Cytokeratin-19 positivity is acquired along cancer progression and does not predict cell origin in rat hepatocarcinogenesis

Although the expression of the stem/progenitor cell marker cytokeratin-19 (CK-19) has been associated with the worst clinical prognosis among all HCC subclasses, it is yet unknown whether its presence in HCC is the result of clonal expansion of hepatic progenitor cells (HPCs) or of de-differentiation of mature hepatocytes towards a progenitor-like cell phenotype. We addressed this question by using two rat models of hepatocarcinogenesis: the Resistant-Hepatocyte (R-H) and the Choline-methionine deficient (CMD) models. Our data indicate that the expression of CK-19 is not the result of a clonal expansion of HPCs (oval cells in rodents), but rather of a further step of preneoplastic hepatocytes towards a less differentiated phenotype and a more aggressive behavior. Indeed, although HCCs were positive for CK-19, very early preneoplastic foci (EPFs) were completely negative for this marker. While a few weeks later the vast majority of preneoplastic nodules remained CK-19 negative, a minority became positive, suggesting that CK-19 expression is the result of de-differentiation of a subset of EPFs, rather than a marker of stem/progenitor cells. Moreover, the gene expression profile of CK-19-negative EPFs clustered together with CK-19-positive nodules, but was clearly distinct from CK-19 negative nodules and oval cells.

Conclusion

i) CK-19-positive cells are not involved in the early clonal expansion observed in rat hepatocarcinogenesis; ii) CK-19 expression arises in preneoplastic hepatocyte lesions undergoing malignant transformation; iii) CK-19 positivity in HCCs does not necessarily reflect the cell of origin of the tumor, but rather the plasticity of preneoplastic cells during the tumorigenic process.     

Production of monoclonal antibodies to preneoplastic liver cell populations induced by chemical carcinogens in rats and to transplantable Morris hepatomas

Monoclonal antibodies (moabs) to neoplastic and preneoplastic liver cells in rats have been selected to follow cellular changes in the livers during chemical carcinogenesis. The moabs were induced by immunizations of BALB/c mice with four partially purified liver cell preparations: 1) oval cells induced in male Fischer rats fed 0.05% N-2-acetylaminofluorene in a choline deficient diet: 2) preneoplastic gamma-glutamyltranspeptidase positive hepatocytes induced by i.p. injection of diethylnitrosamine into male Fischer rats followed by 0.02% N-2-acetylaminofluorene and partial hepatectomy (Solt-Farber model): 3) sharply dissected neoplastic nodules induced in male Fischer rats by five 2-week cycles of 0.05% N-2-acetylaminofluorene diet: and 4) Morris hepatomas 7777 and 5123 passaged in male Buffalo rats. The hybridomas were screened by enzyme linked immunosorbent assay or by indirect immunofluorescence on composite cryostat sections of fetal and adult rat liver, liver containing neoplastic nodules, and Morris hepatoma 7777. Positive clones were limit diluted and partially characterized by indirect immunofluorescence on cryostat sections of other preneoplastic and neoplastic rat livers as well as normal rat tissues. Two moabs to oval cells, two moabs to hepatocytes, and one moab to hepatomas have been selected for further study.     

Increased Telomerase Activity in Hyperplastic Nodules and Hepatocellular Carcinomas Induced by a Choline-deficient L-Amino Acid-defined Diet in Rats

Activation of telomerase has been reported in several human cancers, including hepatocellular carcinomas (HCCs). We investigated telomerase activity during hepatocarcinogenesis induced by a choline-deficient L-amino acid-defined (CDAA) diet in rats. Male F344 rats were given a CDAA diet or a choline-supplemented L-amino acid-defined (CSAA) diet from 6 weeks of age for 75 weeks, and subgroups were killed 10 weeks, 50 weeks and 75 weeks after the beginning of the experiment. Hyperplastic nodules and HCCs were noted in rats fed a CDAA diet for 50 weeks and 75 weeks, respectively. Normal control liver specimens were obtained from 6-week-old rats. Telomerase activity was assessed by using a telomeric repeat amplification protocol (TRAP). Normal liver and background parenchyma of rats fed either of the diets for 10 weeks or 50 weeks showed weak telomerase activity. In contrast, markedly increased levels were demonstrated in hyperplastic nodules and HCCs. These results suggest that increased telomerase activity may be a biological feature of preneoplastic lesions that evolve to HCCs in rat liver.     

