Tyrosine aminotransferase activity of frog (Rana esculenta) liver--II. Comparative aspects of intracellular distribution

1. A subcellular fractionation procedure for frog liver is reported and validated by the distribution pattern of several marker enzymes, also in comparison with rat liver. 2. The subcellular distribution of tyrosine aminotransferase was investigated in frog liver as compared to rat liver: a different distribution of the enzyme was observed, being the activity mostly recovered in mitochondrial and cytosolic compartments. 3. Results indicate that mitochondrial tyrosine aminotransferase of both frog and rat liver is a matrix enzyme, even if differences are observed concerning its release from the organelles upon detergent treatment.     

A liver factor that interconverts multiple forms of tyrosine aminotransferase.

Three activity peaks of rat liver soluble tyrosine aminotransferase have been resolved using hydroxyl-apatite chromatography. These peaks interconvert during storage of the soluble enzyme preparation in ice for 20 h. A component of a particulate fraction of liver which will interconvert the forms of tyrosine aminotransferase in vitro with no alteration of total enzyme activity has been detected. This factor is present in a 31, 000 gh pellet of liver and is solubilized by sonication. When the factor is subjected to dialysis or incubation at 25°C for 30 min. its effect on tyrosine aminotransferase is greatly diminished.     

Organ specificity of glucocorticoid-sensitive tyrosine aminotransferase. Separation from aspartate aminotransferase isoenzymes

In order to study whether hormone-sensitive tyrosine aminotransferase exists in tissues other than liver, we have devised means to separate the liver-specific enzyme from other enzymes that transaminate tyrosine and to distinguish between the authentic enzyme and the principal "pseudotyrosine aminotransferases," which are the isoenzymes of aspartate aminotransferase. We accomplish this by suppressing proteolysis of the authentic enzyme using a buffer of pH 8.0 containing 0.1 M potassium chloride; enzyme extracted from liver in this buffer migrates as a single peak during chromatography on hydroxylapatite and represents the undegraded native form. A much smaller peak of tyrosine aminotransferase activity elutes at higher ionic strength and corresponds to a mixture of mitochondrial aspartate aminotransferase and partially degraded tyrosine aminotransferase. Cytosolic aspartate aminotransferase, in contrast, adsorbs weakly to the hydroxylapatite column and transaminates tyrosine very poorly although it readily utilizes monoiodotyrosine. The aspartate aminotransferase isoenzymes separate completely from tyrosine aminotransferase during chromatography on DEAE-Sepharose CL-6B. By combining these techniques with the use of specific antibodies, we show that brain, heart, and kidney do not contain tyrosine aminotransferase. Furthermore, we locate both isoenzymes of aspartate aminotransferase on polyacrylamide gels and show that both react histochemically as tyrosine aminotransferases when monoiodotyrosine is used as substrate. Use of these techniques, therefore, permits unambiguous identification of tyrosine aminotransferase and its separation from the background of nonspecific transamination.     

Low Molecular Weight Active Form of Inducible Liver Tyrosine Aminotransferase

RECENT experiments^1–4 suggest that there are several forms of inducible liver tyrosine aminotransferase and that they may be stimulated by different hormones and expressed differently by genetic mutation. We now report the occurrence of a low molecular weight form of enzymatically active soluble tyrosine aminotransferase, which is inducible as is the larger molecular weight enzyme. Assuming that the latter is a tetramer⁵, the former has a tentative molecular weight equivalent to a subunit of the larger enzyme.     

Phorbol ester inhibition of hormonal induction of tyrosine aminotransferase

The liver specific enzyme, tyrosine aminotransferase, can be induced by glucocorticoids, cAMP analogs, or insulin. Each of these different inducing agents is believed to act through a separate pathway. The tumor promoting phorbol esters have been reported to stimulate phosphorylation of the insulin receptor and thereby decrease the ability of insulin to induce tyrosine aminotransferase. Our results demonstrate that TPA will not only inhibit the insulin stimulated increase in tyrosine aminotransferase, but will also inhibit induction of the enzyme by glucocorticoids or by cAMP.     

