Characteristics of the activation by dithiothreitol and Fe2+ of tryptophan hydroxylase from the rat brain

The preincubation of tryptophan hydroxylase extracted from various areas of the central nervous system of the rat with 30 mM dithiothreitol and 50 M ferrous ammonium sulfate under nitrogen atmosphere resulted in a persistent increase of its activity. Studies on the enzyme characteristics indicated that this activation was associated with a doubling in itsV _max and a shift (from 7.6 to 7.2) of the optimal pH for its activity. In contrast, the molecular weight and the apparent affinities of tryptophan hydroxylase for its pterin cofactor and for tryptophan were not significantly altered by the preincubation with dithiothreitol and ferrous ammonium sulfate. Since this treatment did not prevent the stimulatory effects of various compounds (phosphatidylserine, ATP and Mg²⁺, Ca²⁺) on tryptophan hydroxylase activity, this might be a good procedure to activate this enzyme with only minor changes in its regulatory properties.     

EARLY RESPONSE OF RAT BRAIN TRYPTOPHAN HYDROXYLASE ACTIVITY TO CYCLOHEXIMIDE, PUROMYCIN AND CORTICOSTERONE

Abstract— The activity of tryptophan hydroxylase was measured in whole homogenates of midbrain and forebrain areas of the rat brain. A significant elevation of tryptophan hydroxylase in midbrain and forebrain was found within 1 h after injection of corticosterone hemisuccinate Na salt (10mg/kg) into normal rats. A further elevation of tryptophan hydroxylase at 4 h after injection occurred only in the midbrain region. A rapid alteration of tryptophan hydroxylase was also observed following intracistemal injection of a protein synthesis inhibitor, cydoheximide. A significant depression of 50% of normal levels occurred both in midbrain and forebrain regions within 1 h. However. 4 h after injection only the midbrain tryptophan hydroxylase level was depressed, and this depression was 16% of normal levels. This temporal and spatial pattern following cydoheximide injection was not the result of changes in the ability of cydoheximide to inhibit in vivo protein synthesis since [³H]valine incorporation into protein was shown to be equally depressed at both 1 and 5 h in both the midbrain and forebrain. Puromycin blocked [³H]valine incorporation into proteins in the midbrain and forebrain. but only caused a depression of 16% of tryptophan hydroxylase in the midbrain at 4 h. The aminonucleoside derivative of puromycin has no effect on protein synthesis or on tryptophan hydroxylase. Cydoheximide had no effect on tryptophan hydroxylase in vitro. The data suggest that cydoheximide and corticosterone produce an early (1 h) effect on tryptophan hydroxylase unrelated to de novo protein synthesis in regions known to contain perikaryon (midbrain) and axon terminals (forebrain) of 5-HT-containing neurons. The later (4h) effects of these two compounds and puromycin on tryptophan hydroxylase in the perikaryon (midbrain) region of 5-HT-containing neurons probably result from alteration in de novo protein synthesis. The half time of tryptophan hydroxylase in midbrain region is calculated to be 12 h.     

Phosphorylation and Activation of Tryptophan Hydroxylase by Exogenous Protein Kinase A

Abstract: The catalytic subunit of protein kinase A increases brain tryptophan hydroxylase activity. The activation is manifested as an increase in V_max without alterations in the K_m for either tetrahydrobiopterin or tryptophan. The activation of tryptophan hydroxylase by protein kinase A is dependent on ATP and an intact kinase and is inhibited specifically by protein kinase A inhibitors. Protein kinase A also catalyzes the phosphorylation of tryptophan hydroxylase. The extent to which tryptophan hydroxylase is phosphorylated by protein kinase A is dependent on the amount of kinase used and is closely related to the degree to which the hydroxylase is activated. These results suggest that a direct relationship exists between phosphorylation and activation of tryptophan hydroxylase by protein kinase A.     