Persistence of the cholangiocellular and hepatocellular lesions observed in rats fed a choline-deficient/DL-ethionine-supplemented diet.

Male outbred Sprague-Dawley rats were fed a choline-deficient diet containing 0.10% DL-ethionine (CDE) for 4, 6, 10, 14 or 22 weeks followed by a standard diet for up to 59 weeks. Liver sections were histochemically analyzed for the following parameters: basophilia, glycogen content and the activities of glycogen synthase (SYN), glycogen phosphorylase (PHO), glucose-6-phosphatase (G6PASE), glucose-6-phosphate dehydrogenase (G6PDH), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), glycerin-3-phosphate dehydrogenase (G3PDH), 'malic enzyme' (MDH), alkaline phosphatase (ALKPASE) and gamma-glutamyltranspeptidase (GGT). The stop experiments revealed that many of the oval cells proliferating during the first 4-6 weeks may undergo necrotic changes and disappear with time, whereas cholangiofibroses appearing in animals fed CDE for at least 10 weeks are persistent lesions. The sequence of lesions seen in this study, leading from persistent oval cells through cholangiofibroses to cholangiofibromas, strongly suggests that the oval cells are the precursor cells of cholangiocellular tumors. The proliferating oval cells and the hepatic foci consisting of clear and acidophilic or mixed cell populations were always spatially separated and no transitions between oval and parenchymal cells were observed. These results argue against a precursor-product relationship between oval and parenchymal cells. Both proliferating and persistent oval cells, cholangiofibroses and cholangiofibromas showed a strong staining for G6PDH, GAPDH, G3PDH, MDH, ALKPASE and GGT; low PHO, SYN and G6PASE activities were also detected in these lesions. Persistent glycogen-storage foci, which developed in all rats fed CDE for 4-14 weeks followed by a normal lab chow for over a year, had increased PHO, G6PDH, MDH, ALKPASE and GGT activities, while SYN, GAPDH and G3PDH activities remained unaltered and G6PASE activity decreased. Mixed cell foci appearing in animals fed CDE for 22 weeks followed by a normal lab chow for 59 weeks had strongly increased G6PDH, GAPDH, G3PDH, MDH, ALKPASE and GGT activities as well as decreased G6PASE activity. These results indicate that the characteristic metabolic pattern of preneoplastic hepatic foci is independent of the further administration of the carcinogenic diet. The shift from glycogen metabolism to glycolysis and the pentose phosphate pathway occurring during the later stages of CDE-induced hepatocarcinogenesis is an autogenous process apparently directing the disturbed carbohydrate metabolism towards alternative metabolic pathways. A similar metabolic shift also seems to take place during cholangiocarcinogenesis.     

Antigenic relationship between oval cells and a subpopulation of hepatic foci, nodules, and carcinomas induced by the "resistant hepatocyte" model system

