Production of monospecific antibodies to rat liver ornithine decarboxylase and their use in turnover studies

Rat colon ornithine and arginine metabolism: coordinated effects after proliferative stimuli

Ornithine decarboxylase (ODC) catalyzes the first step in the polyamine biosynthetic pathway, a highly regulated pathway in which activity increases during rapid growth. Other enzymes also metabolize ornithine, and in hepatomas, rate of growth correlates with decreased activity of these other enzymes, which thus channels more ornithine to polyamine biosynthesis. Ornithine is produced from arginase cleavage of arginine, which also serves as the precursor for nitric oxide production. To study whether short-term coordination of ornithine and arginine metabolism exists in rat colon, ODC, ornithine aminotransferase (OAT), arginase, ornithine, arginine, and polyamine levels were measured after two stimuli (refeeding and/or deoxycholate exposure) known to synergistically induce ODC activity. Increased ODC activity was accompanied by increased putrescine levels, whereas OAT and arginase activity were reduced by either treatment, accompanied by an increase in both arginine and ornithine levels. These results indicate a rapid reciprocal change in ODC, OAT, and arginase activity in response to refeeding or deoxycholate. The accompanying increases in ornithine and arginine concentration are likely to contribute to increased flux through the polyamine and nitric oxide biosynthetic pathways in vivo.

Preparation and characterization of monoclonal antibodies against ornithine decarboxylase

In order to develop a method for the immunocytochemical detection of ornithine decarboxylase (ODC), EC 4.1.1.17, we have prepared and characterized monoclonal antibodies (MAbs) against ODC. The primary structure of rat ODC (Rattus Norvegicus) was used for the selection of an epitope by computer calculations. The epitope (P16), a hexadecapeptide representing ODC-(345-360), was synthesized by means of solid phase peptide synthesis and coupled to a carrier protein. A bovine serum albumin conjugate of the P16 peptide was used as the immunogen for the production of MAbs in mice. Hybridoma clones were screened and the specificity of the monoclonal antibodies was tested in an ELISA utilizing a thyroglobulin conjugate of the hexadecapeptide. Two hybridoma cell lines were developed, i.e., MP16-2 and MP16-3. The epitope specificity of the MAbs produced by these cell lines was characterized in an ELISA using a set of small peptides representing parts of the P16 hexadecapeptide chain. MP16-2 recognized the ODC-(355-360) portion whereas MP16-3 reacted with the ODC-(345-350) part of the hexadecapeptide. Further studies showed that both MAbs also recognized native ODC but not the inhibited (i.e., ODC labelled with 3H-DFMO) enzyme indicating that the selected epitope was associated with the active site of ODC or a locus in its direct vicinity.

Different turnover of rat fetal and placental ornithine decarboxylases

The half-lives of ornithine decarboxylase (ODC) and S-adenosylmethionine decarboxylase (SAMDC) have been studied in fetuses and placentas from 18-day-pregnant rats. While the turnover of fetal and placental SAMDC were slightly different (t1/2 = 38 and 75 min, respectively) the half-lives of fetal and placental ODC differed markedly. T1/2 of fetal ODC was 15 min, similar to other mammalian ODCs, but placental ODC showed a relatively high half-life, about 160 min. According to that, placental ODC was more resistant than the fetal enzyme to in vivo hyperthermic treatment (40 degrees C, 1 h). Our results suggest that the degradative mechanisms for ODC in rat placenta could be regulated differently to those in other mammalian tissues.

