Alternatively activated macrophages promotes necrosis resolution following acute liver injury

Background & Aim Following acetaminophen (APAP) overdose, acute liver injury (ALI) can occur in patients that present too late for N-acetylcysteine treatment, potentially leading to acute liver failure, systemic inflammation, and death. Macrophages influence the progression and resolution of ALI due to their innate immunological function and paracrine activity. Syngeneic primary bone marrow-derived macrophages (BMDMs) were tested as a cell-based therapy in a mouse model of APAP-induced ALI (APAP-ALI). Methods Several phenotypically distinct BMDM populations were delivered intravenously to APAP-ALI mice when hepatic necrosis was established, and then evaluated based on their effects on injury, inflammation, immunity, and regeneration. In vivo phagocytosis assays were used to interrogate the phenotype and function of alternatively activated BMDMs (AAMs) post-injection. Finally, primary human AAMs sourced from healthy volunteers were evaluated in immunocompetent APAP-ALI mice. Results BMDMs rapidly localised to the liver and spleen within 4 h of administration. Injection of AAMs specifically reduced hepatocellular necrosis, HMGB1 translocation, and infiltrating neutrophils following APAP-ALI. AAM delivery also stimulated proliferation in hepatocytes and endothelium, and reduced levels of several circulating proinflammatory cytokines within 24 h. AAMs displayed a high phagocytic activity both in vitro and in injured liver tissue post-injection. Crosstalk with the host innate immune system was demonstrated by reduced infiltrating host Ly6Chi macrophages in AAM-treated mice. Importantly, therapeutic efficacy was partially recapitulated using clinical-grade primary human AAMs in immunocompetent APAP-ALI mice, underscoring the translational potential of these findings. Conclusion We identify that AAMs have value as a cell-based therapy in an experimental model of APAP-ALI. Human AAMs warrant further evaluation as a potential cell-based therapy for APAP overdose patients with established liver injury. Lay summary After an overdose of acetaminophen (paracetamol), some patients present to hospital too late for the current antidote (N-acetylcysteine) to be effective. We tested whether macrophages, an injury-responsive leukocyte that can scavenge dead/dying cells, could serve as a cell-based therapy in an experimental model of acetaminophen overdose. Injection of alternatively activated macrophages rapidly reduced liver injury and reduced several mediators of inflammation. Macrophages show promise to serve as a potential cell-based therapy for acute liver injury

Notch-IGF1 signalling in biliary epithelial cells drives their expansion and inhibits hepatocyte differentiation

[no abstract available

Senolytic treatment preserves biliary regenerative capacity lost through cellular senescence during cold storage

Liver transplantation is the only curative option for patients with end-stage liver disease. Despite improvements in surgical techniques, nonanastomotic strictures (characterized by the progressive loss of biliary tract architecture) continue to occur after liver transplantation, negatively affecting liver function and frequently leading to graft loss and retransplantation. To study the biological effects of organ preservation before liver transplantation, we generated murine models that recapitulate liver procurement and static cold storage. In these models, we explored the response of cholangiocytes and hepatocytes to cold storage, focusing on responses that affect liver regeneration, including DNA damage, apoptosis, and cellular senescence. We show that biliary senescence was induced during organ retrieval and exacerbated during static cold storage, resulting in impaired biliary regeneration. We identified decoy receptor 2 (DCR2)–dependent responses in cholangiocytes and hepatocytes, which differentially affected the outcome of those populations during cold storage. Moreover, CRISPR-mediated DCR2 knockdown in vitro increased cholangiocyte proliferation and decreased cellular senescence but had the opposite effect in hepatocytes. Using the p21KO model to inhibit senescence onset, we showed that biliary tract architecture was better preserved during cold storage. Similar results were achieved by administering senolytic ABT737 to mice before procurement. Last, we perfused senolytics into discarded human donor livers and showed that biliary architecture and regenerative capacities were better preserved. Our results indicate that cholangiocytes are susceptible to senescence and identify the use of senolytics and the combination of senotherapies and machine-perfusion preservation to prevent this phenotype and reduce the incidence of biliary injury after transplantation.This work was supported by the UK Medical Research MRC (MR/K017047/1) (to S.J.F.), the Computational and Chemical Biology of Stem Cell Niche (MR/L012766/1) (to S.J.F.), the UK Regenerative Medicine Platform (MR/K026666/1) (to S.J.F.), and the Wellcome Trust Institutional Translational Partnership Award (WT iTPA) (to S.F.-G.). J.M.B. was supported by the Spanish Carlos III Health Institute (ISCIII) (PI15/01132, PI18/01075, and Miguel Servet Program CON14/00129 and CPII19/00008) cofinanced by “Fondo Europeo de Desarrollo Regional” (FEDER); “Instituto de Salud Carlos III” (CIBERehd), Spain; “Euskadi RIS3” (2019222054 and 2020333010); and the Department of Industry of the Basque Country (Elkartek: KK-2020/00008). This research was funded in whole or in part by The Wellcome Trust (grant number 209710/Z/17/Z), a cOAlition S organization

Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration.