Absence of tyrosine aminotransferase multiple forms in several mammalian animals

Tyrosine aminotransferase multiple forms occurring in rat liver are not present in all mammalian species. Among animals examined only rat and mouse liver possesses multiple forms of tyrosine aminotransferase; in guinea-pig, rabbit, bovine and sheep liver the enzyme occurs in a single form. The presence of lysosomal converting factor (cathepsin T), responsible for arising of multiple forms of tyrosine aminotransferase in rat liver, has been checked in another species lacking enzyme subforms. Lysosomal extracts of guinea-pig liver interconverts tyrosine aminotransferase from rat liver; lysosomal extracts of rat liver does not generate multiple forms of the enzyme from guinea-pig liver. It has been concluded that in some animals hepatic tyrosine aminotransferase is resistant to the proteolytic cleavage by lysosomal cathepsin T.     

Complementation of subunits from glycogen phosphorylases of frog and rabbit skeletal muscle and rabbit liver.

Activity can be induced in potentially active rabbit skeletal muscle phosphorylase monomers covalently bound to Sepharose by noncovalent interaction with soluble subunits carrying inactive pyridoxal 5'-phosphate analogs or even salicyladlehyde. These analogs are themselves incapable of reconstituting active holophorphorylase from apophosphorylase. Phosphorylases with one intrinsically inactive and one potentially active subunit have about one half of the activity of the native phosphorylase dimer. The usefulness of this technique for subunit complementation was demonstrated by forming hybrid phosphorylases with inactive Sepharose-bound rabbit skeletal muscle subunits containing pyridoxal 5'-phosphate monomethylester and soluble activatable frog muscle and rabbit liver phosphorylase monomers. The inactive Sepharose-bound subunit induced in each case activity in the soluble subunit. But whereas the inactive rabbit muscle phosphorylase subunit even transmitted its characteristic temperature dependence of the rate of the reaction to the frog muscle subunit, it could not propagate its control properties to the liver enzyme. Differences of hybrid phosphorylases are related to immunological and amino acid divergencies among the component enzymes.     

Tyrosine aminotransferase in frog liver.

1. In frog liver, tyrosine aminotransferase is located mainly in cytoplasm. The enzyme is an anionic protein of mol. wt. 115 000 daltons, specific toward 2-oxoglutarate. The enzyme separates on ion-exchange chromatography into two active forms. 2. Administration of triiodotyronine in vivo induces the activity of the enzyme. Epinephrine and glucagon have no effect, and cAMP and insulin repress this activity by about 70%. 3. Triiodotyronine stimulates incorporation of [14C]leucine into protein, and the amount of the enzyme in the nacent polysome-bound protein is considerably increased.     

Activity of a purified nonsteroidal gametic factor on the inducibility of hepatic delta-aminolevulinic acid synthetase, NADPH-oxidase and tyrosine aminotransferase in senescent rats

The effect of a water soluble nonsteroidal factor extracted from the male gamete on the activity of certain liver inducible enzymes during aging has been examined. Three enzymes have been studied: delta-aminolevulinic acid synthetase, NADPH-oxidase and tyrosine aminotransferase whose inducibility by ethanol, phenobarbital and ACTH, respectively, show age dependent alterations. The results here reported show that this factor is able to restore the enzyme inducibility in the liver of aging (600-day-old) rats without affecting the response of young (40-day-old) rats. Since the enzyme inducibility is altered during aging, and in the majority of rat hepatomas this factor might enter, possibly, in the regulation of enzyme activity also of neoplastic cells.     

Stabilization of rat liver tyrosine aminotransferase by tetracycline.

