Identification of a peroxisome proliferator-responsive element upstream of the human peroxisomal fatty acyl coenzyme A oxidase gene

Peroxisome proliferators cause a rapid and coordinated transcriptional activation of genes encoding the enzymes of the peroxisomal beta-oxidation pathway in rats and mice. Cis-acting peroxisome proliferator responsive elements (PPREs) have been identified in the 5'-flanking region of H202-producing rat acyl-CoA oxidase (ACOX) gene and in other genes inducible by peroxisome proliferators. To gain more insight into the purported nonresponsiveness of human liver cells to peroxisome volume density and in the activity of the beta-oxidation enzyme system, we have previously cloned the human ACOX gene, the first and rate-limiting enzyme of the peroxisomal beta-oxidation system. We now present information on a regulatory element for the peroxidase proliferator-activated receptor (PPAR)/retinoid X receptor (RXR) heterodimers. The PPRE, consists of AGGTCA C TGGTCA, which is a direct repeat of hexamer half-sites interspaced by a single nucleotide (DR1 motif). It is located at -1918 to -1906 base pairs upstream of the transcription initiation site of this human ACOX gene. This PPRE specifically binds to baculovirus-expressed recombinant rat PPAR alpha/RXR alpha heterodimers. In transient transfection experiments, the maximum induction of luciferase expression by ciprofibrate and/or 9-cis-retinoic acid is dependent upon cotransfection of expression plasmids for PPAR alpha and RXR alpha. The functionally of this human ACOX promoter was further demonstrated by linking it to a beta-galactosidase reporter gene or to a rat urate oxidase cDNA and establishing stably transfected African green monkey kidney (CV1) cell lines expressing reporter protein. The human ACOX promoter has been found to be responsive to peroxisome proliferators in CV1 cells stably expressing PPAR alpha, whereas only a basal level of promoter activity is detected in stably transfected cells lacking PPAR alpha. The presence of a PPRE in the promoter of this human peroxisomal ACOX gene and its responsiveness to peroxisome proliferators suggests that factors other than the PPRE in the 5'-flanking sequence of the human ACOX gene may account for differences, if any, in the pleiotropic responses of humans to peroxisome proliferators.

Immunohistochemical analysis of p53 mutations in bronchioloalveolar carcinoma and conventional pulmonary adenocarcinoma

Mutations of p53 tumor suppressor gene have been shown to contribute to tumorigenesis in a variety of human cancers. Normally, p53 protein degrades rapidly and is not detected by immunohistochemical procedure, but mutant p53 and wild-type p53 stabilized by certain viral oncoproteins can accumulate to immunohistochemically demonstrable levels. Conventional pulmonary adenocarcinomas and bronchioalveolar carcinomas, although morphologically similar, exhibit different biological behavior and clinical prognosis. To explore the differences in the expression of p53 protein in these two tumor types, we performed immunohistochemistry on 10 conventional pulmonary adenocarcinomas and 12 bronchioalveolar carcinomas on formalin-fixed and paraffin-embedded material, using the commercially available monoclonal antibody against the mutant p53 protein. Intense nuclear staining was observed in 80% (8/10) of conventional pulmonary adenocarcinomas, whereas all 12 bronchioalveolar carcinomas were negative for p53 protein. These observations indicate that altered p53 protein (probably mutant) is overexpressed in conventional adenocarcinomas and may be involved in its tumorigenesis or progression. On the other hand, the lack of p53 expression in bronchioalveolar carcinomas suggests that an alternative pathway is likely to be responsible for its tumorigenesis. Furthermore, p53 protein immunostaining may be useful as an adjunct in differentiating conventional pulmonary adenocarcinomas from bronchioalveolar carcinomas.

