The Role of Nodal Processing in Pluripotent Progenitors

Nodal and its co-receptors of the EGF-CFC family are essential during chordate development, both to maintain pluripotent progenitor cells and to subsequently coordinate their allocation to the different germ layers. How these distinct Nodal activities are kept in balance is unknown. Previous work in our laboratory established that the Nodal proprotein must be cleaved by proprotein convertases (PC) to induce itself on time in the mouse epiblast. However, expression of a knock-in allele encoding a PC-resistant mutant Nodal precursor (Nr) is sufficient to induce a subset of Nodal target genes during gastrulation, including Fgf4 in the epiblast, and Bmp4 in extraembryonic ectoderm (ExE). Here, I extend these findings by showing that these NodalNr/Nr embryos also partially maintain a panel of trophoblast stem cell (TSC) markers. To better define how Nodal maintains pluripotency and how it might signal to TSCs in the ExE, and as a means to genetically uncouple Nodal production from processing, I treated cultured TSCs and NodallacZ/lacZ embryonic stem cells (ESCs) with recombinant Nodal or with cleavage-resistant mutant Nodal precursor. I show that recombinant mature Nodal stimulates Smad2 phosphorylation in both ESCs and TSCs, even though the latter do not express Nodal coreceptors of the EGF-CFC family. In contrast, recombinant Nr failed to activate the canonical Smad pathway in either cell type, and hence preferentially stimulated Jnk and p38 MAPK signaling. Yet, none of these activities were sufficient to promote self-renewal of mouse ESCs or TSCs under any of the culture conditions examined. Using lentiviral overexpression of constitutively active receptors with mutations in the Smad2,3 binding site, I observed that TSC stemness apparently can be maintained independently of Smad2,3 activation. These results suggest that mature Nodal or its unprocessed precursor likely promote the self-renewal of TSCs in vivo through a non-canonical, Smad-independent signaling pathway, but that available recombinant proteins for unknown reasons cannot fully mimic this activity in vitro, at least under the conditions examined.

Definition of in Vitro Microenvironments to Characterize and Control Pancreatic Progenitor Expansion and Differentiation

Chiara Greggio

The pancreas plays a central role in metabolism. The exocrine pancreas, composed of ductal and acinar cells, secretes and delivers digestive enzymes into the duodenum where they contribute to food digestion. The endocrine pancreas, constituted by the islets of Langerhans, secretes hormones in the blood to control glucose levels. In particular, insulin is the hormone produced by β-cells that instructs the peripheral tissues to uptake circulating glucose. Diabetes mellitus is a heterogeneous disease characterized by deregulated glucose homeostasis due to an impaired insulin function. The advancements in clinical practice have made of diabetes a chronic, instead of a lethal, disease; yet no definitive cure is available. Beta-cell transplantation offers promising results, especially for type 1 diabetes where β-cells are selectively eliminated by an autoimmune attack. Unfortunately its application suffers from the scarcity of transplantable pancreas/islets from cadaveric donors. Human embryonic stem cells (ESCs) or induced pluripotent stem cells (iPSCs) would constitute unlimited sources of transplantable β-cells, but the available differentiation protocols are not yet optimal, especially with regards to the numbers and the functionality of the generated β-cells. It is anticipated that a stepwise protocol would succeed in generating mature β-cells in vitro if it is capable of fully mimicking the embryonic development of these cells. Many aspects of pancreatic organogenesis have been elucidated and could serve as a guide for driving the commitment to β-cells. Unfortunately, pancreatic progenitors in vitro do not behave as in the intricate context of an embryo. This severely limits both the understanding of pancreatic development at the single-cell level and our ability in manipulating the process. The aim of our work was to develop in vitro methodologies to sustain pancreatic progenitor culture and expansion and to establish conditions to manipulate their progeny. To this aim, we combined an informed approach based on developmental biology and an empirical one. We first observed that pancreatic epithelial explants from embryonic day 10.5 mice could be cultured in presence of Matrigel™ and exogenous FGFs even in the absence of the mesenchyme that normally surrounds the epithelium. Notably, the removal of mesenchyme did not affect the endocrine commitment pattern of pancreatic progenitors. We then defined culture conditions allowing for the expansion of dissociated embryonic pancreatic progenitors in a three-dimensional Matrigel™-based environment. Under these conditions, progenitors proliferated and self-organized to generate pancreatic organoids containing both progenitors and differentiated cells, mostly exocrine, after 7 days of culture. When grafted into recipient pancreatic explants, the cultured progenitors contributed to the three epithelial pancreatic lineages (ductal, endocrine, acinar), integrating seamlessly into the endogenous cellular network. Thus, cultured progenitors retained their potential to differentiate into endocrine cells, but expressed it only in the appropriate niche. Subsequent removal of single components from the culture system led to the identification of some essential requirements for the maintenance/expansion of dissociated pancreatic progenitors, such as a strong FGF signaling and the Rho-associated kinase (ROCK) inhibitor Y-27632. In addition to this, we observed that only small clusters of pancreatic progenitors, but not single cells, were able to generate pancreatic organoids, suggesting a pivotal role for intercellular signaling in progenitor maintenance and expansion. By manipulating the components of the medium, we could affect fate commitment. In particular, the removal of FGF1 increased the yield of endocrine cells generated in vitro. In our search for a full control over the in vitro niche, we explored chemically defined matrices to replace Matrigel™. We showed that pancreatic progenitors could be cultured on laminin-functionalized hydrogels, although less efficiently than in Matrigel™. Moreover, differentiation into exocrine and endocrine cells occurred spontaneously under these conditions. By comparing Matrigel™, hydrogel microwells and two-dimensional culture systems, we uncovered the importance of a tridimensional architecture for pancreatic progenitor maintenance. We showed that pancreatic progenitors lost their identity as they flattened onto 2D surfaces, whereas 3D culture systems maintained the epithelial character of pancreatic progenitors and allowed the acquisition of apical polarization. To conclude, our work provides the first detailed characterization of in vitro culture systems for expansion and manipulation of dissociated embryonic pancreatic progenitors. Further implementation will hopefully allow the establishment of a fully-defined in vitro niche for developing pancreas with potential fundamental implications for the expansion of ES-derived pancreatic progenitors and their differentiation into functional β-cells.

