[Experimental model of hepatic tumor in the rat: description and results of intrahepatic implantation technique]. / Modello sperimentale di neoplasia epatica nel ratto: descrizione e risultati della tecnica di impianto intraepatico.

In order to investigate new therapeutic strategies for hepatocellular carcinoma (HCC), an animal model easily reproducible of hepatic tumor is necessary. Several techniques of intrahepatic tumor implantation have been reported in the literature. Many of them have the disadvantage of high rate of artificial neoplastic extrahepatic dissemination, both peritoneal and systemic. These drawbacks interfere with the evaluation of treatment efficacy. In this study we describe a modified technique of intrahepatic tumor implantation in the rat, previously reported by Yang in 1992, which is based on the insertion in the liver, after neoplastic tissue, of a piece of hemostatic sponge (Spongostan) that permits to significantly reduce the rate of artificial neoplastic dissemination. Nine ACI/T rats were used and Morris hepatoma 3924A was implanted in the right hepatic lobe. In all cases an intrahepatic tumor take was documented by MRI and by histological examination. No lung metastases were observed. In only one animal peritoneal and subcutaneous nodules were seen, likely due to a technique mistake. According to tumor growth curve it is possible to observe that, with this technique, a 1 cm tumor nodule is obtainable 10 days after the implantation, without extrahepatic metastases, easily detectable by imaging techniques such as MRI used in this study. In conclusion this modified technique of intrahepatic tumor implantation permits to obtain an intrahepatic tumor animal model which is easily reproducible and suitable for the evaluation of efficacy of experimental therapies for HCC.

Regulation of manganese superoxide dismutase (MnSOD) in chronic experimental alcoholism: effects of vitamin E-supplemented and -deficient diets.

In order to investigate the pathogenic mechanism responsible for liver injury associated with chronic alcoholism, we studied the effects of different dietary vitamin E levels in chronically ethanol (EtOH)-fed rats on the activity and mRNA regulation of the manganese superoxide dismutase (MnSOD) enzyme. Evidence is accumulating that intermediates of oxygen reduction may in fact be associated with the development of alcoholic liver disease. Since low vitamin E liver content seems to potentiate EtOH-linked oxidative stress, we studied the effect of EtOH treatment in livers from rats fed a diet deficient or supplemented with vitamin E. Chronic EtOH feeding enhanced hepatic consumption of vitamin E in both groups of EtOH-treated animals, irrespectively of the vitamin E level of the basal diet and the effect was observed in both the microsomal and mitochondrial fractions. Both EtOH-fed groups exhibited increased MnSOD gene expression, while the enzyme activity was enhanced only in the vitamin E-deprived group of EtOH-treated animals. The significant increase in manganese liver content found only in this last group could explain the rise of enzyme activity. In fact, in the absence of a parallel increase of the prosthetic ion manganese, MnSOD mRNA induction was not accompanied by a higher enzymatic activity. These findings support the role of oxidative alteration in the EtOH-induced chronic hepatotoxicity in which MnSOD response might represent a primary defence mechanism against the damaging effect of oxygen radical species.

Manganese content and high-affinity transport in liver and hepatoma.

Morris hepatomas 3924A and 9618A have much lower endogenous contents of Mn than normal rat liver. This work studied the uptake of Mn by slices of these three tissues over a range of concentrations from 0.05 to 100 microM. The influx was assessed with 54Mn while atomic absorption measurements determined the total content. At medium Mn from 0.05 to 5 microM, entry of 54Mn in 2 min was taken as the initial rate and within this period the apparent concentration of Mn in the cell water exceeded that in the medium. Liver showed three apparently saturable uptake systems, the medium concentrations of Mn for half-maximal uptake rate being 0.075, approximately 2, and 100 microM. Hepatoma 3924A appeared to have only two systems, the half-maximal concentration for the higher affinity mechanism being, at 0.34 microM, substantially greater than that for liver. At no concentration was the uptake rate of Mn by hepatoma 3924A less than that of liver although there was some indication that Mn uptake by 9618A was somewhat less than that by the other two tissues. It is concluded that liver and hepatoma 3924A have systems for Mn uptake with affinities that enable them to be active at the plasma concentration (approximately 0.1 microM) as well as uptake systems of less affinity. However, differences in these systems between liver and hepatomas do not account for the differences in endogenous Mn content.