Immunohistochemical evidence for the presence of tryptophan hydroxylase in the brains of insects as revealed by sheep anti-tryptophan hydroxylase polyclonal antibody

Immediately following the discovery of tryptophan hydroxylase in Drosophila, we demonstrated the presence of tryptophan hydroxylase in the brain of the beetle Harmonia axyridis (Coleoptera: Coccinellidae). However, whether tryptophan hydroxylase is present in the brains of other insects is still a matter of discussion. In the current study, sheep anti-tryptophan hydroxylase polyclonal antibody has been applied to test for tryptophan hydroxylase immunoreactivity in a broader taxonomic range of insect brains, including holometabolous and hemimetabolous insects: one species each of Coleoptera, Hymenoptera, Diptera, and Blattaria, and two species of Lepidoptera. All species show consistent tryptophan hydroxylase immunoreactivity with distribution patterns matching that of serotonin. The immuno-positive results of such an antibody in brains from diverse orders of insects suggest that specific tryptophan hydroxylase responsible for central serotonin synthesis is probably present in the brains of all insects. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. This work was supported by grants from the National Natural Science Foundation of China (grant no. 30470546) and the Natural Science Foundation of Jilin Province (grant no. 20030550–7).     

THE ROLE OF INTRANEURONAL 5-HT AND OF TRYPTOPHAN HYDROXYLASE ACTIVATION IN THE CONTROL OF 5-HT SYNTHESIS IN RAT BRAIN SLICES INCUBATED IN K+-ENRICHED MEDIUM

Abstract— The incubation of brain stem slices from adult rats in a K⁺-enriched medium containing a 5-HT uptake inhibitor (fluoxetine) significantly increased their capacity to synthesize 5-HT from tryptophan. The K+-induced stimulation of 5-HT synthesis was at least partly dependent on the depletion of the indoleamine in tissues since: (1) a good correlation was found between the respective changes in 5-HT release and synthesis evoked by high K⁺ concentrations in the presence of various 5-HT uptake inhibitors; (2) the modifications in endogenous 5-HT levels produced by in vim treatments with drugs (reserpine, pargyline) or by incubating slices with 5-HT altered the stimulating effect of high K⁺ concentrations and fluoxetine on 5-HT synthesis; (3) the replacement of Ca²⁺ by Co²⁺ (4 mM) or EGTA (0.1 mM) in the incubating medium completely prevented the increased 5-HT release and synthesis evoked by high K⁺ concentrations and fluoxetine. The extraction of tryptophan hydroxylase from incubated tissues revealed that the increased 5-HT synthesis occurring in K⁺-enriched medium was associated with an activation of this enzyme. Kinetic analyses indicated that this activation resulted from an increase in the V_max of tryptophan hydroxylase, its apparent affinities for both tryptophan and 6-MPH₄ being not significantly affected. In contrast to the tryptophan hydroxylase from tissues incubated in normal physiological medium, the activated enzyme from tissues depolarized by K⁺ was hardly stimulated by Ca²⁺-mediated phosphorylating conditions. This led to the proposition of a hypothetical model by which the Ca²⁺ influx produced by the neuronal depolarization would trigger the activity of a Ca²⁺-dependent protein kinase capable of activating tryptophan hydroxylase. Although this sequence is still largely speculative it must be emphasized that, as expected from such a model, the regional differences in the K⁺-evoked activation of tryptophan hydroxylase in slices (cerebral cortex > brain stem > spinal cord) were parallel to those of the Ca²⁺-dependent protein phosphorylation (r= 0.92) and those of the activating effect of phosphorylating conditions on soluble tryptophan hydroxylase (r= 0.96).     

GLUCOCORTICOIDS AS A REGULATORY FACTOR FOR BRAIN TRYPTOPHAN HYDROXYLASE

—The normal developmental rise of tryptophan hydroxylase levels in neonatal rat brain was blocked by adrenalectomy. Similarly, adrenalectomy prevented the rescrpine-induced elevation of tryptophan hydroxylase activity in brain stem of adult mice. In both cases, the effects of adrenalectomy could be reversed by replacement injections of corticosterone. Repeated injections of corticosterone (5 mg/kg daily) in fact induced a rise of brain tryptophan hydroxylase levels in neonatal brain. However, neither adrenalectomy nor repeated injections of large doses of the hormone (20 mg/kg, daily) was found to be effective in affecting the normal enzyme levels in adult brain. Apparent K_m of the enzyme for substrate was unchanged by corticosterone in vivo or in vitro. These results indicate that glucocorticoids have a significant role in the regulation of brain tryptophan hydroxylase: possibly as an inducing signal during neonatal development and as a permissive factor at adult age.     

