Biological activity in vitro and in vivo of different insulin derivatives (author's transl)]

The biological activities of des-octapeptide-insulin, des-AsnA21-des-AlaB30-insulin, des-GlyA1-des-PheB1-insulin and trimethionyl-insulin were studied in vitro and in vivo. In vitro we measured, using the isolated diaphragm of the rat, the disappearance rate of glucose in the incubation medium, the incorporation of glucose into the glycogen of the diaphragm and the apntilipolytic activity in the isolated fat cell model. The incorporation of [U-14C]glucose after intraperitoneal injection into the glycogen of the diaphragm and the fat pad tissue was studied in vivo, as well as the incorporation of 14C from [U-14C]glucose into the lipids of the fat pad tissue of the rat.     

Effect of acetate on glucose utilization by isolated rat thymocytes

The effects of acetate and ammonium salts on glucose metabolism, aminoisobutyric acid influx, and radioiodinated insulin binding in isolated thymocytes were studied. Acetate in the concentration range, 0.1–30 mm, was found to inhibit basal and insulin-stimulated CO₂ production whereas ammonium chloride at concentrations greater than 0.3 mm was slightly stimulatory. Ammonium salts inhibited glucose incorporation into glycogen and aminoisobutyric acid influx only at high concentration (30 mm). Neither acetate nor ammonium salts had significant effects on glucose incorporation into glycogen or aminoisobutyric acid influx at lower concentrations. No effect on insulin binding was observed. The observation that very low concentrations of acetate can perturb these biological assay systems suggests that other biological functions may be affected by trace amounts of buffer salts carried over from protein isolation steps.     

Vanadate potentiates the glycogenic action of insulin-like growth factors on isolated diaphragm.

Na3VO4 (6.5 mumol/100 g rat weight), co-injected with a trace amount of [14C]glucose, increased within 15 min the incorporation of radiolabel in diaphragmal glycogen. After 2 h the vanadate-induced increases were 12-fold in the diaphragm and 7-8-fold in heart and liver. In contrast, when added to isolated diaphragms for up to 1 h, vanadate (0.1-5 mM) had no effect on the synthesis of glycogen from 5 mM glucose. In search of a putative mediator of vanadate's action in vivo, insulin and the insulin-like growth factors (IGFs) were considered. Their plasma concentration was not affected by vanadate treatment. In isolated diaphragms, 1 mM vanadate did not potentiate insulin-induced glycogen synthesis, but it caused a several-fold increase in glycogen synthesis in the presence of concentrations of IGF-I which, alone, had no effect. A similar synergism occurred between vanadate and IGF-II. We propose that the glycogenic action of vanadate in vivo, at least in some tissues, involves a potentiation of the action of IGF-I.     

Studies on two groups of aminoacyl-tRNA synthetases from rat liver

Aminoacyl-tRNA synthetases from rat-liver cytoplasm were fractionated into two groups, characterized by their sedimentation coefficients of about 20S and 5S, respectively. These two groups of synthetases could be isolated from postmicrosomal supernatant either by gradient centrifugation, by gel filtration or by acid treatment at pH 5.2. Both groups were required for maximal amino acid incorporation in a cell-free system.     

The detection of promutagen activation by extracts of cells expressing cytochrome P450IA2 cDNA: preincubation dramatically increases revertant yield in the Ames test