Rat liver tyrosine aminotransferase was purified 200-fold and an antiserum raised against it in rabbits. 2. Hepatic tyrosine aminotransferase activity was increased fourfold by tyrosine, twofold by tetracycline, 2.5-fold by cortisone 21-acetate and ninefold by a combination of tyrosine and cortisol administered intraperitoneally to rats. 3. Radioimmunoassay with 14C-labelled tyrosine aminotransferase, in conjunction with rabbit antiserum against the enzyme, revealed that cortisol stimulates the synthesis of the enzyme de novo, but that tetracycline has no such effect. 4. Incubation of rat liver homogenates with purified tyrosine aminotransferase in vitro leads to a rapid inactivation of the enzyme, which tetracycline partially inhibits. 5. The inactivation is brought about by intact lysosomes, and the addition of 10mM-cysteine increases the rate of enzyme inactivation, which is further markedly increased by 10mM-Mg2+ and 10mM-ATP. Here again tetracycline partially inhibits the decay rate, leading to the inference that the increase of tyrosine aminotransferase activity in vivo by tetracycline is brought about by the latter inhibiting the lysosomal catheptic action.     

Immunological study of carbon tetrachloride-mediated induction of tyrosine aminotransferase in rat liver

Administration of CCl₄ (1.0 ml/kg) to rats resulted in a rise of liver tyrosine aminotransferase (l-tyrosine:2-oxoglutarate aminotransferase, EC 2.6.1.5) activity to a maximum of about 3.6 times the normal level 6 hr later. An immunological titration study proved that the phenomenon was due to increased enzyme content. Using an isotopic-immunochemical procedure the half-life of liver tyrosine aminotransferase at 3.5 hr after CCl₄ administration was shown to be 11.9 hr in contrast to 2.1 hr in the normal liver. Immunochemical analysis revealed that enzyme synthesis was decreased by CCl₄. Thus, in the early stage of CCl₄ poisoning, enzyme synthesis proceeded at a moderate rate while degradation was markedly impaired, resulting in the rise of tyrosine aminotransferase in the liver tissue.Several hours after administration of hydrocortisone to adrenalectomized rats, induced tyrosine aminotransferase reached its peak activity and then subsided to the basal level. At any time following hydrocortisone administration, administration of CCl₄ consistently caused an elevation of the enzyme activity above the level in controls not treated with CCl₄. Actinomycin D (5 mg/kg) also increased the enzyme at an early period of induction cycle but failed to do so at a later period.The CCl₄-mediated “superinduction” of hormonally preinduced tyrosine aminotransferase, like the induction of this enzyme by CCl₄ at a basal level, was found to be caused by the differential inhibitory effect of CCl₄ on the synthesis and degradation of this enzyme.     

Glucocorticoid receptor of frog (Rana esculenta) liver

The presence of a glucocorticoid soluble receptor is demonstrated in frog liver cytosol. The kinetic characterization of frog liver cytosolic receptor for glucocorticoids is reported and its steroid specificity assessed. Results indicate a gross similarity between frog liver and mammalian glucocorticoid receptor, being a major difference the reduced binding capacity.     

Translation of poly-A RNA from rat liver in vitro. Evidence for a high molecular weight subunit of tyrosine aminotransferase

Poly-A RNA extracted from the rat liver was translated in a cell-free wheat germ system and a rabbit reticulocyte lysate. The subunit of tryptophan pyrrolase precipitated by specific antiserum after synthesis in vitro has the same molecular weight as the corresponding subunit derived from the rat liver. With specific antiserum prepared against tyrosine aminotransferase, however, a radioactive protein from both the in vitro assays was precipitated with an about 5% higher molecular weight than the tyrosine aminotransferase subunit precipitated from rat liver. The immunological evidence and the comparison of the specific peptide patterns prepared by cyanogen bromide treatment showed that the in vitro product corresponds to tyrosine aminotransferase. Various concentrations of potassium or spermidine used in the wheat germ translation system did not alter the size of the enzyme subunit synthesized. The run of the tyrosine aminotransferase purified form the rat liver in the SDS-polyacrylamide gel electrophoresis was not influenced by treatment with Escherichia coli alkaline phosphatase. The possibility is discussed that the larger enzyme synthesized in vitro represents a precursor molecule which is cleaved proteolytically in vivo.     

