Tryptophan 5-monooxygenase from mouse mastocytoma P815. A simple purification and general properties

Dorsal raphe neuroinflammation promotes dramatic behavioral stress dysregulation

Impulsivity, risk-taking behavior, and elevated stress responsivity are prominent symptoms of mania, a behavioral state common to schizophrenia and bipolar disorder. Though inflammatory processes activated within the brain are involved in the pathophysiology of both disorders, the specific mechanisms by which neuroinflammation drives manic behavior are not well understood. Serotonin cell bodies originating within the dorsal raphe (DR) play a major role in the regulation of behavioral features characteristic of mania. Therefore, we hypothesized that the link between neuroinflammation and manic behavior may be mediated by actions on serotonergic neurocircuitry. To examine this, we induced local neuroinflammation in the DR by viral delivery of Cre recombinase into interleukin (IL)-1β(XAT) transgenic male and female mice, resulting in overexpressing of the proinflammatory cytokine, IL-1β. For assertion of brain-region specificity of these outcomes, the prefrontal cortex (PFC), as a downstream target of DR serotonergic projections, was also infused. Inflammation within the DR, but not the PFC, resulted in a profound display of manic-like behavior, characterized by increased stress-induced locomotion and responsivity, and reduced risk-aversion/fearfulness. Microarray analysis of the DR revealed a dramatic increase in immune-related genes, and dysregulation of genes important in GABAergic, glutamatergic, and serotonergic neurotransmission. Behavioral and physiological changes were driven by a loss of serotonergic neurons and reduced output as measured by high-performance liquid chromatography, demonstrating inflammation-induced serotonergic hypofunction. Behavioral changes were rescued by acute selective serotonin reuptake inhibitor treatment, supporting the hypothesis that serotonin dysregulation stemming from neuroinflammation in the DR underlies manic-like behaviors.

Experimentally calibrated computational chemistry of tryptophan hydroxylase: trans influence, hydrogen-bonding, and 18-electron rule govern O2-activation

Insight into the nature of oxygen activation in tryptophan hydroxylase has been obtained from density functional computations. Conformations of O(2)-bound intermediates have been studied with oxygen trans to glutamate and histidine, respectively. An O(2)-adduct with O(2)trans to histidine (O(his)) and a peroxo intermediate with peroxide trans to glutamate (P(glu)) were found to be consistent (0.57-0.59mm/s) with experimental Mössbauer isomer shifts (0.55mm/s) and had low computed free energies. The weaker trans influence of histidine is shown to give rise to a bent O(2) coordination mode with O(2) pointing towards the cofactor and a more activated O-O bond (1.33A) than in O(glu) (1.30A). It is shown that the cofactor can hydrogen bond to O(2) and activate the O-O bond further (from 1.33 to 1.38A). The O(his) intermediate leads to a ferryl intermediate (F(his)) with an isomer shift of 0.34mm/s, also consistent with the experimental value (0.25mm/s) which we propose as the structure of the hydroxylating intermediate, with the tryptophan substrate well located for further reaction 3.5A from the ferryl group. Based on the optimized transition states, the activation barriers for the two paths (glu and his) are similar, so a two-state scenario involving O(his) and P(glu) is possible. A structure of the activated deoxy state which is high-spin implies that the valence electron count has been lowered from 18 to 16 (glutamate becomes bidentate), giving a "green light" that invites O(2)-binding. Our mechanism of oxygen activation in tryptophan hydroxylase does not require inversion of spin, which may be an important observation.