Phytic acid, an iron chelator, attenuates pulmonary inflammation and fibrosis in rats after intratracheal instillation of asbestos

Reactive oxygen species, especially iron-catalyzed hydroxyl radicals (.OH) are implicated in the pathogenesis of asbestos-induced pulmonary toxicity. We previously demonstrated that phytic acid, an iron chelator, reduces amosite asbestos-induced .OH generation, DNA strand break formation, and injury to cultured pulmonary epithelial cells (268[1995, Am. J. Physiol.(Lung Cell. Mol. Physiol.) 12:L471-480]). To determine whether phytic acid diminishes pulmonary inflammation and fibrosis in rats after a single intratracheal (it) instillation of amosite asbestos, Sprague-Dawley rats were given either saline (1 ml), amosite asbestos (5 mg; 1 ml saline), or amosite treated with phytic acid (500 microM) for 24 hr and then instilled. At various times after asbestos exposure, the rats were euthanized and the lungs were lavaged and examined histologically. A fibrosis score was determined from trichrome-stained specimens. As compared to controls, asbestos elicited a significant pulmonary inflammatory response, as evidence by an increase (approximately 2-fold) in bronchoalveolar lavage (BAL) cell counts at 1 wk and the percentage of BAL neutrophils (PMNs) and giant cells at 2 wk (0.1 vs 6.5% and 1.3 vs 6.1%, respectively; p < 0.05). Asbestos significantly increased the fibrosis score at 2 wk (0 +/- 0 vs 5 +/- 1; p < 0.05). The inflammatory and fibrotic changes were, as expected, observed in the respiratory bronchioles and terminal alveolar duct bifurcations. The increased percentage of BAl PMNs and giant cells persisted at 4 wk, as did the fibrotic changes. Compared to asbestos alone, phytic acid-treated asbestos elicited significantly less BAL PMNs (6.5 vs 1.0%; p < 0.05) and giant cells (6.1 vs 0.2%; p < 0.05) and caused significantly less fibrosis (5 vs 0.8; p < 0.05) 2 wk after exposure. We conclude that asbestos causes pulmonary inflammation and fibrosis in rats after it instillation and that phytic acid reduces these effects. These data support the role of iron-catalyzed free radicals in causing pulmonary toxicity from asbestos in vivo.

Transformation of mammalian cells by overexpressing H2O2-generating peroxisomal fatty acyl-CoA oxidase

Peroxisome proliferators induce qualitatively predictable pleiotropic responses, including development of hepatocellular carcinomas in rats and mice despite the inability of these compounds to interact with and damage DNA directly. In view of the nongenotoxic nature of peroxisome proliferators, it has been postulated that hepatocarcinogenesis by this class of chemicals is due to a receptor-mediated process leading to transcriptional activation of H2O2-generating peroxisomal fatty acyl-CoA oxidase (ACOX) in liver. To test this hypothesis, we overexpressed rat ACOX in African green monkey kidney cells (CV-1 cells) under control of the cytomegalovirus promoter. A stably transfected CV-1 cell line overexpressing rat ACOX, designated CV-ACOX4, when exposed to a fatty acid substrate (150 microM linoleic acid) for 2-6 weeks, formed transformed foci, grew efficiently in soft agar, and developed adenocarcinomas when transplanted into nude mice. These findings indicate that sustained overexpression of H2O2-generating ACOX causes cell transformation and provide further support for the role of peroxisome proliferation in hepatocarcinogenesis induced by peroxisome proliferators.

Expression of peroxisomal enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase enzyme and its mRNA in peroxisome proliferator-induced liver tumors

We have examined ciprofibrate and dehydroepiandrosterone (DHEA)-induced hepatic lesions for the peroxisomal beta-oxidation system enzyme peroxisomal enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase (PBE) and its mRNA using SDS-polyacrylamide gel electrophoresis, antibodies and cDNA probe. All 12 neoplastic nodules and nine hepatocellular carcinomas (HCCs) that were analyzed for PBE mRNA by in situ hybridization showed an intense signal comparable to the adjacent non-neoplastic liver. SDS-polyacrylamide gel electrophoresis of postnuclear fractions of six HCC and adjacent liver tissue showed a marked increase in an 80 kDa polypeptide. Immunoblot and Northern blot analysis showed a marked increase in PBE enzyme and PBE mRNA respectively in HCC and adjacent non-neoplastic liver tissue. In control livers (animals not treated with peroxisome proliferators), the levels of PBE enzyme and mRNA were very low or undetectable. The results of this study clearly indicate that peroxisome proliferator (PP)-induced liver lesions express peroxisomal enzymes to the same extent as adjacent liver and that these enzymes are not useful markers for identification of PP-induced lesions.

