Potential role for peroxisome proliferator activated receptor (PPAR) in preventing colon cancer.

BACKGROUND: Peroxisome proliferator activated receptors (PPARs) are nuclear hormone receptors involved in genetic control of many cellular processes. PPAR and PPAR have been implicated in colonic malignancy. Here we provide three lines of evidence suggesting an inhibitory role for PPAR in colorectal cancer development. METHODS: Levels of PPAR mRNA and protein in human colorectal cancers were compared with matched non-malignant mucosa using RNAse protection and western blotting. APC(Min)/+ mice were randomised to receive the PPAR activator methylclofenapate 25 mg/kg or vehicle for up to 16 weeks, and small and large intestinal polyps were quantified by image analysis. The effect of methylclofenapate on serum stimulated mitogenesis (thymidine incorporation), linear cell growth, and annexin V and propidium iodide staining were assessed in human colonic epithelial cells. RESULTS: PPAR (mRNA and protein) expression levels were significantly depressed in colorectal cancer compared with matched non-malignant tissue. Methylclofenapate reduced polyp area in the small intestine from 18.7 mm(2) (median (interquartile range 11.1, 26.8)) to 9.90 (4.88, 13.21) mm(2) (p=0.003) and in the colon from 9.15 (6.31, 10.5) mm(2) to 3.71 (2.71, 5.99) mm(2) (p=0.009). Methylclofenapate significantly reduced thymidine incorporation and linear cell growth with no effect on annexin V or propidium iodide staining. CONCLUSIONS: PPAR may inhibit colorectal tumour progression, possibly via inhibition of proliferation, and may be an important therapeutic target.

Studies on the induction of rat hepatic CYP1A, CYP2B, CYP3A and CYP4A subfamily form mRNAs in vivo and in vitro using precision-cut rat liver slices.

1. Real-time quantitative reverse transcription-polymerase chain reaction methodology (TaqMan(R)) was used to examine the induction of some selected rat hepatic cyto-chrome P450 (CYP) forms in vivo and in vitro using cultured precision-cut liver slices. 2. TaqMan primers and probe sets were developed for rat CYP1A1, CYP1A2, CYP2B1, CYP2B1/2, CYP3A1, CYP3A2 and CYP4A1 mRNAs. 3. To characterize the responsiveness of the rat CYP mRNA TaqMan primers and probe sets, rats were treated in vivo with a single intraperitoneal dose of 500 mg kg(-1) Aroclor 1254 (ARO) and with four daily oral doses of either 50 mg kg(-1) day(-1) dexamethasone (DEX) or 75 mg kg(-1) day(-1) methylclofenapate (MCP). Treatment with ARO produced 22 600-, 5480-, 648-, 52-, 47- and 9-fold increases in levels of CYP1A1, CYP2B1, CYP2B1/2, CYP1A2, CYP3A1 and CYP3A2 mRNA, respectively. DEX treatment produced 97-, 24-, 8- and 4-fold increases, respectively, in CYP3A1, CYP2B1, CYP2B1/2 and CYP3A2 mRNA levels, and MCP produced 339-, 126- and 25-fold increases, respectively, in CYP4A1, CYP2B1 and CYP2B1/2 mRNA levels. All three CYP inducers also increased microsomal CYP content and produced corresponding increases in CYP1A, CYP2B, CYP3A and CYP4A form marker enzyme activities. 4. Rat liver slices were cultured for 6 and 24 h in medium containing 0.1 micro M insulin and 0.1 micro M DEX, and also for 24 h in medium containing only 0.1 micro M insulin (DEX-free medium). Liver slices were cultured in control medium or in medium containing either 10 micro M beta-naphthoflavone (BNF), 10 micro g ml(-1) ARO, 500 micro M sodium phenobarbitone (NaPB), 20 micro M pregnenolone-16alpha -carbonitrile (PCN), 50 micro M Wy-14,643 (WY) or 50 micro M MCP. 5. With the exception of the effect of BNF on CYP1A1 mRNA levels, the induction of all the CYP mRNAs studied was greater after 24- than after 6-h treatment. Generally, the magnitude of induction of CYP mRNA levels was greater after 24 h in liver slices cultured in DEX-free than in DEX-supplemented medium. 6. Treatment of liver slices with BNF and ARO for 24 h in DEX-free medium produced 21- and 35-fold increases, respectively, and 38- and 37-fold increases, respectively, in CYP1A1 and CYP1A2 mRNA levels. NaPB, PCN, WY and MCP did not increase either CYP1A1 or CYP1A2 mRNA levels. 7. After 24 h, levels of CYP2B1/2 mRNA were increased 18-, 20-, 9-, 16- and 13-fold by treatment with ARO, NaPB, PCN, WY and MCP, respectively. PCN also produced 56- and 4-fold increases, respectively, in CYP3A1 and CYP3A2 mRNA levels. 8. Treatment with WY and MCP for 24 h produced 437- and 186-fold increases, respectively, in levels of CYP4A1 mRNA. None of the other CYP inducers studied had any effect on CYP4A1 mRNA levels. 9. The results demonstrate the utility of cultured precision-cut liver slices as an in vitro model system to evaluate the effects of xenobiotics on rat CYP1A, CYP2B, CYP3A and CYP4A form mRNA levels.