Although proliferation of small ductular-like cells, designated oval cells, is often observed during the early stages of chemically induced hepatocarcinogenesis, their role during the carcinogenic process remains controversial. To investigate the possibility that oval cells may give rise to preneoplastic lesions that ultimately progress to hepatocellular carcinomas, we have carried out phenotypic analysis with a panel of monoclonal antibodies to determine if there is an antigenic relationship between oval cells and hepatic foci, nodules, and tumors induced by the resistant hepatocyte model system. In this model, rats are given a single dose (200 mg/kg) of diethylnitrosamine, followed by a brief exposure to 2-acetylaminofluorene and a partial hepatectomy. We found that approximately 10% of the early focal lesions observed 28 days after diethylnitrosamine expressed either one or both of the oval cell antigens designated OC.2 and OV-6. By 28 weeks after diethylnitrosamine, 16 of 16 hepatic nodules heterogeneously expressed OV-6 whereas 5-10% of the persistent nodules contained scattered small hepatocyte-like cells that expressed OC.2. Examination of resistant hepatocyte-induced primary hepatocellular carcinomas with an expanded panel of monoclonal antibodies demonstrated that most cells comprising 29 of 29 tumors expressed OV-6 and that 15-20% of the OV-6-positive tumors contained subpopulations of cells also expressing 3 additional oval cell antigens, OC.2, OC.3, and OV-1. All of the tumors examined expressed normal levels of the hepatocyte antigens, H.1 and HBD.1, and had dramatically reduced levels of H.2, H.4, and cell CAM 105 but showed elevated levels of the transferrin receptor, gamma-glutamyltranspeptidase, and the normal hepatocyte antigen, H.5. In conclusion, our findings demonstrate an antigenic relationship between oval cells and a subpopulation of hepatic foci, nodules, and tumors in the resistant hepatocyte model, suggesting that at least some primary tumors may be derived from oval cells in this model system.     

Ethanol interactions with a choline-deficient,ethionine-supplemented feeding regime potentiate pre-neoplastic cellular alterations in rat liver

To examine the effect of ethanol on hepatocarcinogenesis induced by a choline-deficient, ethionine-supplemented (CDE) diet, rats were fed either an ethanol-supplemented diet or ethanol-free, isocaloric diet for 2 months, followed by a CDE diet or control diet for up to 8 months. Changes to cellular composition and pattern of gene expression in the liver were determined at 0 and 3 days, and 1, 2 and 3 weeks after commencing the CDE diet, using histological/immunochemical techniques and northern analysis. Oval cells in the liver were identified morphologically and by expression of pi-glutathione S-transferase (pi-GST), alpha-fetoprotein (AFP) and the embryonic isoform of pyruvate kinase (M2-PK). Oval cell numbers and changes in the pattern of gene expression induced by the CDE diet were accelerated by pre-treatment with ethanol. At all stages, the proportion of oval cells in the test group exceeded that in controls. After 1 week, oval cells had spread sufficiently from the periportal region to be observed pericentrally in test animals and by 3 weeks, extensive formation of ductal structures was apparent, which were absent in controls. Additionally, M2-PK and AFP mRNA were detected earlier, and in greater abundance in animals pre-treated with ethanol. After 8 months of CDE treatment, one or two small hepatic foci (<10 hepatocytes), strongly positive for pi-GST, were detected in the liver of ethanol-pre-treated animals. These foci were absent in CDE-treated animals; however, animals pre-treated with ethanol followed by chronic CDE treatment showed increased size (>40 hepatocytes) and numbers of foci, correlating with the extent of liver damage and varying from 5 to 50% of the liver section. Our data suggest that ethanol pre-treatment potentiates the short-term effects of the CDE diet by enhancing oval cell proliferation, while chronic CDE administration enhances the appearance of pre-malignant hepatic foci that are observed with ethanol pre-treatment alone.     

Peroxisome proliferator-induced hepatocarcinogenesis: histochemical analysis of ciprofibrate-induced preneoplastic and neoplastic lesions for gamma-glutamyl transpeptidase activity

Previous studies revealed that putative preneoplastic and neoplastic lesions induced in the liver by Wy-14,643, a peroxisome proliferator, were gamma-glutamyl transpeptidase (GGT) negative. For ascertainment as to whether phenotypes of foci and carcinomas induced by all peroxisome proliferators are similarly GGT negative, altered areas (AAs), neoplastic nodules (NNs), and hepatocellular carcinomas (HCCs) induced in the livers of male F344 rats by chronic dietary administration of ciprofibrate (0.025% wt/wt in chow; CAS: 52214-84-3) were analyzed histochemically for GGT activity. Eighty-nine percent of AAs, 91% of NNs, and 91% of HCCs were GGT negative. The GGT-negative property of these various hepatic preneoplastic and neoplastic lesions persisted at 8 weeks after the withdrawal of ciprofibrate treatment. The results of this study indicate that the absence of GGT activity is a common feature in hepatic lesions induced by structurally unrelated peroxisome proliferators and is not related to the drug toxicity. The proposal was made that peroxisome proliferators do not derepress the activity of the GGT gene during hepatocarcinogenesis in the rat.     

