Glucagon stimulation of rat hepatic phenylalanine hydroxylase through phosphorylation in vivo

Phenylalanine hydroxylase activities in extracts of livers from rats pretreated with glucagon are higher than in controls. This time-dependent activation is seen when the hydroxylase is assayed in the presence of tetrahydrobiopterin, but not in the presence of 2-amino-4-hydroxy-6,7-dimethyltetrahydropterin. A maximum 4-fold stimulation of hydroxylase activity was correlated with a conversion of the multiple forms of the enzyme to a single form. This form is characterized by an increased extent of phosphorylation compared to the unactivated enzyme. Incorporation of radioactive inorganic phosphate into phenylalanine hydroxylase following administration of glucagon was determined after specific immunoprecipitation of the enzyme from partially purified preparations. Sodium dodecyl sulfate disc gel electrophoresis showed that stimulation of enzyme activity is accompanied by incorporation of 32Pi into the protein to the extent of 0.7 mol/mol of hydroxylase subunit. These results demonstrate the phosphorylation of hepatic phenylalanine hydroxylase in vivo and strongly support the idea that the activity of this enzyme can be hormonally regulated through a phosphorylation mechanism.     

In vitro activation of rat liver phenylalanine hydroxylase by phosphorylation.

Essentially pure phenylalanine hydroxylase from rat liver can be activated between 2.5- and 3.0-fold by treatment with Mg2+, ATP, protein kinase, and cyclic AMP. The activation is seen when the hydroxylase is assayed in the presence of tetrahydrobiopterin, but not in the presence of 2-amino-4-hydroxy-6,7-dimethyltetrahydropteridine. In the presence of [gamma-32P]ATP, activation is accompanied by incorporation of 32P into the protein to the extent of 0.7 mol/mol of hydroxylase subunit (Mr = 50,000). Cehmical analysis of the untreated enzyme shows that it already contains about 0.3 mol of Pi/mol of hydroxylase. These results suggest that the activity of the hydroxylase may be regulated by phosphorylation.     

Phenylalanine hydroxylase in liver cells. Correlation of glucagon-stimulated enzyme phosphorylation with expressed activity.

Phenylalanine is transported rapidly into, but is not concentrated by, liver cells. Glucagon increased flux through phenylalanine hydroxylase; a half-maximal response was obtained at 0.7 nM. Under control conditions, 0.2-0.3 mol of phosphate were incorporated per mol of subunit of the hydroxylase at steady state. Glucagon increased this incorporation of phosphate into the hydroxylase to a maximal value of approx. 0.6 mol of phosphate per subunit; a half-maximal response was obtained at 0.3 nM. Glucagon, added simultaneously with [32P]Pi to liver cells, inhibited incorporation of 32P into the enzyme. The effects of glucagon were reproduced with dibutyryl cyclic AMP. Changes in phosphorylation correlated closely with changes in flux through phenylalanine hydroxylase in cell incubations.     

Cloning and expression of recombinant human pineal tryptophan hydroxylase in Escherichia coli: purification and characterization of the cloned enzyme.

The first step in the biosynthesis of melatonin in the pineal gland is the hydroxylation of tryptophan to 5-hydroxytryptophan. A cDNA of human tryptophan hydroxylase (TPH) was cloned from a library of human pineal gland and expressed in Escherichia coli. This cDNA sequence is identical to the cDNA sequence published from the human carcinoid tissue [1]. This human pineal hydroxylase gene encodes a protein of 444 amino acids and a molecular mass of 51 kDa estimated for the purified enzyme. Tryptophan hydroxylase from human brainstem exhibits high sequence homology (93% identity) with the human pineal hydroxylase. The recombinant tryptophan hydroxylase exists in solution as tetramers. The expressed human pineal tryptophan hydroxylase has a specific activity of 600 nmol/min/mg when measured in the presence of tetrahydrobiopterin and L-tryptophan. The enzyme catalyzes the hydroxylation of tryptophan and phenylalanine at comparable rates. Phosphorylation of the hydroxylase by protein kinase A or calmodulin-dependent kinase II results in the incorporation of 1 mol of phosphate/mol of subunit, but this degree of phosphorylation leads to only a modest (30%) increase in BH(4)-dependent activity when assayed in the presence of 14-3-3. Rapid scanning ultraviolet spectroscopy has revealed the formation of the transient intermediate compound, 4alpha-hydroxytetrahydrobiopterin, during the hydroxylation of either tryptophan or phenylalanine catalyzed by the recombinant pineal TPH.     