CYP isoform induction screening in 96-well plates: use of 7-benzyloxy-4-trifluoromethylcoumarin as a substrate for studies with rat hepatocytes.

1. In this study, 7-benzyloxy-4-trifluoromethylcoumarin (BFC) was evaluated as a substrate to assess the induction of cytochrome P450 (CYP) isoform enzyme activities in rat hepatocytes using a 96-well plate format. 2. BFC was metabolized by both untreated and sodium phenobarbitone (NaPB)-treated rat hepatocytes in a time- and concentration-dependent manner to the highly fluorescent product 7-hydroxy-4-trifluoromethylcoumarin (HFC). 3. HFC was extensively conjugated with D-glucuronic acid and/or sulphate in both untreated and NaPB-treated rat hepatocytes, thus necessitating the inclusion of an enzymatic deconjugation step in the assay procedure. 4. The time-course of induction of 7-ethoxyresorufin metabolism by the CYP1A inducer beta-naphthoflavone (BNF), 7-benzyloxyresorufin metabolism by the CYP2B inducer NaPB and BFC metabolism b both BNF and NaPB was studied in rat hepatocytes treated for 24-96 h. The optimal time for induction of metabolism of all three substrates was 72 h, with no medium changes being necessary during this period. 5. The effect of treatment with 0.5-20 microM BNF, 50-2000 microM NaPB, 2-20 microM dexamethasone (DEX), 20-100 microM methylclofenapate (MCP), and 50 and 200 microM isoniazid (ISN) for 72 h on BFC metabolism in cultured rat hepatocytes was studied. BFC metabolism was induced by treatment with BNF, NaPB and MCP, but not with either DEX or ISN. 6. The metabolism of BFC in liver microsomes from the control rat and rat treated with CYP isoform inducers was also studied. BFC metabolism was induced by treatment with NaPB, BNF and DEX. 7. The metabolism of BFC was also studied using microsomes from baculovirus-infected insect cells containing rat cDNA-expressed CYP1A, CYP2B, CYP2C and CYP3A isoforms. Whereas BFC was metabolized to some extent by all the rat cDNA-expressed CYP isoforms examined, at a substrate concentration of 2.5 microM the greatest rates of BFC metabolism were observed with the CYP1A1, CYP1A2 and CYP2B1 preparations. 8. In summary, the results demonstrate that BFC is a good substrate for assessing the induction of CYP1A and CYP2B isoforms in rat hepatocytes in a 96-well plate format.

High throughput ribonuclease protection assay for the determination of CYP3A mRNA induction in cultured rat hepatocytes.

1. A rapid 96-well plate based method for the determination of CYP3A mRNA induction in primary rat hepatocytes has been developed which has substantial advantages over current technologies including the ability to test the effect of relatively large numbers of new chemical entities on the expression of CYP3A mRNA in hepatocytes. 2. The ribonuclease protection assay detects changes in mRNA levels in small numbers of hepatocytes by the utilization of a radiolabelled antisense riboprobe that will hybridize CYP3A1 and CYP3A23. Using in situ hybridization techniques in conjunction with Amersham 96-well Cytostar-T scintillating microplates, there is no need for isolation of mRNA. A simple ribonuclease digestion step allows quantitative data to be generated easily within 1 week of hepatocyte isolation. 3. Rat hepatocytes were cultured for 48 h post-isolation on the Cytostar plates coated with a basal matrix of Matrigel. Prototypical CYP3A inducers (dexamethasone and pregnenolone 16alpha-carbonitrile) have been studied using various treatment periods from 0.5 to 24 h. Methylclofenapate and beta-naphthoflavone, prototypical inducers of CYP4A and CYP1A respectively, have been used as controls to show specificity of the [33P]-labelled riboprobe for the CYP3A family. 4. Time-dependent increases in CYP3A mRNA were demonstrated following exposure of hepatocytes to prototypical CYP3A inducers, but not for methylclofenapate or beta-naphthoflavone, so demonstrating specificity for CYP3A mRNA over CYP1A and CYP4A. Analysis of the 24-h induction data demonstrates that significant differences from controls can be determined and that induction potential can be assessed. The system has the potential to screen for overall CYP3A mRNA induction in response to compounds at an early stage in drug research.

