ABSTRACT
Metabolic dysfunction-associated steatotic liver disease (MASLD), formerly known as non-alcoholic fatty liver disease (NAFLD), is characterized by intrahepatic triglyceride accumulation and can progress to metabolic dysfunction-associated steatohepatitis (MASH) and liver fibrosis. Hepatic de novo lipogenesis (DNL), activated by glucose and insulin, is a central pathway contributing to early-stage development of MASLD. The emerging global prevalence of MASLD highlights the urgent need for pharmaceutical intervention to combat this health threat. However, the identification of novel drugs that could inhibit hepatic DNL is hampered by a lack of reliable, insulin-sensitive, human, in vitro, hepatic models. Here, we report human skin stem cell-derived hepatic cells (hSKP-HPC) as a unique in vitro model to study insulin-driven DNL (iDNL), evidenced by both gene expression and lipid accumulation readouts. Insulin-sensitive hSKP-HPC showed increased sterol regulatory element-binding protein 1c (SREBP-1c) expression, a key transcription factor for DNL. Furthermore, this physiologically relevant in vitro human steatosis model allowed both inhibition and activation of the iDNL pathway using reference inhibitors and activators, respectively. Optimisation of the lipid accumulation assay to a high-throughput, 384-well format enabled the screening of a library of annotated compounds, delivering new insights on key players in the iDNL pathway and MASLD pathophysiology. Together, these results establish the value of the hSKP-HPC model in preclinical development of antisteatotic drugs to combat MASLD.
Subject(s)
Insulin , Non-alcoholic Fatty Liver Disease , Humans , Insulin/metabolism , Lipogenesis/genetics , Liver/metabolism , Hepatocytes/metabolism , Non-alcoholic Fatty Liver Disease/drug therapy , Non-alcoholic Fatty Liver Disease/metabolism , Triglycerides/metabolism , Stem Cells/metabolismABSTRACT
Phospholipidosis is a metabolic disorder characterized by intracellular accumulation of phospholipids. It can be caused by short-term or chronic exposure to cationic amphiphilic drugs (CADs). These compounds bind to phospholipids, leading to inhibition of their degradation and consequently to their accumulation in lysosomes. Drug-induced phospholipidosis (DIPL) is frequently at the basis of discontinuation of drug development and post-market drug withdrawal. Therefore, reliable human-relevant in vitro models must be developed to speed up the identification of compounds that are potential inducers of phospholipidosis. Here, hepatic cells derived from human skin (hSKP-HPC) were evaluated as an in vitro model for DIPL. These cells were exposed over time to amiodarone, a CAD known to induce phospholipidosis in humans. Transmission electron microscopy revealed the formation of the typical lamellar inclusions in the cell cytoplasm. Increase of phospholipids was already detected after 24â¯h exposure to amiodarone, whereas a significant increase of neutral lipid vesicles could be observed after 72â¯h. At the transcriptional level, the modulation of genes involved in DIPL was detected. These results provide a valuable indication of the applicability of hSKP-HPC for the quick assessment of drug-induced phospholipidosis in vitro, early in the drug development process.
Subject(s)
Drug Evaluation, Preclinical/methods , Hepatocytes/drug effects , Lipidoses/chemically induced , Phospholipids/metabolism , Skin/cytology , Stem Cells/cytology , Amiodarone/toxicity , Cell Differentiation/drug effects , Cells, Cultured , Drug-Related Side Effects and Adverse Reactions , Flow Cytometry , Gene Expression/drug effects , Hep G2 Cells , Hepatocytes/ultrastructure , Humans , Lipidoses/genetics , Lysosomes/drug effects , Lysosomes/metabolism , Male , Phospholipids/geneticsABSTRACT
The umbilical cord (UC) represents an important source of mesenchymal stem cells (MSC). These human UC-derived MSC (UC-MSC) have already been isolated using a protocol based on the migratory and plastic adhesive properties of MSC (UC-MSC-Mig). The UC-MSC-Mig isolation method, however, is difficult to standardize. Therefore, we developed an enzymatic isolation protocol (UC-MSC-Enz) to overcome the above mentioned disadvantages. First, we investigated the UC-MSC-Enz for their MSC properties. We found that UC-MSC-Enz express the MSC markers CD73, CD90 and CD105 and are able to differentiate into osteoblasts, adipocytes and chondroblasts fulfilling the MSC criteria of the International Society for Cellular Therapy. Previously we found that UC-MSC-Mig are unique among MSCs due to their significant expression of several hepatic (progenitor) markers. Therefore, we also investigated the expression of hepatic transcription factors and other hepatic markers in UC-MSC-Enz at both the mRNA and protein level. We found that the expression of hepatic transcription factors (GATA4, GATA6, SOX9 and SOX17) and hepatic markers (AFP, DPP4, CX43, DKK1, DSG2, KRT18 and KRT19) in UC-MSC-Enz was not significantly different from those of UC-MSC-Mig. Consequently, this optimized enzyme-based method represents a fast, robust and standardized way to isolate UC-MSC for a broad range of applications.