The effect of chronic ethanol feeding on ornithine decarboxylase activity and liver regeneration

The effects of ethanol on liver regeneration are poorly understood. Acute and chronic exposure to ethanol have been found to exert opposite effects on the induction of ornithine decarboxylase, the rate-limiting enzyme for polyamine biosynthesis. Polyamines are necessary for DNA synthesis and liver regeneration after chemical or surgical liver injury. Short-term exposure to ethanol, which inhibits ornithine decarboxylase has been shown to inhibit DNA synthesis and liver regeneration, whereas more chronic exposure to ethanol increases ornithine decarboxylase activity and therefore could conceivably stimulate DNA synthesis and regeneration. To explore this later possibility, the effects of chronic ethanol consumption on ornithine decarboxylase activity, DNA synthesis and liver regeneration were studied in rats after sham laparotomy and partial hepatectomy. Chronic ethanol feeding failed to inhibit the induction of ornithine decarboxylase that occurred after partial hepatectomy and yet significantly inhibited posthepatectomy DNA synthesis and restitution of liver mass. These data suggest that the induction of hepatic polyamine biosynthesis is dissociated from DNA synthesis and liver regeneration after chronic consumption of ethanol.

Inactivation of mitochondrial carbamoyl phosphate synthetase induced by ascorbate, oxygen, and Fe3+ in the presence of acetylglutamate: protection by ATP and HCO3- and lack of inactivation of ornithine transcarbamylase

Of the two mitochondrial enzymes of the urea cycle, carbamoyl phosphate synthetase (CPS) was and ornithine transcarbamylase (OTC) was not inactivated by the Fe3+-oxygen-ascorbate model system for mixed-function oxidation [R. L. Levine, (1983) J. Biol. Chem. 258, 11828-11833]. The susceptibility of OTC was not increased by its substrates, products, or inhibitors, whereas that of CPS was markedly increased by acetylglutamate (its allosteric activator) when ATP was absent. Thus, acetylglutamate binds in the absence of ATP and exposes to oxidation essential groups of the enzyme. We estimate for this binding a KD value of 1.6 mM, which greatly exceeds the KD values (less than 10 microM) determined in the presence of ATP and bicarbonate. ATP, and even more, mixtures of ATP and bicarbonate protected CPS from inactivation. Acetylglutamate exposes the site for the ATP molecule that yields Pi, and it appears that ATP protects by binding at this site. Experiments of limited proteolysis with elastase suggest that oxidation prevents this binding of ATP and show that it accelerates cleavage of CPS by the protease, thus supporting the idea that oxidation may precede proteolysis. Trypsin, chymotrypsin, and papain also hydrolyze the oxidized enzyme considerably faster than the native enzyme. Our results also support the idea that oxidative inactivation is site specific and requires sites on the enzyme for Me2+ and, possibly, for a nucleotide.

Regulation of polyamine biosynthesis by antizyme and some recent developments relating the induction of polyamine biosynthesis to cell growth. Review

This review considers the role of antizyme, of amino acids and of protein synthesis in the regulation of polyamine biosynthesis. The ornithine decarboxylase of eukaryotic cells and of Escherichia coli can be non-competitively inhibited by proteins, termed antizymes, which are induced by di- and poly- amines. Some antizymes have been purified to homogeneity and have been shown to be structurally unique to the cell of origin. Yet, the E. coli antizyme and the rat liver antizyme cross react and inhibit each other's biosynthetic decarboxylases. These results indicate that aspects of the control of polyamine biosynthesis have been highly conserved throughout evolution. Evidence for the physiological role of the antizyme in mammalian cells rests upon its identification in normal uninduced cells, upon the inverse relationship that exists between antizyme and ornithine decarboxylase as well as upon the existence of the complex of ornithine decarboxylase and antizyme in vivo. Furthermore, the antizyme has been shown to be highly specific; its Keq for ornithine decarboxylase is 1.4 X 10(11) M-1. In addition, mammalian cells contain an anti-antizyme, a protein that specifically binds to the antizyme of an ornithine decarboxylase-antizyme complex and liberates free ornithine decarboxylase from the complex. In E. coli, in which polyamine biosynthesis is mediated both by ornithine decarboxylase and by arginine decarboxylase, three proteins (one acidic and two basic) have been purified, each of which inhibits both these enzymes. They do not inhibit the biodegradative ornithine and arginine decarboxylases nor lysine decarboxylase. The two basic inhibitors have been shown to correspond to the ribosomal proteins S20/L26 and L34, respectively. The relationship of the acidic antizyme to other known E. coli proteins remains to be determined. In mammalian cells, ornithine decarboxylase can be induced by a broad spectrum of compounds. These range from hormones and growth factors to natural amino acids such as asparagine and to non-metabolizable amino acid analogues such as alpha-amino-isobutyric acid. The amino acids that induce ornithine decarboxylase as well as those that promote polyamine uptake utilize the sodium dependent A and N transport systems. Consequently, they act in concert and increase intracellular polyamine levels by both mechanisms. The induction of ornithine decarboxylase by growth factors, such as NGF, EGF, and PDGF as well as by insulin requires the presence of these same amino acids and does not occur in their absence. However, the inducing amino acid need not be incorporated into protein nor covalently modified.(ABSTRACT TRUNCATED AT 400 WORDS)

