Project description:In eutherian mammals, dosage compensation of X-linked genes is achieved by X chromosome inactivation. X inactivation is random in embryonic and adult tissues, but imprinted X inactivation (paternal X silencing) has been identified in the extraembryonic membranes of the mouse, rat, and cow. Few other species have been studied for this trait, and the data from studies of the human placenta have been discordant or inconclusive. Here, we quantify X inactivation using RNA sequencing of placental tissue from reciprocal hybrids of horse and donkey (mule and hinny). In placental tissue from the equid hybrids and the horse parent the allelic expression pattern was consistent with random X inactivation, and imprinted X inactivation can clearly be excluded. We characterized horse and donkey XIST gene, and demonstrated that XIST allelic expression in female hybrid placental and fetal tissues is negatively correlated with the other X-linked genes chromosome-wide, which is consistent with the XIST-mediated mechanism of X inactivation discovered previously in mice. As the most structurally and morphologically diverse organ in mammals, the placenta also appears to show diverse mechanisms for dosage compensation that may result in differences in conceptus development across species.

Project description:In eutherian mammals, dosage compensation of X-linked genes is achieved by X chromosome inactivation. X inactivation is random in embryonic and adult tissues, but imprinted X inactivation (paternal X silencing) has been identified in the extraembryonic membranes of the mouse, rat, and cow. Few other species have been studied for this trait, and the data from studies of the human placenta have been discordant or inconclusive. Here, we quantify X inactivation using RNA sequencing of placental tissue from reciprocal hybrids of horse and donkey (mule and hinny). In placental tissue from the equid hybrids and the horse parent the allelic expression pattern was consistent with random X inactivation, and imprinted X inactivation can clearly be excluded. We characterized horse and donkey XIST gene, and demonstrated that XIST allelic expression in female hybrid placental and fetal tissues is negatively correlated with the other X-linked genes chromosome-wide, which is consistent with the XIST-mediated mechanism of X inactivation discovered previously in mice. As the most structurally and morphologically diverse organ in mammals, the placenta also appears to show diverse mechanisms for dosage compensation that may result in differences in conceptus development across species. Examine allelic expression from individual samples of invasive trophoblast tissue of the chorionic girdle from gestation day 33-34 conceptuses of 5 horses, 3 donkeys, 6 mules, and 1 hinny.

Project description:The discovery of genomic imprinting through studies of manipulated mouse embryos indicated that the paternal genome has a major influence on placental development. However, previous research has not demonstrated paternal bias in imprinted genes. We applied RNA sequencing to trophoblast tissue from reciprocal hybrids of horse and donkey, where genotypic differences allowed parent-of-origin identification of most expressed genes. Using this approach, we identified a core group of 15 ancient imprinted genes of which 10 were paternally expressed. An additional 78 candidate novel imprinted genes identified by RNA-seq also showed paternal bias. Pyrosequencing was used to confirm the imprinting status of six of the novel genes, including the insulin receptor (INSR), which may play a role in growth regulation with its reciprocally imprinted ligand, histone acetyltransferase (HAT1), the first example of an imprinted gene involved in chromatin modification, and LY6G6C, the first imprinted gene to be identified in the major histocompatibility complex. The 78 novel candidate imprinted genes displayed parent-of-origin expression bias in placenta but not fetus, and most showed less than 100% silencing of the imprinted allele. Some displayed variability in imprinting status among individuals. This results in a unique epigenetic signature for each placenta that contributes to variation in the intrauterine environment and thus presents the opportunity for natural selection to operate on parent-of-origin differential regulation. Taken together, these features highlight the plasticity of imprinting in mammals and the central importance of the placenta as a target tissue for genomic imprinting. Examine allelic expression from four individual samples of invasive trophoblast tissue of the chorionic girdle from gestation day 33 conceptuses of horse, donkey, mule and hinny.

Project description:Profiling of differential allelic expression in horse, donkey, mule and hinny placental tissue

Project description:Profiling of differential allelic expression in horse, donkey, mule, and hinny placental tissues.