The coordinate regulation of DNA synthesis and suppression of apoptosis is differentially regulated by the liver growth agents, phenobarbital and methylclofenapate.

The coordinate regulation of DNA synthesis and suppression of apoptosis was investigated in a rat hepatocyte cell culture system which supports high level induction of DNA synthesis by the peroxisome proliferator, methylclofenapate (MCP) (Plant, N.J. et al., 1998, Carcinogenesis, 19, 925-931). The peroxisome proliferators are hepatocyte mitogens in chemically defined media: glucocorticoid-induced PPARalpha is linked to peroxisome proliferator mitogenesis (Plant, N.J. et al., 1998, Carcinogenesis, 19, 925-932). Phenobarbital (PB) induced moderate induction of DNA synthesis (200-300% of control), but the peak of induction was 40 h after treatment. In hepatocytes that had undergone DNA synthesis, PB increased the proportion of binucleates by 200-300%. Both PB and MCP were able to suppress apoptosis in a dose-dependent manner, while the endogenous mitogen epidermal growth factor failed to suppress apoptosis. The suppression of apoptosis by MCP was reversible; withdrawal of MCP led to rapid induction of apoptosis. The presence of hydrocortisone is required for suppression of apoptosis by peroxisome proliferators, but not for PB. MCP failed to suppress apoptosis in primary cultures of guinea-pig hepatocytes. Comparison of the stability of hepatocytes labelled with bromodeoxyuridine (BrdUrd) and [3H]thymidine revealed that approximately 40% of cells labelled with BrdUrd were lost over a period of 14 days, whereas cells labelled with thymidine remained stable over this period. Hepatocytes were therefore treated with MCP, labelled with [3H]thymidine, maintained for 14 days, and peroxisome proliferator withdrawn. While the apoptotic index in unlabelled cells was 1.7%, no apoptosis was detected in labelled cells. In order to compare the mechanism of suppression of apoptosis, hepatocytes were cultured in the presence of either PB or MCP for 14 days. When MCP was substituted for PB in cells cultured in the presence of PB, the monolayer was maintained, but when PB was used to replace MCP in cells cultured in the presence of MCP, the monolayer of hepatocytes degenerated rapidly. The results demonstrate mechanistic differences in the coordinate regulation of cell growth and apoptosis in hepatocytes by PB and MCP.

The peroxisome proliferators are hepatocyte mitogens in chemically-defined media: glucocorticoid-induced PPAR alpha is linked to peroxisome proliferator mitogenesis.

Peroxisome proliferator-induced mitogenesis is believed to play a role in hepatocarcinogenesis, but it has not been possible to demonstrate high level induction of DNA synthesis by peroxisome proliferators in cultured hepatocytes. We now show that four structurally dissimilar peroxisome proliferators (methylclofenapate, Wy-14 643, tetradecyl-3-thia acetic acid and clofibrate) cause high level induction of DNA synthesis in primary cultures of rat hepatocytes, routinely 7-9 fold above control, with up to 29% of cells undergoing S-phase. Peroxisome proliferators induce DNA synthesis rapidly, with maximal response 24 h after dosing [compared with 48 h for epidermal growth factor (EGF)]; indeed, peroxisome proliferators were mitogenic in a chemically defined medium, i.e. with no added exogenous growth factors. EGF-treated hepatocytes that had undergone DNA synthesis comprised 23% binucleated cells, whereas hepatocytes induced into S-phase by peroxisome proliferators contained only 3% binucleated cells, demonstrating a distinct response of hepatocytes to peroxisome proliferators and EGF. The presence of a glucocorticoid was essential for peroxisome proliferator-induced DNA synthesis, but not for EGF-induced DNA synthesis, demonstrating that the requirement for glucocorticoids is selective for peroxisome proliferators. Hydrocortisone was shown to induce the expression of peroxisome proliferator activated receptor-alpha (PPAR alpha), and we propose that it is the glucocorticoid-induced expression of PPAR alpha that is essential for peroxisome proliferator mitogenesis. This in vitro system provides a powerful tool for investigating the mechanism and role of peroxisome proliferator-induced mitogenesis in liver growth and carcinogenesis.