Identification by hydrogen/deuterium exchange of structural changes in tyrosine hydroxylase associated with regulation

The activity of tyrosine hydroxylase is regulated by reversible phosphorylation of serine residues in an N-terminal regulatory domain and catecholamine inhibition at the active site. Catecholamines such as dopamine bind very tightly to the resting enzyme; phosphorylation of Ser40 decreases the affinity for catecholamines by 3 orders of magnitude. The effects of dopamine binding and phosphorylation of Ser40 on the kinetics of deuterium incorporation into peptide bonds were examined by mass spectrometry. When dopamine is bound, three peptic peptides show significantly slower deuterium incorporation, 35-41 and 42-71 in the regulatory domain and 295-299 in the catalytic domain. In the phosphorylated enzyme, peptide 295-299 shows more rapid incorporation of deuterium, while 35-41 and 42-71 can not be detected. These results are consistent with tyrosine hydroxylase existing in two different conformations. In the closed conformation, the regulatory domain lies across the active site loop containing residues 295-298; this is stabilized when dopamine is bound in the active site. In the open conformation, the regulatory domain has moved out of the active site, allowing substrate access; this conformation is favored by phosphorylation of Ser40.

Characterization of metal ligand mutants of phenylalanine hydroxylase: Insights into the plasticity of a 2-histidine-1-carboxylate triad

The iron atom in the nonheme iron monooxygenase phenylalanine hydroxylase is bound on one face by His285, His290, and Glu330. This arrangement of metal ligands is conserved in the other aromatic amino acid hydroxylases, tyrosine hydroxylase and tryptophan hydroxylase. A similar 2-His-1-carboxylate facial triad of two histidines and an acidic residue are the ligands to the iron in other nonheme iron enzymes, including the alpha-ketoglutarate-dependent hydroxylases and the extradiol dioxygenases. Previous studies of the effects of conservative mutations of the iron ligands in tyrosine hydroxylase established that there is some plasticity in the nature of the ligands and that the three ligands differ in their sensitivity to mutagenesis. To determine the generality of this finding for enzymes containing a 2-His-1-carboxylate facial triad, the His285, His290, and Glu330 in rat phenylalanine hydroxylase were mutated to glutamine, glutamate, and histidine. All of the mutant proteins had low but measurable activities for tyrosine formation. In general, mutation of Glu330 had the greatest effect on activity and mutation of His290 the least. All of the mutations resulted in an excess of tetrahydropterin oxidized relative to tyrosine formation, with mutation of His285 having the greatest effect on the coupling of the two partial reactions. The H285Q enzyme had the highest activity as tetrahydropterin oxidase at 20% the wild-type value. All of the mutations greatly decreased the affinity for iron, with mutation of Glu330 the most deleterious. The results complement previous results with tyrosine hydroxylase in establishing the plasticity of the individual iron ligands in this enzyme family.

Influence of human tryptophan hydroxylase 2 N- and C-terminus on enzymatic activity and oligomerization

Tryptophan hydroxylase (TPH) catalyses the first and rate limiting step in the biosynthesis of the neurotransmitter serotonin. There are two TPH isoenzymes in humans, encoded by two different genes: TPH1 and the recently described TPH2. We have expressed both human enzymes and various deletion mutants of TPH2 (DeltaN44, DeltaC17, DeltaC19, DeltaC51) in COS7 cells. TPH1 and 2 displayed different kinetic properties with a lower K(m) value of TPH1. Removal of 44 amino acids from the N-terminus of TPH2 resulted in a 3-4-fold increased V(max), which indicates a strong inhibitory function of this part on the enzymes activity. TPH1 and 2 were able to form homooligomers and also heterooligomers with each other. The different deletion mutants (DeltaC17, DeltaC19 and DeltaC51), which lack the putative C-terminal leucine zipper tetramerization domain, existed as monomeric enzymes. While short deletions (DeltaC17 and DeltaC19) hardly changed V(max) values, the DeltaC51 mutant lost 99% of TPH activity. These data identify a region between the C-terminal oligomerization domain and the catalytic domain, which is indispensable for TPH2 activity.