EPFL2011

Quantitative analysis of SOX2 and OCT4 expression in pluripotency and differentiation

Daniel Strebinger

Embryonic stem (ES) cells have the capacity to give rise to all cell types of the adult organism and can be used as a model to study early cell fate decisions as they closely recapitulate in vivo events. The M and G1 phases have been suggested to be the key time windows for pluripotent cells to engage toward differentiation and SOX2 and OCT4 have been shown to orchestrate the dissolution of pluripotency and induction of cell fate commitment. Furthermore, it is known that the levels of some pluripotency transcription factors fluctuate over time, leading to the notion that ES cells experience dynamic heterogeneity, where for example low levels of NANOG can be found in cells prone to differentiation, whereas cells with high NANOG expression are in a robust pluripotent state. However, it remains unclear if and how (i) the action of transcription factors in specific cell cycle phases and (ii) protein level variations of factors that show mild differences between single cells impact cell fate decisions. This is in part due to the lack of quantitative single-cell meth-ods allowing dissecting the origin and functional consequences of gene expression heterogeneity. In this work, we established a method based on internal tagging of endogenous proteins with an excisable reporter to perform absolute molecule quantification in single living cells. This enabled us to investigate fluctuations of endogenous protein expression levels, the heterogeneity of degradation rates between individual cells and determine absolute amounts of proteins synthesized over the cell cycle. Additionally, inducible excision of the tag enabled us to estimate endogenous mRNA half-lives. Next, by using live-cell microscopy of fusion proteins, we show that SOX2 and OCT4 stay bound to mitotic chromosomes through their DNA binding domains. We then characterized the function of SOX2 at the M-G1 transition, showing that its absence specifically in this phase impairs pluripotency maintenance and abolishes its ability to induce neuroectodermal commitment. This suggests, that transcription factor activity at the M-G1 transition is essential for cell fate maintenance and differentiation. Lastly, we show that mild endogenous fluctuations in the levels of key transcription factors in ES cells bias cell fate decisions. We found that high OCT4 levels at the onset of differentiation increase the probability of single cells to commit to both neuroectoderm and mesendoderm. Further, we showed that high SOX2 levels result in a higher number of cells acquiring a neuroectodermal cell fate. This not only shows that the differentiation potential of embryonic stem cells is highly sensitive to small variations in intracellular concentrations of pluripotency transcription factors but further suggests that endogenous fluctuations of these are a major source of heterogeneity in cell fate decisions. In conclusion, the presented work identifies that the SOX2 activity in the M-G1 transition is important for cell fate maintenance and differentiation. Furthermore, the heterogeneity of protein levels governs cell fate decisions, suggesting the existence of different short-lived cell states in populations of presumed homogenous cells. We think that the minor differences in the levels of transcription factors and the cell cycle specific sensitivity of cells to transcription factor activity could be important mechanisms guiding maintenance and differentiation potential in various stem cell types.

EPFL2018

Definition of in Vitro Microenvironments to Characterize and Control Pancreatic Progenitor Expansion and Differentiation

Chiara Greggio

EPFL2011

Quantitative analysis of SOX2 and OCT4 expression in pluripotency and differentiation

Daniel Strebinger

EPFL2018