Deregulation of DNA-dependent protein kinase catalytic subunit contributes to human hepatocarcinogenesis development and has a putative prognostic value.

BACKGROUND: The DNA-repair gene DNA-dependent kinase catalytic subunit (DNA-PKcs) favours or inhibits carcinogenesis, depending on the cancer type. Its role in human hepatocellular carcinoma (HCC) is unknown. METHODS: DNA-dependent protein kinase catalytic subunit, H2A histone family member X (H2AFX) and heat shock transcription factor-1 (HSF1) levels were assessed by immunohistochemistry and/or immunoblotting and qRT-PCR in a collection of human HCC. Rates of proliferation, apoptosis, microvessel density and genomic instability were also determined. Heat shock factor-1 cDNA or DNA-PKcs-specific siRNA were used to explore the role of both genes in HCC. Activator protein 1 (AP-1) binding to DNA-PKcs promoter was evaluated by chromatin immunoprecipitation. Kaplan-Meier curves and multivariate Cox model were used to study the impact on clinical outcome. RESULTS: Total and phosphorylated DNA-PKcs and H2AFX were upregulated in HCC. Activated DNA-PKcs positively correlated with HCC proliferation, genomic instability and microvessel density, and negatively with apoptosis and patient's survival. Proliferation decline and massive apoptosis followed DNA-PKcs silencing in HCC cell lines. Total and phosphorylated HSF1 protein, mRNA and activity were upregulated in HCC. Mechanistically, we demonstrated that HSF1 induces DNA-PKcs upregulation through the activation of the MAPK/JNK/AP-1 axis. CONCLUSION: DNA-dependent protein kinase catalytic subunit transduces HSF1 effects in HCC cells, and might represent a novel target and prognostic factor in human HCC.

Forkhead box M1B is a determinant of rat susceptibility to hepatocarcinogenesis and sustains ERK activity in human HCC.

BACKGROUND AND AIMS: Previous studies indicate unrestrained cell cycle progression in liver lesions from hepatocarcinogenesis-susceptible Fisher 344 (F344) rats and a block of G(1)-S transition in corresponding lesions from resistant Brown Norway (BN) rats. Here, the role of the Forkhead box M1B (FOXM1) gene during hepatocarcinogenesis in both rat models and human hepatocellular carcinoma (HCC) was assessed. METHODS AND RESULTS: Levels of FOXM1 and its targets were determined by immunoprecipitation and real-time PCR analyses in rat and human samples. FOXM1 function was investigated by either FOXM1 silencing or overexpression in human HCC cell lines. Activation of FOXM1 and its targets (Aurora Kinose A, Cdc2, cyclin B1, Nek2) occurred earlier and was most pronounced in liver lesions from F344 than BN rats, leading to the highest number of Cdc2-cyclin B1 complexes (implying the highest G(2)-M transition) in F344 rats. In human HCC, the level of FOXM1 progressively increased from surrounding non-tumorous livers to HCC, reaching the highest levels in tumours with poorer prognosis (as defined by patients' length of survival). Furthermore, expression levels of FOXM1 directly correlated with the proliferation index, genomic instability rate and microvessel density, and inversely with apoptosis. FOXM1 upregulation was due to extracellular signal-regulated kinase (ERK) and glioblastoma-associated oncogene 1 (GLI1) combined activity, and its overexpression resulted in increased proliferation and angiogenesis and reduced apoptosis in human HCC cell lines. Conversely, FOXM1 suppression led to decreased ERK activity, reduced proliferation and angiogenesis, and massive apoptosis of human HCC cell lines. CONCLUSIONS: FOXM1 upregulation is associated with the acquisition of a susceptible phenotype in rats and influences human HCC development and prognosis.

Hepatocellular carcinoma as a complex polygenic disease. Interpretive analysis of recent developments on genetic predisposition.

The different frequency of hepatocellular carcinoma (HCC) in humans at risk suggests a polygenic predisposition. However, detection of genetic variants is difficult in genetically heterogeneous human population. Studies on mouse and rat models identified 7 hepatocarcinogenesis susceptibility (Hcs) and 2 resistance (Hcr) loci in mice, and 7 Hcs and 9 Hcr loci in rats, controlling multiplicity and size of neoplastic liver lesions. Six liver neoplastic nodule remodeling (Lnnr) loci control number and volume of re-differentiating lesions in rat. A Hcs locus, with high phenotypic effects, and various epistatic gene-gene interactions were identified in rats, suggesting a genetic model of predisposition to hepatocarcinogenesis with different subset of low-penetrance genes, at play in different subsets of population, and a major locus. This model is in keeping with human HCC epidemiology. Several putative modifier genes in rodents, deregulated in HCC, are located in chromosomal segments syntenic to sites of chromosomal aberrations in humans, suggesting possible location of predisposing loci. Resistance to HCC is associated with lower genomic instability and downregulation of cell cycle key genes in preneoplastic and neoplastic lesions. p16(INK4A) upregulation occurs in susceptible and resistant rat lesions. p16(INK4A)-induced growth restraint was circumvented by Hsp90/Cdc37 chaperons and E2f4 nuclear export by Crm1 in susceptible, but not in resistant rats and human HCCs with better prognosis. Thus, protective mechanisms seem to be modulated by HCC modifiers, and differences in their efficiency influence the susceptibility to hepatocarcinogenesis and probably the prognosis of human HCC.

