Biomedical research relies heavily on the use of model organisms to gain insight into human health and development. Traditionally, the mouse has been the favored vertebrate model, due to its experimental and genetic tractability. Non-rodent embryological studies however highlight that many aspects of early mouse development, including the egg-cylinder topology of the embryo and its method of implantation, diverge from other mammals, thus complicating inferences about human development. In this study, we constructed a morphological and molecular atlas of rabbit development, which like the human embryo, develops as a flat-bilaminar disc. We report transcriptional and chromatin accessibility profiles of almost 180,000 single cells and high-resolution histology sections from embryos spanning gastrulation, implantation, amniogenesis, and early organogenesis. Using a novel computational pipeline, we compare the transcriptional landscape of rabbit and mouse at the scale of the entire organism, revealing that extra-embryonic tissues, as well as gut and PGC cell types, are highly divergent between species. Focusing on these extra-embryonic tissues, which are highly accessible in the rabbit, we characterize the gene regulatory programs underlying trophoblast differentiation and identify novel signaling interactions involving the yolk sac mesothelium during hematopoiesis. Finally, we demonstrate how the combination of both rabbit and mouse atlases can be leveraged to extract new biological insights from sparse macaque and human data. The datasets and analysis pipelines reported here set a framework for a broader cross-species approach to decipher early mammalian development, and are readily adaptable to deploy single cell comparative genomics more broadly across biomedical research.
Traditionally, the mouse has been the favored vertebrate model for biomedical research, due to its experimental and genetic tractability. However, non-rodent embryological studies highlight that many aspects of early mouse development, such as its egg-cylinder gastrulation and method of implantation, diverge from other mammals, thus complicating inferences about human development. Like the human embryo, rabbits develop as a flat-bilaminar disc. In this study, we constructed a morphological and molecular atlas of rabbit development. We report transcriptional and chromatin accessibility profiles for over 180,000 single cells and highresolution histology sections from embryos spanning gastrulation, implantation, amniogenesis, and early organogenesis. Using a neighborhood comparison pipeline, we compare the transcriptional landscape of rabbit and mouse at the scale of the entire organism. We characterize the gene regulatory programs underlying trophoblast differentiation and identify signaling interactions involving the yolk sac mesothelium during hematopoiesis. We demonstrate how the combination of both rabbit and mouse atlases can be leveraged to extract new biological insights from sparse macaque and human data. The datasets and computational pipelines reported here set a framework for a broader cross-species approach to decipher early mammalian development, and are readily adaptable to deploy single cell comparative genomics more broadly across biomedical research.
Early organogenesis represents a key step in animal development, where pluripotent cells divide and diversify to initiate formation of all major organs. Here, we used scRNA-Seq to profile over 300,000 single cell transcriptomes sampled in 6 hour intervals from mouse embryos between E8.5 and E9.5. Combining this dataset with our previous E6.5 to E8.5 atlas resulted in a densely-sampled time course of over 400,000 cells from early gastrulation to organogenesis. Computational lineage reconstruction at full organismal scale identified complex waves of blood and endothelial development, including a new molecular programme for somite-derived endothelium. To assess developmental fates across the primitive streak, we dissected the E7.5 primitive streak into four adjacent regions, performed scRNA-Seq and predicted cell fates computationally. We next defined early developmental state/fate relationships experimentally by a combination of orthotopic grafting, microscopic analysis of graft contribution as well as scRNA-Seq to transcriptionally determine cell fates of the grafted primitive streak regions after 24h of in vitro embryo culture. Experimentally determined fate outcomes were in good agreement with the fates predicted computationally, thus demonstrating how classical grafting experiments can be revisited to establish high-resolution cell state/fate relationships. Such interdisciplinary approaches will benefit future studies in both developmental biology as well as guide the in vitro production of cells for organ regeneration and repair.
The evolutionary origin of the vertebrate brain is still a major subject of debate. Its distinctive dorsal position and development from a tubular neuroepithelium are unique to the chordate phylum. Conversely, apical organs (AO) are larval sensory/neurosecretory centers found in many invertebrate taxa, including in animals without a brain. Previous studies have shown that AOs are specified by a conserved set of genes under the influence of Wnt signalling. Although most of these genes are expressed in chordate nervous systems (including vertebrates), no AOs have ever been described in this group of animals. Here we have exploited single-cell genomic approaches to characterize cells showing AO profiles in sea urchin (ambulacrarian), amphioxus (invertebrate chordate) and zebrafish (vertebrate chordate). This, in combination with co-expression analysis in amphioxus embryos, has allowed us to identify an active and dynamic anterior Gene Regulatory Network (aGRN) in the three deuterostome species. We have further discovered that as well as controlling AO specification in sea urchin, this aGRN is involved in the formation of the hypothalamic region in amphioxus and zebrafish. Using a functional approach, we find that the aGRN is controlled by Wnt signalling in amphioxus, and that suppression of the aGRN by Wnt overactivation leads to a loss of forebrain cell types. The loss of the forebrain does not equate to a reduction of neuronal tissue, but to a loss of identity, suggesting a new role for Wnt in amphioxus in specifically positioning the forebrain. We thus propose that the aGRN is conserved throughout bilaterians and that in the chordate lineage was incorporated into the process of neurulation to position the brain, thereby linking the evolution of the AO to that of the chordate forebrain.
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