Expression of alpha, mu and pi class glutathione S-transferases in oval and ductal cells in liver of rats placed on a choline-deficient, ethionine-supplemented diet.

Expression of the alpha, mu and pi class glutathione S-transferases (GSTs) in hepatocytes, oval cells and ductal cells derived from the livers of rats placed on a choline-deficient, ethionine-supplemented (CDE) diet for 5 weeks was investigated. An overall decrease in the expression of alpha and mu class GSTs and an over-expression of pi class GST was observed in the liver after CDE treatment as indicated by Northern blotting analysis. Massive disruption of the liver with oval cell infiltration in the sinusoids throughout the lobule occurred after 5 weeks CDE treatment. 'Duct-like' structures consisting of oval-like cells (ductal cells) with rounder nuclei and more cytoplasm than oval cells within the sinusoids were also apparent. Immunocytochemical analysis revealed that the altered expression of GST in the whole liver is attributed to a differential expression of alpha, mu and pi class GSTs in the different cell types in the liver, including hepatocytes, oval cells around the portal region and among the sinusoids, and oval-like cells (ductal cells) in the 'duct-like' structures. In vitro studies using purified oval-ductal cells and hepatocyte populations confirmed the differential expression of GSTs in the varying cell populations in situ. The expression of the alpha and mu class GSTs in hepatocytes does not appear to be altered by the CDE diet. Heterogeneity in distribution of pi class GST was observed in the hepatocyte population, some hepatocytes were stained strongly while no staining was observed in others. Oval and ductal cells represent two distinct populations displaying different expression of GSTs. Pi class GST was detected in the majority of oval and ductal cells. Alpha class GST was detected in < 5% of the oval cell population and was found in > 50% of the ductal cell population. In contrast, mu class GST was absent in ductal cells and was present in 24% of oval cells around the portal region. This supports the view that ductal cells are not of bile ductal origin since mu GST is present in normal bile duct epithelial cells. Furthermore the change in expression of GSTs in the liver after CDE treatment is attributed to the large increase in oval and ductal cell populations.     

Modification of the cellular cytoskeleton and hepatic tumor promotion

Non transformed epithelial hepatic cells (established cell line and adult rat hepatocytes) treated by liver tumor promoters, phenobarbital and biliverdin, for 24 and 48 h showed a fragmentation and loss of F-actin and a depolymerisation of microtubules. This pattern closely resembles that of transformed cells which were not susceptible to the action of promoters. In liver preneoplastic nodules obtained from rats submitted to an initiation-promotion process, actin almost completely disappeared with the concomitant appearance of a characteristic enzymatic pattern rich in GGT and GST-P. Therefore, cytoskeleton of hepatic cells is a target for tumor promoters and could play a role in promotion mechanism.     

Differentiation of oval cells into duct-like cells in preneoplastic liver of rats placed on a choline-deficient diet supplemented with ethionine

Feeding male Wistar rats a choline-deficient diet containing0.07% DL-ethionine (CDE diet) for up to 5 weeks results in theproduction of two distinct non-parenchymal cell populations,oval and duct-like cells. These cells can undergo replicationand display different patterns ofexpression of glutathione S-transferases(GSTs) and pyruvate kinases (PKs). Oval cells were firstdetectedaround the periportal region after 1 week of CDE treatment andinfiltrated the parenchyma after 2 weeks. Duct-like structuresfirst appeared as isolated ducts in the parenchymal region at2 weeks and were easily detected after 2.5 weeks. These duct-likestructures differed from thebile ducts which reside in the portalregion. Large concentrations of duct-like structures in cyst-likeclusters were detected after 5 weeks. Enlargement of these structuresfrom single ducts toclusters of up to 20 ducts was observedover 3–5 weeks of CDE treatment. The number of cells forminga duct increased from 5 to 30 cells. We established a doubleimmunocytochemical staining technique to characterize the ovaland duct-like cells for their expression of GSTs and PKs.     