Two slightly different protocols, the plate incorporation method and the preincubation method, are used in the Ames Salmonella mutagen test. Using a preincubation method, we recently demonstrated efficient activation of a number of food-derived promutagens by extracts of mammalian cells expressing cDNAs of rat-liver cytochrome P450IA2 and of a P450IA2-IA1 hybrid. We report here that, for 2-amino-3,4-dimethylimidazo[4,5-ƒ]quinoline (MeIQ), 1-aminoanthracene and several other promutagens, preincubation dramatically increased the number of revertant colonies in the Ames test when extracts of cytochrome P450IA2-containing transfected cells or low concentrations of rat-liver extracts were used as the source of activating enzymes. At higher concentrations of rat-liver extract protein, the effect of preincubation was less pronounced. The effect of preincubation was not due to the low protein concentrations in the assays since increasing the total protein concentration did not abolish the requirement for preincubation for the detection of MeIQ activation at low concentrations of rat-liver extract. In experiments where P450IA2 synthesized in transfected cells in culture is used to study promutagen activation, the plate incorporation protocol may seriously underestimate the capacity of cell extracts to activate promutagens. Thus, interlaboratory comparisons become difficult and unnecessarily large quantities of cell extract protein may be needed to detect promutagen activation. Whenever Ames test assays are carried out under conditions where P450 concentration limits revertant yield, it would be prudent to examine both the preincubation and plate incorporation protocol.     

The detection of promutagen activation by extracts of cells expressing cytochrome P450IA2 cDNA: preincubation dramatically increases revertant yield in the Ames test.

Two slightly different protocols, the plate incorporation method and the preincubation method, are used in the Ames Salmonella mutagen test. Using a preincubation method, we recently demonstrated efficient activation of a number of food-derived promutagens by extracts of mammalian cells expressing cDNAs of rat-liver cytochrome P450IA2 and of a P450IA2-IA1 hybrid. We report here that, for 2-amino-3,4-dimethylimidazo[4,5-f]quinoline (MeIQ), 1-aminoanthracene and several other promutagens, preincubation dramatically increased the number of revertant colonies in the Ames test when extracts of cytochrome P450IA2-containing transfected cells or low concentrations of rat-liver extracts were used as the source of activating enzymes. At higher concentrations of rat-liver extract protein, the effect of preincubation was less pronounced. The effect of preincubation was not due to the low protein concentrations in the assays since increasing the total protein concentration did not abolish the requirement for preincubation for the detection of MeIQ activation at low concentrations of rat-liver extract. In experiments where P450IA2 synthesized in transfected cells in culture is used to study promutagen activation, the plate incorporation protocol may seriously underestimate the capacity of cell extracts to activate promutagens. Thus, interlaboratory comparisons become difficult and unnecessarily large quantities of cell extract protein may be needed to detect promutagen activation. Whenever Ames test assays are carried out under conditions where P450 concentration limits revertant yield, it would be prudent to examine both the preincubation and plate incorporation protocol.     

Inhibition of metabolic effects of growth hormone by various inhibitors of cyclic nucleotide phosphodiesterase

When isolated diaphragms of hypophysectomized rats were incubated with bovine growth hormone in the presence of the cyclic nucleotide inhibitors theophylline, quinine and papaverine, the stimulatory effects of the hormone on leucine incorporation into protein, α-aminoisobutyric acid and 3-O-methylglucose transport were suppressed or abolished entirely. The degree of suppression of the hormone effects appeared to correlate with the extent of glycogenolysis caused by the drugs. Thoephylline also rapidly reversed the stimulation of protein synthesis and amino acid and sugar transport produced by growth hormone. When protein synthesis and transport were stimulated by preincubation of the diaphragm with growth hormone, the subsequent addition of theophylline to the medium inhibited the hormonal effects on protein synthesis and sugar transport within 15 min and the effect on amino acid transport within 60 min. These results may mean that the rapid in vitro effects of growth hormone on protein synthesis and membrane transport in rat diaphragm muscle are mediated by a reduction in the cellular level of cyclic AMP or some other nucleotide.Attempts to block the action of growth hormone on 3-O-methylglucose transport by preincubation of the diaphragm with high concentrations (10 mM) of cyclic GMP, cyclic UMP, cyclic TMP and cyclic CMP were unsuccessful. Also an effort was made to mimic the action of growth hormone on sugar transport by incubating the diaphragm with high concentrations of imidazole and histamine, agents known to activate cyclic nucleotide phosphodiesterase. Slight stimulatory effects were obtained, but they could not be correlated with any certainty to the actions of imidazole and histamine on phosphodiesterase.Like growth hormone, insulin also stimulates protein synthesis and amino acid and sugar transport in the isolated rat diaphragm. However, the actions of insulin on these processes were not abolished by theophylline, suggesting some basic difference in the mode of action of these two hormones on protein synthesis and membrane transport in muscle.     

