Tryptophan catabolism by tryptophan pyrrolase in rat liver. The effect of tryptophan loads and changes in tryptophan pyrrolase activity.

We investigated how changes in tryptophan pyrrolase activity and tryptophan loads affect the breakdown of tryptophan was estimated by injecting rats with [ring-2-14-C]tryptophan and measuring respiratory 14-CO2. We concluded, contrary to previous reports, that induction of tryptophan pyrrolase definitely will increase the rate of tryptophan breakdown. Tryptophan loads also increase tryptophan breakdown even in circumstances where there is no increase in tryptophan pyrrolase activity, presumably by increasing the saturation of the enzyme. After a tryptophan load (50 mg per kg) the increase in liver tryptophan concentration lasts only 30 min. The rapid return of liver tryptophan to normal may be due partly to the high turnover rate of liver tryptophan. We estimate that tryptophan pyrrolase degrades tryptophan in vivo at a rate that is equivalent to the whole liver tryptophan concentration in 7.5 min or less.     

Effects of melanin on tyrosine hydroxylase and phenylalanine hydroxylase.

Melanin inhibited rat liver phenylalanine hydroxylase, but activated tyrosine hydroxylase from rat brain (caudate nucleus), rat adrenal glands, and bovine adrenal medulla. Activation of tyrosine hydroxylase by melanin was demonstrated with the extensively dialyzed enzyme and in suboptimal concentrations of the substrate (tyrosine) and the cofactor (6-methyltetrahydropterin). Tyrosine hydroxylase from rat brain was activated by melanin more markedly than that from rat adrenal glands. Purified and extensively dialyzed bovine adrenal tyrosine hydroxylase had two Km values with 6-methyltetrahydropterin, depending upon its concentrations, but the melanin-activated tyrosine hydroxylase had a single Km value and showed the classical Michaelis-Menten kinetics.     

Inhibition of phenylalanine hydroxylase activity by alpha-methyl tyrosine, a potent inhibitor of tyrosine hydroxylase.

Inhibitors of phenylalanine hydroxylase and tyrosine hydroxylase were used in the assay of phenylalanine hydroxylase in liver and kidney of rats and mice. Parachlorophenylalanine (PCPA), methyl tyrosine methyl ester and dimethyl tyrosine methyl ester showed 5–15% inhibition while α-methyl tyrosine seemed to inhibit phenylalanine hydroxylase to the extent of 95–98% at concentrations of 5 × 10 ⁻⁵M –1 × 10 ⁻⁴M. After a phenylketonuric diet (0.12% PCPA + 3% excess phenylalanine), the liver showed 60% phenylalanine hydroxylase activity and kidney 82% that present in pair-fed normals. Hepatic activity was normal after 8 days refeeding normal diet whereas kidney showed 63% of normal activity. The PCPA-fed animals showed 34% in liver and 38% in kidney as compared to normals; in both cases normal activity was noticed after refeeding. The phenylalanine-fed animals showed activity similar to that seen in phenylketonuric animals. The temporary inducement of phenylketonuria in these animals may be due to a slight change in conformation of the phenylalanine hydroxylase molecule; once the normal diet is resumed, the enzyme reverts back to its active form. This paper also suggests that α-methyl tyrosine when fed in conjunction with the phenylketonuric diet may suppress phenylalanine hydroxylase activity completely in the experimental animals thus yielding normal tyrosine levels as seen in human phenylketonurics.     

The effect of stress on the activity of hepatic tryptophan pyrrolase, of tyrosine aminotransferase in various organs and on the level of tryptophan in the liver and plasma of rats.

In rats subjected to 400 revolutions in Noble-Collip drums, hepatic tryptophan pyrrolase activity increases and plasma tryptophan level decreases. After bilateral adrenalectomy, the alterations of plasma tryptophan are even more pronounced and liver tryptophan increases in contrast to tryptophan pyrrolase activity which remains unchanged after injury. The possible significance of the posttraumatic increase of tryptophan pyrrolase in intact animals for brain serotonin metabolism and hepatic gluconeogenesis is underlined. The activity of tyrosine aminotransferase in liver, brain, adrenal, kidney and muscle tissue of rats was determined with special reference to the possible effect of the before-mentioned stress procedure. Organ homogenates were centrifuged at 15000 x g and both supernatants and pellets were investigated for enzyme activity with the exception of the liver, where only the supernatant fraction was used. Tyrosine aminotransferase activity in the liver supernatant considerably exceeded the corresponding values in both supernatant and pellet of the remaining organs, in which a prevalence of the mitochondrial enzyme was obvious. In contrast to the clear-cut increase of the hepatic enzyme during stress, essentially no changes were noted in the brain, the adrenals, kidney or muscle under similar conditions...     