Developmental role of tryptophan hydroxylase in the nervous system

The serotonin 5-hydroxytryptamine (5-HT) neurotransmitter system contributes to various physiological and pathological conditions. 5-HT is the first neurotransmitter for which a developmental role was suspected. Tryptophan hydroxylase (TPH) catalyzes the rate-limiting reaction in the biosynthesis of 5-HT. Both TPH1 and TPH2 have tryptophan hydroxylating activity. TPH2 is abundant in the brain, whereas TPH1 is mainly expressed in the pineal gland and the periphery. However, TPH1 was found to be expressed predominantly during the late developmental stage in the brain. Recent advances have shed light on the kinetic properties of each TPH isoform. TPH1 showed greater affinity for tryptophan and stronger enzymic activity than TPH2 under conditions reflecting those in the developing brain stem. Transient alterations in 5-HT homeostasis during development modify the fine wiring of brain connections and cause permanent changes to adult behavior. An increasing body of evidence suggests the involvement of developmental brain disturbances in psychiatric disorders. These findings have revived a long-standing interest in the developmental role of 5-HT-related molecules. This article summarizes our understanding of the kinetics and possible neuronal functions of each TPH during development and in the adult.

Distinctive iron requirement of tryptophan 5-monooxygenase: TPH1 requires dissociable ferrous iron

A peripheral type of tryptophan 5-monooxygenase (EC 1.14.16.4), TPH1, is very unstable in vitro, but the inactivation was reversible and full reactivation occurs upon anaerobic incubation with a high concentration of dithiothreitol (DTT, 15 mM). In this study, distinctive iron requirement of TPH1 was revealed through analysis of the enzyme's inactivation and activation by DTT. For this purpose, all the glasswares, plastics, Sephadex G-25 gels, and reagents including protein solutions had been treated with metal chelators, and apo-TPH was prepared by treatment with EDTA. Apo-TPH thus prepared exclusively required free Fe2+ for its catalytic activity; 10(-8) M was enough under the strict absence of Fe3+ but 10(-12) M was too low. No other metal ions including Fe3+ were effective. It appeared that Fe3+ bound to the enzyme with a higher affinity than Fe2+, resulting in the inactivation. Ascorbate, a non-thiol reducing agent, did not substitute DTT in the activation of TPH1, but enhanced the Fe2+-dependent activity of apo-TPH as effectively as DTT. Thus, the DTT-activation was essentially substituted by preparation of apo-TPH by the EDTA treatment and the assay of apo-TPH in the presence of Fe2+ and ascorbate. The activation of TPH1 by incubation with DTT was accompanied by exposure of 9 sulfhydryls out of the total 10 cysteine residues, but the cleavage of disulfide bonds seemed not to be crucial, even if it occurred. The effect of DTT was substituted by some other sulfhydryls whose structure was analogous to that of commonly used metal chelators. Based on these observations, the following dual roles of DTT are proposed: (1) in the activation of TPH, DTT removes inappropriate bound iron (Fe3+) as a chelator, keeping Fe3+ away from the enzyme's binding site which needs to bind Fe2+ for the catalytic activity, and (2) in both the activation and reaction processes, DTT prevents oxidation of Fe2+ to Fe3+ as a reducing agent.

Different properties of the central and peripheral forms of human tryptophan hydroxylase

Tryptophan hydroxylase (TPH) catalyses the rate-limiting reaction in the biosynthesis of serotonin. In humans, two different TPH genes exist, located on chromosomes 11 and 12, respectively, and encoding two enzymes (TPH1 and TPH2) with an overall sequence identity of 71%. We have expressed both enzymes as various fusion proteins in Escherichia coli and using an in vitro transcription/translation system, and compared their solubility and kinetic properties. TPH2 is more soluble than TPH1, has a higher molecular weight and different kinetic properties, including a lower catalytic efficiency towards phenylalanine than TPH1. Both enzymes are phosphorylated by cAMP-dependent protein kinase A. TPH2 was phosphorylated at Ser19, a phosphorylation site not present in TPH1. The differences between TPH1 and TPH2 have important implications for the regulation of serotonin production in the brain and the periphery and may provide an explanation for some of the diverging results reported for TPH from different sources in the past.