Phenethylbiguanide and the inhibition of hepatic gluconeogenesis in the guinea pig

1. Phenethylbiguanide inhibits the synthesis of phosphoenolpyruvate from malate or 2-oxoglutarate by isolated guinea-pig liver mitochondria. This inhibition is time- and concentration-dependent, with the maximum decrease in the rate of phosphoenolpyruvate synthesis (80%) evident after 10min of incubation with 1mm-phenethylbiguanide. 2. The phosphorylation of ADP by these mitochondria is also inhibited at increasing concentrations of phenethylbiguanide and there is a progressive increase in AMP formation. Guinea-pig liver mitochondria are more sensitive to this inhibition in oxidative phosphorylation caused by phenethylbiguanide than are rat liver mitochondria. 3. Simultaneous measurements of O(2) consumption and ADP phosphorylation with guinea-pig liver mitochondria oxidizing malate plus glutamate in State 3 indicated that phenethylbiguanide at low concentrations (0.1mm) inhibits respiration at Site 1. At higher phenethylbiguanide concentrations Site 2 is also inhibited. 4. Gluconeogenesis from lactate, pyruvate, alanine and glycerol by isolated perfused guinea-pig liver is inhibited to various degrees by phenethylbiguanide. Alanine is the most sensitive to inhibition (60% inhibition of the maximum rate by 0.1mm-phenethylbiguanide), whereas glycerol is relatively insensitive (25% inhibition at 4mm). 5. Gluconeogenesis from lactate and pyruvate by perfused rat liver was also inhibited by phenethylbiguanide, but only at high concentrations (8mm). Unlike guinea-pig liver, the inhibitory effect of phenethylbiguanide on rat liver was reversible after the termination of phenethylbiguanide infusion. 6. The time-course of inhibition of gluconeogenesis from the various substrates used in this study indicated a time-dependency which was related in part to the concentration of infused phenethylbiguanidine. This time-course closely paralleled that noted for the inhibition by phenethylbiguanide of phosphoenolpyruvate synthesis in isolated guinea-pig liver mitochondria.     

The biosynthesis of intestinal mucins. The effect of salicylate on glycoprotein biosynthesis by sheep colonic and human gastric mucosal tissues in vitro

1. Incubation of sheep colonic mucosal scrapings in Krebs-Ringer buffer for 2(1/2)hr. in the presence of salicylate (15mm) resulted in decreased incorporation of radioactivity into the epithelial glycoprotein from the following labelled precursors: 16.6mum-d-[2-(14)C]glucose (83.9% inhibition), 20mum-l-[U-(14)C]threonine (82%) and (35)SO(4) (2-)(79%). Oxygen uptake measured simultaneously was diminished to 41% of the control value. 2. At lower concentrations of salicylate (e.g. 3.75mm), incorporation of 20mum-l-[U-(14)C]threonine was little affected (3-6% inhibition), whereas utilization of 4mum-d-[U-(14)C]glucose and (35)SO(4) (2-) was inhibited (41-48% and 40-59% of the control values respectively). 3. Analysis of the papain-digested glycoprotein from tissue incubations with 16.6mum-d-[2-(14)C]glucose in the presence of salicylate (3.75mm) showed large decreases in labelling of N-acetylneuraminic acid and N-glycollylneuraminic acid residues (57% and 34% of the control values respectively) and of hexosamine constituents (glucosamine, 55% inhibition; galactosamine, 33% inhibition). Labelling of neutral sugars (galactose and fucose) was relatively little affected (9 and 11% inhibition respectively). 4. Glucose 6-phosphate transaminase and glucosamine 6-phosphate acetylase in particle-free enzyme preparations of the sheep tissue were unaffected by salicylate at the above concentrations. Acetyl-CoA synthetase was markedly inhibited. 5. Human gastric mucosa (from operation), on incubation as above, had in one experiment an oxygen consumption of 9.9mul./hr./mg. dry wt. of tissue and incorporated 5mum-d-[U-(14)C]glucose (15.8% of the total radioactivity added) into bound hexosamine (20.6% of the total radioactivity incorporated), hexoses (glucose and galactose, 5.7%) and fucose (14.2%). The presence of salicylate (15mm) decreased the incorporation of 5mum-d-[U-(14)C]glucose into the glycoprotein by 74%, all sugar constituents being affected, without influence on the rate of oxygen consumption. 6. The results suggest an inhibitory effect of salicylate on glycoprotein biosynthesis at the level of the amino sugar intermediates.     

