Three days after subdiaphragmal vagotomy, the rate of local blood flow in the muscular layer of rat jejunum increases, decreases on the 7th-30th day, and is normalized on the 60th-220th day. Po 2 is lowered within 3-30 days, but not after 14 days. Microhemodynamic disturbances are accompanied by changes in the configuration of the microvessels, increased permeability of their walls, and modification of the aggregation status of the blood. Correlations between the dynamics of blood flow rate, its kinetic parameters, and Po~, on the one hand, and morphological reorganization of the microcirculatory bed, on the other, suggest that hypoxia of the small intestine muscles developing after vagotomy has a circulatory nature.
Proliferative activity and lipid composition (phospholipids and gangliosides) were studied in rat hepatoma-27 transplanted subcutaneously or intrahepatically (as models for primary and metastasizing tumors). The mitotic index of subcutaneously transplanted hepatoma far exceeded that of the intrahepatically transplanted tumor. The overall amounts of both phospholipids and gangliosides increased appreciably in the subcutaneously growing hepatoma (in contrast to the intrahepatically growing tumor) in comparison to the control hepatic tissue. The ganglioside composition in the tumors differs from that in the liver: ganglioside GD3 appears, whereas gangliosides GD1b and GT1b decrease in amount in the intrahepatic tumor compared to the control liver and disappear in the subcutaneously transplanted hepatoma. In both tumor types, the amounts of both phosphatidylethanolamine and sphingomyelin exceed the control values. Comparison of these results with previously reported data concerning the phospholipid and ganglioside composition in the regenerating rat liver indicates that the difference in the lipid composition between the subcutaneously and intrahepatically growing hepatomas-27 is due to their different proliferative status and also their microenvironment.
We studied dense 24-hour cultures of rat hepatocytes in serum-free medium on collagen-coated slides. As before, a circahoralian rhythm of protein synthesis was observed in control cultures in a fresh medium. No rhythm was found after addition of 1-10 μM dopamine to the medium containing such cultures. The rhythm was observed after addition of 0.3 μM ganglioside to pretreated-dopamine cultures. Dopamine is likely to influence the conditioning of intercellular medium with gangliosides. Deficit of this endogenous synchronizing factor in the intercellular medium blocks self-organization of the protein synthesis rhythm. Thus, in contrast to previously studied norepinephrine and serotonin, as well as gangliosides, which organized the population rhythm of protein synthesis, dopamine disorganized the rhythm, impairing direct intercellular interactions.
Dopamine was injected intravenously (9 μg/kg) or intraperitoneally (15 μg/kg) to Wistar rats (3-4 months, 300-400 g). Hepatocytes were isolated 40 min after dopamine injection. Dense cultures were maintained on collagen-coated glasses. By the 5th hour, the circaholarian rhythm of protein synthesis in hepatocytes cultures was absent in the dopamine group, but was present in cultures from animals receiving physiological saline (NaCl). The rhythm-disorganizing effect of dopamine was reversible. The rhythm was observed in cultures of hepatocytes isolated 1 day after dopamine treatment. The effect of dopamine was abolished by melatonin. The protein synthesis rhythm was revealed in 5-h cultures of hepatocytes from rats receiving melatonin (32 ng/kg) 40 min after intraperitoneal injection of dopamine. The results of our in vitro experiments with addition of dopamine into the medium of cultured hepatocytes [1] suggest that dopamine in vivo produces a direct effect on liver cells. The observed changes are discussed taking into account the biochemical mechanisms for a direct cell-cell interaction and previously unknown properties of catecholamines.
Dense cultures of hepatocytes from old rats (~2 years old, body weight 530-610 g) are different from similar cultures of hepatocytes from young rats by the low amplitude of protein synthesis rhythm. Addition of glutamic acid (0.2, 0.4, or 0.6 mg/ml) into the culture medium with hepatocytes of old rats resulted in increase in the oscillation amplitudes of the protein synthesis rhythm to the level of young rats. A similar action of glutamic acid on the protein synthesis kinetics was observed in vivo after feeding old rats with glutamic acid. Inhibition of metabotropic receptors of glutamic acid with α-methyl-4-carboxyphenylglycine (0.01 mg/ml) abolished the effect of glutamic acid. The amplitude of oscillation of the protein synthesis rhythm in a cell population characterizes synchronization of individual oscillations caused by direct cell-cell communications. Hence, glutamic acid, acting as a receptor-dependent transmitter, enhanced direct cell-cell communications of hepatocytes that were decreased with aging. As differentiated from other known membrane signaling factors (gangliosides, norepinephrine, serotonin, dopamine), glutamic acid can penetrate into the brain and thus influence the communications and protein synthesis kinetics that are disturbed with aging not only in hepatocytes, but also in neurons.
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