Expression and purification of human tryptophan hydroxylase from Escherichia coli and Pichia pastoris

Tryptophan hydroxylase (TPH) from several mammalian species has previously been cloned and expressed in bacteria. However, due to the instability of wild type TPH, most successful attempts have been limited to the truncated forms of this enzyme. We have expressed full-length human TPH in large amounts in Escherichia coli and Pichia pastoris and purified the enzyme using new purification protocols. When expressed as a fusion protein in E. coli, the maltose-binding protein-TPH (MBP-TPH) fusion protein was more soluble than native TPH and the other fusion proteins and had a 3-fold higher specific activity than the His-Patch-thioredoxin-TPH and 6xHis-TPH fusion proteins. The purified MBP-TPH had a V(max) of 296 nmol/min/mg and a K(m) for L-tryptophan of 7.5+/-0.7 microM, compared to 18+/-5 microM for the partially purified enzyme from P. pastoris. To overcome the unfavorable properties of TPH, the stabilizing effect of different agents was investigated. Both tryptophan and glycerol had a stabilizing effect, whereas dithiothreitol, (6R)-5,6,7,8,-tetrahydrobiopterin, and Fe(2+) inactivated the enzyme. Irrespective of expression conditions, both native TPH expressed in bacteria or yeast, or TPH fusion proteins expressed in bacteria exhibited a strong tendency to aggregate and precipitate during purification, indicating that this is an intrinsic property of this enzyme. This supports previous observations that the enzyme in vivo may be stabilized by additional interactions.

A unique central tryptophan hydroxylase isoform

Serotonin (5-hydroxytryptophan, 5-HT) is a neurotransmitter synthesized in the raphe nuclei of the brain stem and involved in the central control of food intake, sleep, and mood. Accordingly, dysfunction of the serotonin system has been implicated in the pathogenesis of psychiatric diseases. At the same time, serotonin is a peripheral hormone produced mainly by enterochromaffin cells in the intestine and stored in platelets, where it is involved in vasoconstriction, haemostasis, and the control of immune responses. Moreover, serotonin is a precursor for melatonin and is therefore synthesized in high amounts in the pineal gland. Tryptophan hydroxylase (TPH) catalyzes the rate limiting step in 5-HT synthesis. Until recently, only one gene encoding TPH was described for vertebrates. By gene targeting, we functionally ablated this gene in mice. To our surprise, the resulting animals, although being deficient for serotonin in the periphery and in the pineal gland, exhibited close to normal levels of 5-HT in the brain stem. This led us to the detection of a second TPH gene in the genome of humans, mice, and rats, called TPH2. This gene is predominantly expressed in the brain stem, while the classical TPH gene, now called TPH1, is expressed in the gut, pineal gland, spleen, and thymus. These findings clarify puzzling data, which have been collected over the last decades about partially purified TPH proteins with different characteristics and justify a new concept of the serotonin system. In fact, there are two serotonin systems in vertebrates, independently regulated and with distinct functions.

Proteasome-driven turnover of tryptophan hydroxylase is triggered by phosphorylation in RBL2H3 cells, a serotonin producing mast cell line