Expression of L- and M2-pyruvate kinases in proliferating oval cells and cholangiocellular lesions developing in the livers of rats fed a methyl-deficient diet

Male outbred Sprague-Dawley rats were fed a cholinedeficientdiet containing 0.1% w/w DL-ethionine (CDE) for up to 22 weeks.The expression of the pyruvate kinase isoenzymes L (L-PK) andM₂ (M₂ was immunohistochemically analyzed in liver slices fromrats killed 4, 10, 14 and 22 weeks after starting the treatment.M₂ was detected in bile duct epithelial cells of untreated ratsand in proliferating oval cells, cholangiofibroses and cholangiofibromasof CDE-fed animals. Thus, M₂ can be viewed as a positive markerof the bile duct epithellial/oval cell compartment. L-PK, aparenchymal cell-specific protein in untreated rat liver, wasnot present In proliferating oval cells, but was consistentlyobserved In cells that were part of the ductal structures inthe cholangiofibroses and cholanglofibromas. Based on theirmorphology, the L-PK-posltlve duct cells were undoubtedly partof the bile duct epithellal cell lineage and no L-PK-positivehepatocyte-like cells were observed in the ducts. Hence, thisstudy clearly shows that the mere presence of a liver parenchymalcell marker in cells of the bile duct epithelial/oval cell compartmentdoes not necessarily preclude that these cells are undergoinga differentiation into preneoplastic parenchymal cells, as haspreviously been suggested.     

Immunohistochemical localization of inducible nitric oxide synthase and 3-nitrotyrosine in rat liver tumors induced by N-nitrosodiethylamine.

Human liver cancers have been associated mainly with chronic inflammations such as viral hepatitis B or C. This suggests that prolonged cell damage by chronic inflammation is critical in cancer development. Overproduction of nitric oxide (NO.) and its derivative (NOx, peroxynitrite) has been implicated as a cause of tissue damage by inflammation, thus contributing to tumor promotion. We have demonstrated the expression of the inducible isoform of nitric oxide synthase (iNOS) and 3-nitrotyrosine, a marker of peroxynitrite formation, by immunohistochemistry in preneoplastic and neoplastic rat liver tissues induced by continuous infusion of N-nitrosodiethylamine with mini-pumps. The preneoplastic lesions were characterized by proliferation of phenotypically altered hepatic foci (PAHF), dysplastic hepatocytes and oval cells. Histologically, the tumors were hepatocellular carcinomas (HCCs) of trabecular, (pseudo)glandular and solid types with or without cholangiocellular involvement. iNOS was located mainly in oval cells, capillary endothelial and muscular cells, epithelia of cholangiomas and glandular HCCs. 3-Nitrotyrosine was observed in the cytoplasms of PAHF and dysplastic hepatocytes in preneoplasias and in the cytoplasms of some living or apoptotic HCC cells, connective tissues, proteinaceous fluids, sinusoidal endothelia of tumorous hepatocytes and cholangiomas in tumors. From these observations, we suggest that: (i) chronic tissue damage by chemical carcinogens may act to induce iNOS and peroxynitrite formation; (ii) oval cells play a key role in development and/or growth of tumor tissues by producing NO. via iNOS, which may also cause tissue damage by peroxynitrite; (iii) iNOS can be considered as a phenotypic marker in cells of oval cell lineage and neovascularized capillaries in tumor tissues.     