An upstream region of the enoyl-coenzyme A hydratase/3-hydroxyacyl-coenzyme A dehydrogenase gene directs luciferase expression in liver in response to peroxisome proliferators in transgenic mice

Peroxisome proliferators, which are structurally diverse nonmutagenic agents, induce hepatocarcinogenesis in rats and mice. Exposure to these xenobiotics leads to a rapid and coordinated transcriptional activation of the genes for the peroxisomal beta-oxidation enzyme system pathway in the liver. We have previously identified a peroxisome proliferator-responsive element in the 5'-flanking region of the rat peroxisomal hydratase/dehydrogenase (PBE) gene, the second enzyme in the beta-oxidation pathway. The peroxisome proliferator-responsive element in the PBE gene was shown to direct the induction of a luciferase reporter gene in vitro. We have now used this 3.2-kilobase 5'-flanking region of the PBE gene fused to the coding region of luciferase to generate transgenic mice. Three independent lines of transgenic mice expressed luciferase in response to ciprofibrate, a peroxisome proliferator. The induction of luciferase is specific to the liver; this agrees with the tissue-specific induction of PBE. Two other hypolipidemic drugs, nafenopin and Wy-14,643, were also capable of inducing luciferase activity in the liver. This study suggests that the PBE upstream element can be used to direct and modulate the expression of cloned genes by changing the levels of peroxisome proliferators. Also, the PBE-luciferase transgenic mouse should be an excellent model system for screening xenobiotics for potential peroxisome proliferator property.

Increased expression of sulfated glycoprotein-2 and DNA fragmentation in the pancreas of copper-deficient rats

Recent morphological studies from our laboratory have shown that copper deficiency-induced pancreatic involution in rats is secondary to apoptosis (M. S. Rao, A. V. Yeldandi, V. Subbarao, and J. K. Reddy, 1993, Am. J. Pathol. 142, 1952-1957). To corroborate the morphological findings, we have examined pancreases from copper-deficient rats for expression of sulfated glycoprotein-2 (SGP-2) mRNA and DNA fragmentation, which are considered as specific markers of apoptosis. Agarose gel electrophoresis of the DNA extracted from pancreases of rats maintained on copper deficient diet (CUDD) for 5 and 7 weeks showed characteristic "ladder" pattern, whereas DNA from control rats and rats maintained on CUDD for 3 weeks showed no fragmentation. These findings correlated well with the histological changes. Northern blot analysis of total RNA revealed a marked increase in the expression of SGP-2 mRNA at 5 weeks followed by a gradual decrease at 6 and 7 weeks. These results further support that the mechanism of copper deficiency-induced pancreatic involution is through apoptosis.

Uric acid degrading enzymes, urate oxidase and allantoinase, are associated with different subcellular organelles in frog liver and kidney

On the basis of differential and density gradient centrifugation studies, the site of the uric acid degrading enzymes, urate oxidase and allantoinase, in amphibia was previously assigned to the hepatic peroxisomes. Using specific antibodies against frog urate oxidase and allantoinase, we have undertaken an immunocytochemical study of the localization of these two proteins in frog liver and kidney, and demonstrate that whereas urate oxidase is present in peroxisomes, allantoinase is localized in mitochondria. Urate oxidase and allantoinase were detected by immunoblot analysis in both frog liver and kidney. The subcellular localization of these two enzymes was ascertained by Protein A-gold immunocytochemical staining of Lowicryl K4M-embedded tissue. Peroxisomes in frog liver parenchymal cells and kidney proximal tubular epithelium contained a semi-dense subcrystalloid core, which was found to be the exclusive site of urate oxidase localization. Allantoinase was detected within mitochondria, but not in peroxisomes of hepatocytes or proximal tubular epithelium. No allantoinase was detected in the mitochondria of nonhepatic parenchymal cells in liver and of the cells lining the distal convoluted tubules of the kidney. These results demonstrate that, unlike rat kidney peroxisomes which lack urate oxidase, peroxisomes of frog kidney contain this enzyme. Contrary to previous assumptions, these studies also clearly establish that urate oxidase and allantoinase, the first two enzymes involved in uric acid degradation, are localized in different subcellular organelles in frog liver and kidney.