Biopterin metabolism and phenylalanine hydroxylase activity during early liver regeneration

Rat liver biopterin content and the activities of two enzymes involved in biopterin metabolism, sepiapterin reductase and dihydropteridine reductase, were not altered twenty-four hours after partial hepatectomy. This surgical procedure did, however, produce a vigorous regenerative response as verified by an increase in ornithine decarboxylase activity. The tetrahydrobiopterin-dependent activity of phenylalanine hydroxylase was increased in homogenates of regenerating liver. The pteridine requirements for the expression of this activation, and the behavior of the enzyme on calcium-phosphate cellulose columns suggest that elevated levels of cyclic adenosine monophosphate in regenerating liver induce phosphorylation and activation of phenylalanine hydroxylase. This increase in the activity of the primary enzyme of phenylalanine catabolism was interpreted as a compensatory response designed to maintain homeostasis prior to liver regeneration.     

Studies on phenylalanine and tyrosine hydroxylation by rat brain tyrosine hydroxylase.

Tyrosine hydroxylase (EC1.14.16.2), presumably the rate-limiting enzyme in the biosynthesis of catecholamines, is known to catalyze the hydroxylation of both phenylalanine and tyrosine. Using both an isolated enzyme preparation and a synaptosomal preparation, where some architectural integrity of the tissue has been preserved, we have attempted to evaluate the manner in which these two substrates are hydroxylated by rat brain tyrosine hydroxylase. In the presence of tetrahydrobiopterin the isolated enzyme catalyzes the hydroxylation of phenylalanine to 3,4-dihydroxyphenylalanine with the release of free tyrosine as an obligatory intermediate. In contrast, the rat brain striatal synaptosomal preparation in the presence of endogenous cofactor converts phenylalanine to 3,4-dihydroxyphenylalanine without the release of free tyrosine.     

Stimulation of liver tryptophan pyrrolase during heat exposure.

Exposure of rats to heat (39 +/- 1 degree C) stimulated liver tryptophan pyrrolase 2-fold between 3 and 48 h. Plasma corticosterone increased 2-fold after 1 h of heat exposure and decreased to a low value of 50% by 16 h. The effect of heat exposure on the enzyme was obtained in adrenalectomized animals. Stimulation by cortisol and tryptophan of the enzyme was also obtained in heat exposure, and the effects seemed to be additive. The concentration of tryptophan in the liver remained unchanged, and that in the plasma decreased to about 50% at 8 h exposure to heat and reverted to normal by 46 h. Simultaneous administration of noradrenaline to heat-exposed rats had no effect, whereas that of thyroxine partly prevented the stimulation of the enzyme activity. Hypothyroid conditions obtained by thyroidectomy or treatment with propylthiouracil significantly stimulated the enzyme activity. Cycloheximide treatment of heat-exposed rats did not prevent the stimulation of the enzyme activity. The results indicate that the effect of heat exposure on liver tryptophan pyrrolase is obtained, due to the accompanying hypothyroid condition, by increasing the activity of the existing protein by a mechanism possibly different from those known at present.     

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.     

Reduced 6,6,8-trimethylpterins. Preparation, properties and enzymic reactivities with dihydropteridine reductase, phenylalanine hydroxylase and tyrosine hydroxylase

The substrates of dihydropteridine reductase (EC 1.6.99.7), quinonoid 7,8-dihydro(6 H)pterins, are unstable and decompose in various ways. In attempting to prepare a more stable substrate, 6,6,8-trimethyl-5,6,7,8-tetrahydro(3 H)pterin was synthesised and the quinonoid 6,6,8-trimethyl-7,8-dihydro(6 H)pterin derived from it is extremely stable with a half-life in 0.1 M Tris/HCl (pH 7.6, 25 degrees C) of 33 h. Quinonoid 6,6,8-trimethyl-7,8-dihydro(6 H)pterin is not a substrate for dihydropteridine reductase but it is reduced non-enzymically by NADH at a significant rate and it is a weak inhibitor of the enzyme: I50 200 microM, pH 7.6, 25 degrees C when using quinonoid 6-methyl-7,8-dihydro(6 H)pterin as substrate. 6,6,8-Trimethyl-5,6,7,8-tetrahydropterin is a cofactor for phenylalanine hydroxylase (EC 1.14.16.1) with an apparent Km of 0.33 mM, but no cofactor activity could be detected with tyrosine hydroxylase (EC 1.14.16.2). Its phenylalanine hydroxylase activity, together with the enhanced stability of quinonoid 6,6,8-trimethyl-7,8-dihydro(6 H)pterin, suggest that it may have potential for the treatment of variant forms of phenylketonuria.     

Determination of tryptophan, tyrosine, and phenylalanine by second derivative spectrophotometry

Second derivative spectrophotometry has been useful for the determination of aromatic amino acids. However, published methods produce erroneous results, because those methods measure second derivative values by the vertical distance between peak and trough which is subject to variation according to the aromatic amino acid composition of proteins. This paper presents a method of second derivative spectrophotometry which measures second derivative absorbance values by means of the vertical distance from baseline to the derivative curve at a wavelength specifically assigned to each aromatic amino acid, and makes corrections for the interference from other amino acids at the same wavelength. The Appendix describes a computational method for obtaining absolute values of second derivative absorbances directly from normal absorbance values without using the spectrophotometer's derivative mode, because most commercial instruments produce completely arbitrary second derivative values which make comparison of data obtained on two different instruments impossible.