The burden of HIV-associated neurocognitive disorder (HAND) in post-HAART era: a multidisciplinary review of the literature.

OBJECTIVE: The purpose of the present multidisciplinary review is to give an updated insight into the most recent findings regarding the pathophysiology, diagnosis and therapeutics of HIV-associated neurocognitive disorder (HAND). MATERIALS AND METHODS: We performed a comprehensive search, through electronic databases (Pubmed - MEDLINE) and search engines (Google Scholar), of peer-reviewed publications (articles and reviews) and conferences proceedings on HAND pathophysiology, diagnosis, and therapy, from 1999 to 2016. RESULTS: It seems to be increasingly clear that neurodegeneration in HIV-1 affected patients is a multi-faceted disease involving numerous factors, from chronic inflammation to central nervous system (CNS) compartmentalization of HIV. Diagnosis of HAND may benefit from both laboratory analysis and advanced specific neuroimaging techniques. As regards HAND therapy, modified HAART combinations and simplification strategies have been tested, while novel exciting frontiers seem to involve the use of nanoparticles with the ability to cross the Blood-Brain Barrier (BBB). CONCLUSIONS: Albeit highly active antiretroviral therapy (HAART) allowed a major decrease in morbidity and mortality for AIDS patients, CNS involvement still represents a challenge in HIV patients even today, affecting up to 50% of patients with access to combination antiretroviral therapy (cART). Future studies will have to focus on CNS compartmentalization, drugs' ability to penetrate and suppress viral replication in this compartment, and on new approaches to reduce HIV-associated neuroinflammation.

Chemoprevention of rat liver carcinogenesis by S-adenosyl-L-methionine: a long-term study.

Previous work has shown a consistent fall in S-adenosyl-L-methionine (SAM) in the liver of diethylnitrosamine-initiated rats, during the development of preneoplastic lesions, in persistent nodules (PNs), and hepatocellular carcinomas. The injection of SAM into rats causes the reconstitution of the SAM pool, coupled with growth restraint, remodeling, and apoptosis of preneoplastic cells, and inhibits the development of PNs and hepatocellular carcinomas. To evaluate if SAM treatment causes a long-term prevention of preneoplastic and neoplastic liver lesions or merely causes a delay in their development, we evaluated the effect of a relatively short SAM treatment on the development of preneoplastic and neoplastic lesions in a long-term study. Male Wistar rats were subjected to initiation with diethylnitrosamine, followed by selection and then by the administration of phenobarbital for 16 weeks. After selection, the rats were given i.m. injections of a purified SAM preparation (384 mumol/kg/day) for 24 weeks. In SAM-treated rats, a decrease in the incidence of PNs was found 6, 14, and 24-28 months after initiation. At the end of SAM treatment the number of PNs per rat liver, nodule diameter, and labeling and mitotic indices of nodular cells decreased considerably in control rats. Nodule diameter started to increase rapidly again only 8 months after arresting SAM treatment, when complete recovery of DNA synthesis in nodular cells occurred. The majority of nodules present in the liver 6-28 months after initiation belonged to the clear and acidophilic cell types, with lower percentages of mixed cell and basophilic cell types. A decrease in basophilic nodules occurred in SAM-treated rats. Fourteen and 24-28 months after initiation hepatocellular carcinoma incidence was 11 of 12 and 10 of 10 in control rats, respectively, and only 1 of 12 and 3 of 11 in SAM-treated rats. At the 24th-28th month all control rats had tumors identified as 2 poorly differentiated carcinomas, 6 trabecular carcinomas, or 3 adenocarcinomas, while only 2 relatively small trabecular carcinomas and 1 small glandular tumor developed in SAM-treated rats. In 3 of 11 SAM-treated rats, but in none of the control rats, leukemic infiltration of liver occurred 24-28 months after initiation. Leukemic infiltration of the spleen occurred in 5 and 3 control and SAM-treated rats, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

Inhibition of promotion and persistent nodule growth by S-adenosyl-L-methionine in rat liver carcinogenesis: role of remodeling and apoptosis.