Isozyme profiles of oval cells, parenchymal cells, and biliary cells isolated by centrifugal elutriation from normal and preneoplastic livers

The fetal liver isozymes aldolase A and pyruvate kinase K increase in livers of adult rats fed a choline deficient-diet containing 0.1% ethionine. Oval cells isolated by centrifugal elutriation from preneoplastic livers of animals receiving the carcinogenic diet contained these fetal forms as well as fetal-adult isozyme hybrids. In contrast, parenchymal cells isolated from the livers of these animals had only aldolase B and pyruvate kinase L, the same isozymes present in parenchymal cells of normal adult rats. Liver homogenates from rats receiving the carcinogenic diet contain lactate dehydrogenase (LDH) 1, LDH 2, and LDH 3 in addition to LDH 4 and LDH 5, which are the forms detected in normal liver homogenates. LDH 1, LDH 2, and LDH 3 are present in oval cells of preneoplastic livers and in biliary epithelial cells of normal livers, but not in parenchymal cells isolated from normal and preneoplastic livers. Cells of biliary epithelium from normal livers also contain aldolase A and pyruvate kinase K, but not the fetal-adult isozymes present in oval cell populations. The results indicate that, in animals receiving this carcinogenic diet, isozyme alterations associated with neoplasia result from the proliferation of a new cell population which contains these enzymes and not from "dedifferentiation" of mature hepatocytes. Furthermore, the data suggest that this new cell population may include a liver stem cell compartment containing cells in transitional states of differentiation.     

Decrease of hepatic stellate cells in rats with enhanced sensitivity to clofibrate-induced hepatocarcinogenesis

To examine the possible involvement of nonparenchymal cells in the development of preneoplastic hepatic lesions induced by clofibrate (CF), alterations of these cells were investigated immunohistochemically in glutathione S-transferase M1 gene polymorphic rats (KS and NC types) with different cancer susceptibilities. After CF administration for 8 weeks, α-smooth muscle actin (α-SMA)-positive hepatic stellate cells (HSC) were markedly decreased in sensitive KS-type rats, but not in the NC-type rats. Kupffer cells were decreased with similar extents between them. The sinusoidal endothelial cells were not changed in either type. The other markers for HSC, vimentin and CRBP1, also confirmed the decrease of HSC in the KS type. The decrease of HSC was not observed at 4 weeks of CF administration. Preneoplastic peroxisomal bifunctional enzyme-negative foci were detected in the KS-type rats at 8 weeks of CF administration, but not at 4 weeks. Human HSC were cultured in the presence of clofibric acid and expression of most HSC marker genes, such as vimentin and α-SMA (ACTA2), evaluated by a microarray, was not altered by the treatment, suggesting that HSC loss in the KS-type rats was not due to the direct toxic effect of CF. The expression levels of most HSC marker genes were low in both control and CF-treated rat livers. A possible link between HSC loss and the development of preneoplastic hepatic foci is discussed.     

In situ hybridization studies on expression of albumin and alpha-fetoprotein during the early stage of neoplastic transformation in rat liver

The expressions of albumin and alpha-fetoprotein (AFP) genes were studied in early preneoplastic liver lesions produced by the Solt-Farber protocol using "in situ" hybridization with single stranded RNA probes. In normal rat liver, albumin was expressed at a lower level in the centrilobular than in the periportal areas of the liver acinus, whereas the bile duct epithelium did not show any expression. Five weeks after initiation with diethylnitrosamine, islands of hepatocytes were present which showed heterogeneous expression of albumin and were surrounded by cells comprised of albumin negative hepatocytes and oval cells. gamma-Glutamyltranspeptidase positive foci of enzyme altered cells were located in albumin positive areas. Albumin expression gradually decreased in permanent nodules but increased in the hepatocytes outside the nodules during the first five months after initiation with diethylnitrosamine. Remodeling nodules, which were partly gamma-glutamyltranspeptidase and albumin positive, were also present. However, no consistent correlation was found between gamma-glutamyltranspeptidase positive and albumin negative areas during the first 5 months after initiation. Occasionally, cells showing an elevated expression of albumin were found in permanent nodules. These cells were located in the vicinity of oval type cells, which also showed a weak expression of albumin. AFP was expressed at high level in oval cells 5 weeks after the initiation. However, oval cells observed at later time points, either around the neoplastic nodules or inside the nodules showed only low expression of AFP. Hepatocytes in the enzyme-altered foci and in neoplastic nodules were always negative for AFP. The presence of strongly albumin positive cells inside the neoplastic nodules in close proximity to oval type cells suggests that these cells may be derived from primitive "stem-cell"-like oval cells.     

