Project description:Mammalian embryonic development begins with the specification and segregation of the two extra-embryonic lineages, trophectoderm and primitive endoderm, from the pluripotent embryonic lineage, the epiblast. To establish a map of epiblast (EPI) versus primitive endoderm (PrE) lineage segregation which occurs within the inner cell mass (ICM), we comprehensively characterised the gene expression profiles of individual inner cells during blastocyst development. Lineage represents the two embryonic cell lineages: the epiblast (EPI), and the primitive endoderm (PE), which are segregated within the inner cell mass(ICM) during blastocyst development.

Project description:Preimplantation stages of mouse embryo development involve temporal and spatial specification and segregation of three late blastocyst cell lineages; trophectoderm (TE), primitive endoderm (PrE) and epiblast (EPI). Spatial separation of the outer TE lineage from the two inner-cell-mass (ICM) lineages (PrE and EPI) starts with the 8- to 16-cell transition and concludes following transit through the 16- to 32-cell stages. This results in a nascent early blastocyst ICM derived from descendants of primary founding inner cells and a secondarily contributed population; of which subsequent relative EPI versus PrE potencies are subject to debate. We showed that generation of primary but not the secondary ICM populations is highly dependent on temporally discreet activation of the mammalian target of rapamycin (mTOR – specifically mTORC1) around 8-cell stage M-phase entry. Moreover, that this role is mediated via the regulated function of the 7-methylguanosine- (7mG) cap binding initiation complex (EIF4F) and potentiating the translation of a subset of key but otherwise intransigent mRNAs containing 5’ UTR terminal oligopyrimidine (TOP-) sequence motifs. To find out translation of which mRNAs is regulated by mTOR during 8- to 16-cell transition, we analysed proteomes of control and mTOR-inhibited embryos during this time window.

Project description:We performed RNA-sequencing, ChIP-sequncing and Brif-sequencing on Rbbp5 knockout (KO) and wild-type (WT) mouse ICM and E5.0 epiblast. Our results showed that Rbbp5 KO lead to significant reduction of H3K4me3 modification at early blastocyst stage. The change in H3K4me3 landscape occured before the transcriptome change. Moreover, Rbbp5 KO specifically affected epiblast lineages the most at late blastocyst stage and the KO embryos died at E5.5.

Project description:We have developed a method for rapidly identifying early, regionally-expressed molecules: FACS-Assisted Microdissection of Photolabeled cells (FAM-P). For our first FAM-P project, we injected embryos with purified Kaede protein, a stony coral protein that fluoresces at 514 nm (green) prior to- and 582 nm (red) after photoconversion at 405 nm. We used the scanning laser of a confocal microscope to photolabel late blastula-stage embryos along 4-6 tiers of marginal cells, comprising the mesoderm and endoderm germ layer precursors. This procedure left the neurectoderm precursor cells marked by green fluorescence and the mesendoderm precursor cells marked by red fluorescence. Embryonic cells were dissociated and subjected to FACS, separating red mesendoderm precursors from green neurectoderm precursors. RNA was extracted and linearly amplified once, then dye-labeled and co-hybridized to a microarray with over 30,000 oligos representing more than 20,000 unique zebrafish genes. In validation of our strategy, many genes known to have elevated expression in the late blastula margin (e.g., squint, fgf8, lim1 and gata5) and several genes known to be specific to the early neurectoderm (e.g., sox31 and otx2) were independently identified by this approach. In addition to known genes, our method has identified dozens of previously uncharacterized genes that are enriched in the pre-mesendoderm or pre-neurectoderm. Keywords: 40% epiboly-stage embryos, injected with purified Kaede protein, differentially photolabeled, disaggregated and FACS sorted

Project description:The epiblast of vertebrate embryos is comprised of neural and non-neural ectoderm, with the border territory at their intersection harbouring neural crest and cranial placode progenitors. Here we profile avian epiblast cells as a function of time using single-cell RNA-seq to define transcriptional changes in the emerging ‘neural plate border’. The results reveal gradual establishment of heterogeneous neural plate border signatures, including novel genes that we validate by fluorescent in situ hybridization. Developmental trajectory analysis shows that segregation of neural plate border lineages only commences at early neurulation, rather than at gastrulation as previously predicted. We find that cells expressing the prospective neural crest marker Pax7 contribute to multiple lineages, and a subset of premigratory neural crest cells shares a transcriptional signature with their border precursors. Together, our results suggest that cells at the neural plate border remain heterogeneous until early neurulation, at which time progenitors become progressively allocated toward defined lineages.