Effect of glucagon on phenylalanine metabolism and phenylalanine-degrading enzymes in the rat

Glucagon administered subcutaneously to rats for 10 days had no significant effect on liver phenylalanine hydroxylase activity, but induced liver dihydropteridine reductase more than twofold. In rats administered a phenylalanine load orally, glucagon treatment stimulated oxidation and depressed urinary phenylalanine excretion. These responses could not be related to an effect of glucagon on hepatic tyrosine-alpha-oxoglutarate aminotransferase activity. Even in rats with phenylalanine hydroxylase activity depressed to 50% of control values by p-chlorophenylalanine administration, glucagon treatment increased the phenylalanine-oxidation rate substantially. Although hepatic phenylalanine-pyruvate aminotransferase was increased tenfold in glucagon-treated rats, glucagon treatment did not increase urinary excretion of phenylalanine transamination products by rats given a phenylalanine load. Glucagon treatment did not affect phenylalanine uptake by the gut or liver, or the liver content of phenylalanine hydroxylase cofactor. It is suggested that dihydropteridine reductase is the rate-limiting enzyme in phenylalanine degradation in the rat, and that glucagon may regulate the rate of oxidative phenylalanine metabolism in vivo by promoting indirectly the maintenance of the phenylalanine hydroxylase cofactor in its active, reduced state.     

The interaction of aromatic amino acids with rat liver phenylalanine hydroxylase

We have examined the interaction of hepatic phenylalanine hydroxylase with the phenylalanine analogs, tryptophan and the diastereomers of 3-phenylserine (beta-hydroxyphenylalanine). Both isomers of phenylserine are substrates for native phenylalanine hydroxylase at pH 6.8 and 25 degrees C, when activity is measured with the use of the dihydropteridine reductase assay coupled with NADH in the presence of the synthetic cofactor, 6-methyl-5,6,7,8-tetrahydropterin. However, while erythro-phenylserine exhibits simple Michaelis-Menten kinetics (Km = 1.2 mM, Vmax = 1.2 mumol/min X min) under these conditions, the threo isomer exhibits strong positive cooperativity (S0.5 = 4.8 mM Vmax = 1.4 mumol/min X mg, nH = 3). Tryptophan also exhibits cooperativity under these conditions (S0.5 = 5 mM, Vmax = 1 mumol/min X mg, nH = 3). The presence of 1 mM lysolecithin results in a hyperbolic response of phenylalanine hydroxylase to tryptophan (Km = 4 mM, Vmax = 1 mumol/min X mg) and threo-phenylserine (Km = 2 mM, Vmax = 1.4 mumol/min X mg). erythro-Phenylserine is a substrate for native phenylalanine hydroxylase in the presence of the natural cofactor, L-erythro-tetrahydrobiopterin (BH4) (Km = 2 mM, Vmax 0.05 mumol/min X mg, nH = 2). Preincubation of phenylalanine hydroxylase with erythro-phenylserine results in a 26-fold increase in activity upon subsequent assay with BH4 and erythro-phenylserine, and hyperbolic kinetic plots are observed. In contrast, both threo-phenylserine and tryptophan exhibit negligible activity in the presence of BH4 unless the enzyme has been activated. The product of the reaction of phenylalanine hydroxylase with either isomer of phenylserine was identified as the corresponding p-hydroxyphenylserine by reaction with sodium periodate and nitrosonaphthol. With erythro-phenylserine, the hydroxylation reaction is tightly coupled (i.e. 1 mol of hydroxyphenylserine is formed for every mole of tetrahydropterin cofactor consumed), while with threo-phenylserine and tryptophan the reaction is largely uncoupled (i.e. more cofactor consumed than product formed). Erythro-phenylserine is a good activator, when preincubated with phenylalanine hydroxylase (A0.5 = 0.2 mM), with a potency about one-third that of phenylalanine (A0.5 = 0.06 mM), while threo-phenylserine (A0.5 = 6 mM) and tryptophan (A0.5 approximately 10 mM) are very poor activators. Addition of 4 mM tryptophan or threo-phenylserine or 0.2 mM erythro-phenylserine to assay mixtures containing BH4 and phenylalanine results in a dramatic increase in the hydroxylation at low concentrations of phenylalanine.(ABSTRACT TRUNCATED AT 400 WORDS)     

