Activation of peroxisome proliferator-activated receptor alpha enhances apoptosis in the mouse liver.

Chronic exposure to peroxisome proliferators (PPs) leads to increased incidence of liver tumors in rodents. Liver tumor induction is thought to require increased hepatocyte proliferation and suppression of apoptosis. Transcript profiling showed increased expression of proapoptotic genes and decreased expression of antiapoptotic genes in the livers of mice exposed to the PP WY-14,643 (WY). We tested the hypothesis that prior exposure to WY would increase susceptibility to apoptosis inducers such as Jo2, an antibody which activates the Fas (Apo-1/CD95) death pathway. When compared to their untreated counterparts, wild-type mice pretreated with WY exhibited increased caspase-3 activation and hepatocyte apoptosis following challenge with Jo2. Livers from WY-treated peroxisome proliferator-activated receptor alpha (PPARalpha)-null mice were resistant to the effects of Jo2. In the absence of Jo2 and detectable apoptosis, wild-type mice treated with WY exhibited increases in the activated form of caspase-9. As caspase-9 is a component of the apoptosome, we examined the expression of upstream effectors of apoptosome activity including members of the Bcl-2 family. The levels of the antiapoptotic Mcl-1 transcript and protein were significantly decreased by PPs. PPARalpha-null mice were also resistant to another treatment (concanavalin A) that induces hepatocyte apoptosis. These results (1) indicate that PPARalpha activation increases sensitivity of the liver to apoptosis and (2) identify a mechanism by which PPARalpha could serve as a pharmacological target in diseases where apoptosis is a contributing feature.

The transcriptional response to a peroxisome proliferator-activated receptor alpha agonist includes increased expression of proteome maintenance genes.

The nuclear receptor peroxisome proliferator-activated receptor alpha (PPARalpha), in addition to regulating lipid homeostasis, controls the level of tissue damage after chemical or physical stress. To determine the role of PPARalpha in oxidative stress responses, we examined damage after exposure to chemicals that increase oxidative stress in wild-type or PPARalpha-null mice. Primary hepatocytes from wild-type but not PPARalpha-null mice pretreated with the PPAR pan-agonist WY-14,643 (WY) were protected from damage to cadmium and paraquat. The livers from intact wild-type but not PPARalpha-null mice were more resistant to damage after carbon tetrachloride treatment. To determine the molecular basis of the protection by PPARalpha, we identified by transcript profiling genes whose expression was altered by a 7-day exposure to WY in wild-type and PPARalpha-null mice. Of the 815 genes regulated by WY in wild-type mice (p < or = 0.001; > or =1.5-fold or < or =-1.5-fold), only two genes were regulated similarly by WY in PPARalpha-null mice. WY increased expression of stress modifier genes that maintain the health of the proteome, including those that prevent protein aggregation (heat stress-inducible chaperones) and eliminate damaged proteins (proteasome components). Although the induction of proteasomal genes significantly overlapped with those regulated by 1,2-dithiole-3-thione, an activator of oxidant-inducible Nrf2, WY increased expression of proteasomal genes independently of Nrf2. Thus, PPARalpha controls the vast majority of gene expression changes after exposure to WY in the mouse liver and protects the liver from oxidant-induced damage, possibly through regulation of a distinct set of proteome maintenance genes.

Zonal distribution of cell proliferation in the liver of untreated B6C3F1 and C57BL mice.

To determine the lobular distribution of hepatocellular proliferation, S-phase response was measured in untreated adult male B6C3F1 and C57BL mice at ages 11, 14, and 23 weeks. The percentage of cells in S-phase (labeling index, LI) was evaluated using immunohistochemical detection of 5-bromo-2'-deoxyuridine (BrdU). The BrdU was delivered either by a single ip injection 2 hr prior to sacrifice or via an osmotic minipump implanted subcutaneously for 3 or 7 days. Mitotic and apoptotic indices were determined on H&E stained sections. Animals of both strains and all ages revealed highest LI in the intermediate compartment of the liver acinus (zone 2) irrespective of the length of BrdU application. Cell proliferation in this zone was at all time points significantly higher than elsewhere in the liver. The mitotic index confirmed the data obtained by the S-phase response study. Apoptosis was rarely observed. With regard to rodent data in chemical carcinogenesis and the way they should be evaluated, this study proved that the acinar distribution of proliferating cells in liver of mice is different from that in rats, since, according to the literature, rats reveal highest cell proliferative activity in the periportal zone.

Evaluation of potential modes of action of inhaled ethylbenzene in rats and mice.

Potential factors underlying the tumorigenic activity of ethylbenzene (EB) were examined in F344 rats and B6C3F1 mice inhaling 750 ppm EB vapor 6 h/day, 5 days/week, for one or four weeks. Target tissues (kidneys of rats and livers and lungs of mice) were evaluated for changes in organ weights, mixed function oxygenases (MFO), glucuronosyl transferase activities, S-phase DNA synthesis, apoptosis, alpha2u-globulin deposition, and histopathology. In male rats, kidney weight increases were accompanied by focal increases in hyaline droplets, alpha2u-globulin, degeneration, and S-phase synthesis in proximal tubules. In female rats, only decreased S-phase synthesis and MFO activities occurred. In mice, increased liver weights were accompanied by hepatocellular hypertrophy, mitotic figures, S-phase synthesis, and enzyme activities. S-phase synthesis rates in terminal bronchiolar epithelium were elevated and accompanied by loss of MFO activity. Exposure to a nontumorigenic level of 75 ppm for one week caused few changes. These data, considered with the general lack of EB genotoxicity, suggest a mode of tumorigenesis dependent upon increased cell proliferation and altered population dynamics in male rat kidney and mouse liver and lungs. A similar response in the kidneys of female rats appears to require a longer exposure period than was employed.