Interconversion of multiple forms of tyrosine aminotransferase in vitro and in vivo in cultured hepatoma cells.

Corticosteroid-induced tyrosine aminotransferase (EC 2.6.1.5) from cultured hepatoma cells was separated by carboxymethyl-Sephadex chromatography into three molecular forms resembling those described previously in the rat liver. Enzyme forms were isolated and used as purified substrates to examine their in vitro interconversion by various subcellular fractions. Isolated form III was converted to forms II and I, and isolated form II was converted to form I by the coarse particulate fraction sedimenting at 1000 X g. This activity was inhibited by the serine enzyme inhibitor phenylmethane sulfonyl fluoride or by raising the pH to 8.7. Conversion of enzyme forms in vitro in the opposite direction (I leads to II leads to III) could not be detected. The distribution of enzyme forms in vivo was examined by the use of experimental conditions that prevent their in vitro interconversion during cell extraction. Tyrosine aminotransferase extracted from cell subjected to various treatments that affect the rates of enzyme synthesis or degradation existed always predominantly as form III. It appears, therefore, that multiple forms of tyrosine aminotransferase are not related to the turnover of this enzyme in vivo.     

Interconversion of multiple forms of tyrosine aminotransferase in vitro and in vivo in cultured hepatoma cells

Corticosteroi-induced tyrosine aminotransferase (EC 2.6.1.5) from cultured hepatoma cells was separated by carboxymethyl-Sephadex chromatography into three molecular forms resembling those described previously in the rat liver. Enzyme forms were isolated and used as purified substrates to examine their in vitro interconversion by various subcellular fractions. Isolated form III was converted to forms II and I, and isolated form II was converted to form I by the coarse particulate fraction sedimenting at 1000 × g. This activity was inhibited by the serine enzyme inhibitor phenylmethane sulfonyl fluoride or by raising the pH to 8.7. Conversion of enzyme forms in vitro in the opposite direction (I → II → III) could not be detected. The distribution of enzyme forms in vivo was examined by the use of experimental conditions that prevent their in vitro interconversion during cell extraction. Tyrosine aminotransferase extracted from cells subjected to various treatments that affect the rates of enzyme synthesis or degradation existed always predominantly as form III. It appears, therefore, that multiple forms of tyrosine aminotransferase are not related to the turnover of this enzyme in vivo.     

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.     

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.     

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.     

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.     

Protection of tyrosine aminotransferase against proteolytic digestion by nucleotide derivatives

The abilities of several nucleotides to protect tyrosine aminotransferase (L-tyrosine: 2-oxoglutarate aminotransferase, EC 2.6.1.5) against proteolytic inactivation in vitro have been examined as part of an ongoing investigation of the role of cyclic GMP in the intracellular degradation of the hepatic enzyme. Although neither cyclic GMP nor cyclic AMP was found to exert such a protective effect, certain nucleotide analogs were observed to inhibit the inactivation of tyrosine aminotransferase by trypsin and chymotrypsin. The nucleotides which conferred the strongest protection were the dibutyryl derivatives of cyclic GMP and cyclic AMP. This phenomenon appears to require a purine nucleotide with hydrophobic substituent(s), while the cyclic phosphate is not essential. The nucleotides probably act by direct interaction with tyrosine aminotransferase as indicated by changes in kinetic properties and heat stability of the enzyme and by their failure to inhibit trypsin when other protein substrates, including another aminotransferase, were used. Dibutyryl cyclic AMP was shown to block the appearance of a characteristic 43 kDa tryptic cleavage product of tyrosine aminotransferase but not the conversion of the native 54 kDa form to a size of 50 kDa. Arguments are presented against the involvement of the protective effect in the actions of dibutyryl cyclic nucleotides on tyrosine aminotransferase in cells.     