Pathologic features of lung biopsy specimens from influenza pneumonia cases

Most histopathologic descriptions of influenza pneumonia are based on autopsy findings in fatal cases during epidemics and pandemics of influenza. We describe the histologic findings of influenza pneumonia observed in biopsy material derived from six sporadic cases of influenza (influenza A, four cases; influenza B, one case; and influenza A and B, one case). Four patients recovered completely, one patient died, and one was lost to follow-up. In addition to confirming previously published pathologic descriptions of influenza pneumonia, we also document a spectrum of less severe histologic findings with mild acute lung injury and bronchiolitis obliterans with organizing pneumonia.

Role of apoptosis in copper deficiency-induced pancreatic involution in the rat

Rats maintained on a copper-deficient diet supplemented with a copper-chelating agent, triethylenetetramine tetrahydrochloride, for 8 to 10 weeks show marked involution of pancreatic acinar tissue. The present study deals with the possible mechanism of pancreatic acinar cell involution during copper deficiency. Sequential light and electron microscopic observations during the copper-depletion regimen, suggest that apoptosis is the main cause of progressive loss of acinar cells. At 4 weeks of copper deficiency, the apoptotic index was 2 +/- 0.6/1,000 cells. By 6 weeks, the apoptotic index reached a maximum of 95 +/- 25/1,000. By 8 weeks, there was almost total loss of acinar cells. The earliest change of apoptosis was characterized by condensation and margination of chromatin against nuclear membrane. Subsequently, several apoptotic bodies displayed pyknotic nucleus and eosinophilic cytoplasmic condensation. Apoptotic bodies were extruded into the interstitium or phagocytosed by unaffected acinar cells. No associated pancreatic inflammation was present. These results indicate that apoptosis is the process involved in pancreatic involution caused by copper deficiency. The molecular mechanism(s) by which copper deficiency causes apoptosis remain unclear.

Comparative effects of dehydroepiandrosterone and related steroids on peroxisome proliferation in rat liver

Dehydroepiandrosterone (DHEA) is known to induce peroxisome proliferation and peroxisomal enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase (PBE) mRNA in the rat liver. We have compared the effects of 6 intermediate metabolites of DHEA on the induction of peroxisome proliferation and PBE mRNA. Administration of epiandrosterone, etiocholanolone, androstenedione, estrone or estradiol for 2 weeks in the diet at 0.45% concentration to adult male F-344 rats failed to induce significant increases in peroxisome proliferation and PBE mRNA when compared to the parent compound DHEA. Dietary administration of 5-androstene-3 beta,17 beta-diol (ADIOL) for 2 weeks at 0.45% concentration caused an increase in PBE mRNA and peroxisome proliferation but to a lesser extent than DHEA. Following a single intragastric dose of DHEA an increase in PBE mRNA level was observed in the liver at 1 hr and continued to 16 hrs., but not with its metabolites. These results strongly suggest that DHEA or possibly another yet to be identified metabolite might be responsible for peroxisome proliferation.

Phenotypic properties of liver tumors induced by dehydroepiandrosterone in F-344 rats

Dehydroepiandrosterone (DHEA), a C19 adrenal steroid hormone, induces peroxisome proliferation in liver cells and is hepatocarcinogenic in the rat. The present study deals with the phenotypic properties of DHEA-induced liver lesions. A majority of the altered areas (80-87%), neoplastic nodules (> 94%) and hepatocellular carcinomas (HCC, 80-100%) lacked the marker enzymes gamma-glutamyltranspeptidase and placental form of glutathione S-transferase (GSTP). Northern blot analysis of HCC from 4 rats revealed no detectable GSTP mRNA. These HCC, however, showed a marked decrease in the staining of glucose-6-phosphatase and adenosine triphosphatase. These results indicate that the phenotypic properties of liver tumors induced by DHEA and amphipathic carboxylate peroxisome proliferators are similar.

