The increase in hepatic tyrosine aminotransferase activity by ethanol administration involves an acceleration of enzyme synthesis

The present study was conducted to examine the nature of the increase in tyrosine aminotransferase (TAT) activity by acute ethanol administration. A significant rise in aminotransferase activity was observed as early as 1 hr after intact rats were gavaged with ethanol. Ethanol administration also increased TAT activity in adrenalectomized rats. Inhibition of ethanol metabolism by pyrazole administration had no effect on the ethanol-induced increase in TAT activity. Immunochemical analyses revealed that the enhancement of TAT activity in ethanol-fed rats correlated with an increase in aminotransferase protein. Measurement of the rate of TAT synthesis showed that in ethanol-fed rats, [3H]leucine was incorporated into the aminotransferase protein at a higher rate than in controls by a factor which was similar to the enhancement in enzyme activity. Our findings indicate that an acceleration of TAT synthesis fully accounts for the increase in TAT activity during the early stage of enzyme induction. TAT induction by ethanol administration is not dependent upon an increase in adrenal corticosteroid production, nor does it require ethanol metabolism.     

Ontogeny of tyrosine aminotransferase in Xenopus laevis.

The development of tyrosine aminotransferase (TAT) activity in Xenopus laevis embryos was studied. Undivided eggs can transaminate tyrosine to some extent. The enzyme activity increases after hatching on the third day of development. In the early stages of development, the transamination of tyrosine is due to aspartate aminotransferase (ASAT, EC 2.6.1.1), both isoenzymes of which are present in the undivided egg. No specific TAT (EC 2.6.1.5) can be detected until the age of about 1 day, at which time neurulation is complete and the rapid development of the foregut and visceral pouches and arches has begun. The appearance of the enzyme is immediately preceded by a steep increase in the concentration of free tyrosine. Tyrosine aminotransferase is known to be induced by its substrate in the adult liver, and a similar effect may operate in the embryo.     

Use of the tyrosine aminotransferase induction system for the demonstration of the signal effect of glucocorticoid hormones

The induction of tyrosine aminotransferase (TAT) in the HTC hepatoma cell line is observed after a single administration of an active steroid. A few minutes of contact between the cells and dexamethasone or corticosterone is sufficient to induce TAT synthesis to its maximal level. When radiolabeled hormones are used, no radioactivity is found in the cell one hour after removal of the hormone from the culture medium, whereas TAT activity remains optimal. Thus, the hormone behaves like a start signal for the optimal synthesis of the enzyme and its continuous presence in the medium is not necessary during the whole induction cycle.     

Factors Affecting Developmental Increase of Tyrosine Aminotransferase in Rat Liver Immediately after Birth

Labeling with ³⁵S-methionine of dispersed hepatocytes prepared from neonatal rat liver and successive immunoprecipitation with antiserum against tyrosine aminotransferase (TAT) indicated that increase of TAT activity to a peak about 12 hours after birth and the decrease thereafter are mainly due to changes of TAT synthesis. Similar changes of TAT activity was also observed in the livers of premature neonates which were taken out by Caesarian section and nursed by foster mothers. This indicated that the appearance of TAT activity at this period is not an event programmed along with fetal development but is triggered by birth. The level of glucagon in neonatal plasma increased after birth. Administration of glucagon to neonates caused a great increase of TAT activity whereas the effect of dexamethasone was not so evident. These suggested that glucagon is an important factor affecting the abrupt appearance of TAT after birth.     

Rosmarinic acid formation and differential expression of tyrosine aminotransferase isoforms in Anchusa officinalis cell suspension cultures

Time-course changes in rosmarinic acid (RA) formation and activities of tyrosine aminotransferase (TAT) isoforms were examined in Anchusa officinalis suspension cultures. Three TAT isoforms (TAT-1, TAT-3, TAT-4) were resolved by Mono-Q anion-exchange column chromatography. The proportion of the TAT-3 activity within the total TAT activity remained high regardless of the growth stage of the cultured cells. TAT-1 activity was positively correlated with the rate of RA biosynthesis during linear growth stage of the culture cycle, while TAT-4 activity was rapidly induced in conjunction with transfer to fresh medium coincident with a transient increase in RA synthesis. Based on these results, as well as the substrate specificity of each TAT isoform, it was concluded that both TAT-1 and TAT-4 are closely involved in RA biosynthesis. TAT-1 controls conversion of tyrosine to 4-hydroxyphenyl pyruvate, and TAT-4 acts by participating in the formation of tyrosine and phenylalanine via prephenate.Abbreviations PAL phenylalanine ammonia-lyase - TAT tyrosine aminotransferase - RA rosmarinic acid     

