Studies on the inhibition of glycogenolysis by D-galactosamine in rat liver hepatocytes.

Effect of galactosamine on glycogenolysis was studied in isolated hepatocytes. It was found that addition of galactosamine strongly inhibited glycogenolysis in normal hepatocytes. Galactosamine-inhibited glycogenolysis was not stimulated by epinephrine or glucagon. This inhibition was specific as no such inhibition was observed with galactose, 2-deoxy-glucose or glucosamine. The glucagon-stimulated cyclic AMP formation in galactosamine-treated hepatocytes was the same as in normal cells; Glc-1-P and Glc-6-P did not accumulate nor was lactate formation enhanced. The glucose production by hepatocytes from regenerating liver was only slightly inhibited by galactosamine and glucagon addition stimulated glycogenolysis in the presence of the amino sugar.     

Fasting-induced apoptosis in rat liver is blocked by cycloheximide.

The effect of cycloheximide (CH) on the fasting-induced changes of rat liver cell and protein turnover has been investigated. Late starvation phase (3-4-day-fasting period) was characterised by a decrease in liver weight and protein and DNA content. The loss of DNA was not related to liver cell necrosis but due not only to depression of cell proliferation as shown by the drop in the labelling index but also induction of apoptosis. This type of apoptosis was documented by the increase in the apoptotic index (cells labelled by TUNEL) and transglutaminase activity as well as by DNA fragmentation. The liver cells of fasted rats appeared smaller as shown by the higher cell density and DNA/protein ratio than in controls. Females were more resistant to fasting-induced apoptosis than males. A single dose of CH, a drug primary known as inhibitor of protein synthesis, induced or enhanced apoptosis in fed and 2-days fasted male rats, respectively, without any sign of cell necrosis. On the contrary, the administration of repeated doses of CH blocked apoptosis induced by fasting. CH "froze" protein and DNA content as well as apoptotic process at the level of 2 days-fasted rats. While fasting-induced liver protein loss resulted from a marked reduction in protein synthesis with a slight decrease in degradation, repeated treatment with CH virtually blocked protein loss by abolishing protein catabolism. These data suggest a direct relationship between the catabolic side of protein turnover and the apoptotic process.     

Influence of D-galactosamine upon the NAD-metabolism in rat liver

After application of D-galactosamine a hepatitis develops in the rat liver. This can be prevented by different agents, including tryptophan. Yet it has not been possible to give definitive conclusions about the mechanism of galactosamine hepatitis. In this paper we report about the influence of galactosamine on the NAD metabolism. D-galactosamine inhibits the NAD synthesis initiated by nicotinamide in normal and adrenalectomized animals. The NAD synthesis from tryptophan is prevented in normal animals, in adrenalectomized ones however there is an increase of NAD in the presence of D-galactosamine reduces the activity of the ADPR transferase. Inhibitors of the ADPR transferase prevent the galactosamine hepatitis. From the results presented we conclude that the ADPR transferase plays an important role in the development of the galactosamine hepatitis.     

Changes induced by fasting and cycloheximide in the vacuolar apparatus of rat hepatocytes. A morphometric investigation

An increase in the number of autophagic vacuoles and in the size of the dense and residual bodies was observed in the hepatocytes of rats fasted for 24 hours; moreover, the number of dense bodies was reduced. These data suggest that the previously reported acceleration in cell protein degradation caused by fasting can be accounted for by enhanced autography. The treatment with cycloheximide, which was previously found to prevent this proteolytic response, also prevents the appearance of signs of enhanced autophagic activity.     

Modification of oestrogen-induced uterine hyperaemia by drugs in the ovariectomized rat.

Uterine blood flow in ovariectomized rats was measured by means of radioactive microspheres. Blood flow was increased from 55 ml min-1 100 g-1 by treatment (i.v.) with 0.5 microgram oestradiol kg-1 and reached 680 ml min-1 100 g-1 within 60 min. This oestrogen-induced increase of blood flow was reduced significantly by pretreatment with mepyramine (a histamine H1-receptor antagonist), cellulose sulphate (a kininogen-depleting agent) and aprotinin (a kininogenase inhibitor). Cimetidine (a histamine H2-receptor antagonist), kallikrein (kininogenase enzyme) and atropine (an anticholinergic drug) had no effect on the increased uterine blood flow. Indomethacin and AH 7170, which inhibit the formation of prostaglandins, also caused a lower increase in uterine blood flow. None of the pretreatments fully inhibited the oestrogen-induced increase in blood flow, suggesting that more than one mediator may be involved.     

