Project description:In Xenopus laevis, a number of studies identified vegetal factors that specify the germ line, endoderm and dorsal axis, but there are few studies demonstrating roles for animal-enriched maternal mRNAs. Therefore, we carried out a microarray analysis to identify novel maternal transcripts enriched in animal blastomeres. We sought to maximize differences between animal and vegetal samples. To that end, we dissected 8-cell embryos into animal blastomeres and vegetal blastomeres, and further dissected the vegetal blastomeres into vegetal-most halves (VP) and equatorial regions (discarded).

Project description:To identify asymmetrically localized maternal mRNAs along the animal-vegetal axis in cleavage Xenopus embryos, we isolated animal and vegetal blastomeres at 8-cell stage, extracted the maternal mRNA respectively and analyzed them by RNA-seq technology. We identified 43 maternal transcripts significantly enriched in the vegetal region (FDR<0.05) by R/Bioconductor package DESeq RNAseq of animal and vegetal blastomeres with 2 biological replicates

Project description:We have examined whether twin blastomeres from 2-cell stage mouse embryos differ in mRNA content. Amplified mRNA from 12 blastomeres derived from six embryos approximately mid-way through their second cell cycle was analyzed. Probes displaying normalized values greater than 0.25 were selected and examined for consistent bias in expression within blastomere pairs. Although transcript content varied both between individual embryos and twin blastomeres, no consistent asymmetries were observed for the majority of genes. On the other hand, 769 genes displayed a greater than 1.4-fold difference in expression across 5 of 6 pairs of blastomeres and 178 genes differed across all 6 pairs. These genes separated into two groups by class discovery clustering. Of the 769 differentially expressed genes, 163 were significantly up- or down-regulated in one sister blastomere compared to the other. Transcripts encoding proteins implicated in RNA processing and cytoskeletal organization were highly represented among the most abundant, differentially distributed mRNA. We conclude that there are many differences that distinguish twin blastomeres derived from a single 2-cell stage embryo but that only a few of these differences are consistent across multiple pairs of embryos. We hypothesize that a stochastically-based lack of synchrony in cell cycle progression between the two cells might explain some or all of the asymmetries in transcript composition. 6 pairs of blastomeres were analyzed for a total of 12 samples.

Project description:Animal embryos have the remarkable property of self-organization. Over 125 years ago Hans Driesch separated the two blastomeres of sea urchin embryos and obtained twins, in what was the foundational experiment of experimental embryology. Since then, embryonic twinning has been obtained experimentally in many animals by diverse methods. In a recent study, we developed bisection methods that generate identical twins reliably from Xenopus blastula embryos. In the present study we investigated the transcriptome of regenerating half-embryos after sagittal and dorsal-ventral (D-V) bisections. Individual embryos were operated at midblastula with an eyelash hair and cultured until early gastrula (stage 10.5) or late gastrula (Stage 12) and analyzed the transcriptome of each half-embryo by RNAseq. Because many genes are activated by wound healing, stringent analyses were used to identify genes upregulated in identical twins but not in either dorsal or ventral fragments. At early gastrula cell division-related genes such as histones were identified, whereas at late gastrula pluripotency genes (such as sox2) and germ layer determining genes (such as eomesodermin, ripply2 and activing receptor ACVRI) and a number of secretory pathway components (serpinH1, fucoleptin and sialyl transferase). These findings are consistent with a model in which cell division is required to heal damage, while maintaining pluripotency to permit formation of the organizer with a displacement of 900 from its original site. In addition, the extensive transcriptomic data presented here (30 RNA-seq libraries of individual whole or regenerating half-embryos) provides a useful resource for data mining gene expression during early vertebrate development.

Project description:Transcriptomes were determined for all blastomeres of 28 embryos at the 2- (n=8), 4- (n=16) and 8-cell (n=4) stages, and for individual cells taken from 16- (n=6) and 32- (n=6) cell stage embryos. We also carefully monitored the 2- to 4-cell divisions noting whether the cleavage plane was meridional (M, along the Animal-Vegetal (AV) axis marked by the second attached polar body) or equatorial (E, bisecting the AV axis) and the order in which such divisions occurred. This resulted in four groups of 4-cell stage embryos: ME, EM, MM and EE, which were all collected 10 hours after the first 2- to 4-cell division.