Role of glucocorticoids and resident liver macrophages in induction of tyrosine aminotransferase

Administration of cortisol to an animal induces tyrosine aminotransferase (TAT) in the liver. A similar effect was observed after stimulation of resident liver macrophages (Kupffer cells) by dextran sulfate. Actinomycin D completely blocks enzyme induction both by cortisol and dextran sulfate, whereas their combined effect gives an additive result. In primary culture of hepatocytes, dextran sulfate inhibits TAT activity, but conditioned macrophage medium reliably increases enzyme activity in hepatocytes. However, incubation of isolated macrophages in the presence of dextran sulfate and such medium transfer into hepatocyte culture results in even more pronounced increase in TAT activity. In a combined culture of hepatocytes and non-parenchymal liver cells, reproducing intercellular interactions in vitro, cortisol and non-parenchymal cells exhibit an additive effect on TAT activity. These results show that liver macrophages release a factor of unknown nature launching the mechanism of TAT induction independently of cortisol, a classic TAT inducer.     

Assignment of the human tyrosine aminotransferase gene to chromosome 16

Summary The liver enzyme tyrosine aminotransferase (TAT; EC 2.6.1.5) catalyzes the rate-limiting step in the catabolic pathway of tyrosine. Deficiency in TAT enzyme activity underlies the autosomally inherited disorder tyrosinemia II (Richner-Hanhart syndrome). Using a human TAT cDNA clone as hybridization probe, we have determined the chromosomal location of the TAT structural gene by Southern blot analysis of DNAs from a series of human x rodent somatic cell hybrids. The results assign the TAT gene to human chromosome 16.     

Mechanism of a decrease of inducibility of tyrosine aminotransferase by carcinogenic aminoazo dyes. Absence of direct influence of o-aminoazotoluene on the enzyme molecules

The effect of o-aminoazotoluene (OAT) on the activity of tyrosine aminotransferase (TAT) from mouse liver cytosol under its incubation in the presence of the systems providing for the metabolic activation of the cancerogen (liver microsomes and NADPH2) and dephosphorylation of TAT molecules (light mitochondria and ATP) was studied. It was shown that OAT has neither direct nor indirect (via the phsophorylation--dephosphorylation systems) effect on the activity of TAT. It was concluded that the decrease of TAT induction by hydrocortisone in vivo resulting from injection of OAT to the mice is not due to the direct influence of the cancerogen on the enzyme molecules.     

Behaviour of tyrosine amino transferase and convertase during the first hours after hepatectomy in rats

The activity of rat liver tyrosine amino transferase (TAT) increases after hepatectomy with a first prominent peak at 8 h and a second peak at 18 h. This change in activity is probably due to de novo enzyme synthesis since it is prevented by actinomycin-D (AMD). In the same period an increase of the lysosomal converting enzyme (convertase) which catalyses the in vitro transition of TAT from form I to form III, has been observed; this is not accompanied by changes of other lysosomal enzymes, such as acid phosphatase and cathepsin L. The activity of convertase is equal to that of the controls (sham operated animals) 2 h after hepatectomy, increases three times at 5 h, maintains the same value at 8 h and then decreases slowly to control level after 24 h. The correlation between the activity changes of the two enzymes strongly suggests a physiological role of convertase in TAT turnover.     

Effects of glucagon and an analogue of cAMP on tyrosine aminotransferase in isolated chick embryo hepatocytes.