A direct effect of growth hormone on the incorporation of precursors into proteins and nucleic acids of perfused rat liver

1. The livers of rats were perfused in situ. When the amino acid concentration in the perfusing medium was that present in rat plasma, the addition of growth hormone to the medium stimulated the incorporation of labelled amino acids into liver protein only marginally and not to a statistically significant extent. When, however, the amino acid concentration was raised to three times that present in rat plasma, growth hormone significantly and substantially stimulated amino acid incorporation into protein within 30min. of perfusion of normal rat liver. 2. A significant effect of growth hormone on labelling of normal rat-liver protein was seen with concentrations not much greater than those reported to be present in rat plasma. 3. The labelling of nucleic acids of normal and hypophysectomized rat liver by [(3)H]orotic acid was enhanced by addition of growth hormone to the perfusing medium when normal concentrations of amino acids were used. 4. At elevated concentrations of amino acids, growth hormone stimulated labelling of nucleic acids of hypophysectomized rat liver at 30 and 60min. of perfusion. Under these conditions, nucleic acids of normal rats were labelled to about the same extent in control and hormone-treated livers at 30min. and, because of a fall in the radioactivity of the control livers, there was more labelled nucleic acids in growth-hormone-treated livers at 60min. than in the control livers. 5. Growth hormone, unlike insulin, had no inhibitory effect on the release of glucose by the perfused liver. 6. It is concluded that growth hormone can stimulate the incorporation of precursor into proteins and nucleic acids of liver directly and without the mediation of other organs or of insulin.     

Alterations in regulation of insulin biosynthesis in pregnancy and starvation studied in isolated rat islets of Langerhans

1. Insulin biosynthesis in isolated rat islets of Langerhans was determined by the incorporation of [(3)H]leucine into newly synthesized islet proteins. Anti-insulin serum covalently coupled to a solid phase (CNBr-activated Sepharose 4B) was used to separate the immunoreactive proinsulin and insulin from other islet proteins. This method was applied to a study of the regulation of insulin biosynthesis in isolated rat islets of Langerhans during pregnancy, and immediately after a period of food deprivation. 2. Islets isolated from pregnant rats showed an increased basal rate of synthesis compared with the non-pregnant controls. In addition, they showed a significant increase in biosynthesis of proinsulin and insulin in comparison with the normal islets over a range of glucose concentrations of 2-20mm. 3. Addition of the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine significantly increased the insulin-synthetic response of normal islets over the glucose range 5-20mm, so that their glucose response approached that of islets from pregnant rats. 4. Normal female rates were injected with a long-acting progesterone derivative (hydroxyprogesterone hexanoate), to investigate the role of progesterone on the increased insulin biosynthesis observed in islets in pregnancy. There appeared to be no marked difference in insulin biosynthesis between the islets from the progesterone-injected and control rats in the presence of 2mm- or 6mm-glucose alone. However, in the presence of 4mm- or 6mm-glucose and 3-isobutyl-1-methylxanthine there was a significant increase in insulin biosynthesis in the progesterone-treated animals. 5. Total islet protein biosynthesis was determined by the incorporation of [(3)H]leucine into trichloroacetic acid-precipitable islet proteins. Islets isolated from normal rats showed a 1.6-fold increase in incorporation over the glucose concentration range 2-20mm, and this value remained unchanged during starvation; however, rates of incorporation were significantly raised in islets isolated from pregnant rats in the presence of 20mm-glucose. 6. Islets from starved and fed control rats were incubated in the presence of increasing concentrations of glucose or glucose+3-isobutyl-1-methylxanthine. The islets isolated from the starved animals showed a diminished insulin-synthetic response to glucose as compared with the controls; this response was partially restored to normal values by elevation of cyclic AMP concentrations by using 3-isobutyl-1-methylxanthine. 7. It is suggested that the alterations in glucose-stimulated insulin biosynthesis observed in islets during pregnancy and after a period of starvation could be attributable, at least in part, to a long-term alteration of the cyclic AMP system, and in pregnancy to a direct or indirect effect of progesterone on beta-cell function.     

