Abstract
Human dermal fibroblasts can be reprogrammed into hepatocyte-like (HEP-L) cells by the expression of a set of transcription factors. Yet, the metabolic rewiring suffered by reprogrammed fibroblasts remains largely unknown. Here we report, using stable isotope-resolved metabolic analysis in combination with metabolomic-lipidomic approaches that HEP-L cells mirrors glutamine/glutamate metabolism in primary cultured human hepatocytes that is very different from parental human fibroblasts. HEP-L cells diverge glutamine from multiple metabolic pathways into deamidation and glutamate secretion, just like periportal hepatocytes do. Exceptionally, glutamine contribution to lipogenic acetyl-CoA through reductive carboxylation is increased in HEP-L cells, recapitulating that of primary cultured human hepatocytes. These changes can be explained by transcriptomic rearrangements of genes involved in glutamine/glutamate metabolism. Although metabolic changes in HEP-L cells are in line with reprogramming towards the hepatocyte lineage, our conclusions are limited by the fact that HEP-L cells generated do not display a complete mature phenotype. Nevertheless, our findings are the first to characterize metabolic adaptation in HEP-L cells that could ultimately be targeted to improve fibroblasts direct reprogramming to HEP-L cells.
Highlights
Human dermal fibroblasts can be reprogrammed into hepatocyte-like (HEP-L) cells by the expression of a set of transcription factors
To obtain a broad picture of the metabolic changes induced after reprogramming to hepatocyte-like cells (HEP-L) cells, we performed an untargeted metabolite profiling of cell media incubated for 24 hours with Human dermal fibroblasts (HDF) or HEP-L cells
Direct conversion of human fibroblasts to HEP-L cells can be achieved by expression of a specific set of transcription factors[2]
Summary
Human dermal fibroblasts can be reprogrammed into hepatocyte-like (HEP-L) cells by the expression of a set of transcription factors. Glutamine contribution to lipogenic acetyl-CoA through reductive carboxylation is increased in HEP-L cells, recapitulating that of primary cultured human hepatocytes. These changes can be explained by transcriptomic rearrangements of genes involved in glutamine/glutamate metabolism. Periportal hepatocytes deamidate ammonia by a liver-specific glutaminase (GLS2), not inhibited by glutamate concentration[8,9], releasing ammonia and glutamate, the latter being partially secreted Glutamate generated by these upstream periportal hepatocytes is in part captured by perivenous hepatocytes coupled to glutamine synthesis and release, supporting an interorgan glutamine flux[10,11]. We detect lower rate of reductive carboxylation attributed to an incomplete metabolic rewiring of reprogrammed HEP-L cells
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