Streaming liver. VII: DNA turnover in acinus zone-3

Seeds in the liver

The liver is a crucial organ for homeostasis and has a tremendous self-renewal and regenerative capacity. It has long been believed that the self-renewal and repair of the liver within a given physiological condition or its repopulation in chronic liver diseases, when hepatocyte proliferation is impaired, will primarily be conducted by the proliferating duct cells, termed "oval cells" or hepatic progenitor cells (HPCs). In addition, numerous studies have revealed that HPCs are the initial tumor cells of liver cancer under certain micro-environments. However, benefit from the extensive application of lineage tracing strategies using the Cre/LoxP system, researchers have redefined the fate of these bipotential cells, raising obvious controversies regarding the capacity of liver cells to control their own biology and differentiation. Here, we review the relevant articles, focusing on cell-lineage tracing to better understanding seed cells and their distinct fate in the liver.

Liver Stem Cells: Experimental Findings and Implications for Human Liver Disease

Evidence from human histopathology and experimental studies with rodents and zebrafish has shown that hepatocytes and cholangiocytes may function as facultative stem cells for each other in conditions of impaired regeneration. The interpretation of the findings derived from these studies has generated considerable discussion and some controversies. This review examines the evidence obtained from the different experimental models and considers implications that these studies may have for human liver disease.

Self-renewing diploid Axin2(+) cells fuel homeostatic renewal of the liver

The source of new hepatocytes in the uninjured liver has remained an open question. By lineage tracing using the Wnt-responsive gene Axin2 in mice, we identify a population of proliferating and self-renewing cells adjacent to the central vein in the liver lobule. These pericentral cells express the early liver progenitor marker Tbx3, are diploid, and thereby differ from mature hepatocytes, which are mostly polyploid. The descendants of pericentral cells differentiate into Tbx3-negative, polyploid hepatocytes, and can replace all hepatocytes along the liver lobule during homeostatic renewal. Adjacent central vein endothelial cells provide Wnt signals that maintain the pericentral cells, thereby constituting the niche. Thus, we identify a cell population in the liver that subserves homeostatic hepatocyte renewal, characterize its anatomical niche, and identify molecular signals that regulate its activity.

Sox9 and programming of liver and pancreatic progenitors

Recent advances in developmental biology have greatly expanded our understanding of progenitor cell programming and the fundamental roles that Sox9 plays in liver and pancreas organogenesis. In the last 2 years, several studies have dissected the behavior of the Sox9+ duct cells in adult organs, but conflicting results have left unanswered the long-standing question of whether physiologically functioning progenitors exist in adult liver and pancreas. On the other hand, increasing evidence suggests that duct cells function as progenitors in the tissue restoration process after injury, during which embryonic programs are sometimes reactivated. This article discusses the role of Sox9 in programming liver and pancreatic progenitors as well as controversies in the field.

Total parenteral nutrition-associated cholestasis after selective damage to acinar zone 3 hepatocytes by bromobenzene in the rat

Total parenteral nutrition is known to cause cholestasis, but the hepatic site of this effect has not been determined. The purpose of our study was to observe the effect of TPN on bile flow and bile salt secretion rate in rats after selective damage to acinar zone 3. Bromobenzene, 3.8 mmol/kg, was injected i.p., and the animals were studied 48 hours later. Experimental groups received either parenteral nutrition or saline for 2 hours. Bromobenzene caused selective damage to acinar zone 3 hepatocytes, and reduced baseline bile flow (23.99 +/- 1.09 vs 37.2 +/- 1.66, mean +/- SEM, microliter/min/kg, p < 0.001). Bromobenzene had no effect on bile salt secretion rate. Total parenteral nutrition decreased bile flow in the bromobenzene treated groups, despite the selective hepatic damage to acinar zone 3 (20.54 +/- 1.07 vs 23.28 +/- 1.63, mean +/- SEM, p < 0.001). Total parenteral nutrition reduced bile salt secretion rate in healthy animals, but this reduction was not seen in bromobenzene treated rats. Our results suggest that bile flow reduction in response to total parenteral nutrition is mediated through an effect on acinar zones 1 and 2, as this reduction is still observed after zone 3 destruction by bromobenzene. Zone 3 hepatocytes may be involved in the effect of parenteral nutrition on bile salt secretion, as the reduction in secretion rate seen in healthy animals was not observed in bromobenzene treated rats.

Streaming liver. VIII: Cell production rates following partial hepatectomy

Twenty-four young, female, random-bred rats weighing 250 g were partially hepatectomized and killed in groups of four animals at the following times: 1 h and 1, 2, 3, 7 and 14 days. One hour before killing, each rat was injected i.p. with 0.5 microCi [3H]-thymidine, specific activity 5 Ci/mmol/g body weight. Livers were processed histologically and dipped into liquid emulsion for autoradiography. Twenty-four hours after partial hepatectomy, hepatocyte and littoral labelling indices rose, reaching on the third day respective peak values of 3.7%, and 15.4%, whereupon they declined, remaining slightly above pre-treatment level. Labelling indices served for cell production estimates. On day 3 the hepatocyte labelling index rose 26-fold. At the same time hepatocytes doubled their ploidy, indicating that half of the observed L.I. increase was directed to DNA accumulation and not to cell division. The hepatocyte production rate therefore increased 13-fold (or 1300%). The acinus diameter increased 15%, and cell density declined 5%, so that the acinus capacity to retain cells increased only 5%. Since the acinus did not enlarge proportionally to cell production, it is concluded that 95% of newly formed cells were eliminated. Partial hepatectomy thus triggers two processes: an acute process lasting about a week marked by massive and rapid cell turnover during which most newly formed cells are eliminated; and a second, more protracted process which serves for liver mass restoration. It is proposed that partial hepatectomy induces an acute shortage of a hitherto unknown metabolite that is produced by newly formed cells immediately after hepatectomy.