Effect of nucleoside triphosphate and magnesium ion concentration on the stability and function of rat liver polysomes in vitro

The effects of different concentrations of ATP, GTP, UTP and CTP on polysome stability and function in a cell-free protein-synthesizing system prepared from rat liver were studied. Increasing the concentration of ATP in the incubation medium to 15mm resulted in progressive disaggregation of the polysomes; at ATP concentrations above 2mm their capacity to incorporate amino acids into peptide chains diminished. The same disaggregation phenomenon could be produced by incubating polysomes in a buffered medium containing 5mm-Mg(2+) and increasing concentrations of ATP. Although the disaggregating action of ATP could be prevented by increasing Mg(2+) concentration, the amino acid incorporation in the cell-free protein-synthesizing system remained impaired. The effects of different concentrations of GTP, UTP and CTP on polysome stability were similar to those of ATP. Increasing the concentrations of each nucleoside triphosphate also inhibited the hydrolysis of GTP in the cell-free protein-synthesizing system.     

Absence of mutagenic activity of benorylate,paracetamol and aspirin in the Salmonella//mammalian microsome test

Benorylate and its two major hydroyssis products, paracetamol and aspirin were examined for mutagenicity in the Salmonella/mammalian microsome screening test. The compounds were tested in 6 strains of Salmonella typhimurium (TA1535, TA1537, TA1538, TA100, TA97 and TA98) in the presence and absence of a rat-liver microsome activation system. Benorylate did not show evidence of mutagenic activity in the 6 strains tested with or without metabolic activation at concentrations ranging from 0.006 to 3 mg per plate. Paracetamol and aspirin likewise did not show any evidence of mutagenic activity at concentrations ranging from 0.1 to 50 mg per plate for the former and 0.01 to 50 mg per plate for the latter.     

Determination of acetaldehyde in rat blood by the use of rat liver aldehyde dehydrogenase

A method has been developed for the determination of low concentrations of acetaldehyde in rat blood. The method involves extraction of blood in perchloric acid followed by a fluorimetric determination of acetaldehyde in neutralized extracts by the use of a low K_m aldehyde dehydrogenase isolated from rat liver mitochondria. Acetaldehyde concentrations down to 2 to 3 μm could be detected in blood samples of 0.1 ml containing high concentrations of ethanol (10–40 mm). Due to its simplicity, sensitivity, and the use of a low-cost fluorimeter, this enzymatic method should be a valuable complement to gas chromatographic methods for acetaldehyde determination.     