Molecular basis of non-responsiveness to peroxisome proliferators: the guinea-pig PPARalpha is functional and mediates peroxisome proliferator-induced hypolipidaemia.

The guinea pig does not undergo peroxisome proliferation in response to peroxisome proliferators, in contrast with other rodents. To understand the molecular basis of this phenotype, the peroxisome proliferator activated receptor alpha (PPARalpha) from guinea-pig liver was cloned; it encodes a protein of 467 amino acid residues that is similar to rodent and human PPARalpha. The guinea-pig PPARalpha showed a high substitution rate: maximum likelihood analysis was consistent with rodent monophyly, but could not exclude rodent polyphyly (P approximately 0.06). The guinea-pig PPARalpha cDNA was expressed in 293 cells and mediated the induction of the luciferase reporter gene by the peroxisome proliferator, Wy-14,643, dependent on the presence of a peroxisome proliferator response element. Moreover the PPARalpha RNA and protein were expressed in guinea-pig liver, although at lower levels than in a species which is responsive to peroxisome proliferators, the mouse. To determine whether the guinea-pig PPARalpha mediated any physiological effects, guinea pigs were exposed to two selective PPARalpha agonists, Wy-14, 643 and methylclofenapate; both compounds induced hypolipidaemia. Thus the guinea pig is a useful model for human responses to peroxisome proliferators.

Effects of peroxisome proliferators and 12-O-tetradecanoyl phorbol-13-acetate on intercellular communication and connexin43 in two hamster fibroblast systems.

Effects of 12-O-tetradecanoyl phorbol 13-acetate (TPA) and the hepatic peroxisome proliferators (HPPs) clofibrate, methyl clofenapate (MCP), di(2-ethylhexyl)phthalate (DEHP) and mono(2-ethylhexyl)phthalate (MEHP) were studied in 2 gap junctional intercellular communication (GJIC) systems, metabolic cooperation in V79 cells and microinjection/dye transfer in Syrian hamster embryo (SHE) cells and V79 cells. TPA inhibited GJIC in both systems but was considerably more potent in V79 cells. SHE cells showed a rapid and transient inhibition of GJIC after exposure to HPPs, with maximal inhibition occurring at 5-15 min. The transient inhibition could be caused by metabolization of the compounds. Clofibrate and MEHP produced strong inhibition of metabolic cooperation in V79 cells at high concentrations, while the effect of MCP and DEHP was lower. However, DEHP, MEHP and clofibrate strongly inhibited dye transfer in V79 cells after a 30 min exposure. Clofibrate also showed a dose- and time-dependent effect on dye transfer in V79 cells. The phosphorylation status of the gap junction protein connexin43 (Cx43) changed minimally in SHE cells after exposure to TPA or HPPs. Cx43 from V79 cells was strongly affected by TPA, but not by HPPs. Immunofluorescence of Cx43 disappeared in both cell types when they were exposed to TPA and MEHP, but not to the other HPPs. Thus, there is no direct correlation between the inhibition of GJIC and changes in the phosphorylation status of Cx43 or the appearance of Cx43 in immunofluorescence experiments. The discrepancies may partly be explained by binding of accessory proteins to Cx43. We point out sequences that may be involved in such binding.

Comparative effects of clofibrate and methyl clofenapate on morphological transformation and intercellular communication of Syrian hamster embryo cells.