A human neuroblastoma cell line with a stable ornithine decarboxylase in vivo and in vitro

A human neuroblastoma cell line (Paju) grew in 10 mM difluoromethyl-ornithine, which at this concentration normally stops the growth of all mammalian cells. Ornithine decarboxylase from Paju was resistant to inhibition in vitro by difluoromethylornithine, and required 10 microM of the compound for 50% inhibition, whereas ornithine decarboxylase from SH-SY5Y cells (another human neuroblastoma) and from rat liver needed only 0.5 microM difluoromethylornithine. Paju ornithine decarboxylase also exhibited a long half-life (over eight hours) in vivo. The half-life of immunoreactive protein was significantly longer than that of the activity. The long half-life of ornithine decarboxylase in Paju cells leads to its accumulation to a specific activity of 2000 nmol/mg of protein per 30 min during rapid growth (the corresponding activity in SH-SY5Y cells was about 2.5). When partially purified ornithine decarboxylase from Paju cells was incubated with rat liver microsomes it was inactivated with a half-life of 75 min. This inactivation was accompanied by a fall in the amount of immunoreactive protein. In the same inactivating system partially purified SH-SY5Y ornithine decarboxylase had a half-life of 38 min and its half-life in vivo was 50 min. The corresponding values for rat liver ornithine decarboxylase were 45 min and 40 min, respectively. Rat liver microsomes also inactivated rat liver adenosylmethionine decarboxylase. These results suggest that Paju ornithine decarboxylase has an altered molecular conformation, rendering it resistant to (i) difluoromethylornithine and (ii) proteolytic degradation both in vivo and in vitro.

Molecular mechanism for the regulation of hepatic ornithine decarboxylase

A single injection of thioacetamide into starved rats induced a 40- to 100-fold increase in hepatic ODC activity. However, immunotitratable ODC protein increased by only 5-fold because of the presence of significant amounts of inactive ODC protein in the liver of untreated starved rats. Polysomal ODC-mRNA activity also increased only 5-fold, a significant amount being present in control liver. Furthermore, the peak of polysomal ODC-mRNA activity preceded that of ODC activity or ODC protein by several hours. These results indicate that the enzyme induction is due not only to increase in polysomal ODC-mRNA activity, but also to some translational and/or post-translational regulation. Exogenously administered diamines or polyamines cause rapid decay of ODC activity and induce antizyme that binds to ODC and inactivates it. Another protein factor, antizyme inhibitor, was found in the liver of thioacetamide-treated or protein-fed rats. Antizyme inhibitor binds to antizyme and reactivates ODC in the ODC-antizyme complex. A small, but significant, amount of antizyme was found in the liver of starved rats. Only small amounts of ODC-antizyme complex were detected in rat liver and cultured hepatocytes, even during the period of rapid ODC decay caused by exogenously added diamines. On the other hand, the complex was present in HTC cells and more especially in ODC-stabilized HMOA cells, even under physiological conditions. On addition of 10(-2) M putrescine, the amount of complex first increased and then decreased in both types of cells. Decay of total ODC activity (free plus complexed ODC) was more rapid with putrescine than with cycloheximide. These results suggest that antizyme plays an essential role in the degradation of ODC by a catalytic effect both in the presence and absence of exogenous putrescine and that antizyme inhibitor stabilizes ODC by removing antizyme.