Hepatocytes were isolated from 17-day-old chick embryos by the use of collagenase. Glucagon and dibutyryl cAMP (bt2cAMP), individually or in combination, stimulated tyrosine aminotransferase (TAT) activity and synthesis in the isolated hepatocytes; maximal stimulation occurred 4 h after exposure of hepatocytes to the inducers. The stimulatory effects produced by glucagon and bt2cAMP were abolished by treatment of hepatocytes with cordycepin or cycloheximide. The effects of the hormone and the cyclic nucleotide were not additive. The induction of the enzyme by glucagon suggests a physiological role for the hormone in the expression of TAT activity during chick embryonic development.     

Sequential changes in ornithine decarboxylase thymidine kinase, and other enzyme activities in regenerating liver in rats on controlled feeding schedules.

The changes in activity of five enzymes including ornithine decarboxylase (ODC), tyrosine aminotransferase (TAT), thymidine kinase (TK), ornithine aminotransferase (OAT) and serine dehydratase (SDH) in the early stage of the regenerating rat liver have been studied under a controlled feeding and lighting schedule. The first three enzyme activities were stimulated sequentially by partial hepatectomy. The earliest response was observed in ODC activity. A significant increase in this enzyme activity was observed at 2 hrs and the maximal level was at 4 hrs after the operation. TAT began to increase at 4 hrs and the maximal level was at 8 hrs. The TK activity was induced at about 24 hrs and the highest value was at 48 hrs after partial hepatectomy.A significant decrease in OAT activity was observed at 24 hrs after the operation and subsequently. Although a decrease in SDH activity was also observed this decrease did not seem to correlate directly with the regeneration process, since a lowered level of the enzyme activity was also found in the sham operated group.     

Isolation, characterization and chromosomal mapping of the mouse tyrosine aminotransferase gene

The tyrosine aminotransferase (TAT) gene is expressed in a tissue and developmental-specific manner. In addition, this gene is regulated by glucocorticoid and polypeptide hormones and its expression is affected when a regulatory region near the albino locus of the mouse is deleted. In order to allow studies of the molecular effects of these deletion mutations we have isolated and characterized the mouse TAT gene. The gene is 9.2 x 10(3) bases in length and consists of 12 exons which give rise to a 2.3 x 10(3) base long messenger RNA. The DNA sequence at the 5' end of the gene was determined and compared with the corresponding sequence of the rat tyrosine aminotransferase gene. The sequence comparison showed extensive homology over the entire region sequenced. In addition, DNA: DNA heteroduplex studies between the mouse and rat tyrosine aminotransferase genes revealed that this homology extends over the entire gene and its flanking sequences. The mouse tyrosine aminotransferase gene has been mapped distal to the serum esterase-1 locus on mouse chromosome 8, using a restriction fragment length polymorphism between two mouse species. Since the albino deletions are located on mouse chromosome 7, the assignment of the TAT gene to chromosome 8 suggests that a regulatory factor(s) affecting TAT gene expression acts in trans.     

Tyrosine aminotransferase deficiency in mink (Mustela vision): A model for human tyrosinemia II

Mink pseudodistemper, a recessive disease associated with high blood tyrosinelevels, is an animal analogue of the human inborn error of metabolism, tyrosinemia II. Affected mink and man have eye and skin lesions. Affected mink have no hepatic tyrosine aminotransferase (TAT) activity, as measured immunologically and biochemically. Hepatic mitochondrial aspartate aminotransferase is increased to 188% of control. This new genetic animal model of TAT deficiency should allow new studies of tyrosine metabolism.Supported by NIH Grants AM-17253 (LAG), 5T32-AM-07093 (LAG), and RCDA AM-0008 (LAG), grants from the Wisconsin State Mink Advisory Board, and a BRSG grant for the Graduate School of the University of Wisconsin, Madison, Publication No. 82 of the dermatology research laboratories of Duke University Medical Center.     

Inhibition of hormonal induction of tyrosine aminotransferase by polyamines in freshly isolated rat hepatocytes.