Influence of alloxan diabetes and insulin treatment on the activity of alanine aminotransferase in rat brain regions, liver and heart

Studies with brain alanine aminotransferase showed higher activity of the enzyme in the soluble fraction of cerebellum. Among the tissues, the liver soluble fraction was the richest source of the enzyme. Alloxan-induced diabetes caused both regional and time-dependent variations in the activity of brain alanine aminotransferase. Significant among these changes were the decrease in both soluble and particulate enzyme from cerebral hemispheres and an increase in the soluble enzyme activity from cerebellum at early stages of diabetes. Brain stem did not show any marked change in enzyme activity. Liver and heart enzyme, however, increased significantly after 1-2 weeks of diabetes. Insulin treatment to diabetic animals caused an 'over-shoot' in soluble alanine aminotransferase activity, particularly in cerebellum and liver.     

Control of ketogenesis from amino acids. III. In vitro and in vivo studies on ketone body formation lipogenesis and oxidation of tyrosine by rats.

Ketone body formation from tyrosine was studied in rat liver in vitro with special references to the activities of tyrosine aminotransferse (EC 2.6.1.5) and p-hydroxyphenylpyruvate hydroxylase (EC 1.14.2.2). Liver was obtained from rats which had been given a high protein diet or cortisol to induce various levels of tyrosine aminotransferase. The enzyme activities of the preparations were plotted against the amounts of ketone body formed from tyrosine. It was found that over a low range of tyrosine aminotransferase activities, activity was proportional to the amount of ketone body formed. However, above this range, ketone body formation ceased to increase and p-hydroxyphenylpyruvate started to accumulate. This inhibition of ketone body formation and accumulation of the p-hydroxyphenylpyruvate could be prevented by addition of ascorbate. These results suggest that the primary factor regulating metabolism of tyrosine in vitro is tyrosine aminotransferase and when the activity of this is high so that it is no longer rate limiting, p-hydroxyphenylpyruvate hydroxylase becomes the rat limiting step because its activity is inhibited by the accumulation of p-hydroxyphenylpyruvate. For in vivo studies rats were given a high protein diet or cortisol to induce various levels of tyrosine aminotransferase and then injected with a tracer dose of [U- or 1- 14C]tyrosine. Then their respiratory 14CO2 and the incorporation of 14C into total lipids of liver were measured. The amounts of radioactivity in CO2 and lipids were found to be proportional to the tyrosine aminotransferase activity and were not affected by the free tyrosine concentration in the liver. After injection of [U- 14C]acetate the radioactivities in CO2 and lipids were not proportional to the tyrosine aminotransferase activity. These results indicate that the enzyme activity also regulates tyrosine metabolism in vivo. In vivo studied gave no evidence of the participation of p-hydroxyphenylpyruvate hydroxylase in regulation of tyrosine metabolism.     

Kynurenine aminotransferase and alpha-aminoadipate aminotransferase: III. Evidence for identity with halogenated tyrosine aminotransferase.

A nearly homogeneous preparation of α-aminoadipate (kynurenine) aminotransferase exhibited substantial activity with 3,5-diiodo-L-tyrosine, a major substrate for halogenated tyrosine aminotransferase. The new activity was found, according to heat inactivation and several inhibition studies, not to be attributable to contamination. Many of the properties previously reported for the two enzymes are identical or very similar. This paper lists these similarities and reports our observations of additional similarities of these activities in the supernatant and mitochondrial fractions of both rat kidney and liver. The properties of the purified enzyme and the noted similarities suggest that α-aminoadipate aminotransferase, kynurenine aminotransferase, and halogenated tyrosine aminotransferase activities are associated with the same protein. These activities are discussed in terms of a possible role in thyroid hormone metabolism.     

Studies on the different molecular forms of tyrosine aminotransferase from rat liver and hepatoma cells

In an attempt to clarify the significance of the separable forms of tyrosine aminotransferase, the enzyme from rat liver and from cultured hepatoma cells was studied by carboxymethyl-Sephadex chromatography. Our studies of the form conversion during the purification procedure of the enzyme, where all cellular components were quickly discarded, do not allow us to invoke a specific "converting factor", the existence of which in the particulate fraction has been suggested. Moreover the addition of serine protease inhibitors is not sufficient to prevent the classical conversion. More probably, several factors depending on the environmental conditions might influence different reactions which lead to a preferential conformation of the enzyme in vitro. The difference in the PO4- content of the various enzyme forms and the consecutive differences in negative charge may be the determining factor in the elution pattern of the three forms of the isolated soluble enzyme. This observation raises the possibility that phosphorylation might play a specific role in the regulation of tyrosine aminotransferase synthesis.     