Radiation injury in rat lung. IV. Modification by D-penicillamine

To determine whether D-penicillamine, known to reduce fibrosis in irradiated rat lung (W. F. Ward, A. Shih - Hoellwarth , and R. D. Tuttle , Radiology 146, 533-537, 1983), also ameliorates radiation injury in the pulmonary endothelium, we measured angiotensin-converting enzyme (ACE) activity, plasminogen activator (PLA) activity, and prostacyclin (PGI2) production in the lungs of penicillamine-treated (10 mg/day, po, continuous after irradiation) and untreated rats from 2 weeks to 6 months after a single dose of 25 Gy of 60Co gamma rays to the right hemithorax. Both ACE and PLA activity in the irradiated right lung of untreated rats decreased dramatically between the 1st and 2nd months after exposure, then reached a plateau through 6 months at approximately 25 and 50% of the normal level, respectively. For the first 2 months after irradiation, penicillamine-treated animals exhibited significantly (P less than 0.05) higher activities of both ACE and PLA than did untreated rats. From 3 to 6 months after irradiation, however, the only significant drug effect on these enzymes was a 25% increase in PLA activity at 6 months. PGI2 production by the irradiated lung of untreated rats increased continuously, and at 6 months was approximately 10 times higher than normal. Penicillamine significantly (P less than 0.05) reduced this hypersecretion, and at 6 months after irradiation, PGI2 production by the lungs of drug-treated rats was only half that of untreated animals. In contrast, the drug had no significant effect on enzyme activities in the lungs of sham-irradiated rats. Thus the antifibrotic agent D-penicillamine delays the onset of radiation-induced enzyme dysfunction in the pulmonary endothelium. In addition at 6 months after irradiation, the lungs of penicillamine-treated rats exhibit 25% more PLA activity and only half as severe a hypersecretion of PGI2 as do the lungs of untreated animals. The drug is most effective in ameliorating endothelial damage during the first 2 months after irradiation, preceding the development of interstitial fibrosis. However, the effect of this penicillamine regimen on pulmonary endothelial function is not as large as its effect on collagen accumulation in irradiated rat lung.     

Modification of the metabolism of rat epididymal spermatozoa by spermine.

Spermine (1 to 10 mM) markedly enhanced (2- to 7-fold) the formation of labelled lactate from radioactive fructose in rat epididymal spermatozoa $\text{in vitro}$. The combination of spermine and calcium (1 mM), the latter ion inconsistently stimulating the formation of carbon dioxide and lactate from fructose, resulted in a striking synergistic stimulation of the fructolysis in epididymal spermatozoa. The production of lactate from fructose in the presence of spermine and calcium increased 5- to 30-fold over that in normal Ringer solution. Spermidine, but not putrescine, also stimulated the formation of lactate from fructose in epididymal spermatozoa. While stimulating the aerobic fructolysis the polyamines inhibited the formation of radioactive CO₂ from (2-¹⁴C)pyruvate thus apparently interfering with the reactions of the tricarboxylic acid cycle. In this respect, however, oxidized spermine {N,N′-bis(3-propion-aldehyde)-1,4-diaminobutane} was far more effective.Spermine (and spermidine) being normal constituents of the secretions of male accessory sexual glands in most mammals could conceivably belong to the factors responsible for the “intensely glycolytic” nature of ejaculated spermatozoa.     

Effects of cycloheximide on protein degradation and gluconeogenesis in the perfused rat liver.

Cycloheximide at concentrations above 18 muM produced a 93% inhibition of total protein synthesis measured by valine incorporation in the perfused rat liver. Rates of protein degradation were estimated by perfusing livers prelabeled in vivo with L-[1-14C]valine with medium containing 15 mM L-valine. Thus labeled valine released from liver protein during perfusion was greatly diluted and reincorporation of label was minimized. Cycloheximide at 18 muM inhibited protein degradation by over 60%, after a delay of 15-20 min. Associated with these effects were dose-dependent increases in the rates of glucose and urea production. Glucose production increased 3 fold, from 0.54 +/- 0.07 in control to 1.85 +/- 0.24 mumol/min/100 g rat in cycloheximide-treated livers. Urea production increased from 0.24 +/- 0.02 to 0.62 +/- 0.06 mumol/min/100 g rat. No changes in liver glycogen or cyclic AMP content were seen. The data suggest that inhibition of protein synthesis provides an increased availability of intra-cellular amino acids and that many of these are rapidly degraded, yielding urea and glucose. This is supported by the fact that intracellular alanine levels were significantly increased following cycloheximide treatment. It is possible that the inhibition of protein degradation by cycloheximide is due to altered intra-cellular pools of amino acids or their metabolites.     