We have analysed the effects of natural aliphatic polyamines on hormonal induction of tyrosine aminotransferase (TAT) in suspensions of hepatocytes isolated from adult fed rats. Glucagon or cyclic AMP derivatives (dibutyryl and 8-bromo) used alone caused a 4-5 fold increase in enzyme activity within 4h. This effect was independent of glucocorticoids, which also increased TAT activity (2.5-fold); when combined, the effects of the two inducers were additive. Spermine and putrescine totally inhibited the hormonally-mediated increase in enzyme activity when added at the onset of incubation with the inducers. Furthermore, polyamines could block the hormonal effect at any time during the course of TAT induction, with, however, a 30 min lag period, suggesting that they must enter the cells. Hepatocytes were indeed shown to take up spermine. At low external concentrations (less than 50 microM), an Na+-dependent, saturable and concentrative mechanism was predominant; at high concentrations (greater than 0.5 mM) transport occurred mainly through a non-saturable, Na+-independent mechanism, building up intracellular concentrations slightly lower than those in the medium. Dose-dependence analysis of the polyamine effect on enzyme induction indicated that half-maximal and maximal inhibition occurred with 0.75 mM- and 2.5 mM-spermine respectively, whereas 2.5mM- and 7.5 mM-putrescine were required respectively to obtain similar effects. Spermidine was much less effective and cadaverine had virtually no effect. None of the polyamines affected the rate of decay of TAT, nor did they directly or indirectly cause enzyme inactivation, indicating that a post-translational modification was unlikely to account for the polyamine effects. Similarly, these effects could not be ascribed to a non-specific inhibition of overall protein synthesis. We conclude that, in hepatocytes, polyamines (or their metabolites) directly interfere with one or several steps controlled by hormones in the synthesis of tyrosine aminotransferase.     

Variation of tyrosine aminotransferase expression during the day in rats of different ages.

The activity of the enzyme tyrosine aminotransferase and the synthesis of its specific mRNA were evaluated at different hours of the day in the liver of 3-, 12- and 24-month old BN rats. The enzyme activity has a circadian rhythm with a peak at midnight in 3- and 12-month old, which shifts to 03.00 hrs in 24-month old animals, in agreement with previous results. The expression of TATmRNA also changes during the day indicating circadian fluctuations which change with age. In 3-month old rats the TATmRNA peak is at 19.00 hrs, preceding that of the enzyme activity. In 12-month old rats the TATmRNA synthesis reaches a maximum at midnight and in 24-month old rats at 03.00 hrs. The results show that the circadian rhythm of tyrosine aminotransferase activity is due to a different gene expression throughout the day, which is influenced by age.     

Activation of production of mouse liver enzymes in rat hepatoma-mouse lymphoid cell hybrids

The production of four liver-specific enzymes (tyrosine aminotransferase or TAT, alanine aminotransferase, aldolase B, and alcohol dehydrogenase) has been analyzed in rat hepatoma-mouse lymphoid cell hybrids containing a 1s or 2s complement of rat chromosomes. The hybrid clones which retain a nearly 2s complement of rat chromosomes show high activity of all four enzymes; those which contain a 1s rat complement show partial or complete extinction of these enzymes. The tyrosine aminotransferase produced by most of the hybrid clones is identifiable as being of both rat and mouse origin, based upon criteria of temperature sensitivity and electrophoretic mobility; antiserum to the rat liver enzyme was used to distinguish the pseudo-TAT produced by the lymphoid parent from liver-TAT produced by hepatoma and hybrid cells. By the criteron of electrophoretic mobility, the liver form (B) of aldolase, produced by only some of the hybrid clones, appears to be composed of both rat and mouse subunits. We conclude that when extinction of tissue-specific proteins does not occur or is only partial in hybrid cells (due to gene dosage effects), the genomes of both parents may be active in directing synthesis of these proteins.     

Induction of particulate and soluble isoenzymes of tyrosine aminotransferase by hydrocortisone in the liver of rats as a function of age.

The induction of soluble cytoplasmic (c-), and particulate mitochondrial (m-) and nuclear (n-) isoenzymes of tyrosine aminotransferase (TAT) by hydrocortisone in the liver of 6-, 35- and 76- week old rats was studied. In contrast to the earlier reports, both the particulate isoenzymes (m- &; n-TAT) are induced by hydrocortisone. This induction is actinomycin D sensitive. The degree and pattern of induction of the three isoenzymes of TAT vary with age. The possibility of separate regulatory mechanisms for the synthesis of the three isoenzymes is discussed.