Following severe or chronic liver injury, adult ductal cells (cholangiocytes) contribute to regeneration by restoring both hepatocytes and cholangiocytes. We recently showed that ductal cells clonally expand as self-renewing liver organoids that retain their differentiation capacity into both hepatocytes and ductal cells. However, the molecular mechanisms by which adult ductal-committed cells acquire cellular plasticity, initiate organoids and regenerate the damaged tissue remain largely unknown. Here, we describe that ductal cells undergo a transient, genome-wide, remodelling of their transcriptome and epigenome during organoid initiation and in vivo following tissue damage. TET1-mediated hydroxymethylation licences differentiated ductal cells to initiate organoids and activate the regenerative programme through the transcriptional regulation of stem-cell genes and regenerative pathways including the YAP-Hippo signalling. Our results argue in favour of the remodelling of genomic methylome/hydroxymethylome landscapes as a general mechanism by which differentiated cells exit a committed state in response to tissue damage.RCUK Cancer Research UK ERC H2020 Wellcome Trus

Impaired hepatocyte regeneration confers lineage plasticity in the biliary epithelium: a study of the transcriptional heterogeneity within the biliary epithelium following injury

Chronic liver disease is a major global health burden, accounting for approximately 2 million deaths per year and the prevalence in the United Kingdom is ever-increasing. Currently the only definitive treatment option for patients suffering from chronic liver disease is orthotopic liver transplant. The shortage of suitable donor organs prompts the search for novel disease-modifying and curative therapies. Despite the varying aetiology, chronic liver disease is always characterised by compromised regenerative capacity of hepatocytes – the main functional cell types of the liver. Recent studies highlight the capacity for lineage plasticity of the biliary cells which can act as facultative liver progenitor cells and differentiate into hepatocytes to repair the damaged liver parenchyma. However, it is still unknown whether all biliary cells have a similar regenerative capacity, or a population of pre-committed progenitors exist in the liver. I hypothesise that in the damaged liver the biliary cells are transcriptionally heterogeneous and that differentiation of biliary cells into hepatocytes is underpinned by a modulation of a unique set of genes and signalling pathways. I utilised two established clinically relevant murine models of chronic liver disease to study the mechanisms that underpin the differential regenerative response following diet induced liver injury, depending on the proliferative capacity of the native hepatocytes. I employed bulk transcriptomic and scRNA-Seq technologies to study the transcriptional differences that arise in biliary cells isolated from these models. I identified populations of cells exclusively present in the models in which biliary to hepatocyte differentiation occurs. These results confirm that following liver injury, the biliary cells represent a heterogeneous population and reveal novel potential therapeutic targets that can inform cell therapy and drug discovery campaigns, seeking to develop innovative solutions for the treatment of chronic liver disease by enhancing the endogenous capacity of biliary cells to differentiate into hepatocytes on demand

TFEB regulates murine liver cell fate during development and regeneration.

It is well established that pluripotent stem cells in fetal and postnatal liver (LPCs) can differentiate into both hepatocytes and cholangiocytes. However, the signaling pathways implicated in the differentiation of LPCs are still incompletely understood. Transcription Factor EB (TFEB), a master regulator of lysosomal biogenesis and autophagy, is known to be involved in osteoblast and myeloid differentiation, but its role in lineage commitment in the liver has not been investigated. Here we show that during development and upon regeneration TFEB drives the differentiation status of murine LPCs into the progenitor/cholangiocyte lineage while inhibiting hepatocyte differentiation. Genetic interaction studies show that Sox9, a marker of precursor and biliary cells, is a direct transcriptional target of TFEB and a primary mediator of its effects on liver cell fate. In summary, our findings identify an unexplored pathway that controls liver cell lineage commitment and whose dysregulation may play a role in biliary cancer