The hydroxylation of phenylalanine and tyrosine by tyrosine hydroxylase from cultured pheochromocytoma cells.

Pheochromocytoma tyrosine hydroxylase was reported to have unusual catalytic properties, which might be unique to the tumor enzyme (Dix, T. A., Kuhn, D. M., and Benkovic, S. J. (1987) Biochemistry 24, 3354-3361). Two such properties, namely the apparent inability to hydroxylate phenylalanine and an unprecedented reactivity with hydrogen peroxide were investigated further in the present study. Tyrosine hydroxylase was purified to apparent homogeneity from cultured pheochromocytoma PC12 cells. The purified tumor enzyme was entirely dependent on tetrahydrobiopterin (BH4) for the hydroxylation of tyrosine to 3,4-dihydroxyphenylalanine and hydrogen peroxide could not substitute for the natural cofactor. Indeed, in the presence of BH4, increasing concentrations of hydrogen peroxide completely inhibited enzyme activity. The PC12 hydroxylase exhibited typical kinetics of tyrosine hydroxylation exhibited typical kinetics of tyrosine hydroxylation, both as a function of tyrosine (S0.5 Tyr = 15 microM) and BH4 (apparent Km BH4 = 210 microM). In addition, the enzyme catalyzed the hydroxylation of substantial amounts of phenylalanine to tyrosine and 3,4-dihydroxyphenylalanine (apparent Km Phe = 100 microM). Phenylalanine did not inhibit the enzyme in the concentrations tested, whereas tyrosine showed typical substrate inhibition at concentrations greater than or equal to 50 microM. At higher substrate concentrations, the rate of phenylalanine hydroxylation was equal to or exceeded that of tyrosine. Essentially identical results were obtained with purified tyrosine hydroxylase from pheochromocytoma PC18 cells. The data suggest that the tumor enzyme has the same substrate specificity and sensitivity to hydrogen peroxide as tyrosine hydroxylase from other tissues.     

Affinity labeling of the active site and the reactive sulfhydryl associated with activation of rat liver phenylalanine hydroxylase

A pterin analogue, 5-[(3-azido-6-nitrobenzylidene)amino]-2,6-diamino-4-pyrimidinone (ANBADP), was synthesized as a probe of the pterin binding site of phenylalanine hydroxylase. The photoaffinity label has been found to be a competitive inhibitor of the enzyme with respect to 6,7-dimethyltetrahydropterin, having a Ki of 8.8 +/- 1.1 microM. The irreversible labeling of phenylalanine hydroxylase by the photoaffinity label upon irradiation is both concentration and time dependent. Phenylalanine hydroxylase is covalently labeled with a stoichiometry of 0.87 +/- 0.08 mol of label/enzyme subunit. 5-Deaza-6-methyltetrahydropterin protects against inactivation and both 5-deaza-6-methyltetrahydropterin and 6-methyltetrahydropterin protect against covalent labeling, indicating that labeling occurs at the pterin binding site. Three tryptic peptides were isolated from [3H]ANBADP-photolabeled enzyme and sequenced. All peptides indicated the sequence Thr-Leu-Lys-Ala-Leu-Tyr-Lys (residues 192-198). The residues labeled with [3H]ANBADP were Lys198 and Lys194, with the majority of the radioactivity being associated with Lys198. The reactive sulfhydryl of phenylalanine hydroxylase associated with activation of the enzyme was also identified by labeling with the chromophoric label 5-(iodoacetamido)fluorescein [Parniak, M. A., & Kaufman, S. (1981) J. Biol. Chem. 256, 6876]. Labeling of the enzyme resulted in 1 mol of fluorescein bound per phenylalanine hydroxylase subunit and a concomitant activation of phenylalanine hydroxylase to 82% of the activity found with phenylalanine-activated enzyme. Tryptic and chymotryptic peptides were isolated from fluorescein-labeled enzyme and sequenced. The modified residue was identified as Cys236.     