The resistant hepatocyte model (initiation/selection) and the triphasic model (initiation/selection followed by phenobarbital, for a maximum of 16 weeks) were compared for their ability to generate enzyme-altered foci (EAF) and nodules in the liver of Wistar rats initiated by diethylnitrosamine. The effects of S-adenosyl-L-methionine (SAM) on the development of preneoplastic tissue was tested in these experimental models. In the absence of phenobarbital (PB), EAF and early nodules (EN) went through a phase of rapid growth, between 4 and 9 weeks after initiation, to a phase in which progressive decrease in number and size occurred. By the 26th week only a few remodeling EAF and nodules were found. In PB-treated rats a rapid increase in the percentage of liver occupied by EAF and EN, up to the 9th week after initiation, was followed by a period of slow growth (from the 9th to the 20th week) and then, after PB withdrawal (20th week), by a drop in the number and size of EAF and EN. However, at the 26th week actively growing nodules with a low tendency to spontaneous remodeling (persistent nodules) developed. EAF and EN showed a high DNA synthesis 5 weeks after initiation. Thereafter, progressive decline in DNA synthesis, coupled with remodeling and decrease in number of biochemical markers, was seen both in the absence and, even though to a lesser extent, in the presence of PB, indicating that preneoplastic lesions became increasingly insensitive to PB. Relatively few apoptotic bodies could be observed in EAF and EN during PB treatment. After PB withdrawal, decrease in growth potential was coupled with increase in apoptotic bodies. In contrast, in persistent nodules relatively high apoptosis occurred which partially counterbalanced high DNA synthesis. Administration of SAM for a maximum of 16 weeks, starting at the 4th week after initiation, caused a great decrease in number and size of EAF and EN, associated with inhibition of DNA synthesis, high cell death by apoptosis, high remodeling, and loss of biochemical markers, in preneoplastic lesions of both PB-treated and untreated rats. A 1-8-week SAM treatment, started after the development of persistent nodules, caused a great regression of nodular lesions, coupled with a sharp fall in DNA synthesis and increase in apoptosis. It is suggested that inhibition by SAM of the development of preneoplastic tissue is linked to a shift of the equilibrium between cell production and cell death in favor of cell death.(ABSTRACT TRUNCATED AT 400 WORDS)

Identification of genetic loci controlling hepatocarcinogenesis on rat chromosomes 7 and 10.

Neoplastic liver nodules and hepatocellular carcinomas (HCCs) were induced, by "resistant hepatocyte" model, 32 and 70 weeks after initiation with diethylnitrosamine, respectively, in F344 Brown Norway (BN), and (BNxF344)F1 rats. Nodule number/liver (N) did not significantly differ among rat strains, whereas nodule mean volume (V) and nodule volume fraction (VF) were higher in susceptible F344 than in resistant BN and BFF1 strains and were predictive of subsequent development of HCCs. Genomic scanning of 157 backcross BFF1xF344 rats with 190 polymorphic microsatellites, and linkage analysis, revealed two quantitative trait loci (QTL) on chromosomes 7 and 10, which showed significant linkage with VF, and two QTL on chromosomes 4 and 8, which showed suggestive linkage with V and VF. On the basis of phenotypic patterns of homozygous and heterozygous backcross progeny and of allelic distribution pattern, QTL on chromosomes 10, 8, and 4 were tentatively identified as resistance loci, and QTL on chromosome 7 was identified as susceptibility locus for rat hepatocarcinogenesis. An analysis of interactions allowed us to identify additional putative QTL on chromosomes 5 and 8 and suggested an additive effect of loci on chromosomes 10, 8, and 4 for VF and V. These data are the first to identify chromosomal regions containing putative susceptibility/resistance loci for rat hepatocarcinogenesis, which seems to be highly complex in terms of the number of genetic factors involved.

Correlation between S-adenosyl-L-methionine content and production of c-myc, c-Ha-ras, and c-Ki-ras mRNA transcripts in the early stages of rat liver carcinogenesis.