The role of delta-6- and delta-9-desaturase in the fatty acid metabolism of hepatomas with different growth rate.

The fatty acid composition of microsomal membranes from Morris hepatomas 9618A, slow growing, and 3924A, fast growing, confirm the higher content in oleic acid and the loss of PUFAs of the tumours with respect to controls. The specific activities of delta-9-desaturase indicate alternative metabolic pathways for the increased production of oleic acid in the two hepatomas. The delta-6-desaturase activity is much lower in tumours than in controls. However the loss of PUFAs found in tumours seems to be mostly due to a low content in linoleic acid.

Ethanol treatment up-regulates the expression of mitochondrial manganese superoxide dismutase in rat liver.

On the basis of the well-known effect of ethanol poisoning on the prooxidant/antioxidant balance of human and rodent liver we tested the response of the mitochondrial manganese-containing superoxide dismutase (MnSOD) in the liver of rats following an acute ethanol load or chronically intoxicated with an alcohol-supplemented solid diet for three weeks. In both conditions the enzyme activity and messenger RNA were monitored. In the acutely treated animals MnSOD was induced (post-)translationally already at 3 hours after ethanol injection, reached the maximum level (about 50% increment) at 9 hours and decreased thereafter. Chronic ethanol feeding caused an up-regulation of the enzyme at the mRNA level, with a good correlation between the transcript and the enzyme activity during the first two weeks of treatment. After 20 days the mRNA level dropped to normal, whereas the activity still remained high. Chronic alcohol intake also led to a significant decrease in the content of vitamin E in the liver mitochondrial and microsomal fractions, suggesting the occurrence of an enhanced lipid peroxidation, consequent to the ethanol-induced oxidative stress. The response of MnSOD appears to be a protective mechanism that the genetic machinery builds up to partially overcome such a condition.

Restoration of hydroperoxide-dependent lipid peroxidation by 3-methylcholanthrene induction of cytochrome P-448 in hepatoma microsomes.

Microsomal membranes from the slow-growing Morris hepatoma 9618A catalyze, in the presence of t-butyl hydroperoxide, lower rates of lipid peroxidation than rat liver microsomes. The cytochrome P-450 content of hepatoma microsomes is about 40% that of the liver. SKF 525-A, an inhibitor of mixed-function oxidase, produces in hepatoma microsomes a P-450 type I binding spectrum similar to that of hepatic microsomes. The concentration of the inhibitor required for half-maximal spectral change is about 2 microM in both microsome types. SKF 525-A or ethylmorphine inhibit lipid peroxidation of normal and tumor microsomes to the same extent (about 60%). Treatment of the tumor-bearing rats with 3-methylcholanthrene increases the hepatoma cytochrome P-450 to values comparable to those of control membranes, although the hemoprotein has a peak in the CO-reduced difference absorption spectrum at 448 nm. The cytochrome P-448 induction is accompanied by an almost complete restoration of the hydroperoxide-dependent lipid peroxidation.

Cytochrome P-450 deficiency and resistance to t-butyl hydroperoxide of hepatoma microsomal lipid peroxidation.

Lipid peroxidation of microsomes from rat liver and Morris hepatoma 9618A was induced by means of tert-butyl hydroperoxide (t-BuOOH). In rat liver microsomes t-BuOOH stimulated an early formation of lipid hydroperoxides (LOOH) and an increasing accumulation of malondialdehyde; t-BuOOH was completely consumed and cytochrome P-450 was rapidly destroyed. In hepatoma microsomes (60% deficiency of cytochrome P-450) a remarkable inhibition of both malondialdehyde and LOOH was observed; t-BuOOH was consumed only partially and cytochrome P-450 was destroyed slowly. In the presence of aminopyrine, malondialdehyde production was inhibited to the same extent (about 70%) in normal and tumour microsomes. The concentration of t-BuOOH required to achieve half-maximal velocity of malondialdehyde accumulation was comparable in the two microsome types. It is proposed that the deficiency of cytochrome P-450 limits the activation of t-BuOOH to the free radical species which initiate lipid peroxidation. Low cytochrome P-450 content would also affect the LOOH-dependent propagation of lipid peroxidation.

Superoxide-dependent lipid peroxidation and vitamin E content of microsomes from hepatomas with different growth rates.