Project description:We have developed a method for rapidly identifying early, regionally-expressed molecules: FACS-Assisted Microdissection of Photolabeled cells (FAM-P). For our first FAM-P project, we injected embryos with purified Kaede protein, a stony coral protein that fluoresces at 514 nm (green) prior to- and 582 nm (red) after photoconversion at 405 nm. We used the scanning laser of a confocal microscope to photolabel late blastula-stage embryos along 4-6 tiers of marginal cells, comprising the mesoderm and endoderm germ layer precursors. This procedure left the neurectoderm precursor cells marked by green fluorescence and the mesendoderm precursor cells marked by red fluorescence. Embryonic cells were dissociated and subjected to FACS, separating red mesendoderm precursors from green neurectoderm precursors. RNA was extracted and linearly amplified once, then dye-labeled and co-hybridized to a microarray with over 30,000 oligos representing more than 20,000 unique zebrafish genes. In validation of our strategy, many genes known to have elevated expression in the late blastula margin (e.g., squint, fgf8, lim1 and gata5) and several genes known to be specific to the early neurectoderm (e.g., sox31 and otx2) were independently identified by this approach. In addition to known genes, our method has identified dozens of previously uncharacterized genes that are enriched in the pre-mesendoderm or pre-neurectoderm. Keywords: 40% epiboly-stage embryos, injected with purified Kaede protein, differentially photolabeled, disaggregated and FACS sorted 34k expression arrays were generated by printing Oligo nucleotides from three different sets (MWG, Compugen and Operon) onto epoxy slides. Total RNA from Kaede protein-injected and FAM-P treated zebrafish embryos was amplified using an Ambion kit (Cat#1753), labeled with Cy dyes and hybridized overnight to the oligo chip in a MAUI chamber. The experiment comparing mesendoderm was performed four times (twice with WIK/AB hybrid strain embryos, once with EK strain embryos and once with AB strain embryos) each time including a dye swap, for a total of eight (four forward and four dye-swap) hybridizations. Three control cRNA probes were also generated from AB-strain embryos, namely: (1) whole 40% epiboly stage embryos, (2) FACS-sorted green cells from dissociated 40% epiboly embryos that were Kaede-injected but NOT photolabeled and (3) FACS-sorted red cells from dissociated 40% epiboly embryos that were Kaede-injected AND photolabeled. These probes were each generated three times, each time including a dye swap and co-hybridized as follows: (1) whole embryo cRNA vs green cell cRNA (three forward and three dye-swap hybridiizations) and (2) green cell cRNA vs. red cell cRNA (three forward and three dye-swap hybridizations).

Project description:Single-cell RNA sequencing of the caudal lateral epiblast and underlying mesoderm region of early headfold wild type embryos

Project description:Expression profiling of D. melanogaster embryos expressing bagpipe ectopically in the mesoderm, measured in a timecourse of embryogenesis. Three one-hour timepoints were assayed (3.5-4.5, 4.5-5.5, 5.5-6.5 hrs after egg laying). Homozygous ectopically expressing embryos were collected using from a large scale cross of UAS-bin and twist-Gal4, 24B-Gal4 flies, in parallel to stage-matched controls. Four independent collections were performed at each timepoint. Total RNA was extracted and amplified. Ectopically expression and respective reference samples were hybridized together on INDAC oligo-arrays.

Project description:ES cells are differentiated into mesenderm cell linage by Activin A treatment. During this differentaition, gene expression profile of ES cells, day 4 mesendoderm cell, day 5 mesendoderm cells and mesoderm cells are examined.

Project description:Around implantation, the epiblast transits from naïve to primed pluripotency, before giving rise to the three germ layers. How chromatin is reconfigured during this developmental window remains poorly understood. We performed a genome-wide investigation of chromatin landscapes during this period. We find that enhancers in ectoderm are already pre-accessible in embryonic day 6.5 (E6.5) Epi when cells enter a primed pluripotent state. Unexpectedly, strong H3K4me3 emerges at developmental gene promoters in E6.5 epiblast and positively correlates with H3K27me3, thus establishing bivalency. These genes also show enhanced spatial interactions. Both the strong bivalency and spatial clustering are virtually absent in preimplantation embryos and are markedly reduced in fate-committed lineages. Finally, we show that KMT2B is essential for establishing bivalent H3K4me3 at E6.5 but becomes partially dispensable later. Its deficiency leads to impaired activation of developmental genes and subsequent embryonic lethality. Thus, our data characterize lineage-specific chromatin reconfiguration and a unique chromatin state for primed pluripotency.