Project description:Cellular senescence is associated with aging but also impacts various physiological and pathological processes such as embryonic development and wound healing. Factors secreted by senescent cells can affect their microenvironment, including local spreading of senescence. Acute severe liver disease is associated with hepatocyte senescence and frequently progresses to multi-organ failure. Why the latter occurs is poorly understood however, the presence of hepatic senescence is associated with poor prognosis and extrahepatic organ failure in acute liver disease. Here, using genetic mouse models of hepatocyte-specific senescence, we demonstrate senescence development in extrahepatic organs and associated organ dysfunction in response to liver senescence. In patients with acute indeterminate hepatitis, the extent of hepatocellular senescence predicts the occurrence of extrahepatic dysfunction, need for liver transplantation and mortality. We identify the Transforming Growth Factor β (TGFβ) pathway as a critical mediator of systemic spread of senescence and TGFβ inhibition blocks senescence transmission to other organs preventing renal dysfunction. Our results highlight the systemic consequences of organ-specific senescence which, independent of aging, contributes to multi-organ dysfunction.

Project description:Inter-organ transmission of hepatocellular senescence induces multi-organ dysfunction through the TGFbeta signalling pathway

Project description:Induction of hepatocyte senescence is known to inhibit hepatocellular carcinoma (HCC). Until now, it has not been clear how the degree of liver injury dictates hepatocyte senescence and carcinogenesis. In this study, we investigated whether the severity of injury determines cell fate decisions between hepatocyte senescence and carcinogenesis. After testing of different degrees of liver injury, we found that hepatocyte senescence is strongly induced in the setting of severe acute liver injury. Longer-term, moderate liver injury did not result into hepatocyte senescence, but instead led to a significant incidence of HCC. In addition, carcinogenesis was significantly reduced by the induction of severe acute injury after chronic moderate liver injury. We conclude that severe acute liver injury leads to hepatocyte senescence along with a low incidence of HCC, whereas chronic moderate injury allows hepatocytes to proliferate rather than to enter into senescence, and correlates with a high incidence of HCC. This study improves our understanding in hepatocyte cell fate decisions and suggests a potential clinical strategy to induce senescence to treat HCC.

Project description:Liver injury results in rapid regeneration through hepatocyte proliferation and hypertrophy. However, after acute severe injury, such as acetaminophen poisoning, effective regeneration may fail. We investigated how senescence underlies this regenerative failure. In human acute liver disease, and murine models, p21-dependent hepatocellular senescence was proportionate to disease severity and was associated with impaired regeneration. In an acetaminophen injury model a transcriptional signature associated with the induction of paracrine senescence is observed within twenty four hours, and is followed by one of impaired proliferation. In genetic models of hepatocyte injury and senescence we observed transmission of senescence to local uninjured hepatocytes. Spread of senescence depended upon macrophage derived TGFβ1 ligand. In acetaminophen poisoning inhibition of TGFβ receptor 1 (TGFβR1) improved survival. TGFβR1 inhibition reduced senescence and enhanced liver regeneration even when delivered after the current therapeutic window. This mechanism, in which injury induced senescence impairs regeneration, is an attractive therapeutic target for acute liver failure.

Project description:Acute liver failure is a critical clinical issue in liver diseases, characterized by extensive hepatocyte death involving various mechanisms, including apoptosis, necroptosis, and ferroptosis. Ferroptosis, an iron-dependent form of non-apoptotic cell death marked by significant lipid peroxidation, plays a crucial role in the pathogenesis of multiple liver disorders.This cell death results in elevated levels of acute phase proteins synthesized and secreted by the liver. While previous studies indicated that the ORM2 protein does not directly influence apoptotic signaling pathways, our findings reveal that its knockout in acute liver injury models significantly worsens damage and reduces the median survival time of mice. In contrast, liver-specific overexpression of Orm2 markedly mitigates acute liver injury.We found that Orm2 exerts its protective effects by non-competitively binding to NCOA4, inhibiting ferroautophagy, and reducing iron ion accumulation, thereby decreasing ferroptosis during acute liver injury. Additionally, interference with TAX1BP1 gene expression compensates for the increased sensitivity to ferroptosis resulting from Orm2 knockdown. Importantly, ORM2 infusion therapy protects against acute damage in various organs, including the liver. Mechanistically, ORM2 in plasma enters damaged cells via endocytosis, regulating iron homeostasis and alleviating acute injury caused by ferroptosis.In summary, Orm2 is a potential protective factor against abnormal iron accumulation and ferroptosis, reducing acute organ damage. These findings suggest that acute phase proteins may play a role in cellular resistance to death during organ injury and offer a potential adjunctive therapeutic strategy for acute organ damage caused by ferroptosis.