Stabilization of ornithine decarboxylase and N1-spermidine acetyltransferase in rat liver by methylglyoxal bis(guanylhydrazone)

The activities of ornithine decarboxylase and spermidine N1-acetyltransferase started to rise in normal rat liver 4 h after the intraperitoneal injection of methylglyoxal bis(guanylhydrazone) (MGBG; 80 mg/kg). Ornithine decarboxylase had its greatest activity 24 h after a single injection of MGBG and the acetyltransferase peaked 8 h after the injection. Measurement of the apparent half-life of ornithine decarboxylase after MGBG treatment revealed a clear decrease in the decay rate of the enzyme in both normal and regenerating rat liver. MGBG slowed the decay of the transferase also in normal rat liver, as well as inhibiting its activity in vitro. The stabilization by MGBG of these two short-lived proteins involved in metabolism of polyamines should lead to their accumulation in liver, thus explaining their increased activities. In the case of ornithine decarboxylase, studies with a specific antibody against mouse kidney ornithine decarboxylase showed that the rise in ornithine decarboxylase activity after MGBG application was not due to the appearance of an immunologically different isozyme.

Cell-free synthesis of ornithine decarboxylase. Changes in mRNA activity in the liver of thioacetamide-treated rats

Ornithine decarboxylase (ODC)mRNA associated with free polysomes of rat liver was translated in a reticulocyte lysate cell-free system. Newly synthesized ODC protein was identified by specific immunoprecipitation, molecular size as determined by polyacrylamide gel electrophoresis with sodium dodecyl sulfate, and competition by excess unlabeled ODC in the immunoprecipitation. A single injection of thioacetamide was found to cause several fold increases in both immunotitratable ODC protein and polysomal ODC-mRNA activity, while it provoked a much larger increase in ODC activity in rat liver. The results indicate that the induction of hepatic ODC activity by thioacetamide treatment is due not only to an increase in the activity of polysomal ODC-mRNA but also to a translational and/or posttranslational control.

Dissociation of RNA synthesis from the calcium requirement for serum-increased ornithine decarboxylase activity in rat glioma cells

When C6-2B rat glioma cells were stimulated with calf serum in the presence of calcium, ornithine decarboxylase activity increased maximally in 6-8 h after an initial 2-3 h lag period wherein RNA synthesis occurred. The increase of ornithine decarboxylase activity in serum-stimulated C6-2B cells was prevented by the calcium chelator EGTA, but EGTA had no effect upon RNA synthesis as judged by [3H]uridine incorporation into RNA. In addition, the calcium requirement for increased ornithine decarboxylase activity was temporally distal to the lag period. EGTA appeared to inhibit the synthesis of ornithine decarboxylase, because the half-life values of ornithine decarboxylase activity were similar (37-47 min) in the presence of EGTA or protein synthesis inhibitors such as cycloheximide or emetine. Also, calcium readdition rapidly reversed EGTA inhibition of ornithine decarboxylase activity by a mechanism which could be blocked by cycloheximide.

Measurement of the amount of ornithine decarboxylase in Saccharomyces cerevisiae and Saccharomyces uvarum by using alpha-[5-14C]difluoromethylornithine