A SENSITIVE MICROASSAY FOR TRYPTOPHAN HYDROXYLASE IN BRAIN

—A specific and sensitive, radioisotopic microassay for tryptophan hydroxylase (EC 1.14.36) is described, which is capable of determining enzymatic activity in as little as 5 μg of crude brainstem homogenate. 5-Hydroxytryptophan, the immediate product of hydroxylation of tryptophan is enzymatically converted to N-acetylserotonin. A radioisotopic label is then introduced by the enzymatic methylation of N-acetylserotonin in the presence of [³H]methyl-S-adenosyl-methionine. The [³H]-melatonin thus formed is isolated by extraction and counted. With this assay, the activity in individual hypothalamic nuclei (arcuate nucleus, median eminence, suprachiasmatic nucleus, and medial forebrain bundle) has been measured.     

Regulation of tryptophan and tyrosine hydroxylase

The synthesis of the neurotransmitters serotonin, norepinephrine, and the dopamine is regulated by the initial amino acid hydroxylases. Little is known about the factors that regulate the level of tryptophan hydroxylase in tissue. However, the level of tyrosine hydroxylase is regulated by transsynaptic induction. Acute regulation of in vivo hydroxylase activity appears to be by substrate availability in the case of tryptophan hydroxylase and possibly by feedback inhibition with tyrosine hydroxylase. A newly described phenomenon which has been termed “receptor mediated feedback inhibition” involving neuronal feedback regulation of the activity of both tyrosine and tryptophan hydroxylase may also have an important role.     

CHARACTERIZATION OF THE Ca2+-INDUCED PROTEOLYTIC ACTIVATION OF TRYPTOPHAN HYDROXYLASE FROM THE RAT BRAIN STEM

The incubation of the 35,000 g supernatant of a rat brain stem homogenate in the presence of 7.5 mM-CaC1₂ for 10 min at 25°C resulted in a more than 2-fold increase in its tryptophan hydroxylase activity. This activation was irreversible and involved a reduction in the molecular weight of the enzyme, from 220,000 to 160,000. The partially proteolysed tryptophan hydroxylase, in contrast to the native enzyme, could not be activated by trypsin, sodium dodecyl sulphate, phosphatidylserine or phosphorylating conditions; dithiothreitol and Fe²⁺ were the only compounds whose stimulating effect on the enzymatic activity was not prevented by the Ca²⁺ -induced proteolysis of tryptophan hydroxylase. These findings suggest that the mol. wt. 60,000 fragment removed by the Ca²⁺ dependent neutral proteinase plays a critical role in the regulatory properties of tryptophan hydroxylase.     

The action of fenfluramine andp-chloramphetamine on serotonergic mechanisms: A comparative study in rat brain nuclei

A single injection of fenfluramine orp-chloroamphetamine (PCA) (100 mol/kg intraperitoneally) decreases the serotonin (5HT) content and the tryptophan hydroxylase activity in various areas of the rat brain. Other reports have shown that a single injection of fenfluramine or PCA causes cytopathological changes in a serotonergic midbrain nucleus which was termed B9 by Dahlstrom and Fuxe (1). Despite this cytopathological change, fenfluramine fails to reduce the tryptophan hydroxylase activity in B9. In hippocampus the decrease of tryptophan hydroxylase elicited by fenfluramine persists for less than 21 days; in contrast PCA reduces the tryptophan hydroxylase activity in hippocampus, striatum, septal nuclei and B9 for longer than 21 days. Probably the decrease of tryptophan hydroxylase elicited by PCA in B9 is due to retrograde degeneration; the intensity and duration of the biochemical lesion elicited by fenfluramine and PCA in serotonergic terminals are a factor in determining the extent of the biochemical lesion in serotonergic cell bodies.     