Effect of glucagon on hepatic phenylalanine hydroxylase in vivo

Moderate doses of glucagon (20 g/kg I.V.) are sufficient to stimulate rat hepatic phenylalanine hydroxylase in vivo. In addition, the stimulation of the tetrahydrobiopterin-dependent phenylalanine hydroxylase activity in livers of animals fed on a high-protein diet has been correlated with an elevated phosphate content. The tetrahydrobiopterin-dependent hydroxylase activity in these animals can be further elevated by glucagon-stimulated phosphorylation. These results indicate that physiological changes in glucagon concentration modulate rat liver phenylalanine hydroxylase activity in vivo. The current understanding of the role of phosphorylation in regulating human phenylalanine hydroxylase is also considered.     

Phosphopeptide analysis of phenylalanine hydroxylase isolated from liver cells exposed to hormonal stimuli.

Hormonal control of the phosphorylation of phenylalanine hydroxylase was studied by using rat liver cells incubated with [32P]Pi. After immunoprecipitation from cell extracts, the hydroxylase was subjected to proteinase digestion and subsequent sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. V8-proteinase digestion yielded one major 32P-labelled fragment, of approx. 9 kDa. Chymotrypsin digestion gave five 32P-labelled fragments ranging from approx. 39 kDa to approx. 10 kDa. Noradrenaline (10 microM) and glucagon (0.1 microM) enhanced the 32P content of all peptide fragments uniformly. Phorbol ester, in contrast with ionophore A23187, did not stimulate enzyme phosphorylation or enhance phenylalanine metabolism in liver cells. These results are discussed in relation to the nature of the protein kinase(s) that mediate phosphorylation of phenylalanine hydroxylase in liver cells.     

Phenylalanine positively modulates the cAMP-dependent phosphorylation and negatively modulates the vasopressin-induced and okadaic-acid-induced phosphorylation of phenylalanine 4-monooxygenase in intact rat hepatocytes.

The state of phosphorylation of phenylalanine hydroxylase was determined in isolated intact rat hepatocytes. 32P-labeled phenylalanine hydroxylase was immunoisolated from cells loaded with 32Pi or from cell extracts 'back-phosphorylated' with [gamma-32P]ATP by cAMP-dependent protein kinase. The rate of phenylalanine hydroxylase phosphorylation in cells with elevated cAMP was similar to that observed for the isolated enzyme phosphorylated by homogeneous cAMP-dependent protein kinase. The phosphorylation rate in cAMP-stimulated cells was increased up to four times (reaching 0.018 s-1) by the presence of phenylalanine, the phosphate content (mol/mol hydroxylase) increasing to 0.5 from the basal level (0.17) in 50 s. The half maximal effect of phenylalanine was obtained at a physiologically relevant concentration (110 microM). The synthetic phenylalanine hydroxylase cofactor dimethyltetrahydropterin also enhanced the cAMP-stimulated phosphorylation of phenylalanine hydroxylase, presumably by displacing the endogenous cofactor, tetrahydrobiopterin. Phenylalanine was a negative modulator of the phosphorylation of phenylalanine hydroxylase induced by incubating cells with vasopressin or with the phosphatase inhibitor okadaic acid. The same site on the phenylalanine hydroxylase was phosphorylated in response to these two agents as in response to elevated cAMP. The available evidence suggested that not only vasopressin, but also okadaic acid, acted by stimulating the multifunctional Ca2+/calmodulin-dependent protein kinase II or a kinase with closely resembling properties.     

