Claudio Canepa

Action of chronic CCl4 on the retinol and dolichol content of rat liver parenchymal and non-parenchymal cells

We studied dolichol, on account of its role in membrane fluidity and fusion, and retinol, on account of its behaviour in liver fibrosis, in isolated parenchymal and sinusoidal rat liver cells after CCl4 treatment for 3, 5 and 7 weeks. Retinol uptake was also investigated by administering a load of retinol three days before sacrifice. In hepatocytes, dolichol decreased and seemed to be the preferred target of lipid peroxidation by CCl4; indeed, retinol increased especially after vitamin A load. Two subfractions of hepatic stellate cells were obtained: in the subfraction called Ito-1, dolichol decreased, while the supplemented retinol was no longer stored; in the subfraction called Ito-2, the values were intermediate. In Kupffer and endothelial cells dolichol was higher after three weeks, in agreement with fibrogenesis. Retinol increased after retinol load, in Kupffer and endothelial cells, in agreement with their scavenger function. The different behaviour of dolichol content in parenchymal and non-parenchymal cells suggests that dolichol may have different functions in liver cells. Since it has been ascertained that, in liver fibrosis, stellate cells gradually lose retinol, the inability of HCs to send retinol to Ito-1 subfraction or the inability of Ito-1 subfraction to take up and store vitamin A might induce or contribute to the transformation of these cells into a different phenotype. This behaviour is discussed regarding the role of cellular and retinol binding proteins in intracellular retinol content. Moreover a role of dolichol in membrane fluidity and retinol traffic is hypothesised.

Chronic ethanol treatment: dolichol and retinol distribution in isolated rat liver cells

The aim of this study was to use chronic ethanol intoxication for 2 and 4 months as a means of studying the distribution of dolichol and retinol in isolated rat liver parenchymal cells, Kupffer cells, sinusoidal endothelial cells, and two subfractions of hepatic stellate cells: Ito 1 and Ito 2. Dolichol and retinol were studied in two batches of rats: on normal nutrition and after a load of vitamin A given 3 d before sacrifice. New observations reported are: (i) on normal nutrition, after 2 months of treatment, dolichol in HC seems to be the first target of chronic ethanol, while retinol is the first target in hepatic stellate cells; (ii) the various types of liver cells are differently affected by chronic ethanol, which highlights the importance of studying each type of sinusoidal cell; (iii) a load of vitamin A given when the damage has already occurred restores dolichol content in HC while retinol decreases; and, (iv) a link between dolichol and vitamin A metabolism might be supposed after the load of vitamin A: the percentage distribution of dolichol with 18 isoprene units (Dolichol -18) increases in all the control cells but decreases after chronic ethanol treatment. A different role of this dolichol and/or a different compartmentalization within the cell need to be further investigated.

Thioacetamide impairs retinol storage and dolichol content in rat liver cells in vivo.

The aim of this paper was to ascertain whether chronic pretreatment with thioacetamide (TAA) might alter the uptake of a load of retinol and dolichol distribution in hepatocytes (HC), hepatic stellate cells (HSC) (Ito-1 and Ito-2 subfractions), Kupffer (KC) and sinusoidal endothelial cells (SEC). The reason why retinol and dolichol content was studied is that their metabolism and transport might be interrelated and that the two isoprenoids might exert different functions in the cells of the hepatic sinusoid. Rats were treated for 2 and 4 months with TAA, a known fibrogenic hepatotoxin, at a low dosage, to produce an early stage of damage. Three days before sacrifice, the rats were given a load of vitamin A, and cells were isolated to investigate its uptake. In HC, the load of retinol was taken up and accumulated, while a decrease in dolichol preceded retinol increase. In HSC, much less of the retinol load was stored than in controls, and dolichol content also decreased. Various minor modifications were seen in KC and SEC.Collectively, the results show that the distribution of these two isoprenoids, which play important roles in cellular differentiation and proliferation, is differently altered in the multiple cell types that line the hepatic sinusoid, and that both isoprenoids seem to participate in the first steps of liver damage.

Dolichol and vitamin A content in rat liver Ito (perisinusoidal) cells.

Dolichol has been determined in many tissues but to date no data are available on liver Ito (fat storing) cells. In this note dolichol was determined in two subpopulations of liver Ito cells isolated from rats pretreated with vitamin A: Ito-1, vitamin A enriched and Ito-2, relatively poor of vitamin A. Differences were observed in the behaviour of the two fractions after vitamin A pretreatment of rats. In fact, in Ito-1 fraction dolichol increases with the increase of vitamin A, while in Ito-2 fraction it does not change significantly with the increase of vitamin A. These results, while confirming the heterogeneity of fat storing cells, are discussed as to the possible role of dolichol and vitamin A metabolism.

Dolichol and retinol content of rat liver sinusoidal cells after chronic monensin treatment.

