Periodic Reporting for period 4 - HEPASPHER (Mimicking liver disease and regeneration in vitro for drug development and liver transplantation)
Periodo di rendicontazione: 2022-03-01 al 2023-06-30
Objectives. The overall objectives of the project were to identify novel mechanisms, novel mediators, novel biomarkers and novel drugs for the development and treatment of steatosis, NASH, fibrosis and drug-induced hepatotoxicity based on in vivo experiments such as 3D spheroid models with different types of liver cells.
The development of new therapies for chronic liver diseases is currently hampered by the lack of understanding of liver regeneration in humans. By using this model to study the molecular mechanisms behind liver regeneration, we found that the β-catenin signalling pathway plays an essential role in the expansion of liver cells during liver regeneration.
In the development of drugs, the autoinduction of metabolism by the drug in question plays an important role. We indentified new indirect mechanisms for drug-dependent induction of the important enzyme CYP3A4, in which the drug interacts with intracellular signal transduction systems that can indirectly activate the nuclear receptor PXR and cause induction of these drug-metabolising enzymes. This type of induction was relevant to at least 4 other drugs and cannot be mimicked in 2D hepatocyte systems.
A major achievement of the project was the development of an HTS-compatible system to study the aetiology, mechanisms and treatment of liver fibrosis. This has been used for screening chemical libraries to find new candidates for antifibrotic drugs and for the treatment of NASH, as well as to study in detail the mechanisms behind FFA-induced fibrosis, including the identification of released biomarkers such as miRNAs and cytokines, which may be new biomarkers for tracking the development of NASH and fibrosis in vivo in humans.
We evaluated the 3D spheroid system for predictions of drug induced hepatotoxicity. We found that this system could predict the chronic hepatotoxicity at a sensitivity of 72 % and specificity of 100 %, based on screening of 120 different drugs on the market, known to be hepatotoxic or without hepatotoxic effects which constitutes the best in vitro system published for this purpose. We also found formation of spheroid thorns as a new endpoint for drug induced hepatotoxicity to a major extent caused by alteration of the keratin proteins in the spheroids.
Overview of the results and their exploitation and dissemination
In summary, we have developed a new in vitro model for studying human liver with respect to function, diseases and drug-induced injuries. In this 3D hepatic spheroid model we have been able i) to reconstitute and explain mechanisms of chronic drug hepatotoxicity not previously understood, ii) to use the system for high accuracy prediction of hepatotoxic drugs, iii) to develop protocols to study the influence of genetic, dietary and endocrine factors of importance for generating and for treatment of steatosis, iv) to find conditions using various liver donors to establish a HTS compatible model for generation and treatment of NASH and liver fibrosis, v) to identify novel mechanisms by which drugs can induce their own hepatic metabolism, a problem of importance for drug development, vi) to initiate liver regeneration in the spheroids by cytotoxic drugs, wnt ligands or kinase inhibitors making it a nice model for studies of mechanisms of liver regeneration, vii) to identify the formation of thorns as a novel endpoint for drug induced hepatotoxicity, viii) to find the role of CTGF in FFA induced liver fibrosis, ix) to find the specific mechanism and consequence of inflammatory mediators for expression of different drug transporters and drug metabolising enzymes and x) to identify the polymorphic nuclear protein NFIB as a regulator of cytochrome P450 expression with clinical implications for drug treatment.
We have furthermore developed a new triple-culture based spheroid model for identification of the role of LSECs in formation and degradation of liver fibrosis. Here we have found that the metalloproteinase TIMP-1 is present in a subset of LSECs in the human liver and in the spheroids secreted by activated LSECs and contribute to enhanced liver fibrosis. We have been able to see that soluble components are secreted from LSECs which activate the Stellate cells for collagen production but also affect the phenotype of the hepatocytes causing e.g. diminished expression of key drug metabolising enzymes such as CYP3A4. This regulation is partly mediated by IL-6 and implicate important phenotypic alterations in the hepatocytes of patients with steatosis and liver fibrosis leading to increased risk for drug related hepatic adverse reactions.
The majority of papers generated are shown in https://pubmed.ncbi.nlm.nih.gov/?term=ingelman-sundberg+m+AND+spheroids&sort=date&size=100