Concanavalin A alters the turnover rate of tyrosine aminotransferase in cultured hepatoma cells

Concanavalin A added to monolayer cultures of Reuber H-35 hepatoma cells caused a rapid inactivation of tyrosine aminotransferase (L-tyrosine:2-oxoglutarate aminotransferase, E.C. 2.6.1.5) and loss of reactivity with antibody against the native, dimeric enzyme. Analysis of treated cells with an antibody raised against carboxymethylated, denatured enzyme showed that the inactivated enzyme was reactive with this reagent, which does not react with the native enzyme. Subsequent addition of alpha-methyl-D-mannopyranoside to remove concanavalin A restored both enzyme activity and reactivity to antibody against native enzyme. After long-term treatment with concanavalin A, the restored enzyme levels were significantly higher than in controls treated with the sugar but not the lectin. Analysis of the turnover of the enzyme by two methods revealed that the rate of its degradation is reduced about 2-fold in concanavalin A-treated cells. Treatment with H-35 cells with concanavalin A thus effects an alteration in conformation of tyrosine aminotransferase, rendering it somewhat less sensitive to intracellular degradation.     

Purification of rat pancreatic lipase

A procedure for the isolation of lipase (glycerolester hydrolase, EC 3.1.1.3) from rat pancreas is described. The purification scheme includes homogenization of the pancreas, centrifugation at 3,000 rpm, centrifugation at 40,000 rpm, DEAE-cellulose chromatography, precipitation of amylase as the amylase-glycogen complex, gel filtration of the amylase-free proteins on Sephadex G-100, and chromatography on carboxymethyl-Sephadex C-50. The enzyme showed only one band on polyacrylamide gel electrophoresis and had a specific activity of 5330 +/- 80 units/mg of protein.     

Isolation and characterization of active N-terminal truncated apo- and holoenzyme of mammalian liver tyrosine aminotransferase.

Limited proteolysis was used to probe the structure of the apo- and holoenzyme of rat liver tyrosine aminotransferase. Both were subjected to trypsinolysis and the major fragments were isolated and characterized. Trypsin cleaves the apoenzyme after residues Arg57, Lys64, and Lys71 and the holoenzyme after Arg37 and Lys38. The difference in the accessibility of the enzyme deprived or associated with pyridoxal 5'-phosphate reflects two distinct conformations. The activity, the affinity for the ligands and the thermostability of the purified truncated enzyme forms are similar to those of the native apo- and holoenzyme. A model for the domain structure of mammalian tyrosine aminotransferase and a mechanism for its rapid turnover are proposed.     

Tyrosine aminotransferase from rat liver, a purification in three steps.

Tyrosine aminotransferase from rat liver was isolated by a three step purification method involving affinity chromatography, CM-50 chromatography and G-200 gel filtration. In order to synthesize the affinity gel, the coenzyme pyridoxamine-5′-phosphate was coupled via a spacer group to a sepharose matrix. The enzyme preparation showed a single band in SDS-acrylamide gel electrophoresis and contains three multiple enzyme forms. A molecular weight of 50,000 of the tyrosine aminotransferase subunit was estimated.     

Studies on the conversion of multiple forms of tyrosine aminotransferase in rat liver.

Studies from several laboratories have demonstrated the existence of at least three separable forms of the hepatic enzyme, tyrosine aminotransferase. The significance of these separable forms of the enzyme isolated in vitro for the nature and regulation of the enzyme in vivo has been the subject of some controversy. The studies reported in this paper demonstrate the existence of a heat-labile, pH- and temperature-dependent, nondialyzable component associated predominantly with the lysosomal and mitochondrial fraction of rat liver which catalyzes the conversion of form II to forms III and IV of the enzyme. The activity of this conversion factor is not significantly affected by F^?, molybdate ions, or two inhibitors of proteases. On the other hand, the cyanate ion completely inhibits the conversion of form II to forms III and IV of tyrosine aminotransferase, as do iodoacetate and oxidized glutathione. p-Chloromercuribenzoate also markedly inhibits the conversion. Kinetic studies suggest that the shift from one form to another follows the pathway: II to III to IV. Titration of the available sulfhydryl groups of the three forms of the enzyme demonstrates that form II possesses between 16 and 17 titratable SH groups per mole, while forms III and IV possess 15 and 13 or 14, respectively. The possible catalytic mechanism by which the conversion of the multiple forms of tyrosine aminotransferase is accomplished is discussed.     