Role of coenzyme in aminotransferase turnover.

The role of coenzyme in determining intracellular contnet of pyridoxal enzymes was assessed by analyzing effects of pyridoxine deficiency on the rapidly degraded, readily dissociable tyrosine aminotransferase (EC 2.6.1.5) and the slowly degraded, nondissociable alanine aminotransferase (EC 2.6.1.2) of rat liver. Synthesis of the tyrosine enzyme was reduced, leading to a decreased amount of this enzyme, much of which was present as active apoenzyme. Synthesis of alanine aminotransferase was unchanged but much of this enzyme was present as an inactive apoenzyme which retained immunological reactivity. Degradation rates of both enzymes (t1/2 about 1.5 h, tyrosine aminotransferase; about 3 days, alanine aminotransferase) were not changed in pyridoxine deficiency. Hence, interaction with coenzyme is not a significant determinant in intracellular degradation of these aminotransferases. Coenzymes dissociation and intracellular stability probably reflect structural features of the proteins which determine both properties.     

Age-related changes of liver tyrosine aminotransferase in senescent rats

Tyrosine aminotransferase was induced in adult and senescent rat liver and its properties studied. We show the appearance of a 'cross-reacting material' for induced tyrosine aminotransferase of old rats compared to basal enzyme; this cross-reacting material can be provoked in adult rats after injection of cycloheximide, and suppressed in adult and old rats after injection of a serine protease inhibitor (tosylphenylalanine chloromethylketone). Other properties of induced tyrosine aminotransferase (thermostability, Km for tyrosine, isoelectrofocusing) are identical except for the proportion of the three forms and their sensitivity to trypsin in the absence of pyridoxal phosphate, which is increased in senescent animals. The suppression of cross-reacting material clearly indicates that it is not due to errors on old rat liver DNA but rather to post-translational modifications. This demonstrates also the role of serine proteases in tyrosine aminotransferase degradation. We suggest that induced enzyme of senescent rats would undergo a conformational change, possibly due to a release of pyridoxal phosphate from the enzymic molecules, which would thus become more susceptible to proteolytic attack than those of adult rats.     

Physical properties, limited proteolysis, and acetylation of tyrosine aminotransferase from rat liver

The native and one of the modified forms of tyrosine aminotransferase were purified from rat liver and characterized. Several hydrodynamic properties of the native enzyme are: Stokes radius, 46 A; subunit isoelectric point, 5.6; sedimentation coefficient, 5.6 S, frictional ratio, 1.44; diffusion coefficient, 4.65 X 10(-7) cm2 s-1; extinction coefficient of a 1% solution (w:v) at 280 nm, 10.5 cm-1. The molecular weight of the dimeric protein is 110,500 as calculated from the Stokes radius and sedimentation coefficient. The subunit of the modified form is of lower molecular weight than the subunit of the native enzyme and has a pI of about 5.9. During isoelectric focusing, both forms of the enzyme separate into two components. The more acidic component that is resolved from the native enzyme is phosphorylated, but the other component is not. The amino acid composition of native tyrosine aminotransferase differs from values reported for mixtures of the three forms of this enzyme. Neither the native nor the modified forms of the enzyme possess a free alpha-amino group as judged by dansylation, nor can they be digested with leucine aminopeptidase, implying that the NH2-terminus is blocked. The possibility that tyrosine aminotransferase is acetylated was examined by translating poly(A)+RNA from hepatoma cells in a cell-free translational system in the presence and absence of inhibitors of protein acetylation. [35S]Tyrosine aminotransferase synthesized in the presence of the inhibitors has a more basic isoelectric point than the native enzyme as determined by isoelectric focusing, suggesting that the enzyme is acetylated either at the NH2-terminal or the epsilon-amino group of an internal lysine. When digested by either of two lysosomal proteases, tyrosine aminotransferase is cleaved to a smaller size. These data show that tyrosine aminotransferase is susceptible to several post-translational modifications.