DIURNAL RHYTHM AND TURNOVER OF TRYPTOPHAN HYDROXYLASE IN THE PINEAL GLAND OF THE RAT

Tryptophan hydroxylase in the pineal gland of the rat was found to undergo a diurnal rhythm in activity with an elevated activity at night. The rhythm was abolished in constant light. Cycloheximide (15 mg/kg, i.p.), administered both at night and during the day, caused a rapid decay in activity suggesting that tryptophan hydroxylase was subject to a rapid turnover in vivo. The primary site of control appeared to be at the level of translation since actinomycin D had no effect. Some relevant properties of the enzyme were studied. Thiol-containing compounds were shown to substantially protect pineal tryptophan hydroxylase from inactivation at 0°C but provided little protection at higher temperatures. The inactivation process appeared to be independent of oxygen. The activity of the enzyme, lost after ageing at 0°C. could be recovered by incubation with dithiothreitol under anaerobic conditions. Fresh enzyme, or enzyme inactivated at 37°C could not be activated by this process. A re-examination of the action of p-chlorophenylalanine (PCPA) on pineal tryptophan hydroxylase revealed that an irreversible inactivation occurred within 6h (25% of initial activity) followed by a recovery within 24 h. The rapid turnover of the enzyme is the probable reason for the failure of previous studies to observe an irreversible inhibition of this enzyme by PCPA.     

Zebrafish Tyrosine Hydroxylase 2 Gene Encodes Tryptophan Hydroxylase

The primary pathological hallmark of Parkinson disease (PD) is the profound loss of dopaminergic neurons in the substantia nigra pars compacta. To facilitate the understanding of the underling mechanism of PD, several zebrafish PD models have been generated to recapitulate the characteristics of dopaminergic (DA) neuron loss. In zebrafish studies, tyrosine hydroxylase 1 (th1) has been frequently used as a molecular marker of DA neurons. However, th1 also labels norepinephrine and epinephrine neurons. Recently, a homologue of th1, named tyrosine hydroxylase 2 (th2), was identified based on the sequence homology and subsequently used as a novel marker of DA neurons. In this study, we present evidence that th2 co-localizes with serotonin in the ventral diencephalon and caudal hypothalamus in zebrafish embryos. In addition, knockdown of th2 reduces the level of serotonin in the corresponding th2-positive neurons. This phenotype can be rescued by both zebrafish th2 and mouse tryptophan hydroxylase 1 (Tph1) mRNA as well as by 5-hydroxytryptophan, the product of tryptophan hydroxylase. Moreover, the purified Th2 protein has tryptophan hydroxylase activity comparable with that of the mouse TPH1 protein in vitro. Based on these in vivo and in vitro results, we conclude that th2 is a gene encoding for tryptophan hydroxylase and should be used as a marker gene of serotonergic neurons.     

Detection of mitochondrial dysfunction in vitro by laser‐induced autofluorescence

Mitochondrion plays a significant role in a variety of biological functions. Because of their diverse character and location in the cellular systems, mitochondria commonly get exposed to various extrinsic and intrinsic cellular stresses. The present study reports a novel approach to detection of mitochondrial dysfunction based on tryptophan autofluorescence of its proteins in mouse liver, using laser‐induced fluorescence (LIF) as a tool. Mitochondria, isolated from the mouse liver, were initially tested for purity and integrity using lactate dehydrogenase and succinate dehydrogenase (SDH) assays. Mitochondrial stress was induced by treating the isolated mitochondria with heavy metals at 10 and 0.01 mM for sodium arsenite and mercuric chloride, respectively. Upon treatment with the heavy metal, tryptophan autofluorescence quenching was recorded at 281 nm excitation. The functional integrity of the mitochondria treated with heavy metals was evaluated by measuring SDH and cytochrome c oxidase activities at various concentrations of mitochondria, which showed impaired activity as compared to control upto a concentration of 6.25 μg. A significant shift was also observed in the autofluorescence of proteins upto the level below 1 μg, suggesting their conformational change and hence altered structural integrity of mitochondria. Circular dichroism spectroscopy data of the mitochondrial proteins treated with heavy metals further validates their conformational change as compared to untreated control. The present study clearly shows that the LIF can be a novel detection tool to detect altered structural integrity of cellular mitochondria upon stress, and it also possesses the potentiality to combine with other interdisciplinary modalities.     