Inhibition of spontaneous testicular Leydig cell tumor development in F-344 rats by dehydroepiandrosterone

The incidence of spontaneous Leydig cell tumors of testis is very high in old F-344 rats. We have examined the effect of dehydroepiandrosterone (DHEA), a steroid hormone with antimitotic and anticarcinogenic properties, on spontaneous Leydig cell tumorigenesis. Fifteen-week-old male F-344 rats were fed a diet containing DHEA (0.45% w/w) for 84 weeks. At the termination of experiment none of the 13 rats had Leydig cell hyperplasia or Leydig cell tumors. All the eight control rats of comparable age had Leydig cell tumors. These findings suggest that DHEA is a potent inhibitor of spontaneous Leydig cell tumors of testis in aged rats.

Rat urate oxidase produced by recombinant baculovirus expression: formation of peroxisome crystalloid core-like structures

Urate oxidase (EC 1.7.3.3), which catalyzes the oxidation of uric acid to allantoin, is present in most mammals but absent in humans and hominoid primates. In rats and most other mammals that catabolize uric acid to allantoin, this enzyme is localized within the crystalloid cores of peroxisomes present in liver parenchymal cells. To determine whether urate oxidase forms these crystalloid cores or whether core-forming protein(s) exist in association with urate oxidase, a baculovirus expression vector system was used to overproduce the full-length rat urate oxidase in Spodoptera frugiperda cells. Urate oxidase was expressed to a level of approximately 30% of the total protein in this system. Immunoblot analysis demonstrated that the baculovirus-generated protein had electrophoretic and immunologic properties similar to those of urate oxidase expressed in rat liver. Immunofluorescence and electron microscopic examination revealed that the overexpressed recombinant urate oxidase is present in both the cytoplasm and the nucleus of infected insect cells as numerous 1- to 3-microns discrete particles. These insoluble protein aggregates, which were positively stained for urate oxidase by protein A-gold immunocytochemical approach, did not appear to be delimited by a single membrane. They revealed a crystalloid structure reminiscent of rat peroxisomal core consisting of bundles of tubules with an inner diameter of approximately 50 A. The recombinant urate oxidase particles, isolated by a single-step procedure, were composed entirely of 35-kDa urate oxidase subunit. These studies indicate that rat urate oxidase is capable of forming insoluble crystalloid core-like structures.

Hepatocarcinogenicity of dehydroepiandrosterone in the rat

Dehydroepiandrosterone, a major secretory steroid hormone of the human adrenal gland, possesses mitoinhibitory and anticarcinogenic properties. It also induces peroxisome proliferation in the livers of rats and mice. Because peroxisome proliferators exhibit hepatocarcinogenic potential, it is necessary to examine the long term hepatic effects of dehydroepiandrosterone since this hormone is contemplated for use as a potential cancer chemopreventive agent in humans. Dehydroepiandrosterone was administered in the diet at a concentration of 0.45% to F-344 rats for up to 84 weeks. At the termination of the experiment, 14 of 16 rats developed hepatocellular carcinomas. Liver tumors induced by dehydroepiandrosterone lacked gamma-glutamyl transpeptidase and glutathione S-transferase (placental form); these phenotypic properties are identical to the features exhibited by liver tumors induced by other peroxisome proliferators. Dehydroepiandrosterone was also shown to markedly inhibit liver cell [3H]thymidine labeling indices, suggesting that cell proliferation is not a critical feature in liver tumor development with this agent. These results show that although dehydroepiandrosterone exerts anticarcinogenic effects in a variety of tissues, the peroxisome-proliferative property makes it a hepatocarcinogen.

Localization of the human urate oxidase gene (UOX) to 1p22

The human urate oxidase (E.C.1.7.3.3) gene, UOX, is assigned to chromosome 1 by Southern analysis of human x hamster cell hybrids. Using fluorescent in situ hybridization, we have mapped this gene to 1p22.

Molecular evolution of the urate oxidase-encoding gene in hominoid primates: nonsense mutations

Nucleotide sequences of portions of second and fifth exons of urate oxidase encoding gene (UOX) of chimpanzee, gorilla, orangutan, rhesus monkey and squirrel monkey obtained following amplification by polymerase chain reaction have been compared with corresponding sequences of human, baboon and rat UOX. Two or more nonsense mutations are found in the coding regions of this UOX gene thus far analyzed in human, chimpanzee, gorilla and orangutan, but not in the baboon, rhesus monkey and squirrel monkey. Of these nonsense mutations, the stop codon at amino acid position 33 is constant in the human and the three great apes suggesting that this may be the original mutation responsible for the inactivation of the UOX gene during hominoid evolution.