Ornithine decarboxylase (EC 4.1.1.17) activity was about 3-times higher in Saccharomyces uvarum than in Saccharomyces cerevisiae in the middle of logarithmic growth. The enzyme from both sources was inactivated by alpha-difluoromethylornithine. When the binding of [5-14 C]difluoromethylornithine to yeast ornithine decarboxylase was studied it was shown that S. uvarum extracts contained about 40 ng of active ornithine decarboxylase per mg of cellular protein, and that of S. cerevisiae 10-12 ng of active enzyme. It appeared that S. uvarum ornithine decarboxylase could be highly purified by affinity chromatography, but S. cerevisiae enzyme did not bind to the same column. The purified preparation from S. uvarum had an Mr of 73 000 and a 100-fold purification (purified by conventional methods) of ornithine decarboxylase from S. cerevisiae had an Mr of 69 000 on a gel filtration column. When the purified S. ovarum ornithine decarboxylase was labelled with difluoromethylornithine, it co-eluted with native enzyme on a gel filtration column and it ran as a single band on polyacrylamide gel electrophoresis under denaturing conditions at a position corresponding to an Mr of 72 000, indicating that the active enzyme is a monomer. The loss of ornithine decarboxylase activity after addition of cycloheximide and spermidine to culture correlated with the decrease of the binding of difluoromethylornithine to protein.

Studies on the mechanisms of ornithine decarboxylase in vitro inactivation

Hydrocortisone-induced rat liver ornithine decarboxylase appears quite stable in the soluble fraction of the homogenate incubated at 37 degrees C. In contrast, the incubation of the whole homogenate causes a rapid loss of activity. The ornithine decarboxylase-inactivating capacity appears mainly bound to microsomes. Lysosomes seem to play a role only after the microsome-induced inactivation. Different reducing agents (dithiothreitol, NADPH, NADH, GSH) are effective both in preventing and in reversing ornithine decarboxylase inactivation. NADPH is peculiar in that it can reactivate the enzyme at very low concentrations. Oxidized glutathione potentiates the inactivating effect of microsomes. On the basis of present results it is suggested that ornithine decarboxylase may be reversibly inactivated through microsome-catalyzed formation of mixed or enzyme-enzyme disulfides and that NADPH plays a crucial role in ornithine decarboxylase reactivation, probably by cytosolic reductase(s).

Affinity chromatography with specific antibody increases activity and retains antigenicity of ornithine decarboxylase

An affinity chromatography column with antibody specific to ornithine decarboxylase (ODC) was employed successfully for the retention and subsequent partial elution of ODC with enhanced activity and retention of antigenicity. This may be a useful procedure for further attempts to produce antiserum for identification and characterizations of ODC in vitro and in vivo.

Effect of inhibitors of protein synthesis on rat liver spermidine N-acetyltransferase

The increase in spermidine N-acetyltransferase activity in rat liver produced by carbon tetrachloride was completely prevented by simultaneous treatment with inhibitors of protein and nucleic acid synthesis suggesting that the increase results from the synthesis of new protein rather than the release of the enzyme from a cryptic inactive form. Treatment with cycloheximide 2 h after carbon tetrachloride also completely blocked the rise in spermidine N-acetyltransferase seen 4 h later. Such treatment completely prevented the fall in spermidine and rise in putrescine in the liver 6 h after carbon tetrachloride confirming the importance of the induction of spermidine N-acetyltransferase in the conversion of spermidine into putrescine. When cycloheximide was administered to rats in which spermidine N-acetyltransferase activity had been stimulated by prior treatment with carbon tetrachloride or thioacetamide, the activity was lost rapidly showing that the enzyme protein has a rapid rate of turnover. The half-life for the enzyme in thioacetamide-treated rats was 40 min, whereas the half-life for ornithine decarboxylase (which is well known to turn over very rapidly) was 27 min. In carbon tetrachloride-treated rats the rate or protein degradation was reduced and the half-life of spermidine N-acetyltransferase was 155 min and that for ornithine decarboxylase was 65 min. It appears that three of the enzymes involved in the synthesis and interconversion of putrescine and spermidine namely, ornithine decarboxylase, S-adenosylmethionine decarboxylase and spermidine N-acetyltransferase have rapid rates of turnover and that polyamine levels are regulated by changes in the amount of these enzymes.