Oxidized and reduced nicotinamide–adenine dinucleotide phosphate in tissue suspensions of rat liver

1. The concentrations of NADP and NADPH(2) in homogenates of rat liver (expressed as mug./g. wet wt. of tissue homogenized) were compared with values obtained from intact samples of liver taken from the same female rat. With 0.25m-sucrose alone as the suspending medium, or in combination with tris buffer or 0.01-0.1m-nicotinamide, considerable decreases in the sum of the NADP+NADPH(2) concentrations were occasionally observed during 30min. storage of homogenates at 0 degrees . However, addition of 0.5m-nicotinamide+5mm-tris buffer to 0.25m-sucrose for use as a suspending medium maintained the sum of the NADP+NADPH(2) concentrations in homogenates at the level found in intact tissue for at least 30min. at 0 degrees . 2. The effects of freezing intact tissue and homogenates in liquid nitrogen before the extraction of NADP and NADPH(2) were studied. Freezing alone appears to convert a significant amount (approx. 30%) of liver NADPH(2) into an equivalent amount of NADP in intact tissue. This is discussed in terms of the ;bound NADP' reported by Burch, Lowry & Von Dippe (1963). 3. The intracellular distributions of NADP and NADPH(2) in intracellular fractions of rat liver were studied by using a modified centrifuging scheme that allows extraction of the isolated fractions to be performed within 45min. of killing the animal. Approx. 50% of the total NADP+NADPH(2) was found in the large-particle fractions and the remaining 50% was mostly in the soluble fraction of the cell. 4. Further investigations are reported on the nature of ;bound NADP' in rat liver. Most of this material appears associated with the ;nuclear' (containing nuclei, debris, erythrocytes etc.) or large-mitochondrial fractions, or both, obtained by low-speed centrifuging of rat-liver homogenates. 5. Although in some experiments the variations produced in the concentration of NADPH(2) present in large-particle fractions were followed by similar changes in that of ;bound NADP', in other cases no such direct relationship was obtained. Addition of phenazine methosulphate, for example, consistently lowered the concentration of NADPH(2) yet raised the concentration of ;bound NADP' in rat-liver mitochondrial fractions.     

Properties of RNA fractions from nuclei of brain cells which stimulate incorporation of amino acids by brain ribosomes

Abstract— The properties of RNA fractions from nuclei of brain cells which were capable of stimulating amino acid incorporation into proteins of an homologous ribosomal system were investigated. RNA was routinely prepared from crude nuclear preparations of rat brain by a method which involved treatment with sodium dodecyl sulphate and phenol at 65°. The capacity of this preparation to stimulate incorporation of radioactivity from a mixture of 15 l -[¹⁴C]amino acids was greatly enhanced by preliminary incubation of the ribosomal system from brain for 5–20 min. The response was markedly dependent upon the concentrations of ribosomes and of the pH 5 fraction. The optimal level of Mg²⁺ for basal incorporation of amino acids into protein was 8 mm ; however, incorporation in the presence of nuclear RNA was greater at higher concentrations of Mg²⁺. The response to nuclear RNA was also enhanced as the K⁺ concentration was increased from 25 to 100 mm . The stimulatory effect of nuclear RNA on incorporation of l -[¹²C]eucine was either unaltered or depressed by addition of a mixture of 19 l -[¹²C]amino acids each at concentrations, of 10^?8, 10^?2, or 10^?1 mm . Under appropriate conditions of incubation, basal rates of incorporation and rates of incorporation stimulated by nuclear RNA were linear for 30 min. The response was proportional to the concentration of nuclear RNA between 34 and 136 μg. RNA prepared from ribosomes of rat brain essentially failed to stimulate incorporation of amino acids over this range of concentrations. Fractionation of nuclear RNA by centrifugation in sucrose density gradients revealed that 75 per cent of the stimulatory activity was in the fraction which sedimented below 12 S and contained about 25 per cent of the total RNA. Most of the remaining activity was in the 18 S region. Less than 5 per cent of the RNA in the lightest fraction (< 12 S) exhibited amino acid-acceptor activity, The stimulatory action of nuclear RNA on incorporation of amino acids was readily destroyed by mild treatment with pancreatic ribonuclease, whereas amino acid-acceptor activity was relatively resistant to this treatment. The results suggest that the brain may contain low molecular weight RNA with properties of messenger RNA.     

Effect of aromatic acids on protein synthesis in subcellular preparations from the rat brain.