Project description:Inter-organ transmission of hepatocellular senescence induces multi-organ dysfunction through the TGFβ signalling pathway.

Project description:Aging Promotes Metabolic Dysfunction-associated Steatotic Liver Disease and Multi-Organ Dysfunction by Inducing Ferroptotic Stress

Project description:Crosstalk between deregulated hepatocyte metabolism and cells within the tumour microenvironment, and consequent effects on liver tumourigenesis, are incompletely understood. We show here that hepatocyte specific loss of the gluconeogenic enzyme fructose 1,6-bisphosphatase 1 (FBP1) disrupts liver metabolic homeostasis and promotes tumour progression. FBP1 is universally silenced in both human and murine liver tumours, and hepatocyte-specific Fbp1 deletion results in steatosis, concomitant with activation and senescence of hepatic stellate cells (HSCs), exhibiting a senescence-associated secretory phenotype (SASP). Depleting senescent HSCs by senolytic treatment with dasatinib/quercetin or ABT-263 inhibits tumour progression. We further demonstrate that FBP1-deficient hepatocytes promote HSC activation by releasing HMGB1; blocking its release with the small molecule inflachromene limits FBP1-dependent HSC activation, subsequent SASP development, and tumour progression. Collectively, these findings provide genetic evidence for FBP1 as a metabolic tumour suppressor in liver cancer and establish a critical link between hepatocyte metabolism and HSC senescence that promotes tumour growth.

Project description:Strategies that promote functional organ growth with minimal adverse effects are the ultimate goal of regenerative medicine but no single approach is currently available for organ level repair. Here, using an evolutionary adapted in vivo infection model - Mycobacterium leprae, with host cell reprogramming ability and its natural animal host, the nine-banded armadillo (Dasypus novemcinctus) that harbor bacteria in the highly regenerative liver - we present an in vivo model for promoting adult liver growth at organ level without adverse effects. Experimentally infected armadillos harboring bacteria in the liver, but not infection-resistant or drug-treated animals, showed a significantly increased total liver: body weight ratio, indicative of bacterial-driven liver organ growth in living animals. The machine-learning approach revealed an increase in healthy liver lobule number with a proportionate expansion of the hepatocyte mass with integrating vasculature and biliary networks responsible for functional liver growth. Intriguingly, infected enlarged livers show intact microarchitecture but without evidence of hepatocellular damage, fibrosis/scarring or tumorigenesis. Reactivation of armadillo liver progenitor and developmental genes/proteins, as well as upregulation of growth-, metabolism- and differentiation-associated markers with minimal change in oncogenes or tumor suppressor genes, suggests that bacteria have adapted dynamic regenerative, homeostasis and reprogramming mechanisms to promote de novo organogenesis while maintaining tissue integrity and tumor preventive strategies for host-dependent bacterial propagation. Thus, our model may facilitate the unravelling of in vivo endogenous regenerative pathways that effectively re-engage liver organ growth, with broad implications.

Project description:Organ-selective delivery of messenger RNA (mRNA) is critical for fulfilling the therapeutic potential of mRNA-based gene and protein replacement technologies. Despite clinical advances in hepatic delivery of mRNA using lipid nanoparticles (LNPs), strategies for extrahepatic organ-selective mRNA delivery remain underexplored. Here, we report a strategy, termed peptide-encoded organ-selective targeting (POST), that allows digital programming of LNPs, through surface engineering with specific amino acid sequences (POST codes), to deliver mRNA to extrahepatic organs after intravenous administration. Our molecular dynamics simulations also suggest the optimized fracture mechanics of peptide-protein assembly as a mechanism underlying sequence-dependent association between POST code and potentially organ-targeting corona proteins. POST codes are also compatible with organ-selective delivery of different ribonucleic acids and multiple gene editing machineries. This “POST code” platform presents a theoretically unlimited modular repertoire for LNP surface engineering for directing organ-tropism, thereby providing opportunities to broaden the scope and versatility of organ-selective mRNA delivery.