Tyrosine hydroxylase in rat brain dopaminergic nerve terminals. Multiple-site phosphorylation in vivo and in synaptosomes.

Tyrosine hydroxylase, which catalyzes the initial step in catecholamine biosynthesis, is phosphorylated at serines 8, 19, 31, and 40 in intact pheochromocytoma (PC12) cells (Haycock, J.W. (1990) J. Biol. Chem. 265, 11682-11691). After 32Pi labeling of rat corpus striata in vivo or rat corpus striatal synaptosomes, 32P incorporation into tyrosine hydroxylase occurred predominantly at serines 19, 31, and 40. Electrical stimulation (30 Hz, 20 min) of the medial forebrain bundle (containing the afferent dopaminergic fibers) increased 32P incorporation into each of the three sites. Brief depolarization of the synaptosomes with elevated [K+]o (20-60 mM, 5-30 s) or veratridine (50 microM, 2 min) produced a selective increase in 32P incorporation into Ser19. Phorbol 12,13-dibutyrate (1 microM, 5 min) increased 32P incorporation into Ser31, and cAMP-acting agents such as forskolin (10 microM, 5 min) increased 32P incorporation into Ser40. In contrast, 32P incorporation into Ser8, which was usually detectable but very low, was not regulated either in vivo or in situ by any of the activators of signal transduction pathways. In synaptosomes, the only treatment found to increase Ser8 phosphorylation was okadaic acid (a protein phosphatase inhibitor), which increased 32P incorporation into all four phosphorylation sites. Thus, three different signal transduction systems appear to mediate the physiological regulation of tyrosine hydroxylase phosphorylation at three different sites.     

Interaction of tyrosine hydroxylase with ribonucleic acid and purification with DNA-cellulose or poly(A)-sepharose affinity chromatography

Tyrosine hydroxylase in bovine adrenal medulla was activated up to fourfold by incubation with low concentrations (15 micrograms/ml) of ribonucleic acids. At higher RNA concentrations, enzyme activity was inhibited. This interaction with RNA was exploited with the use of poly(A)-Sepharose and DNA-cellulose to effect a rapid purification of stable tyrosine hydroxylase from rat brain and bovine adrenal medulla in high yield (up to 58%). With the purified rat brain enzyme, RNA acted as an uncompetitive inhibitor, a concentration of 15 micrograms/ml lowering the Vmax of tyrosine hydroxylase from 1050 to 569 nmol min-1 mg-1 and lowering the Km for tyrosine from 6.1 to 3.6 microM. With the natural cofactor, tetrahydrobiopterin (BH4), two Km values were obtained, indicating the presence of two forms of the enzyme. Both Km values were decreased only slightly by RNA. The purified brain and adrenal enzymes both contained about 0.07 mol of phosphate/63,000-Da subunit; in both cases, cyclic AMP-dependent protein kinase catalyzed the incorporation of an additional 0.8 mol of phosphate/subunit. The purified enzyme also contains ribonucleic acid, which comprises about 10% of the total mass and appears to be important for full activity.     

Experimental determination of the phosphorylation state of phenylalanine hydroxylase.

A monoclonal antibody (PH 7), which recognizes the phosphorylated form of phenylalanine hydroxylase from human liver, has been used for the analysis of the enzyme in crude cell extracts from rat. In immunoblot analyses of rat liver cell extracts, the extent of binding of PH 7 closely correlates with the phosphorylation state of phenylalanine hydroxylase, as judged by [32P]Pi incorporation. These observations have made possible the rapid non-radioactive quantification of hormonal effects on phenylalanine hydroxylase phosphorylation state. In particular, the glucagon-dependent phosphorylation of phenylalanine hydroxylase in liver cells was investigated. Epidermal growth factor was shown to modulate this process. In addition, this technique was used to demonstrate, for the first time, that dibutyryl cyclic AMP, unlike the Ca2+ ionophore A23187, stimulates the phosphorylation of phenylalanine hydroxylase in isolated kidney tubules from rat.     