The incorporation of [3H]phenylalanine, [3H]tyrosine, and [3H]tryptophan into protein and amino acyl-tRNA was studied in cell-free preparations from rat brain. Tyrosine and tryptophan inhibited the incorporation of phenylalanine into protein, and tyrosine inhibited the incorporation of phenylalanine and tryptophan into amino acyl-tRNAs. In most cases, homogentisate, phenylpyruvate, and phenyllactate inhibited the incorporation of phenylalanine, tyrosine, and tryptophan into protein and amino acyl-tRNAs, and the incorporation of phenylalanine into polyphenylalanine. All other protein amino acids, and phenylacetate, salicylate, and benzoate were wholly ineffectual. The results suggest that the formation of amino acyl-tRNAs may have been the step which was affected most by the inhibitors. The incorporation data at different concentrations of the aromatic amino acids were fitted to the simple Michaelis equation. Homogentisate and phenylpyruvate generally tended to reduce both Km and V in the incorporation of aromatic amino acids into protein and amino acyl-tRNAs, even if V decreased more than Km.     

Inhibition by salicylates of urea synthesis by isolated rat hepatocytes and citrulline synthesis by isolated rat mitochondria: an effect independent of uncoupling

1. Acetylsalicylate and salicylate inhibited urea synthesis by isolated rat hepatocytes and citrulline synthesis by isolated rat mitochondria. The effects were dose-dependent and occurred at drug concentrations seen in salicylate induced hepatoxicity. 2. Although ATP concentration was decreased in the hepatocytes the effect of the salicylates on citrulline synthesis remained after treatment with oligomycin and carbonyl cyanide m-chlorophenyl hydrazone. This suggests that the effect is independent of uncoupling of oxidative phosphorylation. 3. This in vitro inhibition of urea synthesis by salicylates is similar to that produced by valproate and endogenous organic acids, which are also associated with hyperammonaemic clinical toxicity, and is a possible mechanism for the action of salicylates in the hyperammonaemia of Reye's syndrome.     

The effects of salicylate on the activity of rat liver tryptophan pyrrolase in vitro and in vivo

1. Salicylate, in concentrations of 0.05mm and above, inhibits the basal activity of tryptophan pyrrolase in homogenates of rat liver and the activity induced by cortisol but not that induced by tryptophan. The inhibition is abolished by adding haematin to the reaction mixtures. 2. The intraperitoneal injection of 400mg of sodium salicylate/kg in the rat causes a decrease in the tryptophan pyrrolase activity in the liver at 30min, the activity is restored to normal at 2h, increases to sixfold after 5h and returns to the basal value at 12h. The activation of the enzyme by salicylate is prevented by the administration of cycloheximide but not by pretreatment with actinomycin D. The effects of the combined injection of salicylate and cortisol are additive, whereas those of salicylate plus tryptophan are not. The injection of salicylate causes a progressive increase in the holo-/apo-enzyme ratio and an increased content of tryptophan in the liver over a period of 3h. 3. It is suggested that salicylate inhibits tryptophan pyrrolase activity in vitro and in vivo by interacting with iron protoporphyrins and causes a later enhancement of the enzyme activity in vivo by a mechanism involving the release of tryptophan from its binding sites on circulating albumin and on other proteins.     

Absence of mutagenic activity of benorylate, paracetamol and aspirin in the Salmonella/mammalian microsome test

Benorylate and its two major hydrolysis products, paracetamol and aspirin were examined for mutagenicity in the Salmonella/mammalian microsome screening test. The compounds were tested in 6 strains of Salmonella typhimurium (TA1535, TA1537, TA1538, TA100, TA97 and TA98) in the presence and absence of a rat-liver microsome activation system. Benorylate did not show evidence of mutagenic activity in the 6 strains tested with or without metabolic activation at concentrations ranging from 0.006 to 3 mg per plate. Paracetamol and aspirin likewise did not show any evidence of mutagenic activity at concentrations ranging from 0.1 to 50 mg per plate for the former and 0.01 to 50 mg per plate for the latter.