gamma-Glutamyltranspeptidase (GGT)-positive and glutathione S-transferase (placental-GST-P) positive foci were induced in male Wistar rats by initiation with diethylnitrosamine (DENA), followed by selection and phenobarbital (PB). GGT- and GST-P-positive foci occupied 20-46% and 27-68% of liver parenchyma, respectively, 5-9 weeks after initiation. A high DNA synthesis was found in GGT-positive foci. Decrease in S-adenosyl-L-methionine (SAM) level and SAM/S-adenosylhomocysteine (SAH) ratio, and overall DNA hypomethylation occurred in the liver during the development of enzyme altered foci (EAF). These parameters underwent very small and transient changes in the liver of uninitiated rats at the 5th week, when EAF occupied 0.7-1.4% of the liver. At the 9th week, high RNA transcripts of c-myc, c-Ha-ras, and c-Ki-ras were found in the liver of initiated rats, but not in that of uninitiated rats. Immunohistochemical evaluation of c-myc gene product showed overexpression in GST-P-positive cells. SAM treatment of initiated rats caused inhibition of EAF growth, recovery of SAM/SAH ratio and DNA methylation, and decrease in protooncogene expression proportional to the dose and length of treatment. Liver SAM/SAH ratio was positively correlated with DNA methylation, and negatively correlated with transcript levels of the three protooncogenes. Thus, decrease in SAM/SAH ratio and DNA hypomethylation are early features of hepatocarcinogenesis promotion in rats fed a diet containing adequate lipotrope amounts, paralleled by overexpression of growth-related genes and rapid growth. Re-establishment of a physiologic SAM level makes it possible to inhibit protooncogene expression and EAF growth and to prevent late liver lesion development.

Reversal by 5-azacytidine of the S-adenosyl-L-methionine-induced inhibition of the development of putative preneoplastic foci in rat liver carcinogenesis.

The development of gamma-glutamyltranspeptidase (GGT)-positive foci, in Wistar rats, initiated with diethylnitrosamine and subjected to selection according to 'resistant hepatocyte' protocol, was coupled, 7 weeks after initiation, with liver DNA hypomethylation and with a fall in S-adenosylmethionine/S-adenosylhomocysteine (SAM/SAH) ratio, and in 5-methylthio-adenosine (MTA) content. A 15-day treatment with SAM, started 1 week after selection, caused a dose-dependent decrease in the development of GGT-positive foci, recovery of liver SAM/SAH ratio and MTA level, and liver DNA methylation. A 12-day treatment with 20 mumol/kg per day of 5-azacytidine (AzaC), starting 1 week after selection, enhanced growth of GGT-positive foci, caused strong DNA hypomethylation, and partially counteracted the inhibition of GGT-positive foci growth, without affecting recovery of SAM/SAH ratio and MTA level, induced by SAM. These results suggest a role of DNA methylation in the antipromoting effect of SAM.

Modulation by MHC class I antigens of the biology of melanoma cells. Non-immunological mechanisms.

Many human as well as experimental tumours, including melanoma, express reduced levels of major histocompatibility complex (MHC) Class I antigens. Decreased MHC Class I antigen expression may be selected during neoplastic progression because it allows tumour cells to escape killing by cytotoxic T lymphocytes. Furthermore, the regulatory role of MHC Class I antigens in the proliferation of T cells suggests that abnormalities in MHC Class I antigen expression may play a role in the disordered proliferation of malignant cells and in their metastatic potential by non-immunological mechanisms. This paper reviews some of the available evidence supporting the concept of non-immune functions of MHC Class I antigens in the biology of malignant cells, with emphasis on experimental models for metastatic melanoma.

Genomic abnormalities in hepatocarcinogenesis. Implications for a chemopreventive strategy.

Carcinogenesis is a complex process characterized by the cumulative activation of various oncogenes and the inactivation of suppressor genes. Epigenetic mechanisms are also involved. Mutational activation of ras family genes occurs in most spontaneous or carcinogen-induced liver tumors, in susceptible mice, and less frequently in preneoplastic lesions. This suggests a pathogenetic role of these changes in hepatic carcinogenesis, in the mouse. Overexpression of various growth-related genes occurs in preneoplastic tissue during rat liver carcinogenesis, but mutational activation of protooncogenes, notably of ras family genes, seems to be a late and rare event, while c-myc amplification is a late but frequent event in both rodent and human carcinogenesis. However, mutation of the suppressor p53 gene has been found in relatively early preneoplastic lesions in rat liver, and it may be frequently seen in human hepatocellular carcinomas. The possibility that this mutation is involved in the initiation stage of liver carcinogenesis is an attractive hypothesis which needs further evaluation. DNA hypomethylation is involved in carcinogenesis, but the mechanisms underlying this effect are still elusive. Hypomethylation of growth-related genes is associated with their overexpression and this could favor overgrowth of preneoplastic liver tissue. Decrease in S-adenosyl methionine/S-adenosylhomocysteine (SAM/SAH) ratio occurs in the liver of rats fed a methyl deficient diet, which is a carcinogenic treatment, and in preneoplastic liver tissue, developing in initiated/promoted rats fed an adequate diet. The role of low SAM/SAH ratio in carcinogenesis is substantiated by the tumor chemopreventive effect of lipotropic compounds. Treatment with exogenous SAM prevents the development of preneoplastic and neoplastic lesions in rat liver. This is associated with recovery of SAM/SAH ratio, DNA methylation and inhibition of growth-related gene expression. SAM effect on prenoplastic cell growth is abolished by 5-azacytidine, a hypomethylating agent, indicating the involvement of DNA methylation. The possibility that in SAM-treated rats, methylation and inhibition of the expression of growth-related genes is implicated in growth restraint is attractive and should be further evaluated. Modulation of rat liver carcinogenesis by influencing gene expression through DNA methylation or other epigenetic mechanisms could be a new approach to chemoprevention of these tumors.