We previously demonstrated in mast cell lines RBL2H3 and FMA3 that tryptophan hydroxylase (TPH) undergoes very fast turnover driven by 26S-proteasomes [Kojima, M., Oguro, K., Sawabe, K., Iida, Y., Ikeda, R., Yamashita, A., Nakanishi, N. & Hasegawa, H. (2000) J. Biochem (Tokyo) 2000, 127, 121-127]. In the present study, we have examined an involvement of TPH phosphorylation in the rapid turnover, using non-neural TPH. The proteasome-driven degradation of TPH in living cells was accelerated by okadaic acid, a protein phosphatase inhibitor. Incorporation of 32P into a 53-kDa protein, which was judged to be TPH based on autoradiography and Western blot analysis using anti-TPH serum and purified TPH as the size marker, was observed in FMA3 cells only in the presence of both okadaic acid and MG132, inhibitors of protein phosphatase and proteasome, respectively. In a cell-free proteasome system constituted mainly of RBL2H3 cell extracts, degradation of exogenous TPH isolated from mastocytoma P-815 cells was inhibited by protein kinase inhibitors KN-62 and K252a but not by H89. Consistent with the inhibitor specificity, the same TPH was phosphorylated by exogenous Ca2+/calmodulin-dependent protein kinase II in the presence of Ca2+ and calmodulin but not by protein kinase A (catalytic subunit). TPH protein thus phosphorylated by Ca2+/calmodulin-dependent protein kinase II was digested more rapidly in the cell-free proteasome system than was the nonphosphorylated enzyme. These results indicated that the phosphorylation of TPH was a prerequisite for proteasome-driven TPH degradation.

A monoclonal antibody to tryptophan hydroxylase: applications and identification of the epitope

Recombinant rabbit tryptophan hydroxylase (TPH) was expressed in Escherichia coli and purified from inclusion bodies by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). A mouse monoclonal antibody and rabbit and sheep polyclonal antibodies were generated. In immunohistochemical studies of formaldehyde-fixed primate brain, the monoclonal strongly labeled not only cell bodies in the raphe nuclei but also fibers in the cerebral cortex. Truncation mutants and peptide pre-competition were used to localize the epitope to E103SVPWFP109. Although the primary sequences of TPH encoded by mRNAs from brain and pineal gland are identical, differences in the immunoreactivity of TPH protein from these two sources were observed in blot immunolabeling studies. TPH immunoreactivity migrated as an M(r) approximately equal 56000 band in each of the tissues except human pineal glands, in which the TPH reactivity was approximately 3 kDa lower. In addition, the relative intensities of TPH immunolabeling across the four tissues differed among these antibodies and a previously described monoclonal antibody against phenylalanine hydroxylase (PH8), which cross-reacts with TPH. Whereas PH8 exhibited roughly equivalent TPH reactivity per protein in both tissues from both species, TPH from human and rat raphe nuclei was preferentially recognized by the present monoclonal. By contrast, the affinity-purified sheep polyclonal antibody reacted preferentially with TPH from human and rat pineal gland, and the affinity-purified rabbit polyclonal antibody appeared to selectively recognize TPH from human pineal gland.

Tetrahydropterin-dependent amino acid hydroxylases

Phenylalanine hydroxylase, tyrosine hydroxylase, and tryptophan hydroxylase constitute a small family of monooxygenases that utilize tetrahydropterins as substrates. When from eukaryotic sources, these enzymes are composed of a homologous catalytic domain to which are attached discrete N-terminal regulatory domains and short C-terminal tetramerization domains, whereas the bacterial enzymes lack the N-terminal and C-terminal domains. Each enzyme contains a single ferrous iron atom bound to two histidines and a glutamate. Recent mechanistic studies have begun to provide insights into the mechanisms of oxygen activation and hydroxylation. Although the hydroxylating intermediate in these enzymes has not been identified, the iron is likely to be involved. Reversible phosphorylation of serine residues in the regulatory domains affects the activities of all three enzymes. In addition, phenylalanine hydroxylase is allosterically regulated by its substrates, phenylalanine and tetrahydrobiopterin.

