Affiliation:
1. CNRS IRL 2820 Laboratory for Integrated Micro Mechatronic Systems Institute of Industrial Science University of Tokyo Tokyo Japan
2. Department of Chemical System Engineering Graduate School of Engineering University of Tokyo Tokyo Japan
3. Institute of Industrial Science University of Tokyo Tokyo Japan
4. CNRS UMR 7338 Laboratoire de Biomécanique et Bioingénierie Sorbonne Universités Université de Technologies de Compiègne Compiègne France
5. LMI CNRS UMR5615 Université Lyon 1 Villeurbanne France
6. Plateforme Protéomique 3P5 Université de Paris Institut Cochin INSERM CNRS Paris France
7. Laboratory of Cell Growth and Differentiation Institute for Quantitative Biosciences The University of Tokyo Tokyo Japan
Abstract
AbstractAimHepatic zonation is a physiological feature of the liver, known to be key in the regulation of the metabolism of nutrients and xenobiotics and the biotransformation of numerous substances. However, the reproduction of this phenomenon remains challenging in vitro as only part of the processes involved in the orchestration and maintenance of zonation are fully understood. The recent advances in organ‐on‐chip technologies, which allow for the integration of multicellular 3D tissues in a dynamic microenvironment, could offer solutions for the reproduction of zonation within a single culture vessel.MethodsAn in‐depth analysis of zonation‐related mechanisms observed during the coculture of human‐induced pluripotent stem cell (hiPSC)‐derived carboxypeptidase M‐positive liver progenitor cells and hiPSC‐derived liver sinusoidal endothelial cells within a microfluidic biochip was carried out.ResultsHepatic phenotypes were confirmed in terms of albumin secretion, glycogen storage, CYP450 activity, and expression of specific endothelial markers such as PECAM1, RAB5A, and CD109. Further characterization of the patterns observed in the comparison of the transcription factor motif activities, the transcriptomic signature, and the proteomic profile expressed at the inlet and the outlet of the microfluidic biochip confirmed the presence of zonation‐like phenomena within the biochips. In particular, differences related to Wnt/β‐catenin, transforming growth factor‐β, mammalian target of rapamycin, hypoxia‐inducible factor‐1, and AMP‐activated protein kinase signaling, to the metabolism of lipids, and cellular remolding were observed.ConclusionsThe present study shows the interest in combining cocultures of hiPSC‐derived cellular models and microfluidic technologies for reproducing in vitro complex mechanisms such as liver zonation and further incites the use of those solutions for accurate reproduction of in vivo situations.
Subject
Infectious Diseases,Hepatology