Effect of S-adenosyl-L-methionine on the development of preneoplastic foci and the activity of some carbohydrate metabolizing enzymes in the liver, during experimental hepatocarcinogenesis.

gamma-Glutamyltranspeptidase (GGT)-positive foci and glutathione-S-transferase, placental (GST-P)-positive lesions occupied 36% and 54% of liver parenchyma, respectively, in Wistar rats 8 weeks after initiation with diethylnitrosamine, followed by selection. The administration of S-adenosyl-L-methionine (SAM, 384 mumol/kg/day) caused 77% and 42% falls in the percentage of GGT-positive and GST-P-positive lesions, respectively. There also occurred a 46% decrease in labeling index of GGT-positive foci, in SAM-treated rats. These changes were associated with decrease in liver pyruvate kinase (PK), lactate dehydrogenase and glycerol-3-phosphate dehydrogenase. SAM did not affect these enzymatic activities in normal and uninitiated controls, but it caused a consistent increase in initiated rats. Enolase, fructose-biphosphatase and malic enzyme (ME) activities increased in the liver of initiated rats. SAM did not modify significantly these enzymatic activities, either in control or in initiated rats. Glucose-6-phosphate dehydrogenase (G6PDH) was 113% higher in the liver of initiated rats than in uninitiated controls. SAM treatment did not significantly affect this enzymatic activity in uninitiated rats, but caused a great decrease in initiated ones. As expected, there occurred a marked rise in GGT activity in the liver of initiated rats, with respect to controls. SAM caused an increase in GGT activity in normal and uninitiated controls, but it caused a 77% fall in GGT activity in initiated rats, coupled with a 380% rise in remodeling of GGT-positive lesions. Histochemical determination of G6PDH and ME activities showed that in the absence of SAM many preneoplastic lesions expressed higher G6PDH and ME activities than surrounding liver. SAM did not affect ME-positive lesions, while it caused a decrease in the number of G6PDH-positive lesions. Immunohistochemical determination of PK activity, isoenzyme L, showed a decrease in GST-P-positive lesions. Many of these lesions were no longer recognizable as lesions expressing a low PK activity, in SAM-treated rats. However, a relatively small number of GST-P-positive lesions expressing a low PK activity were still present in these rats. These data suggest that glucose channelled into triacylglycerol and pyruvate synthesis decreases in rat liver, during the development of preneoplastic foci, while the production of reducing equivalents and pentose phosphates increases, thus favoring DNA synthesis and detoxification reactions. Decrease in DNA synthesis, in SAM-treated rats, is paralleled by a partial reversion of carbohydrate metabolic features to those present in normal liver.

Comparative effects of L-methionine, S-adenosyl-L-methionine and 5'-methylthioadenosine on the growth of preneoplastic lesions and DNA methylation in rat liver during the early stages of hepatocarcinogenesis.