The Syrian hamster embryo (SHE) cell system was used to evaluate the ability of two hepatocarcinogenic structurally related peroxisome proliferators (PPs) to induce morphological transformation (MT) of SHE colonies and to inhibit gap junctional intercellular communication (GJIC). Clofibrate and methyl clofenapate (MCP), which was shown to be a more active PP and a more potent carcinogen in vivo than clofibrate, were compared. MCP appeared slightly more active in vitro than clofibrate in affecting MT and GJIC of SHE cells. The morphological transformation of SHE colonies was induced by 50 microM MCP, against 100 microM clofibrate. Moreover, 50 microM MCP potentiated the transforming effects of both benzo[a]pyrene and 12-O-tetradecanoylphorbol-13-acetate. The inhibition of GJIC, measured by transfer of lucifer yellow, was transient and occurred at concentrations inducing morphological transformation. MCP inhibited dye transfer at 50 microM and the inhibition lasted up to 24 h at 100 microM. Inhibition of communication lasted only 4 h with clofibrate and occurred at a higher concentration (175 microM). This study showed that both the SHE cell transformation and dye transfer assays were able to display the different activities of the two PPs, even though the difference in potency observed was smaller than in vivo. It also revealed interactions between non-genotoxic carcinogens and the ability of the SHE cell transformation assay to detect these combined effects.

Species differences in response to peroxisome proliferators correlate in vitro with induction of DNA synthesis rather than suppression of apoptosis.

Tumorigenesis caused by the peroxisome proliferator (PP) class of non-genotoxic hepatocarcinogens is species restricted; rat and mouse are considered responsive whereas the available evidence suggests that humans, non-human primates, dogs, hamsters and guinea pigs are non-responsive. We have demonstrated previously that the PP, nafenopin can suppress rat hepatocyte apoptosis both in vitro and in vivo. Here we describe the ability of nafenopin to suppress apoptosis in mouse, hamster, guinea pig and rat hepatocytes and induce S-phase in mouse and rat hepatocytes. Hepatocyte monolayers from all species examined degenerated rapidly in culture. However, nafenopin (50 microM) reversibly maintained the viability of both rat and mouse hepatocytes. This maintenance was associated with a decrease (P < or = 0.01) in the number of hepatocytes displaying chromatin condensation patterns characteristic of apoptosis. Treatment of rat and mouse monolayers with 5 ng/ml transforming growth factor-beta 1 (TGF beta 1) induced high levels of apoptosis (P < or = 0.01); co-addition of nafenopin suppressed this induced apoptosis (P < or = 0.01). TGF beta 1 also induced apoptosis in hamster and guinea pig hepatocytes (P < or = 0.01) and unexpectedly nafenopin was able to suppress this induced apoptosis (P < or = 0.01) as well as reversibly maintaining the viability of hamster and guinea pig hepatocyte monolayers. Thus, all the species examined responded to nafenopin by a suppression of both spontaneous and TGF beta 1-induced apoptosis. In contrast, only rat and mouse hepatocytes showed an induction of S-phase in response to nafenopin (P < or = 0.01). Certain key experiments were repeated using the PPs methyl clofenapate (MCP) (100 microM) and Wy-14, 643 (10 microM). Both were able to suppress spontaneous and TGF beta 1-induced apoptosis in rat and guinea pig hepatocytes although the effects of MCP were weak (P < or = 0.05) compared with nafenopin or Wy-14 643 (P < or = 0.01). The rat and mouse liver tumour promoter, phenobarbitone (PB) was assessed also. Rat hepatocytes responded to PB with a suppression of apoptosis and an induction of S-phase (P < or = 0.01). Hamster and guinea pig cells gave no response in the S-phase assay and exhibited no suppression of either spontaneous or TGF beta 1-induced apoptosis. Interestingly, nafenopin suppressed the apoptosis induced by the DNA damaging drugs, etoposide and hydroxyurea (P < or = 0.01) suggesting that PPs can impact on diverse apoptosis signalling pathways. Overall, species differences in response to the non-genotoxic hepatocarcinogens studied, correlate with induction of DNA synthesis rather than with suppression of apoptosis. The data extend our knowledge of the mechanisms of species differences in non-genotoxic hepatocarcinogenesis, posing interesting questions on the relative roles of apoptosis and DNA synthesis in carcinogenesis.

Induction of cytochrome P450 isoenzymes in cultured precision-cut rat and human liver slices.