Project description:We have examined whether twin blastomeres from 2-cell stage mouse embryos differ in mRNA content. Amplified mRNA from 12 blastomeres derived from six embryos approximately mid-way through their second cell cycle was analyzed. Probes displaying normalized values greater than 0.25 were selected and examined for consistent bias in expression within blastomere pairs. Although transcript content varied both between individual embryos and twin blastomeres, no consistent asymmetries were observed for the majority of genes. On the other hand, 769 genes displayed a greater than 1.4-fold difference in expression across 5 of 6 pairs of blastomeres and 178 genes differed across all 6 pairs. These genes separated into two groups by class discovery clustering. Of the 769 differentially expressed genes, 163 were significantly up- or down-regulated in one sister blastomere compared to the other. Transcripts encoding proteins implicated in RNA processing and cytoskeletal organization were highly represented among the most abundant, differentially distributed mRNA. We conclude that there are many differences that distinguish twin blastomeres derived from a single 2-cell stage embryo but that only a few of these differences are consistent across multiple pairs of embryos. We hypothesize that a stochastically-based lack of synchrony in cell cycle progression between the two cells might explain some or all of the asymmetries in transcript composition.

Project description:To identify asymmetrically localized maternal mRNAs along the animal-vegetal axis in cleavage Xenopus embryos, we isolated animal and vegetal blastomeres at 8-cell stage, extracted the maternal mRNA respectively and analyzed them by RNA-seq technology. We identified 43 maternal transcripts significantly enriched in the vegetal region (FDR<0.05) by R/Bioconductor package DESeq

Project description:The first mitotic division causes both parental genomes present in the zygote to segregate into two biparental diploid daughter cells. This fundamental tenet was challenged by the observation that blastomeres with different genome ploidy and distinct parental genotypes can coexist within individual embryos. We hypothesized that whole parental genomes can segregate into distinct blastomere lines during the multipolar division of the zygote, a phenomenon referred to as “heterogoneic†cell division. Here, we provide evidence of genome-wide segregation errors in two human blastocysts and further pinpoint its origin in a bovine model by mapping the genomic landscape of 82 blastomeres from 25 embryos that underwent multipolar division at the zygote stage using genome-wide SNP arrays and sequencing. In most embryos, the coexistence of androgenetic and diploid or polyploid blastomeres with or without anuclear blastomeres, androgenetic and anuclear blastomeres, and androgenetic and gynogenetic blastomeres within the same embryo provided proof that multipolar zygotic division coincides with heterogoneic segregation of the parental genome. By mapping the segregational origin of the genomic content, we deduced distinct segregation mechanisms underlying heterogoneic cell division including segregation by a tripolar spindle, the pronuclear extrusion of a paternal genome and, the operation of an ectopic paternal or private parental spindles. Polyspermic embryos expel excessive paternal genomes resulting in an androgenetic or polyploid blastomere Confirming the results in human blastocysts we found genome-wide segregation errors to persist in bovine blastocysts.

Project description:The first mitotic division causes both parental genomes present in the zygote to segregate into two biparental diploid daughter cells. This fundamental tenet was challenged by the observation that blastomeres with different genome ploidy and distinct parental genotypes can coexist within individual embryos. We hypothesized that whole parental genomes can segregate into distinct blastomere lines during the multipolar division of the zygote, a phenomenon referred to as “heterogoneic” cell division. Here, we provide evidence of genome-wide segregation errors in two human blastocysts and further pinpoint its origin in a bovine model by mapping the genomic landscape of 82 blastomeres from 25 embryos that underwent multipolar division at the zygote stage using genome-wide SNP arrays and sequencing. In most embryos, the coexistence of androgenetic and diploid or polyploid blastomeres with or without anuclear blastomeres, androgenetic and anuclear blastomeres, and androgenetic and gynogenetic blastomeres within the same embryo provided proof that multipolar zygotic division coincides with heterogoneic segregation of the parental genome. By mapping the segregational origin of the genomic content, we deduced distinct segregation mechanisms underlying heterogoneic cell division including segregation by a tripolar spindle, the pronuclear extrusion of a paternal genome and, the operation of an ectopic paternal or private parental spindles. Polyspermic embryos expel excessive paternal genomes resulting in an androgenetic or polyploid blastomere. Confirming the results in human blastocysts we found genome-wide segregation errors to persist in bovine blastocysts.

Project description:10.1021/acs.analchem.6b01921 Article: Single Cell Proteomics Using Frog (Xenopus laevis) Blastomeres Isolated from Early Stage Embryos, Which Form a Geometric Progression in Protein Content.