Inverse effects of D-galactosamine and inorganic phosphate on glycogenolysis in isolated rat hepatocytes.

Trichloroethanol is an efficient quencher of indole fluorescence of model compounds and proteins [Eftink, M. R. and Ghiron, C. A. (1976) J. Phys. Chem. 80, 486--493]. At low quencher concentrations, the quenching follows the classical Stern-Volmer law. Bimolecular rate constants calculated from measured quenching constants and lifetimes are equal to 6 X 10(9) M-1s-1 and 1.2 X 10(9) M-1s-1 for N-acetyltrypotophanamide and wheat germ agglutinin, respectively. Upon ultraviolet irradiation in the presence of trichloroethanol, transformation of fluorescent tryptophan occurs, leading to a fluorescent photoproduct. This can be easily used as a method for the quantitative determination of fluorescent tryptophan residues in proteins. In good agreement with previous results, two fluorescent tryptophan residues per polypeptide chain are found in wheat germ agglutinin. Concomitantly with the photochemical reactions, the hemagglutinating protein activity and its affinity constant towards chitin oligomers are reduced. A probable location of tryptophan residues in the binding sites of wheat germ agglutinin is proposed.     

Effect of D-galactosamine on nucleotides in the rat heart. Effects of cytidine and uridine administration

The treatment of rats by galactosamine (2 mmol/kg i.p.), which dramatically alters the metabolism of pyrimidine nucleotides in the liver, has been used to investigate the dynamics of pyrimidine nucleotides in the rat heart. Six hours after administration of the drug, the UTP and UDPG myocardial contents were decreased by respectively 40 and 52% while the sum of uracil nucleotides was increased by 66% and that of cytosine nucleotides by 15%. When administered 5 h after galactosamine treatment, cytidine (750 nmol/rat i.v.) induced a further increase in cytosine nucleotides (46% above control value 1 h later) without however effect on uracil nucleotides. On the other hand, the administration of uridine (250 nmol/rat, i.v. 5 h after galactosamine), while restoring UTP, UDPG and the pool of uracil nucleotides, provoked a decrease in cytosine nucleotide level (-17%). In the absence of galactosamine treatment, the administration of uridine and cytidine did not induce changes in nucleotide levels despite a rise in blood cytidine concentration. All these observations support the hypothesis that: 1. the pathway for cytosine nucleotide synthesis predominant in the heart is that utilizing preformed exogenous cytidine and 2. this pathway is mainly controlled by the intracellular concentration of UTP rather than that of CTP.     

Modification of the mitochondrial proteome in response to the stress of ethanol-dependent hepatotoxicity

Mitochondria are particularly susceptible to increased formation of reactive oxygen and nitrogen species in the cell that can occur in response to pathological and xenobiotic stimuli. Proteomics can give insights into both mechanism of pathology and adaptation to stress. Herein we report the use of proteomics to evaluate alterations in the levels of mitochondrial proteins following chronic ethanol exposure in an animal model. Forty-three proteins showed differential expression, 13 increased and 30 decreased, as a consequence of chronic ethanol. Of these proteins, 25 were not previously known to be affected by chronic ethanol emphasizing the power of proteomic approaches in revealing global responses to stress. Both nuclear and mitochondrially encoded gene products of the oxidative phosphorylation complexes in mitochondria from ethanol-fed rats were decreased suggesting an assembly defect in this integrated metabolic pathway. Moreover mtDNA damage was increased by ethanol demonstrating that the effects of ethanol consumption extend beyond the proteome to encompass mtDNA. Taken together, we have demonstrated that chronic ethanol consumption extends to a modification of the mitochondrial proteome far broader than realized previously. These data also suggest that the response of mitochondria to stress may not involve non-discriminate changes in the proteome but is restricted to those metabolic pathways that have a direct role in a specific pathology.     

Regulation of tyrosine transminase degradation in the isolated perfused rat liver by cycloheximide and insulin

In the isolated perfused rat liver, synthesis of the enzyme tyrosine transminase (EC 2.6.1.5) is stimulated by either insulin or glucocorticoid hormone. The antibiotic cycloheximide blocks both synthesis and degradation of tyrosine transminase in insulin-treated perfused livers, whereas it blocks only synthesis of the enzyme in glucocorticoid-treated or untreated livers. When insulin is given in additions to cycloheximide, degradation of the enzyme is blocked in glucocorticoid-treated livers as well. The inhibitory effects on degradation are enzyme-specific, since tryptophan oxygenase (EC 1.13.1.12), the synthesis of which is stimulated by glucocorticoid hormone but not by insulin, is degraded at the same rate under all conditions.