1. The effect of some xenobiotics on levels of selected cytochrome P450 (CYP) isoenzymes determined by Western immunoblotting and associated enzyme activities has been studied in 72-h cultured rat and human precision-cut liver slices. 2. In cultured rat liver slices, 0.5 mM sodium phenobarbitone (PB), 25 microM beta-naphthoflavone (BNF), and 20 micrograms/ml Aroclor 1254 (ARO) induced mixed-function oxidase enzyme activities. Western immunoblotting of liver slice microsomes was performed with antibodies to rat CYP1A2, 2B1/2 and 3A. Compared with 72-h control (dimethyl sulphoxide only treated) rat liver slice microsomes, PB induced CYP2B1/2 and 3A, BNF induced CYP1A2, and ARO induced CYP1A2, 2B1/2, and 3A. 3. The peroxisome proliferators methylclofenapate (MCP), ciprofibrate (CIP) and Wy-14,643 (WY) induced palmitoyl-CoA oxidation in 72-h cultured rat liver slices. Compared with 72-h control rat liver slice microsomes, MCP, CIP, and WY all induced levels of CYP4A. 4. In cultured human liver slices, 20 micrograms/ml ARO, but not 0.5 mM MCP, induced 7-ethoxyresorufin O-deethylase activity. Neither ARO nor MCP had any effect on homogenate palmitoyl-CoA oxidation and microsomal lauric acid 11- and 12-hydroxylase activities. Compared with 72-h control human liver slice microsomes, ARO induced CYP1A2, and MCP appeared to induce CYP4A. Further studies would be required to confirm that CYP4A isoenzymes could be induced by xenobiotics in human liver slices. 5. These results demonstrate that cultured liver slices may be used in evaluating the effect of xenobiotics on both rat and human CYP isoenzymes.

Juxtaposition of peroxisomes and chromosomes in mitotic hepatocytes following methyl clofenapate administration to rats.

Administration of 25 mg/kg/day methyl clofenapate to Alpk/APfSD rats for up to 4 days gave rise to hepatomegaly resulting from a combination of hepatocyte hyperplasia, mainly in the periportal region of the lobule, and centrilobular cell hypertrophy. In hepatocytes undergoing mitosis there was a redistribution of dense vesicles and some peroxisomes to the perinuclear region of the cytoplasm. With increasing length of exposure to methyl clofenapate the number of peroxisomes located in this region during mitosis increased. Chromosomes observed by electron microscopy were seen to lie in close apposition to these organelles. Immunocytochemical localization of the Phase II conjugating enzymes glutathione-S transferase B, C and E showed a dramatic reduction and redistribution of those enzymes in mitotic cells and their absence in the region of the chromosomes. These events may increase the vulnerability of DNA to damage in specific cells.

Ploidy and nuclearity of rat hepatocytes after compensatory regeneration or mitogen-induced liver growth.

The distribution pattern of rat liver parenchymal cells of different ploidy classes was investigated in Wistar rats following cell proliferation induced by surgical partial hepatectomy (compensatory regeneration) or primary mitogens (direct hyperplasia). Animals were killed at 1, 2, 3, 4 and 15 days after the proliferative stimulus, and ploidy and nuclearity were measured using a computer-assisted imaging system in hepatocytes isolated by collagenase perfusion. Analysis of hepatocytes from animals undergoing regeneration after partial hepatectomy revealed a large increase in tetraploid and octoploid mononucleate cells. The most striking feature was the almost complete disappearance of binucleate cells (from 20% to < 1%) at 3 days after partial hepatectomy. On the contrary, when hepatocytes were analyzed after treatment with the mitogen lead nitrate, a high number of binucleate cells (40%) was observed. The increase that was maximal at 3 days after treatment occurred mainly in 4 x 2c and in 8 x 2c compartments. This resulted in an overall increase in the ratio of binucleate/mononucleate cells as well as in the ratio (8c + 16c):(2c + 4c). The cytological changes induced by lead nitrate were not reversible 2 weeks after treatment. Because a massive elimination of excess liver cells occurred by apoptosis during this time period, it appears that polyploid cells are not preferentially eliminated. The hepatic content of DNA at the end of the regression phase was similar to control values. However, because of the higher ploidy state, the number of cells present in the liver 2 weeks after treatment appears to be lower than that of controls (approximately -16%). When liver growth was induced by a single treatment with another mitogen, the peroxisome proliferator nafenopin, a slight increase in the ploidy state of the liver was observed; because of the shift towards higher ploidy classes (8c), the increase in DNA content observed 3 days after a single treatment with nafenopin (+21%) appears to be almost entirely justified by polyploidy rather than by a hyperplastic event.

