Direct On-Chip Differentiation of Intestinal Tubules from Induced Pluripotent Stem Cells.

Intestinal organoids have emerged as the new paradigm for modelling the healthy and diseased intestine with patient-relevant properties. In this study, we show directed differentiation of induced pluripotent stem cells towards intestinal-like phenotype within a microfluidic device. iPSCs are cultured against a gel in microfluidic chips of the OrganoPlate, in which they undergo stepwise differentiation. Cells form a tubular structure, lose their stem cell markers and start expressing mature intestinal markers, including markers for Paneth cells, enterocytes and neuroendocrine cells. Tubes develop barrier properties as confirmed by transepithelial electrical resistance (TEER). Lastly, we show that tubules respond to pro-inflammatory cytokine triggers. The whole procedure for differentiation lasts 14 days, making it an efficient process to make patient-specific organoid tubules. We anticipate the usage of the platform for disease modelling and drug candidate screening.

Identification of Scopulariopsis species by partial 28S rRNA gene sequence analysis.

The genus Scopulariopsis contains over 30 species of mitosporic moulds, which although usually saprophytic may also act as opportunistic pathogens in humans. They have mainly been associated with onychomycosis, and only sporadically reported as a cause of deep tissue infections or systemic disease. Identification of Scopulariopsis species still largely relies on phenotype-based methods. There is a need for a molecular diagnostic approach, that would allow to reliably discriminate between different Scopulariopsis species. The aim of this study was to apply sequence analysis of partial 28S rRNA gene for species identification of Scopulariopsis clinical isolates. Although the method employed did reveal some genetic polymorphism among Scopulariopsis isolates tested, it was not enough for species delineation. For this to be achieved, other genetic loci, within and beyond the rDNA operon, need to be investigated.

Intestinal Epithelium Tubules on a Chip.

The study of epithelial barrier properties in the human body is of paramount interest to a range of disciplines, including disease modeling, drug transport studies, toxicology, developmental biology, and regenerative biology. Current day in vitro studies largely rely on growing epithelial cells in a static environment on membrane cell culture inserts. With the advancement of microfluidic and organ-on-a-chip techniques it became possible to culture 3D intestinal tubules directly against an extracellular matrix (ECM) under flow and without the need for artificial membranes. Here we describe detailed protocols for culturing epithelial tubules in a high-throughput format, assessing their permeability and marker expression. The platform harbors 40 independent microfluidic chips in a microtiter plate format. The resulting 40 epithelial tubules are analyzed in parallel using a high-content microscopy. Protocols described here allow for adoption and routine application of microfluidic techniques by nonspecialized end-users.

Single-cell transcriptomics reveals a new dynamical function of transcription factors during embryonic hematopoiesis.

Recent advances in single-cell transcriptomics techniques have opened the door to the study of gene regulatory networks (GRNs) at the single-cell level. Here, we studied the GRNs controlling the emergence of hematopoietic stem and progenitor cells from mouse embryonic endothelium using a combination of single-cell transcriptome assays. We found that a heptad of transcription factors (Runx1, Gata2, Tal1, Fli1, Lyl1, Erg and Lmo2) is specifically co-expressed in an intermediate population expressing both endothelial and hematopoietic markers. Within the heptad, we identified two sets of factors of opposing functions: one (Erg/Fli1) promoting the endothelial cell fate, the other (Runx1/Gata2) promoting the hematopoietic fate. Surprisingly, our data suggest that even though Fli1 initially supports the endothelial cell fate, it acquires a pro-hematopoietic role when co-expressed with Runx1. This work demonstrates the power of single-cell RNA-sequencing for characterizing complex transcription factor dynamics.

Activation of the TGFß pathway impairs endothelial to haematopoietic transition.

The endothelial to haematopoietic transition (EHT) is a key developmental process where a drastic change of endothelial cell morphology leads to the formation of blood stem and progenitor cells during embryogenesis. As TGFß signalling triggers a similar event during embryonic development called epithelial to mesenchymal transition (EMT), we hypothesised that TGFß activity could play a similar role in EHT as well. We used the mouse embryonic stem cell differentiation system for in vitro recapitulation of EHT and performed gain and loss of function analyses of the TGFß pathway. Quantitative proteomics analysis showed that TGFß treatment during EHT increased the secretion of several proteins linked to the vascular lineage. Live cell imaging showed that TGFß blocked the formation of round blood cells. Using gene expression profiling we demonstrated that the TGFß signalling activation decreased haematopoietic genes expression and increased the transcription of endothelial and extracellular matrix genes as well as EMT markers. Finally we found that the expression of the transcription factor Sox17 was up-regulated upon TGFß signalling activation and showed that its overexpression was enough to block blood cell formation. In conclusion we showed that triggering the TGFß pathway does not enhance EHT as we hypothesised but instead impairs it.