The Influence of the Flow of Detergent and Donor Characteristics on the Extracellular Matrix Composition After Human Pancreas Decellularization.

INTRODUCTION: The extracellular matrix (ECM) consists, among others, of polysaccharides, glycosaminoglycans, and proteins. It is being increasingly used in tissue bioengineering. Obtaining ECM of the highest quality through decellularization is a big challenge because of some differences in organ structure. To deprive organs of the cellular part, chemical, enzymatic, or mechanical methods are used. After decellularization, we get a scaffold made of a variety of proteins, and it is the role of these proteins that can significantly affect the maintenance of the spatial structure and be a suitable environment for cells to rebuild a specific organ. AIM: Estimation of the detergent (Triton X-100) flow parameters and anthropometric donors' decellularization process accuracy on the final ECM composition. MATERIALS: Five human pancreata, rejected from transplantation, were used for decellularization. All organs were harvested from brain-dead donors age 13 to 60 years. METHODS: Decellularization was carried out using the flow method with Triton X-100 as an active agent. The experiment compared 5 different flow values. After decellularization, an assessment of the final DNA concentration and the protein composition was performed. Results were compared to anthropometric data of donors. In addition, a microscopic analysis was also carried out. RESULTS: The best results were obtained using a flow of 120 mL/minute. A higher detergent flow was associated with a lower concentration of residual DNA in scaffold. Analysis of the protein profile with anthropometric data has shown that LAM A2 was increasing with age and LAMA5 was decreasing. Being overweight was associated with a higher proportion of COL1 and 4 and a smaller proportion of COL6.

miR-34/449 control apical actin network formation during multiciliogenesis through small GTPase pathways.

Vertebrate multiciliated cells (MCCs) contribute to fluid propulsion in several biological processes. We previously showed that microRNAs of the miR-34/449 family trigger MCC differentiation by repressing cell cycle genes and the Notch pathway. Here, using human and Xenopus MCCs, we show that beyond this initial step, miR-34/449 later promote the assembly of an apical actin network, required for proper basal bodies anchoring. Identification of miR-34/449 targets related to small GTPase pathways led us to characterize R-Ras as a key regulator of this process. Protection of RRAS messenger RNA against miR-34/449 binding impairs actin cap formation and multiciliogenesis, despite a still active RhoA. We propose that miR-34/449 also promote relocalization of the actin binding protein Filamin-A, a known RRAS interactor, near basal bodies in MCCs. Our study illustrates the intricate role played by miR-34/449 in coordinating several steps of a complex differentiation programme by regulating distinct signalling pathways.