Segregation of brain and organizer precursors is differentially regulated by Nodal signaling at blastula stage

ABSTRACTThe blastula Chordin- and Noggin-expressing (BCNE) center comprises animal-dorsal and marginal-dorsal cells of the amphibian blastula and contains the precursors of the brain and the gastrula organizer. Previous findings suggested that the BCNE behaves as a homogeneous cell population that only depends on nuclear β-catenin activity but does not require Nodal and later segregates into its descendants during gastrulation. In contrast to previous findings, in this work, we show that the BCNE does not behave as a homogeneous cell population in response to Nodal antagonists. In fact, we found that chordin.1 expression in a marginal subpopulation of notochordal precursors indeed requires Nodal input. We also establish that an animal BCNE subpopulation of cells that express both, chordin.1 and sox2 (a marker of pluripotent neuroectodermal cells), and gives rise to most of the brain, persisted at blastula stage after blocking Nodal. Therefore, Nodal signaling is required to define a population of chordin.1+ cells and to restrict the recruitment of brain precursors within the BCNE as early as at blastula stage. We discuss our findings in Xenopus in comparison to other vertebrate models, uncovering similitudes in early brain induction and delimitation through Nodal signaling.This article has an associated First Person interview with the first author of the paper.

Segregation of brain and organizer precursors is differentially regulated by Nodal signaling at blastula stage

ABSTRACTThe Blastula Chordin- and Noggin Expressing Center (BCNE) comprises animal-dorsal and marginal-dorsal cells of the amphibian blastula and contains the precursors of the brain and of the gastrula organizer. Previous findings suggested that the BCNE behaves as a homogeneous cell population that depends only on nuclear β-catenin activity but does not require Nodal and segregates into its descendants later, during gastrulation. In this work, we analyzed if the BCNE is already compartmentalized at the blastula stage. In contrast to previous findings, we show that the BCNE does not behave as a homogeneous cell population in response to Nodal antagonists. In fact, we found that the chordin.1 expression in a marginal subpopulation of notochordal precursors indeed requires Nodal input. We also establish that an animal BCNE subpopulation of cells that express both, chordin.1 and sox2 (a marker of pluripotent neuroectodermal cells), and gives rise to most of the brain, persisted at blastula stage after blocking Nodal. Moreover, RT-qPCR analysis showed that chordin.1 and sox2 expression increased at blastula stage after blocking Nodal. Therefore, Nodal signaling is required to define a population of chordin.1+ cells and to restrict the recruitment of brain precursors within the BCNE as early as at blastula stage.

Transcriptome Remodeling of Differentiated Cells during Chronological Ageing of Yeast Colonies: New Insights into Metabolic Differentiation

We present the spatiotemporal metabolic differentiation of yeast cell subpopulations from upper, lower, and margin regions of colonies of different ages, based on comprehensive transcriptomic analysis. Furthermore, the analysis was extended to include smaller cell subpopulations identified previously by microscopy within fully differentiated U and L cells of aged colonies. New data from RNA-seq provides both spatial and temporal information on cell metabolic reprogramming during colony ageing and shows that cells at marginal positions are similar to upper cells, but both these cell types are metabolically distinct from cells localized to lower colony regions. As colonies age, dramatic metabolic reprogramming occurs in cells of upper regions, while changes in margin and lower cells are less prominent. Interestingly, whereas clear expression differences were identified between two L cell subpopulations, U cells (which adopt metabolic profiles, similar to those of tumor cells) form a more homogeneous cell population. The data identified crucial metabolic reprogramming events that arise de novo during colony ageing and are linked to U and L cell colony differentiation and support a role for mitochondria in this differentiation process.

Gene expression in derivatives of embryonic foregut during prenatal development of the rat.

Proteins characteristic for the adult cellular phenotype, i.e., carbamoylphosphate synthetase (CPS) for liver and small intestine, arginase for liver, glutamate dehydrogenase (GLDH) for pancreas, liver, and small intestine, and amylase for pancreas were studied immunohistochemically in rat embryos and fetuses. At distinct developmental stages, subsets of enzymes appear synchronously in the foregut derivatives, suggesting that gene expression in the different organs is regulated by common factors. In contrast to the long-held opinion that fetal hepatocytes are a homogeneous cell population, it is shown that arginase and CPS are heterogeneously distributed between ED 16 and ED 20. This heterogeneity is related to the vascular architecture of the liver and disappears perinatally as the result of strong stimulation of enzyme synthesis. In addition, an intercellular heterogeneity in CPS content that is not related to the vasculature is observed between ED 14 and ED 20. This "random" heterogeneity reflects temporal differences in the onset of CPS accumulation in individual cells.

Genetic differences in the histochemically defined structure of oligosaccharides in mice.

A wide range of tissues from three interfertile species of mice and an interspecific hybrid was examined with lectins conjugated to peroxidase to localize specifically glycoconjugates containing terminal alpha-N-acetylgalactosamine, alpha-galactose, and alpha-fucose, and the terminal disaccharide galactose-(beta 1----3)-N-acetylgalactosamine. This battery of lectins disclosed marked heterogeneity of glycoconjugates in different histological sites in a given animal and even between cells in a presumably homogeneous cell population within an organ. No variation with any lectin was observed between individuals of two closely related inbred strains of Mus domesticus at any specific histological or cytological site. In contrast, littermates of an outbred strain of Mus castaneus differed in binding of certain lectins at various sites, attesting to a genetic basis for individual variation. Hybrids between castaneus and domesticus mice also showed individual variation. Moreover, extensive differences between the mouse species were demonstrable with every lectin in glycoconjugates of stored secretions, Golgi cisternae, and apical or basolateral plasmalemma in many cell types. Totaling the differences in tabulated staining intensities for each possible species pair gave a measure of the overall extent of difference at 53 histological sites. According to this measure, the three species are about equally divergent from one another. Some differences between species appeared to depend on histological rather than histochemical variation, as, for example, a greater abundance of granular duct cells in the sublingual and submandibular glands in Mus hortulanus. Other differences were apparently derived from pathological change, as exemplified by casts and lymphoid infiltrates in kidney and structurally atypical submandibular gland lobules in Mus castaneus, and possibly by infiltrating cells in intestinal lamina propria and epithelium in Mus castaneus and hortulanus.