Queuosine deficiency in eukaryotes compromises tyrosine production through increased tetrahydrobiopterin oxidation

Queuosine is a modified pyrrolopyrimidine nucleoside found in the anticodon loop of transfer RNA acceptors for the amino acids tyrosine, asparagine, aspartic acid, and histidine. Because it is exclusively synthesized by bacteria, higher eukaryotes must salvage queuosine or its nucleobase queuine from food and the gut microflora. Previously, animals made deficient in queuine died within 18 days of withdrawing tyrosine, a nonessential amino acid, from the diet (Marks, T., and Farkas, W. R. (1997) Biochem. Biophys. Res. Commun. 230, 233-237). Here, we show that human HepG2 cells deficient in queuine and mice made deficient in queuosine-modified transfer RNA, by disruption of the tRNA guanine transglycosylase enzyme, are compromised in their ability to produce tyrosine from phenylalanine. This has similarities to the disease phenylketonuria, which arises from mutation in the enzyme phenylalanine hydroxylase or from a decrease in the supply of its cofactor tetrahydrobiopterin (BH4). Immunoblot and kinetic analysis of liver from tRNA guanine transglycosylase-deficient animals indicates normal expression and activity of phenylalanine hydroxylase. By contrast, BH4 levels are significantly decreased in the plasma, and both plasma and urine show a clear elevation in dihydrobiopterin, an oxidation product of BH4, despite normal activity of the salvage enzyme dihydrofolate reductase. Our data suggest that queuosine modification limits BH4 oxidation in vivo and thereby potentially impacts on numerous physiological processes in eukaryotes.     

Subunit phosphorylation and activation of phosphorylase kinase in perfused rat hearts

The potential correlations between phosphorylase kinase subunit phosphorylation and activation have been examined using 32P-perfused rat hearts exposed to a variety of hormonal stimuli. Phosphate incorporation was measured after isolation of the enzyme by immunoprecipitation from heart extracts. Time courses of catecholamine or glucagon treatment produced a rapid rise in both the activity and the beta subunit phosphorylation of the enzyme, and a slightly slower increase in alpha' subunit phosphorylation. For short durations of catecholamine stimulation, the ratio of phosphate in the alpha' versus beta subunit was dependent upon hormone dose. After removal of hormone, both inactivation and alpha' subunit dephosphorylation were fairly slow, while the beta subunit was dephosphorylated more rapidly. For all of the above conditions, activation correlated with both alpha' and beta subunit phosphorylation. The maximum level of phosphate incorporation observed in response to hormonal stimulation is estimated to be approximately 1.3-1.7 mol of [32P]phosphate/mol of (alpha' beta gamma delta)4, divided about equally between the alpha' and beta subunits. When hearts were treated with hormone either in the absence of added calcium or in the presence of a calcium channel blocker, the time courses of subunit phosphorylation and activation were similar to those seen with standard perfusion conditions, suggesting that if any Ca2+-dependent autophosphorylation of phosphorylase kinase were occurring it does not make a major contribution to the observed hormonal responses. The complicated relationships observed here between phosphorylase kinase subunit phosphorylation and activation for the most part provide physiological affirmation of the patterns observed in vitro, but they also show some possible differences of potential interest.     

Glucagon-induced phosphorylation of pyruvate kinase (type L) in rat liver slices.

The effect of glucagon on the phosphorylation of pyruvate kinase in ³²P-labelled slices from rat liver was investigated. Pyruvate kinase was isolated by immunoadsorbent chromatography. The enzyme was partially phosphorylated in the absence of added hormone (0.2 mol of phosphate/mol of enzyme subunit). Upon incubation with 10^?7 M glucagon, the incorporation of [³²P]phosphate was 0.6–0.7 mol/mol of enzyme subunit. Concomitantly, the concentration of intracellular cyclic 3′,5′-AMP increased from 0.3 to 3.2 μM. The phosphorylation inhibited the enzyme activity at low concentrations of phosphoenolpyruvate (60% at 0.5 mM). Almost maximal phosphorylation of the enzyme was reached within 2 min after the addition of glucagon. The concentration of hormone giving half maximal effect on the pyruvate kinase phosphorylation was about 7×10^?9M. The inactivation of the enzyme paralleled the increase in phosphorylation. It is concluded that pyruvate kinase is phosphorylated in the intact liver cell.     