Gamma radiation inhibits the appearance of induced ornithine decarboxylase activity in Chinese hamster cells

Ornithine decarboxylase activity of Chinese hamster cells (ODC, EC 4.1.1.17) can be induced in plateau phase by change of medium. Exposure of the cells to gamma radiation before induction reduces the amount of ODC activity induced. The dose-response curve is exponential with a D0 of 106 krad. Exposure of BUdR-substituted cells is more effective in reducing ODC induction at high doses, with a D0 of 38 krad. Cells can recover from the reduction incurred by 74 krad if enzyme induction is delayed for 2 hours after exposure. Treatment of the cells with psoralen-plus-light completely inhibits RNA synthesis without affecting protein synthesis (Heimer, Ben-Hur and Riklis 1977, 1978). Using this procedure it is shown that the effect of gamma radiation on inducible ODC activity is due not only to DNA damage by also involves a post-transcriptional effect. This conclusion is supported by employing a heat shock to inhibit protein synthesis prior to gamma-irradiation of log-phase cells. In such cells the increased activity of ODC upon transfer to 37 degrees C is due primarily to enzyme synthesis using pre-existing RNA species during the first few hours. A low concentration of actinomycin D, which inhibits rRNA synthesis, applied during the recovery period, prevents the recovery of the cells' capacity for maximal ODC induction. This may indicate that, in order to recover, the cells have to repair damage to the ribosomes as well as to DNA.

Inhibition of rat ovarian ornithine decarboxylase by ethanol in vivo and in vitro

Intragastric administration of ethanol greatly inhibited ovarian ornithine decarboxylase (L-ornithine carboxy-lyase EC 4.1.1.17) stimulated by human chorionic gonadotropin in vivo. The inhibition occurred only if the treatment with ethanol was started before the injection of hormone. The use of inhibitors for alcohol dehydrogenase and aldehyde dehydrogenase clearly showed that the observed inhibition was a direct effect of ethanol itself. When rat ovarian cells were incubated in vitro with human chorionic gonadotropin the activity of ornithine decarboxylase was also markedly stimulated. This stimulation could also be inhibited by ethanol. Moreover, actinomycin D and alpha-amanitin inhibited the stimulation of ornithine decarboxylase, showing that the enhanced activity in vitro resulted from the synthesis of new mRNA for ornithine decarboxylase. The time dependence of the inhibition caused by ethanol addition resembled that after addition of actinomycin D. This supports the view that one site where ethanol inhibits protein synthesis is at the transcriptional level.

A mutant of Chinese hamster ovary cells resistant to alpha-methyl- and alpha-difluoromethylornithine

We describe a mutant of Chinese hamster ovary cells which is resistant to elevated levels of alpha-methylornithine and alpha-difluoromethylornithine, reversible and enzyme-activated irreversible inhibitors, respectively, of the enzyme ornithine decarboxylase (ODC). The mutant cells have significantly elevated levels of enzyme activity compared to wild-type cells, but several of the physical parameters of the enzyme are completely normal: Michaelis-Menten parameter, Km, affinity for the analog, and half-life. The temporal regulation of this activity in synchronized cells is not perturbed, and the suppression of ODC activity by the addition of putrescine is still observed. Indirect experiments suggest increased concentrations of ODC mRNA in the mutant cells.

Regulation of ornithine decarboxylase activity by amino acids, cyclic AMP and luteinizing hormone in cultured mammalian cells

Any one of five amino acis (alanine, asparagine, glutamine, glycine, and serine) is an essential requirement for the induction of ornithine decarboxylase (EC 4.1.1.17) in cultured chinese hamster ovary (CHO) cells maintained with a salts/glucose, medium. Each of these amino acids induced a striking activation of ornithine decarboxylase in the presence of dibutyryl cyclic AMP and luteinizing hormone. The effect of the other amino acids was considerably less or negligible. The active amino acids at optimal concentrations (10 mM) induced only a 10-20 fold enhancement of enzyme activity alone, while in the presence of dibutyryl cyclic AMP, ornithine decarboxylase activity was increased 40-50 fold within 7-8 h. Of the hormones and drugs tested, luteinizing hormone resulted in the highest (300-500 fold) induction of ornithine decarboxylase with optimal concentrations of dibutyryl cyclic AMP and asparagnine. Omission of dibutyryl cyclic AMP reduced this maximal activation to one half while optimal levels of luteinizing hormone alone caused no enhancement of ornithine decarboxylase activity. The induction of ornithine decarboxylase elicited by dibutyryl cyclic AMP, amino acid and luteinizing hormone was diminished about 50% with inhibitors of RNA and protein synthesis. The specific amino acid requirements for ornithine decarboxylase induction in chinese hamster ovary cells was similar to the requirements for induction in two other transformed cell lines. Understanding the mechanism of enzyme induction requires an identification of the essential components of the regulatory system. The essential requirement for enzyme induction is one of five amino acids. The induction of ornithine decarboxylase by dibutyryl cyclic AMP and luteinizing hormone was additive in the presence of an active amino acid.