Biosynthesis of serotonin in Raphé nuclei of rat brain: effect of p-chlorophenylalanine

The activity of tryptophan hydroxylase (EC 1.99.1.4) in the region of the raphé nuclei of rat brain was higher than that of any other brain area. The content of serotonin and the rate of serotonin synthesis were also highest in the raphé nuclei. Following the administration of p-chlorophenylalanine the injection of tryptophan and pargyline increased the content of serotonin in the region of the raphé nuclei of rat brain. The results suggest that the raphé nuclei retained the capacity to hydroxyl-late tryptophan to some extent after the injection of p-chlorophenylalanine.     

Calcium activation of brain tryptophan hydroxylase.

Using both radioisotopic and fluorometric techniques to measure the activity of midbrain soluble enzyme, we have demonstrated that calcium activates tryptophan hydroxylase. The observed activation apparently results from an increased affinity of the enzyme for both its substrate, tryptophan, and the cofactor 2-amino-4-hydroxy-6-methyl-5,6,7,8-tetrahydropteridine (6-MPH₄). The calcium activation of tryptophan hydroxylase appears to be specific for both enzyme and effector: other brain neurotransmitter biosynthetic enzymes, such as aromatic amino acid decarboxylase(s) and tyrosine hydroxylase, are not affected by calcium (at concentrations ranging from 0.01 mM to 2.0 mM); other divalent cations, such as Ba⁺⁺, Mg⁺⁺, and Mn⁺⁺, have no activating effect on tryptophan hydroxylase. This work suggests that increases in brain serotonin biosynthesis induced by neural activation may be due to influx of Ca⁺⁺ associated with membrane depolarization and resulting activation of nerve ending tryptophan hydroxylase.     

PROPERTIES OF PARTIALLY PURIFIED PIG BRAIN STEM TRYPTOPHAN HYDROXYLASE

—Tryptophan hydroxylase form pig brain has been purified using a method which involved sonic disintegration of a whole homogenate, ammonium sulphate fractionation, hydroxylapatite fractionation, column chromatography on Sephadex G-100 or G-200 and finally electrophoresis on poly-acrylamide gel. The enzyme was stabilized during purification by tryptophan and dithiothreitol. The partially purified enzyme has a molecular weight of 55,000-60,000 as measured by gel-filtration. The K_m of the soluble partially purified enzyme was 0-4 mm , which differed significantly from that of the particulate enzyme (0·02mm ). Enzyme activity was not stimulated by ferrous ion. However, it was inhibited by the chelating agents 8-hydroxyquinoline, O-phenanthroline and EDTA. In contrast to dopamine, high concentration of tryptophan (10 mm ), 5-hydroxytryptamine, tryptamine and tyramine at 0-5 mm concentration did not inhibit the enzyme in the presence of dimethyltetrahydropterin (DMPH4). A number of monoamine oxidase inhibitors, phenelzine, pheniprazine and chlorgyline at 1 mm strongly inhibit the formation of 5-hydroxytryptamine. Evidence is presented for the presence of an endogenous inhibitor of tryptophan hydroxylase.     

