Recent evidence has contradicted the prevailing view that homeostasis and regeneration of the adult liver are mediated by self duplication of lineage-restricted hepatocytes and biliary epithelial cells. These new data suggest that liver progenitor cells do not function solely as a backup system in chronic liver injury; rather, they also produce hepatocytes after acute injury and are in fact the main source of new hepatocytes during normal hepatocyte turnover. In addition, other evidence suggests that hepatocytes are capable of lineage conversion, acting as precursors of biliary epithelial cells during biliary injury. To test these concepts, we generated a hepatocyte fate-tracing model based on timed and specific Cre recombinase expression and marker gene activation in all hepatocytes of adult Rosa26 reporter mice with an adenoassociated viral vector. We found that newly formed hepatocytes derived from preexisting hepatocytes in the normal liver and that liver progenitor cells contributed minimally to acute hepatocyte regeneration. Further, we found no evidence that biliary injury induced conversion of hepatocytes into biliary epithelial cells. These results therefore restore the previously prevailing paradigms of liver homeostasis and regeneration. In addition, our new vector system will be a valuable tool for timed, efficient, and specific loop out of floxed sequences in hepatocytes.
SUMMARY
Liver fibrosis, a form of scarring, gradually develops in chronic liver diseases
when hepatocyte regeneration cannot compensate for hepatocyte death. At earlier stages,
collagen produced by activated myofibroblasts (MFs) functions to maintain tissue
integrity, but upon repeated injury, collagen accumulation suppresses hepatocyte
regeneration, ultimately leading to liver failure. As a strategy to generate new
hepatocytes and limit collagen deposition in the chronically injured liver, we developed
in vivo reprogramming of MFs into hepatocytes using adeno-associated virus (AAV) vectors
expressing hepatic transcription factors. We first identified the AAV6 subtype as
effective in transducing MFs in mouse models of chronic liver disease. We then use
lineage-tracing approaches to show that hepatocytes reprogrammed from MFs replicate
primary hepatocyte function, and that liver fibrosis in AAV treated animals is reduced.
Because AAV vectors are already used for liver-directed human gene therapy, our strategy
has potential for clinical translation into a therapy for liver fibrosis.
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