extraembryonic membranes (EEM) from in vitro produced (IVP) and in vivo (AI) derived embryos. Samples of EEM from AI and IVP pregnancies were collected on days 18 and 32. A piece of the conceptus (day 18) or chorioallantois (day 32) were used for DNA and RNA isolation and subsequent determination of the sex by amplification of a Y-linked region of the DNA. The male and female ratios were analyzed by Chi-square of SAS. A subset of three female and three male EEM samples from each group (AI and IVP, days 18 and 32) were used for transcriptome analysis. Differentially expressed genes (DEGs) between groups, sex, and days were determined using edgeR-robust. A false discovery rate (FDR) <0.05 was used for statistical significance, and Toppgene platform was used for biological processes analysis. Sex ratio was similar on day 18 for AI and IVP groups. On day 32, the IVP group had a greater number of females than males (75 vs 25%, P=0.004). On day 18 female embryos, out of 71 DEGs identified, 50 were upregulated in IVP, and 21 in AI. The trophectoderm marker, TKDP2, was upregulated in the AI group, whereas IGF2, which is involved in placenta development, and APOA2, APOB, and APOE, which are important for lipid metabolism, were upregulated in the IVP group. Male embryos on day 18 had 22 DEGs, being 15 upregulated in AI and 7 in IVP. Female embryos on day 32 had 74 DEGs, with 21 upregulated in AI and 53 in IVP embryos. Some of the genes with increased expression in the IVP group were PTGIS, APOB, and APOH, which are related to lipid synthesis and metabolism. Male embryos on day 32 presented 899 DEGs, 564 upregulated in AI and 335 in IVP. Embryos from IVP had increased expression of genes related to embryo development, morphogenesis, neurogenesis, and developmental growth. In addition, male IVP embryos had decreased expression of genes related to lipid and carbohydrate metabolism. Interestingly, PLAC8B, BRB, pregnancy-associated glycoproteins (PAG) 7, 9, 10, and 19, were also downregulated in IVP male EEM. When comparing IVP males and females, there were 6753 DEGs, with 3091 being upregulated in females, and 3662 in male conceptuses on day 18. Some of the genes upregulated in females were related to placental function such as TKDP4, PLAC8A and PAGs 6, 8, 10, 12, 17, 18 and 19. On males, IFNT-related genes were upregulated (IFNT, IFNT2 IFNT3 and IFN-T). On day d32, there were 6772 DEGs, with 3252 genes with increased expression in female, and 3520 in male placentas. Among the genes increased in female placentas are genes involved in placentation: PAGs 17, 19, 9 and PLAC8B. On the other hand, PAG1 was detected as highly expressed in male placentas. In conclusion, IVP-derived male embryos were more susceptible to alterations in gene expression and these effects extend to the peri-implantation period including genes associated with placental development and markers of placental function.

Project description:Aberrant placental gene expression associated with culture condition and/or deficiencies in transcriptome reprogramming are hypothesized to be the major cause of SCNT and IVP inefficiencies. Therefore, the main objective of this study was to invesitgate the dysregulated genes, molecular pathways and functional alteration in bovine placentas derived from SCNT and IVP pregnancies compared to their AI counterparts Day 7 blastocysts derived from AI, IVP or SCNT were transferred to synchronized cows. The pregnant animals were slaughtered at day 50 of the gestation period and the placentas were then recovered and used for transcriptome analysis using GeneChip bovine genome array

Project description:Aberrant placental gene expression associated with culture condition and/or deficiencies in transcriptome reprogramming are hypothesized to be the major cause of SCNT and IVP inefficiencies. Therefore, the main objective of this study was to invesitgate the dysregulated genes, molecular pathways and functional alteration in bovine placentas derived from SCNT and IVP pregnancies compared to their AI counterparts

Project description:In vitro production systems, as well as cloning technology, may lead to persistent aberrations of gene expression patterns during embryonic and fetal development. In order to get a global overview of gene expression alteration induced by in vitro environment and somatic cell nuclear transfer, we performed microarray analysis of day 16 conceptuses obtained from SCNT, IVP and AI pregnancies. Day 7 blastocysts generated from AI, IVP and SCNT were transferred to synchronized cows. Comparable length of day 16 embryos were recovered and used for transcriptome analysis using GeneChip bovine genome array

Project description:The impact of postnatal heat stress exposure in neonatal calves is not well-understood, and adequate heat abatement methods during the pre-weaning phase are lacking. This study aimed to investigate the impact of pre-weaning heat stress on liver DNA methylation profiles.

Project description:The impact of postnatal heat stress exposure in neonatal calves is not well-understood, and adequate heat abatement methods during the pre-weaning phase are lacking. This study aimed to investigate the impact of pre-weaning heat stress on liver gene expression profiles.

Project description:Exposure to intrauterine heat stress during late gestation affects offspring performance into adulthood. However, underlying mechanistic links between thermal insult in fetal life and postnatal outcomes are not completely understood. Utilizing Reduced Representation Bisulfite Sequencing, this study evaluated DNA methylation of liver and mammary gland of bull calves and heifers that were gestated under maternal conditions of heat stress or cooling, i.e., in utero heat stressed (HT) vs. in utero cooled (CL). Liver samples from bull calves (CT = 5 and HT = 4) were collected at birth while mammary gland samples from heifers (CT = 3 and HT = 3) were collected during their first lactation.