Male Wistar rats, initiated with diethylnitrosamine (DENA), were subjected to a selection treatment, according to the "resistant hepatocyte" model, followed or not followed by phenobarbital (PB). Rats received, for 3 weeks after selection, 4 i.m. doses (96 mmol/kg) of L-methionine, S-adenosyl-L-methionine (SAM), or 5'-methylthioadenosine (MTA), a SAM catabolite formed during polyamine synthesis or by spontaneous splitting of SAM at physiologic temperature and pH. They were then killed. In some rats, SAM and MTA treatments were started 20 weeks after initiation. The animals were killed 3 weeks later and persistent (neoplastic) nodules (PN) were collected. Some rat groups received 1/2 and 1/4 of the above SAM and MTA doses, or 1/8 of the above MTA dose. SAM and MTA, but not methionine, caused a dose-dependent decrease in number and surface area of gamma-glutamyltranspeptidase (GGT)-positive foci, and in labeling index (LI) of focal cells, coupled with remodeling. SAM and MTA liver contents, SAM/S-adenosylhomocysteine (SAH) ratio and overall methylation of liver DNA were low during the development of GGT-positive foci. SAM, but not methionine, caused a dose-dependent recovery of SAM content and DNA methylation, and a partial reconstitution of liver MTA pool. Exogenous MTA only induced the reconstitution of MTA pool, without affecting SAM level and DNA methylation. Recovery of SAM and MTA pool and DNA methylation was found in the rats subjected to SAM plus MTA, indicating the absence of inhibition of DNA methyltransferases in vivo by MTA. MTA also inhibited liver reparative growth in partially hepatectomized rats, without modifying SAM content and DNA methylation of regenerating liver (RL). A high activity of ornithine decarboxylase (ODC) was found in the liver, during the development of preneoplastic foci, and in PN. This activity was inhibited by SAM and MTA treatments. Although MTA was more effective than SAM, the decrease in ODC activity was coupled with a larger fall in DNA synthesis in SAM-treated than in MTA-treated rats. Thus the antipromotion effect of SAM could not merely depend on its (spontaneous) transformation into MTA. Although MTA production may play a role in the SAM antipromotion effect, other mechanisms could be involved. A role of DNA methylation in the inhibition of growth by SAM is suggested. MTA is a potential chemopreventive agent for liver carcinogenesis.

l-5-formyltetrahydrofolate and l-5-methyltetrahydrofolate rescue in L1210 leukemia treated with high methotrexate doses.

Highly purified 5-l-methyltetrahydrofolate (m-THF) and 5-l-formyl-THF (f-THF) preparations were compared for rescuing from methotrexate (MTX) toxicity in DBA2 mice transplanted with L1210 leukemia. Mice received two doses of reduced folates (2 mg/kg, s.c.) 16 and 24 h after a single s.c. MTX dose. f-THF was 1.8 time more effective than m-THF in protecting tumor cells from MTX (800 mg/kg). This MTX dose caused a 57% fall in circulating polymorphonucleates, which was prevented by both reduced folates. Treatment with 800 mg/kg of MTX plus m-THF was 1.5 fold more effective than the same MTX dose plus f-THF in increasing survival time of tumor-bearing mice. These data suggest a higher selectivity and efficacy of l-m-THF with respect to l-f-THF in rescuing from MTX toxicity.

Genetic alterations in liver carcinogenesis: implications for new preventive and therapeutic strategies.

In this review, genetic changes known to occur in human and experimental animal hepatocarcinogenesis are evaluated comparatively, with the aim of identifying genes that could potentially be targets of new preventive and therapeutic strategies, albeit the fact that although a step-by-step analysis of the premalignant stages has been largely accomplished in experimental hepatocarcinogenesis, this goal is still elusive in the case of humans. Overexpression of several of the genes implicated in the MAPK signaling cascade and cell cycle control appears to be most likely responsible for initiated cells acquiring a proliferating phenotype that facilitates the accumulation of structural changes in additional genes, resulting in the generation of autonomously growing preneoplastic and neoplastic lesions. Several gene abnormalities seen in precancerous lesions of rodents also occur in human hepatocellular carcinomas, suggesting that at least some of them could be present also in human precancerous lesions. Furthermore, there are reports that epigenetic events, such as abnormal DNA methylation, may be critical in hepatocarcinogenesis. DNA hypomethylation is an early event, both in human and experimental hepatocarcinogenesis, and its role in the activation of various genes, has been postulated. In recent years, linkage analysis studies have led to the identification of susceptibility/resistance loci that influence the progression stage of hepatocarcinogenesis in mice and rats. The relevance of these findings, though, will depend on the identification of the genes, and on whether in humans there are genes ortholog with rodent's susceptibility/resistance genes. It is proposed that rodent hepatocarcinogenesis represents a promising model for the identification of genes implicated in the early stages of the process, and that many of these genes may represent key targets for the application of gene therapy in the prevention and treatment of liver cancer.

Protooncogene methylation and expression in regenerating liver and preneoplastic liver nodules induced in the rat by diethylnitrosamine: effect of variations of S-adenosylmethionine:S-adenosylhomocysteine ratio.