Aim of this study was to ascertain whether an impairment of communication between parenchymal and non-parenchymal liver cells involves vitamin A intercellular transport. The following approach was adopted: liver cells were isolated from rats treated chronically with the hydrophobic ionophore monensin i.p. for 3, 5, and 7 weeks and their retinol and dolichol content was assessed. Monensin, which alters membrane flow, was used because it had previously been reported to induce liver steatosis, cholestasis and glycogenolysis after acute treatment and, by preliminary morphological examination, to impair vitamin A transport between stellate cells and hepatocytes. Dolichol was chosen as a biochemical marker because it is a membrane lipid that modulates the fluidity and permeability of the membranes that retinol must cross. After monensin treatment, a load of vitamin A was given to rats three days before sacrifice, to ascertain whether its uptake by sinusoidal liver cells was altered. The main result was a dolichol decrease in hepatocytes and in the Ito-1 subfraction. In this latter, monensin induced a decrease in dolichol content only after vitamin A load. Moreover, while the hepatocytes were able to take up a load of vitamin A normally, the Ito-1 subfraction was no longer able to store retinol. Therefore the polarised transport of retinol between hepatocytes and stellate cells seemed impaired. The behaviour of sinusoidal endothelial cells and Kupffer cells might be ascribed to the functions of these cells and is not significantly modified by monensin. In conclusion, the altered cross-talk between sinusoidal cells in liver pathology might involve retinol as well as cytokines. Different pools of dolichol might have a role in this membrane process in a hydrophobic environment.

Association of thioacetamide and ethanol treatment: dolichol and retinol in isolated rat liver cells.

Our aim was to study the distribution of dolichol, dolichol isoprenoids, and retinol in hepatocytes, Kupffer, sinusoidal endothelial and two subfractions of hepatic stellate cells, —Ito‐1 and Ito‐2—, after chronic treatment of rats for 2 and 4 months with a low dosage of thioacetamide associated with ethanol. Each type of cell responded differently to the two hepatotoxins. Overall, ethanol rarely affected the action of thioacetamide. Some new information emerges with regard to these hepatotoxins in comparison with the effects exerted by each of the drugs separately: treatment with thioacetamide plus ethanol determined an early decrease in dolichol in Kupffer cells (about 13% and 50% after 2 and 4 months, respectively). Moreover, after liver damage, a load of vitamin A evidenced altered percentages of the form of dolichol with eighteen isoprene units; these percentages were modified by all treatments in all cell types. The results confirm that dolichol is the preferred target of oxidative stress and suggest a relationship between dolichol and retinol metabolisms, and a possible new role of dolichol precursors, of prenyltransferases and of retinol metabolites in liver pathology.

Dolichol content in isolated sinusoidal liver cells after in vivo chronic treatment with thioacetamide

The content of dolichol, an isoprenoid present in all biological membranes, was determined in isolated sinusoidal liver cells after treatment of rats for 2 and 4 months with a low dosage of the hepatotoxin thioacetamide. The significant decrease in dolichol observed in hepatocytes after 2 months might be explained by peroxidation of the isoprenoid. At the same time point, retinol was retained, and decreased only after 4 months of treatment. After 4 months of treatment therefore both lipids decreased. In a subfraction of hepatic stellate cells, Ito-1 cells, the main storage site of vitamin A, dolichol decreased significantly only after 4 months. A remarkable difference from hepatocytes is that in Ito-1 cells retinol content significantly decreased after 2 months of treatment. In another subfraction, Ito-2 cells, the content of the two isoprenoids decreased in parallel. This heterogeneous subfraction might represent those transitional hepatic stellate cells that, while losing retinol, are in the process of differentiating into myofibroblasts secreting extracellular matrix components. In Kupffer cells and sinusoidal endothelial cells, impairment of dolichol might be observed later, only after 4 months of treatment, while retinol decreases uniformly over time. Starting after two months of treatment, the decrease of dolichol and the increase of retinol in hepatocytes, at the same time as retinol decreases in hepatic stellate cells, might be taken as an early index of incipient liver injury due to thioacetamide. This hypothesis is discussed with regard to a role of dolichol in the modulation of membrane fluidity for intracellular and intercellular retinol transport.

Chronic High Doses of Thioacetamide Followed by Vitamin A Modify Dolichol, Dolichol Isoprenoids, and Retinol Content in Rat Liver Cells

Our line of researches follows the hypothesis that dolichol and retinol metabolism might be interrelated and involved in liver fibrosis. To this end, in this study rats were subjected to chronic treatment with thioacetamide (TAA) (300 mg/L liquid diet) for 1 and 2 months and, after liver damage had occurred, supplemented with vitamin A before sacrifice. Dolichol, dolichol isoprene units, and retinol content were determined in isolated parenchymal and sinusoidal liver cells (hepatic stellate cells; Kupffer cells; sinusoidal endothelial cells). Dolichol increased in hepatocytes after TAA treatment, with or without vitamin A. Dolichol decreased in the other cells. Retinol in general decreased. In hepatocytes, retinol decreased only on normal nutrition, while the vitamin A load was taken up normally. The percentages of dolichol isoprene units (Dol-16 to Dol-20, in rats) confirm that Dol-18, which was not modified in percentage by TAA on normal nutrition, did not increase after vitamin A, as it did in control cells (7–12%). The behavior of Dol-18 was similar in all the cells studied. Vitamin A might reveal a latent damage produced by TAA on dolichol homologues. These data support previous hypotheses that the action of TAA depends on the administration modality, the dosage, and the diet, and that Dol-18 might have different functions and compartmentalization in the cells. Furthermore, the resultssupport the hypothesis that dolichol chain length might be interrelated with retinol metabolism, perhaps through their metabolites.