par Eski, Sema Elif 
;Mi, Jiarui;Pozo Morales, Macarena ;Hovhannisyan, Garnik ;Perazzolo, Camille ;Manco, Rita;Ez-Zammoury, Imane;Barbhaya, Dev;Lefort, Anne ;Libert, Frédérick ;Marini, F.;Gurzov, Esteban Nicolas ;Andersson, Olov;Singh, Sumeet Pal
Référence Nature communications, 16, 1, page (5260)
Publication Publié, 2025-06-01
;Mi, Jiarui;Pozo Morales, Macarena ;Hovhannisyan, Garnik ;Perazzolo, Camille ;Manco, Rita;Ez-Zammoury, Imane;Barbhaya, Dev;Lefort, Anne ;Libert, Frédérick ;Marini, F.;Gurzov, Esteban Nicolas ;Andersson, Olov;Singh, Sumeet Pal Référence Nature communications, 16, 1, page (5260)
Publication Publié, 2025-06-01
Article révisé par les pairs
| Résumé : | The liver's regenerative ability depends on injury extent. Minor injuries are repaired by hepatocyte self-duplication, while severe damage triggers cholangiocyte involvement in hepatocyte recovery. This paradigm is well-documented for adult animals but is less explored during rapid growth. We design two partial liver injury models in zebrafish, which were investigated during growth spurts: 1) partial ablation, killing half the hepatocytes; and 2) partial hepatectomy, removing half a liver lobe. In both injuries, de novo hepatocytes emerged alongside existing ones. Single-cell transcriptomics and lineage tracing with Cre-driver lines generated by genome editing identified cholangiocytes as the source of de novo hepatocytes. We further identify active mTORC1 signalling in the uninjured liver of growing animal to be a regulator of the enhanced plasticity of cholangiocytes. Our study suggests cholangiocyte-to-hepatocyte transdifferentiation as the primary mechanism of liver regeneration during periods of rapid growth. |