S-adenosylmethionine:S-adenosylhomocysteine (SAM/SAH) ratio, 5-methylcytosine (5mC) DNA content, and methylation and expression of c-myc, c-Ha-ras and c-Ki-ras have been studied in liver nodules, induced by diethylnitrosamine according to the 'resistant hepatocyte' model, and in regenerating liver (RL) between 0.5 and 72 h after partial hepatectomy (PH). Nodules, 11, 13 and 21 weeks after initiation, grew actively, showed a low tendency to remodel (persistent nodules), and did not exhibit carcinomatous changes. They underwent extensive remodeling after a 1-week SAM treatment (64 mumol/kg/day), and decreased in size and number after a 3-11-week treatment. A low SAM/SAH ratio was coupled, in nodules, with a high labeling index (LI), 2-fold fall in 5mC DNA content, increase in c-myc, c-Ha-ras and c-Ki-ras expression and hypomethylation of CCGG sequences in the DNA hybridizing with the three protooncogenes. In RL a low SAM/SAH ratio, overall DNA hypomethylation and enhanced c-myc expression were first observed 0.5 h after PH, reached a peak at 5 h and progressively returned to pre-PH levels later on. Maximum expression of c-Ha-ras and c-Ki-ras occurred 24-30 h after PH, roughly coincident with the LI peak. However, no great modifications of the methylation pattern of protooncogene CCGG sequence occurred at any time after PH, indicating the presence of hypomethylated genes and/or DNA sequences different from those investigated in this paper. SAM injection to nodule-bearing rats, for 1-11 weeks before killing, and to hepatectomized rats, 2 days before PH and then up to killing, largely prevented decrease in the SAM/SAH ratio and overall DNA methylation and inhibited LI and protooncogene expression. In nodules these effects were proportional to the treatment length and coupled with methylation of CpG residues in the CCGG sequence of the three protooncogenes studied. SAM treatment left the methylation pattern of these genes unchanged in RL. Kinetics of increase in protooncogene expression suggest a role in the regulation of cell cycle in RL. However, decrease in the SAM/SAH ratio, protooncogene hypomethylation and enhanced expression are apparently stable in nodules 11-21 weeks after initiation and could be implicated in continuous nodule growth and progression. Control of DNA methylation and gene expression by exogenous SAM could be a mechanism of the SAM anti-progression effect.

Inhibition of 3-hydroxy-3-methylglutaryl-CoA reductase activity and gene expression by dehydroepiandrosterone in preneoplastic liver nodules.

Previous work has demonstrated that dehydroepiandrosterone (DHEA) strongly inhibits growth and de novo cholesterol (CH) biosynthesis in preneoplastic rat liver. Administration of a mixture of 4 ribo- or deoxyribonucleosides of adenine, guanine, cytosine and uracil/thymine, prevents growth inhibition but not inhibition of CH synthesis. The purpose of this paper was to identify the site of inhibition of CH synthesis by DHEA. Persistent nodules (PNs) were induced, in diethylnitrosamine-initiated male F344 rats, by 'resistant hepatocyte' protocol. Fifteen weeks after initiation, nodule bearing rats and normal controls received a diet containing 0.6% DHEA for 3 weeks. They were then killed. 3-Hydroxy-3-methylglutaryl-CoA reductase (HMGR) activity and mRNA levels were 18- and 14-fold higher, respectively in nodules than in normal liver. DHEA strongly inhibited HMGR activity in both tissues in vivo, but had a slight effect on HMGR activity, when added in vitro to the reaction mixture for determination of this activity. In vivo DHEA treatment caused a 65% decrease in the level of HMGR mRNA in PNs, which, however, does not seem to completely account for the decrease in HMGR activity (83%). Low density lipoprotein receptor (LDL-R) mRNA level underwent a slight decrease in PNs, with respect to control liver, which did not lead to a significant decrease in 125I-LDL binding to LDL-R. DHEA treatment caused 30% and 24% increases in LDL-R expression and 125I-LDL binding, respectively, in nodules. These observations indicate that in addition to HMGR gene expression, increased influx of LDL into preneoplastic cells may contribute to the deregulation of mevalonate synthesis by DHEA. The observation that HMGR activity and gene expression were still 3- to 5-fold higher in PNs of DHEA-treated rats than in control liver, and previous findings of preneoplastic liver cell growth in the presence of relatively low CH synthesis, suggest that even relatively low levels of mevalonate are sufficient for the growth of preneoplastic liver cells.

Alterations of ornithine decarboxylase gene during the progression of rat liver carcinogenesis.

Liver nodules and carcinomas, developing in F344 rats initiated with diethylnitrosamine, exhibit high ornithine decarboxylase (ODC) activity and DNA synthesis. ODC-related RNAs of 1.8, 2.1 and 2.6 kb are produced by normal rat liver. Early preneoplastic nodules, developing 10 weeks after initiation, showed overproduction of 1.8 and 2.1 kb RNAs, while the 2.6 kb RNA was barely detectable. Rises in the 1.8, 2.1 and 2.6 kb RNAs occur in late nodules (30 weeks after initiation) and in carcinomas. The comparison of different tissues for relative increase in ODC activity, RNA levels and DNA synthesis showed that these parameters behaved in the same way: highest increases occurred in early nodules and carcinomas. These observations suggest that overexpression of ODC gene and alterations in regulatory mechanisms of ODC gene expression may be implicated in the progression of preneoplastic lesions to malignancy. Southern blot analysis of PstI DNA digests revealed the presence of ODC gene rearrangement in two carcinomas and in one late nodule. However, the role of this phenomenon in the progression of preneoplastic lesions is unclear, due to the possibility that ODC pseudogenes are involved instead of or in addition to ODC gene.