Lipid peroxidation of microsomal membranes isolated from rat liver, and Morris hepatomas 9618A (slow-growing) and 3924A (fast-growing) was induced by superoxide radicals generated by the action of xanthine oxidase on xanthine. The peroxidation, measured as malondialdehyde and lipid hydroperoxide formation, was optimized with regard to iron concentration and chelation of iron by ADP. In such conditions hepatoma microsomes catalyze lower rates of lipid peroxidation than the normal counterpart. However, while microsomes from hepatoma 3924A show a marked decrease in both the malondialdehyde and hydroperoxide production rates, microsomes from hepatoma 9618A differ moderately from the control, mainly in the long-term production of hydroperoxides. It is also reported here that the 9618A microsomes partially lack cytochrome P-450 (about 40% deficiency), but they have a fatty acid composition similar to that of control. No differences were found in the content of vitamin E between normal and hepatoma 3924A microsomes. Moreover, induction of vitamin E deficiency in hepatoma 3924A microsomes does not influence the rate of either malondialdehyde or lipid hydroperoxide production. On the basis of these results and previous data on the lipid composition of hepatoma 3924A microsomes it is proposed that the high resistance to superoxide-dependent lipid peroxidation of hepatoma 3924A microsomes is related to the low substrate availability rather than the content of membrane antioxidants; and a limitation only in the propagation phase characterizes the hepatoma 9618A microsomal lipid peroxidation and would be due to the partial deficiency of the endogenous propagating agent, cytochrome P-450.

Lipid peroxidation and fluidity of plasma membranes from rat liver and Morris hepatoma 3924A.

Plasma membranes isolated from the fast-growing, maximal-deviation, Morris hepatoma 3924A exhibit remarkable changes in lipid composition, lipid peroxidation and to some extent in the physical state with respect to rat liver plasmalemmas. A correlation appears to exist between the lower phospholipid: protein ratio, higher cholesterol: phospholipid ratio, lower rate of lipid peroxidation and decrease in fluidity in tumor plasma membranes.

Lipid composition, physical state, and lipid peroxidation of tumor membranes.

Studies were carried out on microsomes isolated from the highly differentiated (slow-growing) Morris hepatoma 9618A, on microsomes and plasma membranes from the poorly differentiated (fast-growing) Morris hepatoma 3924A, and rat liver used as control. The lipid composition (phospholipid and cholesterol content, degree of fatty acid unsaturation) and peroxidation of such membranes has been correlated with the order and fluidity of the membrane bilayer. The results indicate that substrate availability is the rate-limiting step in microsomal and plasma membrane lipid peroxidation of hepatoma 3924A. From diphenylhexatriene fluorescence depolarization measurements it appears that the changes in lipid composition cause an increase in the order of the lipid bilayer on going from the control to hepatoma 9618A and 3924A microsomes, while fluidity is virtually unchanged. Conversely, for similar chemical changes, in plasma membranes from hepatoma 3924A the order is nearly the same and there is a decrease in fluidity. The changes in the above parameters of tumor membranes might be partly related to the loss of protective enzymes against oxygen radicals. This is supported by the observation that inhibition of liver superoxide dismutase and glutathione reductase, by treatment of rats with diethyldithiocarbamate and chloroethyl nitrosourea, respectively, renders the microsomal membranes more resistant to lipid peroxidation in vitro.

Transport of pyruvate in mitochondria from different tumor cells.

A comparative study of the transport of pyruvate in mitochondria isolated from normal rat liver and from three tumors has been carried out. The Km for net pyruvate uptake in mitochondria isolated from Ehrlich ascites tumor cells is practically equal to that measured in normal rat liver mitochondria while, on the other hand, it is higher in Morris hepatomas 44 and 3924A. The Vmax of pyruvate uptake is depressed in all three types of tumor mitochondria as compared to that in the rat liver mitochondria, with the depression being higher in Morris hepatoma 3924A mitochondria. The lower activity of pyruvate translocator in mitochondria isolated from tumor cells as compared to that in rat liver mitochondria is also shown by depression of the rate of pyruvate-supported oxygen uptake. The results document a decreased activity of the pyruvate translocator in tumor mitochondria which seems to be correlated with the growth rate of the tumor cells.