Short-term effect of stress on tyrosine hydroxylase activity

The short-term influences of stress on the activities of tyrosine hydroxylase in vivo and in vitro were examined in mice. The in vivo tyrosine hydroxylase activity was estimated by the rate of dopa accumulation which was measured at 30 min after the injection of NSD-1015 (100 mg kg), an aromatic l-amino acid decarboxylase inhibitor, intraperitoneally and was compared with tyrosine hydroxylase activity measured in vitro. For the in vivo assay, both the accumulation of dopa (tyrosine hydroxylase activity) and that of 5-hydroxytryptophan (tryptophan hydroxylase activity) and the levels of monoamines and the metabolites (noradrenalin, adrenalin, dopamine, normetanephrine, 3-methoxytyramine and serotonin) and those of precursor amino acids, tyrosine and tryptophan, were investigated in ten different brain regions and in adrenals. The amount of dopa accumulation in the brain as a consequence of decarboxylase inhibition, in vivo tyrosine hydroxylase activity, was significantly increased by stress, in nerve terminals (striatum, limbic brain, hypothalamus, cerebral cortex and cerebellum) and also in adrenals. The effect of stress on tyrosine hydroxylase activity in vitro at a subsaturating concentration of 6-methyltetrahydropterin cofactor was also observed in nerve terminals (striatum, limbic brain, hypothalamus, and cerebral cortex). The amount of 5-hydroxytryptophan accumulation, the in vivo tryptophan hydroxylase activity, was also significantly increased in bulbus olfactorius, limbic brain, cerebral cortex, septum and lower brain stem. The influence of stress was also observed on the levels of precursor amino acids, tyrosine and tryptophan and monoamines in specific brain parts. These results suggest that the stress influences both catecholaminergic neurons and serotonergic neurons in nerve terminals in the brain. This effect was also observed on tyrosine hydroxylase activity in vitro in nerve terminals. However, in adrenals, the influence by stress was not observed on the in vitro activity, although dopa accumulation was increased.     

Mutagen sensitivity of kynureninase mutants of the nematode Caenorhabditis elegans

Summary Mutants in the gene flu-2 of the free-living nematode Caenorhabditis elegans are characterised by an altered autofluorescence of the intestine cells, from the light blue of wild-type to a dull green colour. The properties of flu-2 mutants have been investigated. L-kynureninase activity has been detected in wildtype C. elegans. The flu-2 mutants have markedly reduced kynureninase activity, as predicted earlier from chromatographic analysis of trptophan catabolites of wild-type and mutant worms. Associated with this enzymatic block, all flu-2 mutants have enhanced sensitivity to ethyl methane sulfonate (EMS) and -rays.     

Effect of intraventricular injection of 5,7-dihydroxytryptamine on regional tryptophan hydroxylase of rat brain

5,6-DIHYDROXYTRYPTAMINE has been shown to cause selective degeneration of serotonergic neurons in the central nervous sytem (BAUMGARTEN, LACHENMAYER and SCHLOSSBERGER, 1972b). This degeneration is accompanied by depletion of serotonin (BAUMGARTEN et al., 1971; 1972a) and loss of tryptophan hydroxylase activity (VICTOR, BAUMGARTEN and LOVENBERG, 1973) in certain regions of the brain. In the current experiments, the effect of 5,7-dihydroxytryptamine (another dihydroxylated tryptamine derivative) on tryptophan hydroxylase activity has been examined. Since tryptophan hydroxylase is the rate-limiting enzyme in serotonin biosynthesis and has a similar distribution to that of serotonin in the brain, it is used as a biochemical marker of serotonergic neurons, Recent experiments also indicate that 5,7-dihydroxytryptamine causes morphological damage to serotonergic neurons of the central nervous system (BAUMGARTEN and LACHENMAYER, 1972).     

Substrate regulation of serotonin and dopamine synthesis in <Emphasis Type="Italic">Drosophila</Emphasis>

In Drosophila melanogaster, serotonin (5-hydroxytryptamine, 5-HT) is required for both very early non-neuronal developmental events, and in the CNS as a neurotransmitter to modulate behavior. 5-HT is synthesized, at least in part, by the actions of Drosophila tryptophan-phenylalanine hydroxylase (DTPH), a dual function enzyme that hydroxylates both phenylalanine and tryptophan. DTPH is expressed in numerous tissues as well as dopaminergic and serotonergic neurons, but it does not necessarily function as both enzymes in these tissues. Deficiencies in DTPH could affect the production of dopamine and serotonin, and thus dopaminergic and serotonergic signaling pathways. In this paper, we show that DTPH exhibits differential hydroxylase activity based solely on substrate. When DTPH uses phenylalanine as a substrate, regulatory control (end product inhibition, decreased PAH activity following phosphorylation, catecholamine inhibition) is observed that is not seen when the enzyme uses tryptophan as a substrate. These studies suggest that regulation of DTPH enzymatic activity occurs, at least in part, through the actions of its substrate.