by Keyword: Kidney disease

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Dhillon, Poonam, Park, Jihwan, Hurtado del Pozo, Carmen, Li, Lingzhi, Doke, Tomohito, Huang, Shizheng, Zhao, Juanjuan, Kang, Hyun Mi, Shrestra, Rojesh, Balzer, Michael S., Chatterjee, Shatakshee, Prado, Patricia, Han, Seung Yub, Liu, Hongbo, Sheng, Xin, Dierickx, Pieterjan, Batmanov, Kirill, Romero, Juan P., Prósper, Felipe, Li, Mingyao, Pei, Liming, Kim, Junhyong, Montserrat, Nuria, Susztak, Katalin, (2020). The nuclear receptor ESRRA protects from kidney disease by coupling metabolism and differentiation Cell Metabolism In Press, Corrected Proof

Kidney disease is poorly understood because of the organ’s cellular diversity. We used single-cell RNA sequencing not only in resolving differences in injured kidney tissue cellular composition but also in cell-type-specific gene expression in mouse models of kidney disease. This analysis highlighted major changes in cellular diversity in kidney disease, which markedly impacted whole-kidney transcriptomics outputs. Cell-type-specific differential expression analysis identified proximal tubule (PT) cells as the key vulnerable cell type. Through unbiased cell trajectory analyses, we show that PT cell differentiation is altered in kidney disease. Metabolism (fatty acid oxidation and oxidative phosphorylation) in PT cells showed the strongest and most reproducible association with PT cell differentiation and disease. Coupling of cell differentiation and the metabolism was established by nuclear receptors (estrogen-related receptor alpha [ESRRA] and peroxisomal proliferation-activated receptor alpha [PPARA]) that directly control metabolic and PT-cell-specific gene expression in mice and patient samples while protecting from kidney disease in the mouse model.

Keywords: Single-cell RNA sequencing, Single-cell ATAC sequencing, Kidney, Fibrosis, Organoids, Fatty-acid oxidation, PPARA, ESRRA, Proximal tubule cells, Chronic kidney disease

Montserrat, N., Garreta, E., Izpisua Belmonte, J. C., (2016). Regenerative strategies for kidney engineering FEBS Journal , 283, (18), 3303-3324

The kidney is the most important organ for water homeostasis and waste excretion. It performs several important physiological functions for homeostasis: it filters the metabolic waste out of circulation, regulates body fluid balances, and acts as an immune regulator and modulator of cardiovascular physiology. The development of in vitro renal disease models with pluripotent stem cells (both human embryonic stem cells and induced pluripotent stem cells) and the generation of robust protocols for in vitro derivation of renal-specific-like cells from patient induced pluripotent stem cells have just emerged. Here we review major findings in the field of kidney regeneration with a major focus on the development of stepwise protocols for kidney cell production from human pluripotent stem cells and the latest advances in kidney bioengineering (i.e. decellularized kidney scaffolds and bioprinting). The possibility of generating renal-like three-dimensional structures to be recellularized with renal-derived induced pluripotent stem cells may offer new avenues to develop functional kidney grafts on-demand.

Keywords: Induced pluripotent stem cells, Kidney disease, Kidney engineering, Pluripotent stem cells, Renal differentiation