Infrequent activation of K-ras, H-ras, and other oncogenes in hepatocellular neoplasms initiated by methyl(acetoxymethyl)nitrosamine, a methylating agent, and promoted by phenobarbital in F344 rats

Fischer 344/Ncr rats of both sexes were subjected to partial hepatectomy and then initiated 21-24 h later by a single injection of methyl(acetoxymethyl)nitrosamine at 0.1 mmol/kg body weight via the portal vein. Beginning 3 weeks later, development of hepatocellular neoplasms in initiated rats was promoted by feeding 0.05% phenobarbital (PB) in the diet. Not only intrahepatic lesions but also a variety of extrahepatic tumors were induced. High-molecular-weight DNAs were prepared from 67 samples of grossly normal liver containing multiple preneoplastic foci/areas of microscopic dimensions, 137 hepatocellular adenomas (nodules), 93 hepatocellular carcinomas (HCC), 10 cholangiomas, and 25 extrahepatic tumors in 95 rats and tested for transforming activity in the NIH 3T3 transfection assay. DNA preparations from 7 of 93 HCCs, 2 of 10 cholangiomas, 2 of 137 nodules, 1 histiocytic sarcoma, and 1 thyroid carcinoma were positive in the transfection assay. Southern blot analysis showed that NIH 3T3 transformants induced by DNA from 5 HCCs, 1 hepatocellular adenoma, 1 cholangioma, 1 histiocytic sarcoma, and 1 thyroid carcinoma contained an activated K-ras gene of rat origin. Rat-derived H-ras was identified in transformants from 2 additional HCCs and rat c-raf from 1 hepatocellular adenoma. The transforming gene from one cholangioma showed no sequence homology to the ras genes, neu, or c-raf. Immunoprecipitation analysis of ras Mr 21,000 protein in 11 transformants indicated that, based upon protein electrophoretic mobilities, activation of the ras genes consistently resulted from mutations in codon 12 of these genes. Selective oligonucleotide analysis revealed that a G----A transition in the second base of codon 12 of K-ras was present in the 9 K-ras-positive transformants and also in DNAs prepared from the original tumors. In contrast, oligonucleotide hybridization experiments with DNAs from 35 hepatocellular tumors that were negative in transfection assays revealed the presence of mutant K-ras in 1 of 15 HCCs; no mutation could be detected in 20 transfection-negative adenomas. The infrequency of detection of a specific oncogene, more frequent detection of oncogenes in malignant tumors, and failure to observe activated oncogenes in preneoplastic lesions suggest that activation of ras oncogenes may occur as a late and infrequent event in the evolution of some rat hepatocellular neoplasms and that mutation of a specific ras locus is not an obligatory early event in the genesis of these neoplasms.     