Ligand binding to the inhibitory and stimulatory GTP cyclohydrolase I/GTP cyclohydrolase I feedback regulatory protein complexes

GTP cyclohydrolase I feedback regulatory protein (GFRP) mediates feedback inhibition of GTP cyclohydrolase I activity by 6R-L-erythro-5,6,7,8-tetrahydrobiopterin (BH4), which is an essential cofactor for key enzymes producing catecholamines, serotonin, and nitric oxide as well as phenylalanine hydroxylase. GFRP also mediates feed-forward stimulation of GTP cyclohydrolase I activity by phenylalanine at subsaturating GTP levels. These ligands, BH4 and phenylalanine, induce complex formation between one molecule of GTP cyclohydrolase I and two molecules of GFRP. Here, we report the analysis of ligand binding using the gel filtration method of Hummel and Dreyer. BH4 binds to the GTP cyclohydrolase I/GFRP complex with a Kd of 4 microM, and phenylalanine binds to the protein complex with a Kd of 94 microM. The binding of BH4 is enhanced by dGTP. The binding stoichiometrics of BH4 and phenylalanine were estimated to be 10 molecules of each per protein complex, in other words, one molecule per subunit of protein, because GTP cyclohydrolase I is a decamer and GFRP is a pentamer. These findings were corroborated by data from equilibrium dialysis experiments. Regarding ligand binding to free proteins, BH4 binds weakly to GTP cyclohydrolase I but not to GFRP, and phenylalanine binds weakly to GFRP but not to GTP cyclohydrolase I. These results suggest that the overall structure of the protein complex contributes to binding of BH4 and phenylalanine but also that each binding site of BH4 and phenylalanine may be primarily composed of residues of GTP cyclohydrolase I and GFRP, respectively.     

Regulation of acetyl-coenzyme A carboxylase. I. Purification and properties of two forms of acetyl-coenzyme A carboxylase from rat liver

Acetyl-CoA carboxylase of animal tissues is known to be dependent on citrate for its activity. The observation that dephosphorylation abolishes its citrate dependence (Thampy, K. G., and Wakil, S. J. (1985) J. Biol. Chem. 260, 6318-6323) suggested that the citrate-independent form might exist in vivo. We have purified such a form from rapidly freeze-clamped livers of rats. Sodium dodecyl sulfate gel electrophoresis of the enzyme gave one protein band (Mr 250,000). The preparation has high specific activity (3.5 units/mg in the absence of citrate) and low phosphate content (5.0 mol of Pi/mol of subunit). The enzyme isolated from unfrozen liver or liver kept in ice-cold sucrose solution for 10 min and then freeze-clamped has low activity (0.3 unit/mg) and high phosphate content (7-8 mol of Pi/mol of subunit). Citrate activated such preparations with half-maximal activation at greater than 1.6 mM, well above physiological range. The low activity may be due to its high phosphate content because dephosphorylation by [acetyl-CoA carboxylase]-phosphatase 2 activates the enzyme and reduces its dependence on citrate. Since freeze-clamping the liver yields enzyme with lower phosphate content and higher activity, it is suggested that the carboxylase undergoes rapid phosphorylation and consequent inactivation after the excision of the liver. The carboxylase is made up of two polymeric forms of Mr greater than or equal to 10 million and 2 million based on gel filtration on Superose 6. The former, which predominates in preparations from freeze-clamped liver, has higher activity and lower phosphate content (5.3 units/mg and 4.0 mol of Pi/mol of subunit, respectively) than the latter (2.0 units/mg and 6.0 mol of Pi/mol of subunit, respectively). The latter, which predominates in preparations from unfrozen liver, is converted to the active polymer (Mr greater than or equal to 10 million) by dephosphorylation. Thus, the two polymeric forms are interconvertible by phosphorylation/dephosphorylation and may be important in the physiological regulation of acetyl-CoA carboxylase.