Inhibition of mitochondrial oxidative metabolism by SKF-525A in intact cells and isolated mitochondria.

We have examined the effects of various concentrations of SKF-525A (beta-diethylaminoethyldiphenylpropyl acetate X HCl) on the energy metabolism of liver slices, isolated liver mitochondria, and two types of ascites tumor cells, as well as on ion transport in liver slices. In liver slices, 0.2 to 1.0 mM SKF-525A caused an initial stimulation of O2 uptake which was followed, at 0.5 to 1.0 mM, by a progressive inhibition of O2 consumption, a fall of slice ATP content, and a reduced transport of K+, Na+ and Ca2+. In isolated mitochondria, we studied the effects of SKF-525A on the rate of respiration and on the oxidation-reduction responses of NAD(P)+ and cytochrome b in the presence of various substrates. The results suggest that SKF-525A had three distinct actions on liver mitochondria, viz. an uncoupling action at low concentrations (0.02 to 0.17 mM); at higher concentrations (0.2 to 0.5 mM) an inhibition of the oxidation of NAD(P)+-linked substrates, exerted close to the substrate level; also at 0.2 to 0.5 mM, a less effective inhibition of electron transfer at a point between cytochrome b and O2 in the electron-transfer chain. Experiments on O2 consumption and cytochrome b oxidation-reduction changes in ascites cells showed only the first two of these effects in the intact tumor cells. We conclude that inhibition of mitochondrial energy-conserving reactions by SKF-525A can have a marked influence on energy-requiring aspects of liver-cell metabolism, one example of which is inhibition of cation active transport.

Interaction of Na+ and K+ transport with aerobic energy metabolism in slices of Morris hepatoma 3924A.

Addition of increasing concentrations of glucose to slices of Morris hepatoma 3924A greatly stimulated aerobic lactate production and reduced respiration by 20%. Neither the adenine nucleotide content of the slices nor the calculated rate of adenosine 5'-triphosphate synthesis was altered. Ouabain reduced the rate of O2 uptake (by 20 to 25%) and of aerobic lactate production (by 25 to 50%) without affecting adenine nucleotide contents. The reduction by ouabain of the calculated rate of adenosine 5'-triphosphate synthesis was similar whether the slices were utilizing only endogenous substrate or exogenous glucose also. Raising the medium K+ concentration (and correspondingly reducing Na+) partially overcame the inhibition of ion transport by ouabain and partially restored the rates of respiration and aerobic lactate production toward control levels. Electron microscopic observations of mitochondria within the slices incubated under different conditions showed variations in configuration between "orthodox," "condensed" and degenerating forms. Slices preincubated at 1 degrees showed mitochondria in the condensed form: they were restored to the orthodox configuration during incubation at 38 degrees in oxygenated medium. Oligomycin and glucose enhanced the transition, but ouabain reduced the number of mitochondria undergoing the change. The results suggest that in hepatoma 3924A utilization of adenosine 5'-triphosphate by ion transport exerts a simultaneous control of both respiration and aerobic glycolysis, which is presumably mediated by alterations in the availability of adenosine 5-diphosphate. The mitochondria undergo conformational transitions under conditions likely to affect local availability of adenosine 5'-diphosphate within cell compartments, but the transitions are not all externally added adenosine diphosphate on isolated mitochondria.

The control of anaerobic glycolysis by glucose transport and ouabain in slices of hepatoma 3924A.

1. The activities of glycolysis and K-+ transport have been studied in slices of Morris hepatoma 3924A incubated under anaerobic conditions in the presence of different concentrations of glucose (1-50 mM). 2. Ouabain-sensitive net transport of K-+ was observed at all glucose concentrations greater than 1 mM; ouabain reduced the rate of glycolysis by about 25% at all glucose concentrations able to support ion transport. 3. The net entry of glucose into the intracellular phase was studied at varying glucose concentrations. The rate of glucose entry was similar to the rate of glucose utilisation by anaerobic glycolysis at medium concentrations of 10 mM and less, but exceeded the rate of glycolysis at 20 mM and above. 4. The glucose entry was not Na-+-dependent and was not inhibited by ouabain. 5. The results suggest (a) that the reduction in glycolytic activity caused by ouabain is not due to an inhibition of glucose transport and (b) that the glucose transport system of this poorly differentiated hepatoma has properties similar to that of normal liver.