The structure of tyrosine aminotransferase. Evidence for domains involved in catalysis and enzyme turnover

The primary structure of tyrosine aminotransferase, as deduced from the nucleotide sequence of complementary DNA, was confirmed by fast atom bombardment mass spectrometry of tryptic peptides derived from the purified protein. Limited digestion of the native enzyme with trypsin released an acetylated, amino-terminal peptide; the new amino terminus in the modified enzyme was Val65. Endogenous proteases generated a chromatographically separable form of tyrosine aminotransferase that began at Lys35. Neither trypsin nor the other proteases altered the catalytic activity of tyrosine aminotransferase. Reduction of the holoenzyme with sodium borohydride yielded a major tryptic peptide containing phosphopyridoxamine bound to lysine 280, which probably functions in transamination. The carboxyl terminus of tyrosine aminotransferase contains features that typify proteins with short half-lives; it includes two negatively charged, hydrophilic segments that are enriched for glutamyl residues and are similar to a PEST region in ornithine decarboxylase (Rogers, S., Wells, R., and Rechsteiner, M. (1986) Science 234, 364-368). Tyrosine aminotransferase belongs to a superfamily of enzymes which includes aspartate aminotransferase and can be aligned so that many invariant, functional residues coincide. Like the isoenzymes of aspartate aminotransferase, tyrosine aminotransferase may contain two domains, with a central, catalytic core, and a small domain made up of both amino- and carboxyl-terminal components. We speculate that the exposed small domain may confer the unusually rapid degradative rate that characterizes this enzyme.     

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.     

Stereospecificity of sodium borohydride reduction of tyrosine decarboxylase from Streptococcus faecalis.

Sodium boro[3H]hydride reduction of tyrosine decarboxylase from Streptococcus faecalis followed by complete hydrolysis of the enzyme produces epsilon-[3H]pyridoxyllysine. Degradation of this material to [4'-3H]pyridoxamine and stereochemical analysis with apoaspartate aminotransferase shows that the re side at C-4' of the cofactor is exposed to solvent at pH 5.5 and 7.0. After binding of L-tyrosine at pH 5.5 or tyramine at pH 7.0 to the holoenzyme, sodium boro[3H]hydride reduction proceeds from the si face at C-4' of the substrate . cofactor complex. This indicates one of two conformational changes occurs upon binding of substrate; either rotation about the C-4 to C-4' bond in the cofactor or rotation about the axis through the C-5 and C-5' bond.     

Localization and Characterization of alpha-Glucosidase Activity in Brettanomyces lambicus

Brettanomyces lambicus was isolated and identified from a typical overattenuating Belgian lambic beer and exhibited extracellular and intracellular alpha-glucosidase activities. Production of the intracellular enzyme was higher than production of the extracellular enzyme, and localization studies showed that the intracellular alpha-glucosidase is mostly soluble and partially cell wall bound. Both intracellular and extracellular enzymes were purified by ammonium sulfate precipitation, gel filtration (Sephadex G-150, Sephadex G-200, Ultrogel AcA-44), and ion-exchange chromatography (sulfopropyl-Sephadex C-50, (carboxymethyl-Sephadex C-50). The intracellular alpha-glucosidase exhibited optimum activity at 39 degrees C and pH 6.2. The extracellular enzyme exhibited optimum catalytic activity at 40 degrees C and pH 6.0. The molecular masses of purified intracellular and extracellular alpha-glucosidases, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, were 72,500 and 77,250, respectively. For both enzymes there was a decrease in the rate of hydrolysis with an increase in the degree of polymerization, and both enzymes hydrolyzed dextrins isolated from lambic wort (degrees of polymerization, 3 to 9 and more than 9). The K(m) values for p-nitrophenyl-alpha-d-glucopyranoside, maltose, and maltotriose for the intracellular enzyme were 0.9, 3.4, and 3.7 mM, respectively. The K(i) values for both enzymes were between 28.5 and 57 muM for acarbose and between 7.45 and 15.7 mM for Tris. These enzymes are probably involved in the overattenuation of spontaneously fermented lambic beer.     

