Hepatic stellate cells contribute to progenitor cells and liver regeneration
Claus Kordes, … , Diran Herebian, Dieter Häussinger
Claus Kordes, … , Diran Herebian, Dieter Häussinger
Published November 17, 2014
Citation Information: J Clin Invest. 2014;124(12):5503-5515. https://doi.org/10.1172/JCI74119.
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Research Article

Hepatic stellate cells contribute to progenitor cells and liver regeneration

Abstract

Retinoid-storing hepatic stellate cells (HSCs) have recently been described as a liver-resident mesenchymal stem cell (MSC) population; however, it is not clear whether these cells contribute to liver regeneration or serve as a progenitor cell population with hepatobiliary characteristics. Here, we purified HSCs with retinoid-dependent fluorescence-activated cell sorting from eGFP-expressing rats and transplanted these GFP+ HSCs into wild-type (WT) rats that had undergone partial hepatectomy in the presence of 2-acetylaminofluorene (2AAF) or retrorsine, both of which are injury models that favor stem cell–based liver repair. Transplanted HSCs contributed to liver regeneration in host animals by forming mesenchymal tissue, progenitor cells, hepatocytes, and cholangiocytes and elevated direct bilirubin levels in blood sera of GUNN rats, indicating recovery from the hepatic bilirubin–handling defect in these animals. Transplanted HSCs engrafted within the bone marrow (BM) of host animals, and HSC-derived cells were isolated from BM and successfully retransplanted into new hosts with injured liver. Cultured HSCs transiently adopted an expression profile similar to that of progenitor cells during differentiation into bile acid–synthesizing and –transporting hepatocytes, suggesting that stellate cells represent a source of liver progenitor cells. This concept connects seemingly contradictory studies that favor either progenitor cells or MSCs as important players in stem cell–based liver regeneration.

Authors

Claus Kordes, Iris Sawitza, Silke Götze, Diran Herebian, Dieter Häussinger

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Figure 3

Transplanted male HSCs form bile duct cells and functional hepatocytes as investigated by FISH of gender-specific chromosomes and GUNN rats (2AAF/PHX model).

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Transplanted male HSCs form bile duct cells and functional hepatocytes a...
(A) FISH of Y chromosome (red) on a male liver section was used as a positive control. (B) Female liver without positive FISH of Y chromosome. (C) FISH of Y (red) and X (green) chromosomes in male liver. Costaining of (D) HNF4α (green) and (E) panK with FISH of Y chromosome (red) in female host livers after transplantation of male HSCs. Arrows indicate HSC-derived (D) hepatocytes and (E) bile duct cells with Y chromosome. (F) Detection of Y (red) and X (green) chromosomes in female host liver. Arrows indicate diploid and tetraploid HSC–derived male hepatocytes without cell fusion. Microscopic images were taken in the portal fields of injured livers (zone 1). (GI) HSCs were transplanted into GUNN rats that underwent PHX in the presence of 2AAF. (G) The presence of hepatocytes derived from transplanted HSCs in homozygous GUNN rats was analyzed by RT-PCR of Ugt1a1 mRNA followed by enzymatic cleavage (BstNI) of the mutation site. (H) Serum concentrations of direct (red bars) and indirect bilirubin (yellow bars) were determined after 4 weeks and compared with those detected in GUNN rats (controls), which were treated in a similar way but without transplanted HSCs, and in normal rats (n = 3–6; *P < 0.05). (I) Albumin concentrations were measured in the blood serum of normal rats as well as GUNN rats with and without transplanted HSCs (n = 3–6). Scale bars: 50 μm (AD and F); 20 μm (E).