Selective dieldrin promotion of hepatic focal lesions in mice

Chronic exposure to a number of chlorinated pesticides, includingdieldrin, results in an increased and/or multiplicityof hepatocellularneoplasia in mice, with no such effect in similarly treatedrats. One possible explanation of this observed selective carcinogenicityis species-spefic hepatic tumor promotion. In the present studywe examined the dose-response effect of dieldrin (at severaldoses) on focal lesion growth (tumor promotion), hepatocyteapoptosis and DNA synthesisin rat and mouse liver. Preneoplasticfocal hepatic lesions were produced by diethylnitrosamine (DEN). After the lesionsdeveloped, mice and rats were placed intoone of the following dose groups: control (NIH-07 diet) or 0.1,1.0 or 10.0 mg dieldrin/kg diet. Increased focal lesion, volume,number of foci per liver and focal DNA synthetic labeling indeswere observed in 10 mg dieldrin/kg diet-treated mice, but notin similarly treated rats. Dieldrin at dietary concentrationsof0.1and 1.0 mg/kg diet produced an increase in the number ofpreneoplastic lesions (0.1 mg/kg dietat 7 days only) and focalvolume (0.1 mg/kg diet at 7 and 30 days, 1.0 mg/kg diet at 30days), but these concentrations did not increase focal DNA labellingindex. At dietary concentrations of 0.1, 1.0 and 10 mg dieldrin/kgdiet no siginificant change in lesion percent volume, numberof preneoplastic lesions per liver or preneoplastic lesion DNAlabeling index was seen in treated ratscompared with controlrats. Apoptosis, a form of programed cell death, was notdecreasedin foci by any concentration of dieldrin in either rats or mice. Thus our results suggest that dieldrin may function as a mouse-spefictumor promoter through increased lesion DNA sybthesis.     

Loss of peroxisomal enzyme expression in preneoplastic and neoplastic lesions induced by peroxisome proliferators in rat livers.

Immunohistochemical staining of enoyl CoA hydratase (ECH), a key peroxisomal enzyme, revealed that the putative preneoplastic lesions induced in livers by administration of the peroxisome proliferator (PP) clofibrate (0.3% in diet) to rats for 60 weeks or more, lacked this enzyme so that they could be detected as ECH-negative foci. ECH and other peroxisomal enzymes such as acyl CoA oxidase, catalase and carnitine-dependent acetyltransferase were also either not or only weakly expressed in most hepatic hyperplastic nodules and hepatomas induced by ciprofibrate (0.025% in diet), Wy-14,643 (0.1%) or BR-931 (0.2%), while being strongly induced in surrounding hepatocytes. These results indicate that the expression of ECH and other peroxisomal enzymes is repressed in putative preneoplastic and neoplastic lesions induced by PPs in rat livers and that these peroxisomal enzymes might therefore be used as negative markers.     

Precancerous hepatic nodules had significant levels of telomerase activity determined by sensitive quantitation using a hybridization protection assay

BACKGROUND: Telomeric repeat amplification protocol using internal telomerase assay standard (ITAS) (conventional TRAP) has detected telomerase activity in various malignant tumors. With conventional TRAP, it is difficult to differentiate quantitatively low levels of telomerase activity between well-differentiated hepatocellular carcinomas (HCCs) and dysplastic nodules because of quantitative limitation. To apply a telomerase assay for differential diagnosis, we used a hybridization protection assay combined with TRAP (TRAP/HPA). This combination had better sensitivity and wider linearity than conventional TRAP. METHODS: TRAP/HPA was applied for quantitative measurement of telomerase activity in various hepatic tissues. Telomerase activity was evaluated in 10 precancerous hepatic nodules, 17 well-differentiated HCCs, 19 moderately differentiated HCCs, 5 poorly differentiated HCCs, 22 nontumorous chronic hepatic disease samples, and 2 normal liver tissues. RESULTS: Telomerase activity in HCCs tended to increase according to the malignant transformation. The average relative telomerase activity in 0.6 microg protein, which was expressed as cell equivalent activity of MKN-1, a gastric carcinoma cell line, was 8.5 in precancerous hepatic nodules, 87 in well-differentiated HCCs, 265 in moderately differentiated HCCs, 447 in poorly differentiated HCCs, and 0.4 in nontumorous hepatic tissues, including chronic liver diseases. CONCLUSIONS: TRAP/HPA was sensitive enough to distinguish the telomerase activity in precancerous hepatic nodules from that in other lesions. Telomerase activity in precancerous hepatic nodules was higher than that in nontumorous hepatic tissues. However, the activity in precancerous hepatic nodules was lower than that in well-differentiated HCCs, although statistically not significant. The authors suggest that precancerous hepatic nodules with telomerase activity above the diagnostic cutoff level (twice the highest activity in nontumorous hepatic tissues, or the 2 cell equivalent activity of MKN-1) should be treated as malignancy.