Pancreatic hepatocytes. An in vivo model for cell lineage in pancreas of adult rat

Multiple foci of hepatocytes differentiate in the pancreas of adult rats subjected to a copper depletion-repletion regimen. Copper deficiency for seven to nine weeks causes an irreversible depletion of over 80% of the acinar cells in the pancreas. When transferred to a normal diet, these rats exhibit only a minimal and spotty acinar cell recovery. This disruption of tissue organization appears to trigger a profound change in cellular commitment, which leads to hepatocyte differentiation in the "oval cells" in the periductal interstitium and the epithelial cells lining the small pancreatic ductules. Pancreatic hepatocytes express several liver-specific genes including albumin, a2u-globulin, carbamoylphosphate synthetase-I, and urate oxidase. Both carbamoylphosphate synthetase-I and glutamine synthetase, the ammonia-metabolizing enzymes, are expressed by all pancreatic hepatocytes; in liver, these are expressed by different populations of hepatocytes. The magnitude of hepatocyte differentiation in this model should facilitate studies on the molecular events regulating changes in cell lineage or differentiation commitment within the pancreas.

Human urate oxidase gene: cloning and partial sequence analysis reveal a stop codon within the fifth exon

Using the cDNA and selected genomic probes of rat urate oxidase, we have screened the human genomic library and isolated seven clones; one clone (clone 13) contained exonic regions which correspond to the exons 5, 6, and 7 of rat urate oxidase gene. The nucleotide sequence was determined for these three exons and exon/intron junctions, and compared with the sequence from the rat gene. A mutation resulting in a stop codon TGA was found in the fifth exon of the human urate oxidase gene. Sequence analysis of the polymerase chain reaction amplified DNA, corresponding to the fifth exon of urate oxidase from DNA samples from four different individuals, confirmed the same TGA stop codon in all. This single stop codon mutation and/or other mutation(s) in this gene may be responsible for the lack of urate oxidase activity in the human.

Quantitative analysis of hepatocellular lesions induced by di(2-ethylhexyl)phthalate in F-344 rats

Di(2-ethylhexyl)phthalate (DEHP), a peroxisome proliferator, has been shown to be a weak hepatocarcinogen in rats and mice. However, in previous studies no quantitative analysis of tumors was carried out. In the present study, F-344 male rats were given a diet containing 2% DEHP ad libitum for 108 wk. At necropsy livers were quantitatively analyzed for total tumor incidence and the number of lesions per liver after slicing the entire organ at 1- to 2-mm intervals. Neoplastic nodules and/or hepatocellular carcinomas were observed in 11 of 14 rats (78.5%). When evaluated according to the size, 57, 16, and 36% rats contained nodules ranging from 1 to 3, 3 to 5, and greater than 5 mm in size, respectively. The number of nodules per liver ranged from zero to four. These results indicate that DEHP induces tumors in a large number of animals at 2% dose levels. It is clear from this study that when a weak peroxisome proliferator is evaluated for carcinogenic effects, a complete and thorough gross examination of the liver is essential to obtain accurate tumor incidence.

Coexpression of glutamine synthetase and carbamoylphosphate synthase I genes in pancreatic hepatocytes of rat

In the mammalian liver the distribution of ammonia-detoxifying enzymes, glutamine synthetase (GS) and carbamoylphosphate synthase I (ammonia) (CPS-I), is mutually exclusive in that these enzymes are expressed in two distinct populations of hepatocytes that are zonally demarcated in the liver acinus. In the present study we examined the distribution of GS and CPS-I in pancreatic hepatocytes to ascertain if the expression of these two genes in these hepatocytes is also mutually exclusive. Multiple foci of hepatocytes showing no clear acinar organization develop in the adult rat pancreas as a result of a change in the differentiation commitment after dietary copper deficiency. Unlike liver, GS and CPS-I are detected by immunofluorescence in all pancreatic hepatocytes. In situ hybridization revealed that all pancreatic hepatocytes contain GS and CPS-I mRNAs. The sizes of these two mRNAs in pancreas with hepatocytes are similar to those of the liver. The concomitant expression of GS and CPS-I genes in pancreatic hepatocytes may be attributed, in part, to the absence of portal blood supply to the pancreas vis-à-vis the lack of hormonal/metabolic gradients as well as to possible matrix homogeneity in the pancreas.