Project description:Pluripotency of mammalian stem cells is stabilized at different status depending upon the extracellular stimuli of their environment. Now, there is a consensus that mouse embryonic stem cells (mESCs) and iPSCs (miPSCs) represent undifferentiated status very close to ground-state of mammalian development when cultured in optimal condition. Since they have not been activated to commit into any lineages, they are stated as “naïve-state stem cells”. In contrast, human ESCs (hESCs), hiPSCs, and mEpiSCs are considered to possess partially differentiated characteristics compared with mESCs and miPSCs. Thus, they are stated as “primed-state stem cells”. Investigation of the prerequisites for establishment of the naïve-state is significantly important to fully understand mammalian development and to extrapolate the technologies developed with mouse ES/iPS cells for human. We used expression data to understand the gene expression profile and identified distinct characteristics on pluripotent state.

Project description:Pluripotency of mammalian stem cells is stabilized at different status depending upon the extracellular stimuli of their environment. Now, there is a consensus that mouse embryonic stem cells (mESCs) and iPSCs (miPSCs) represent undifferentiated status very close to ground-state of mammalian development when cultured in optimal condition. Since they have not been activated to commit into any lineages, they are stated as “naïve-state stem cells”. In contrast, human ESCs (hESCs), hiPSCs, and mEpiSCs are considered to possess partially differentiated characteristics compared with mESCs and miPSCs. Thus, they are stated as “primed-state stem cells”. Investigation of the prerequisites for establishment of the naïve-state is significantly important to fully understand mammalian development and to extrapolate the technologies developed with mouse ES/iPS cells for human. We used expression data to understand the gene expression profile and identified distinct characteristics on pluripotent state.

Project description:Horse and donkey centromeres

Project description:Human induced pluripotent stem cells (hiPSCs) provide an invaluable source for regenerative medicine; but are limited by proficient lineage specific differentiation. Here we reveal that hiPSCs derived from dermal skin fibroblasts (Fib) vs. human cord blood (CB) cells exhibit equivalent and indistinguishable pluripotent properties, but harbor important propensities for neural and hematopoietic lineage differentiation, independent of reprogramming factors used. Genes associated with germ layer specification were identical in both Fib or CB derived iPSCs; whereas patterns of lineage specific marks emerge upon differentiation induction of hiPSCs that were correlated to the cell type of origin used to create hiPSCs. Functionally, CB-iPSCs predominantly differentiate into hematopoietic cells and even adopt definitive hematopoiesis as evidenced by adult β-globin positive red blood cell development whereas Fib-iPSCs possess enhanced neural capacity. These clear differentiation propensities come at the expense of other lineages and cannot be overcome with additional external stimuli for alternative cell fates. Moreover, these differences in developmental potential are encoded within cultures of CB vs. Fib derived hiPSCs that can be used to predict differentiation propensity.

Project description:Reprogramming of somatic cells into Induced Pluripotent Stem Cells (iPSCs) provided a major leap towards more personalized cellular models for disease modelling and offers great prospects for regenerative medicine. Despite their considerable success, we still lack the ability to control the state of iPSCs fully, especially at the epigenetic level. This can be appreciated at chromosomal regions regulated by genomic imprinting which provides a good read-out for epigenetic fidelity in iPSCs. Indeed, imprinting defects have already been reported in both mouse and human iPSCs. However, the extent, nature, causes and consequences of these defects still remain to be analysed in a systematic manner. To fill this gap in knowledge, we used a controlled secondary reprogramming system whereby the donor mouse embryonic fibroblasts (MEFs) contain a doxycycline (DOX)-inducible Yamanaka cassette and also Single Nucleotide Polymorphisms (SNPs) to distinguish between the two parental alleles. Several female and male isogenic mouse iPSCs (miPSCs) were obtained using independent culture conditions (defined versus serum) and screened by allelic-specific IMPLICON, a targeted next-generation method to measure DNA methylation at imprinted regions with unprecedented genomic coverage of 1000-fold. Our results showed that imprinting defects are remarkably common in miPSCs. Interestingly, we found important differences in gender responses to culture conditions. In particular, female iPSCs exhibit widespread hypomethylation defects regardless of culture conditions, while male miPSCs show tendency for hypomethylation defects under defined conditions, and hypermethylation defects under serum conditions in particular loci. As expected, methylation defects at imprinted regions resulted in dysregulation of monoallelic expression of imprinted genes. Our results are of utmost importance to devise future reprogramming strategies to generate epigenetic error-free iPSCs