Differential tissue-specific expression and induction of cytochrome P450IVA1 and acyl-CoA oxidase.

We have examined the tissue-specific expression and inducibility of acyl-CoA oxidase and cytochrome P450IVA1 (P450IVA1) RNA in rats. Groups of three rats were dosed daily by gavage with methylclofenapate at 25 mg/kg in 5 ml/kg corn oil for nine weeks, or were administered a vehicle control. P450IVA1 and acyl-CoA oxidase RNA were detected using an RNase protection assay. Similar levels of acyl-CoA oxidase RNA were present in control liver and kidney, but the level of this RNA in lung, muscle and testis was 6-11%, and in pancreas was 0.13%, of that in liver. Treatment of rats with methylclofenapate led to an 11-fold induction of acyl-CoA oxidase RNA in liver and also produced a significant induction of this RNA in kidney, lung, muscle and testis of 1.7-fold, 1.3-fold, 2-fold and 1.7-fold, respectively. Acyl-CoA oxidase RNA was not induced in pancreas. P450IVA1 RNA was present in control liver and also in kidney of control rats at 28% of the level in liver. In contrast to acyl-CoA oxidase RNA, P450IVA1 RNA was not detected in lung, pancreas or testis. Methylclofenapate treatment of rats led to an 18-fold induction of P450IVA1 RNA in liver, and a sevenfold induction in kidney. Induction of P450IVA1 was not detected in any of the other tissues examined. Quantification of the relative amounts of acyl-CoA oxidase and P450IVA1 RNA in control liver revealed that acyl-CoA oxidase RNA was present in a 17.5-fold molar excess over P450IVA1 RNA. Western blotting with an anti-P450IVA IgG revealed two bands of similar apparent molecular mass in liver and kidney microsomes, but not in microsomes from the testis of control rats. Methylclofenapate treatment of rats caused an increase in the intensity of these bands in microsomes from liver, but no induction was obvious in kidney. Immunocytochemical staining for both the microsomal P450IVA and peroxisomal acyl-CoA oxidase proteins was restricted to the proximal convoluted tubule in the kidney cortex, with staining being most intense in the S3 region.

Recovery of hyperplastic responsiveness in rat liver after dosing with the peroxisome proliferator methylclofenapate.

Methylclofenapate (MCP) was administered daily by gavage (25 mg/kg) for 7 days to groups of adult male rats. Dosing was interrupted for 28, 35, 56, 70 or 84 days and then resumed (25 mg/kg by gavage at 0 and 24 h). During the second period of dosing animals were killed in groups of three at 6, 12, 18, 24, 30, 36, 42 and 48 h after the resumption of dosing. Hepatocytes in S-phase, labelled with bromodeoxy-uridine, were analysed by flow cytometry, cell sorting and microscopy. It was observed that total S-phase activity was just significantly elevated (approximately 20% of maximum) over corn oil controls after an interval of 28 days between initial and subsequent dosing periods. After an interval of 35 days total S-phase activity was approximately 65% of maximum, and full hyperplastic responsiveness, equal to that observed in naive animals given MCP, was detected after interruptions in dosing of 56, 70 and 84 days. The recovery of S-phase responsiveness during the interruptions in dosing was accompanied by an increase in the proportion of 2 X 2N hepatocytes from approximately 10% in animals dosed continuously with MCP, to approximately 11.4% after 28 days interruption, 17% after 35 days and control levels (approximately 20%) after 56, 70 and 84 days. Irrespective of the magnitude of the hyperplasia elicited by the second period of dosing with MCP, the proportion of 2 X 2N cells was reduced to the same levels as those observed in animals dosed continuously with MCP (approximately 10%). Very low S-phase activity (0.05%) was observed in animals dosed continuously with MCP, this level of activity being similar to that in animals given corn oil continuously.

Induction of acyl-CoA oxidase and cytochrome P450IVA1 RNA in rat primary hepatocyte culture by peroxisome proliferators.