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.     

Stabilization and purification of tyrosine aminotransferase from rat liver

Purification of unmodified tyrosine aminotransferase from rat liver requires that the activity of cathepsin T be minimized, and that losses of enzyme due to dilution or oxidation by prevented. The enzyme was stabilized by pyridoxal 5'-phosphate, dithiothreitol, and potassium phosphate, but was destabilized by L-tyrosine or L-glutamate. A rapid, efficient method for purification of this enzyme included the following steps: twenty-fold induction with a high-casein diet plus dexamethasone phosphate administered in the drinking water; a heat step (65 degrees C) followed by precipitation from 0.20 M sucrose at pH 5.0; and small-scale chromatography on DEAE-cellulose, hydroxyapatite and CM-Sephadex C50 at pH 6.0. These steps yielded more than 10 mg of native enzyme from 35 rats, with a recovery of 68% of the initial activity.     

4-Aminobutyrate aminotransferase. Conformational changes induced by reduction of pyridoxal 5-phosphate

Conformational changes induced in 4-aminobutyrate aminotransferase (4-aminobutyrate:2-oxoglutarate aminotransferase, EC 2.6.1.19) by conversion of pyridoxal-5-P to pyridoxyl-5-P were examined by two independent methods. The reactivity of the SH groups of the reduced enzyme is increased by chemical modification of the cofactor. 1.8 SH per dimer of modified enzyme react with DTNB, whereas 1.2 SH per dimer of the native enzyme react with the attacking reagent under identical experimental conditions. The modified and native forms of the enzyme bind the fluorescent probe ANS, but the number of binding sites for ANS is increased as result of conversion of P-pyridoxal to P-pyridoxyl. After the conformational changes onset by reduction of the cofactor, the modified enzyme binds one molecule of pyridoxal-5-P with a Kd of 0.1 microM to become catalytically competent. The catalytic site of the reduce enzyme was probed with P-pyridoxal analogs. Like resolved 4-aminobutyrate aminotransferase, the reduced species recognize the phosphorothioate analog and regain 40% of the total enzymatic activity. Since the catalytic parameters of reduced and native 4-aminobutyrate aminotransferase are indistinguishable, it is concluded that the additional catalytic site of the reduced enzyme is functionally identical to that of the native enzyme.     

Expression and amplification of cloned rat liver tyrosine aminotransferase in nonhepatic cells

A full-length cDNA for the rat liver enzyme tyrosine aminotransferase has been used to construct mammalian expression vectors by recombinant DNA techniques. These vectors, which have employed either a simian virus 40 or a Rous sarcoma virus promoter, were transfected into a variety of nonhepatic mammalian cell lines in culture. Transient expression of tyrosine aminotransferase was readily observed after transfection into monkey COS cells and mouse L cells. Stable clones that express cloned tyrosine aminotransferase have been isolated from mouse L cells, hamster Wg1a fibroblasts, and Chinese hamster ovary (CHO) cells. A vector capable of expressing both tyrosine aminotransferase and dihydrofolate reductase was stimulated to undergo amplification by treatment with methotrexate in a CHO cell line deficient in the latter enzyme. Levels of tyrosine aminotransferase as much as 50-fold higher than typically seen in glucocorticoid-induced hepatoma cells were achieved in some CHO clones by this technique. The tyrosine aminotransferase produced at these highly amplified levels appeared structurally normal and had no major harmful effects on the cells.