Reversal by ribo- and deoxyribonucleosides of dehydroepiandrosterone-induced inhibition of enzyme altered foci in the liver of rats subjected to the initiation--selection process of experimental carcinogenesis.

The effect of dehydroepiandrosterone (DHEA) on the activity of NADPH-producing enzymes and the development of enzyme-altered foci has been investigated in the liver of female Wistar rats subjected to an initiating treatment (a necrogenic dose of diethylnitrosamine) followed, 15 days later, by a selection treatment [a 15-day feeding of a diet containing 0.03% 2-acetylaminofluorene (2-AAF), with a partial hepatectomy at the midpoint of this feeding]. At the end of the selection treatment all rat groups received, for 15 days, a basal diet containing, when indicated, 0.05% phenobarbital (PB) and/or 0.6% DHEA. The effect of DHEA on the activity of NADPH-producing enzymes was also studied in normal rats fed, for 15 days, a diet containing 0.6% DHEA and in their pair-fed controls. DHEA caused a 43-58% inhibition of glucose-6-phosphate dehydrogenase (G6PD) and, respectively, 338-420% and 21-24% increases in malic enzyme (ME) and isocitric dehydrogenase activities in all rat groups. This was coupled with a great fall in the production of ribulose-5-phosphate, while no change in NADP+/NADPH ratio occurred. Hepatocytes, isolated from DHEA-treated rats, exhibited a very low activity of hexose monophosphate shunt (HMS), which was not stimulated by methylene blue, an exogenous oxidizing agent that markedly stimulated HMS activity in control hepatocytes. DHEA caused a great fall in the percentage of liver occupied by gamma-glutamyltranspeptidase (GGT)-positive foci, in the rats subjected to the initiation-selection treatments. PB enhanced the development of these foci, an effect which was completely overcome by DHEA. In addition, focal cells no longer expressed a G6PD activity higher than that of surrounding liver in DHEA-treated rats, but exhibited a high histochemical reaction for ME. DHEA also caused a great fall in labelling index of GGT-positive foci. Starting at the end of 2-AAF feeding, a mixture of ribonucleosides (RNs) of adenine, cytosine, guanine and uracil and of deoxyribonucleosides (DRNs) of adenine, cytosine, guanine and thymine were injected i.p. every 8 h for 12 days to the rats subjected to the initiation-selection treatments plus PB. Rats were killed 3 days after the end of RN and DRN treatments. These treatments completely overcome the DHEA effect on the development of GGT-positive foci and DNA synthesis by the focal cells, without affecting G6PD activity of both whole liver and putative preneoplastic foci. Experiments with labeled nucleosides revealed that RNs and DRNs produced derivatives that were incorporated into liver DNA.(ABSTRACT TRUNCATED AT 400 WORDS)

The BN rat strain carries dominant hepatocarcinogen resistance loci.

The phylogenetically distant F344 and BN rat strains and their (BN x F344) F1 hybrids were compared for susceptibility to hepatocarcinogenesis using the 'resistant hepatocyte' model. Quantitative stereological analysis of frequency (number/liver) and size (mean volume and volume fraction) of placental form glutathione S-transferase (GST-P)-positive lesions was carried out at 8, 15 and 32 weeks after diethylnitrosamine initiation. The number/liver of GST-P-positive lesions at any time point was slightly higher in BN and (BN x F344) F1 rats than in F344 rats, but not statistically different. However, mean volume and volume fraction of GST-P positive lesions were much higher in F344 than in both BN and (BN x F344) F1 rats at any time point, with a difference of up to > 10-fold. GST-P-positive lesions exhibited a significantly higher labeling index and much lower remodeling in male F344 than in BN and (BN x F344) F1 rats. HCCs were present at 54-57 weeks after initiation in 77% of male F344 and in no (BN x F344) F1 rats and at 70 weeks HCCs were observed in 100% of male F344 and in 23% of (BN x F344) F1 rats. These results suggest that the BN rat strain is resistant to hepatocarcinogenesis and that its resistance is genetically transmitted as a dominant character to F1 hybrids of the BN strain with the F344 susceptible strain.