We have characterized the induction of acyl-CoA oxidase and cytochrome P450IVA1 RNAs in a primary hepatocyte culture system in vitro, using a sensitive and specific RNAse protection assay. Hepatocytes were cultured with a maximal inducing dose of the peroxisome proliferator clofibric acid (1 mM), or vehicle control, for 4 days, and the level of RNAs compared with the level in rats which had been treated with corn oil or clofibric acid (300 mg/kg) for 4 days. The level of acyl-CoA oxidase and P450IVA1 RNAs in 4-day-old control hepatocytes was less than 2% of that in control liver. However, the level of these RNAs in RNA from treated hepatocytes was 61% of that in liver RNA from treated rats. Hepatocytes were treated with the potent peroxisome proliferator methylclofenapate (100 microM), and the induction of RNAs determined at various times after exposure. P450IVA1 RNA was significantly induced 1 h after dosing, rising to 34-fold above control after 8 h, whereas acyl-CoA oxidase RNA was not significantly induced until 4 h, increasing to 5.2-fold above control after 8 h. A similar time course of induction was seen after treatment of hepatocytes with 100 microM-nafenopin, 100 microM-methylclofenapate, 1 mM-clofibric acid or 1 mM-mono(ethylhexyl) phthalate, suggesting that the differential time course of induction of P450IVA1 and acyl-CoA oxidase RNAs is not related to the esterification, structure or potency of the peroxisome proliferator, but is intrinsic to the process of peroxisome proliferation. Hepatocytes were treated with methylclofenapate in the presence and absence of cycloheximide. P450IVA1 RNA was significantly induced by methylclofenapate in the presence of cycloheximide, rising to 17-fold above control after 8 h. However, no induction of acyl-CoA oxidase RNA was detected in the presence of cycloheximide. Therefore we characterize the induction of acyl-CoA oxidase and P450IVA1 RNAs in primary hepatocyte culture in vitro as a faithful model of the induction response in rat liver, and suggest that induction of P450IVA1 RNA is a primary event in the process of peroxisome proliferation.

Regulation of differentially spliced transcripts of acyl-CoA oxidase in the rat.

RNAse protection assay was used to distinguish between and to quantify alternatively spliced transcripts of acyl-CoA oxidase in liver, kidney and testis of control and methylclofenapate treated rats. The ratio of spliced transcripts (type I to II) was 1.18:1 in control liver RNA, with 130 and 110 molecules/cell, respectively, and 3.1:1 in treated liver RNA, with 2800 and 900 molecules/cell. The ratios were 1.6 and 2:1 in control and treated kidney, and 0.31:1 in testis. This is likely to be due to differential splicing, which is, therefore, regulated during peroxisome proliferation, and also in a tissue specific fashion.

Localization and differential induction of cytochrome P450IVA and acyl-CoA oxidase in rat liver.

The peroxisome proliferators are structurally diverse chemicals which induce hyperplasia, hypertrophy and the proliferation of peroxisomes in the rodent liver. Cytochrome P450IVA1 and peroxisomal enzymes, such as acyl-CoA oxidase, are induced and are early markers of treatment with peroxisome proliferators. In this study, rats were dosed intraperitoneally with the potent peroxisome proliferator methylclofenapate and the hepatic induction response was studied. There was no significant change in the enzyme activities of laurate hydroxylase (cytochrome P450IVA1) or acyl-CoA oxidase in the first 8 h after treatment, but the activities had doubled at 24 h, suggesting that these enzymes are not involved in the mediation of early events in peroxisome proliferation. Hepatic cytochrome P450IVA1 mRNA was significantly increased at 6 and 8 h after treatment, rising to 15-fold above control values at 30 h. In contrast, acyl-CoA oxidase mRNA showed no significant change in the first 8 h, but increased to 13-fold above control values at 24 and 30 h, thereby demonstrating different kinetics of induction of the two mRNAs. In order to determine whether cytochrome P450IVA1 and peroxisomal enzymes were included in the same cells, rats were treated daily with sub-maximal (2 or 5 mg/kg) and maximal (25 mg/kg) inducing doses of methylclofenapate for 4 days. The lobular distribution of induced proteins was determined immunocytochemically with antibodies raised against P450IVA1 and acyl-CoA oxidase. Livers from control animals showed minimal staining for both proteins. However, in the livers of animals treated with 2 or 5 mg of methylclofenapate/kg, both acyl-CoA and P450IVA immunostaining was increased, mainly in the centrilobular area. Immunostaining of serial sections revealed that these proteins were induced in the same region of the lobule. A maximal inducing dose of methylclofenapate (25 mg/kg) caused panlobular induction of both proteins. The results demonstrate that these proteins are induced in a dose-dependent manner in the same, spatially distinct, sensitive region of the liver lobule.