Androgen regulated expression of the alpha 2u-globulin gene in pancreatic hepatocytes of rat

Under a copper-deficient regimen, pancreatic cells in the adult rat can be found to undergo differentiation into hepatocytes. Pancreatic hepatocytes induced in male and female rats were examined for the expression of the androgen-inducible hepatic protein, alpha 2u-globulin. Alpha 2u-Globulin protein was demonstrable by immunoperoxidase method in all the pancreatic hepatocytes of male rats. Northern blot analysis confirmed the presence of 1.3 kb alpha 2u-globulin mRNA transcript in the pancreas of male rats with hepatocytes. Orchiectomy resulted in marked decrease of alpha 2u-globulin protein and its mRNA. Administration of dihydrotestosterone to castrated rats resulted in increased levels of alpha 2u-globulin mRNA and the amount of alpha 2u-globulin protein in the pancreatic hepatocytes. Unlike normal males, in intact and ovariectomized females alpha 2u-globulin was not detectable in pancreatic hepatocytes. These results indicate that similar to hepatic parenchymal cells pancreatic hepatocytes synthesize alpha 2u-globulin under androgenic regulation. Furthermore, unlike in liver where it is expressed predominantly in perivenular and midlobular hepatocytes, there is no localized difference in the expression of this gene in the transdifferentiated pancreatic hepatocytes.

Differentiation and cell proliferation patterns in rat exocrine pancreas: role of type I and type II injury

Fully differentiated and functionally specialized acinar cells of the rat pancreas are versatile and adaptable. Acinar cells can be stimulated to divide following administration of a mitogen or after inducing acinar cell necrosis. The degree of compensatory hyperplasia is dependent upon the extent of acinar cell necrosis. Type I injury (subtotal acinar cell necrosis) is followed by marked proliferation of acinar cells leading to complete restitution of the pancreas, whereas subsequent to type II injury (global acinar cell necrosis) there is no restitution of the pancreas because of lack of enough viable cells that have served as precursor cells. Associated with type Ii injury there is proliferation of ductular and periductular cells followed by the development of hepatocytes. In addition, during adverse conditions acinar cells undergo dedifferentiation and form pseudoductular structures. In rats, acinar tissue is a prime target for carcinogens. Transformed acinar cells form foci which are morphologically classified as acidophilic and basophilic lesions. Acidophilic foci which show increased cell proliferation progress to form nodules and acinar cell carcinomas.

Evaluation of liver cell proliferation during ciprofibrate-induced hepatocarcinogenesis

To determine if the carcinogenic potential of peroxisome proliferators is dependent upon their ability to induce cell proliferation, we have investigated the extent of cell proliferation in the livers of rats fed ciprofibrate, a peroxisome proliferator. Male rats were maintained on a diet containing ciprofibrate (0.025% w/w) and killed at selected intervals following 1 week of continuous [3H]thymidine labeling. Evaluation of labeling indices demonstrated a significant increase in cell proliferation during the first week but not in rats killed at the end of 5 and 20 weeks of treatment. Increases in hepatocyte nuclear labeling were found at 40 and 70 weeks of ciprofibrate administration which coincided with the appearance in livers of putative preneoplastic and neoplastic lesions. In a short-term feeding study, ciprofibrate and ethoxyquin were fed to rats at a dietary concentration of 0.025% and 0.5%, respectively, either alone or in combination for 7 days. Ciprofibrate and ethoxyquin either alone or in combination produced marked hepatomegaly and a significant increase in DNA synthesis as demonstrated by [3H]thymidine incorporation and autoradiographic studies. DNA synthesis in the group receiving ciprofibrate and ethoxyquin simultaneously, was slightly more than in animals that received either compound alone, suggesting a synergistic effect, although chronic feeding of these agents together resulted in inhibition of liver carcinogenesis (Rao, M. S. et al. (1984) Cancer Res., 44, 1072-1076). The results of this study further suggest that cell proliferation induced by peroxisome proliferators may be less important in carcinogenesis than peroxisome proliferation induced by these compounds.