Age-related changes in inducible mouse liver enzymes: ornithine decarboxylase and tyrosine aminotransferase

The time required to induce two inducible hepatic enzymes, ornithine decarboxylase (ODC) and tyrosine aminotransferase (TAT), by growth hormone and dexamethasone, respectively, increases with age. Specific activity at the peak of induction is the same for all ages. On the other hand, for basal TAT the specific activity per unit of TAT antigen was found to decrease considerably with age. The half-life of ODC was determined after cycloheximide administration. The apparent half-life at the peak of ODC induction increases from 15 minutes in 3-4-month-old mice to 30 minutes in 24-month-old animals. Loss of efficiency in the protein degradation system is implicated in this phenomenon as no apparent differences could be observed in the susceptibility of ODC and TAT from young or old mice to chymotrypsin. ODC and TAT are activated by temperatures of up to 37 degrees C and 50 degrees C, respectively. ODC is inactivated at 50 degrees C while TAT is inactivated at 76 degrees C. "Young" ODC and TAT are more readily activated or inactivated by heating than the "old" enzymes.

Hormonal control of ornithine decarboxylase in isolated liver cells and the effect of ethanol oxidation

The regulation of ornithine decarboxylase activity was studied in freshly isolated rat hepatocytes incubated in a chemically defined medium for 5 h. Glucagon, dibutyryl cyclic AMP, insulin and dexamethasone produced dramatic increases in ornithine decarboxylase activity, 6--100-times the basal activity. Actinomycin D inhibited completely the stimulatory action of these substances. With glucagon, dibutyryl cyclic AMP and insulin, the rise in ornithine decarboxylase activity was rapid but transient, peaking at 200 min and then declining rapidly. By contrast, the response to dexamethasone was gradual and sustained in the 5 h incubation. The transient nature of the response to glucagon was unaltered by repeated additions of optimally effective doses of glucagon suggesting the development of 'refractoriness' to the actions of this hormone. Ethanol oxidation inhibited by 50% the stimulation of ornithine decarboxylase by glucagon and dexamethasone and this effect was blocked by 4-methylpyrazole, an inhibitor of alcohol dehydrogenase. Acetate (2.5--20 mM), the metabolic product of hepatic ethanol oxidation, was also effective. The data indicate that glucagon, insulin and glucocorticoids are all effective in stimulating the activity of ornithine decarboxylase in isolated hepatocytes but they differ in their duration and time of peak of action. Additionally, the inhibitory effect of ethanol on the hormonal stimulation of ornithine decarboxylase is dependent on its oxidation and may be mediated by acetate.

Current status of age altered enzymes: alternative mechanisms

The occurrence of inactive enzyme molecules in a variety of tissues and animal species has been shown to be of a general nature. The levels of inactive enzyme molecules found in old animals were produced by amino acid analogs in young animals. These levels have been shown to be initially detrimental but subsequently the young system shows recovery by efficiently disposing of the analog-modified proteins. In old animals this disposal is considerably less efficient. Evidence is presented which suggests that post-translational modifications of proteins are the main cause of enzyme inactivation in old animals. Amino acid substitutions and modifications involving charge differences apparently do not contribute significantly to this phenomenon.