The aromatic amino acid hydroxylases

The enzymes phenylalanine hydroxylase, tyrosine hydroxylase, and tryptophan hydroxylase constitute the family of pterin-dependent aromatic amino acid hydroxylases. Each enzyme catalyzes the hydroxylation of the aromatic side chain of its respective amino acid substrate using molecular oxygen and a tetrahydropterin as substrates. Recent advances have provided insights into the structures, mechanisms, and regulation of these enzymes. The eukaryotic enzymes are homotetramers comprised of homologous catalytic domains and discrete regulatory domains. The ligands to the active site iron atom as well as residues involved in substrate binding have been identified from a combination of structural studies and site-directed mutagenesis. Mechanistic studies with nonphysiological and isotopically substituted substrates have provided details of the mechanism of hydroxylation. While the complex regulatory properties of phenylalanine and tyrosine hydroxylase are still not fully understood, effects of regulation on key kinetic parameters have been identified. Phenylalanine hydroxylase is regulated by an interaction between phosphorylation and allosteric regulation by substrates. Tyrosine hydroxylase is regulated by phosphorylation and feedback inhibition by catecholamines.

Immunohistochemical localization of tryptophan hydroxylase in the human and rat gastrointestinal tracts

Because few previous studies have shown the immunohistochemical localization of tryptophan 5-hydroxylase (TPH) in the gastrointestinal tract, we developed a specific antibody against TPH purified from mouse mastocytoma P-815 and stained human and rat gastrointestinal tracts. The specificity of the antibody was examined by Western blotting and by immunohistochemistry in brain sections. Human ileum and colon specimens, rat stomach, duodenum, jejunum, ileum and colon specimens, with and without colchicine treatment were prepared for immunohistochemistry. Immunoelectron microscopic double staining of TPH and serotonin/chromogranin A and immunofluorescence double staining of TPH and serotonin were performed to identify the cell types. Epithelial enterochromaffin (EC) cells, mast cells in the lamina propria and submucosa, and varicose fibers in the submucosa and muscle layer showed positive immunoreactivity in all segments examined from human and normal rat specimens. In colchicine-treated rat specimens, nerve cell bodies in the myenteric plexus were stained. Because the antibody does not cross react with tyrosine hydroxylase as defined in Western blotting or brain sections, these positive structures may contain TPH. The present results show evidence that EC cells, mast cells, and nerve cell bodies and fibers in the gastrointestinal tracts of both the human and the rat contain TPH and therefore may have the ability to synthesize serotonin from tryptophan.

Characterization of a stable form of tryptophan hydroxylase from the human parasite Schistosoma mansoni

A cDNA (Schistosoma mansoni tryptophan hydroxylase; SmTPH) encoding a protein homologous to tryptophan hydroxylase, the enzyme that catalyzes the rate-limiting step in the biosynthesis of serotonin, was cloned from the human parasite Schistosoma mansoni. Bacterial expression of SmTPH as a histidine fusion protein produced soluble active enzyme, which was purified to apparent homogeneity and a final specific activity of 0.17 micromol/min/mg of protein. The purified enzyme was found to be a tetramer of approximately 240 kDa with a subunit size of 58 kDa. Several of the biochemical and kinetic properties of SmTPH were similar to those of mammalian tryptophan hydroxylase. Unlike the mammalian enzyme, however, SmTPH was found to be stable at 37 degrees C, its t((1)/(2)) being nearly 23 times higher than that of a similarly expressed rabbit tryptophan hydroxylase. A semiquantitative reverse transcription polymerase chain reaction showed that the level of SmTPH mRNA in a larval stage of the parasite (cercaria) is 2.5 times higher than in adult S. mansoni, suggesting possible differences in the level of enzyme expression between the two developmental stages. This study demonstrates for the first time the presence of a functional tryptophan hydroxylase in a parasitic helminth and further suggests that the parasites are capable of synthesizing serotonin endogenously.

Iron dependence of tryptophan hydroxylase activity in RBL2H3 cells and its manipulation by chelators

Tryptophan hydroxylase requires Fe2+ for in vitro enzyme activity. In this study, the intracellular activity of tryptophan hydroxylase was assessed by applying 3-hydroxybenzylhydrazine (NSD-1015), an inhibitor of aromatic l-amino acid decarboxylase, to monolayer cultures of RBL2H3 cells, a serotonin producing mast cell line. The effect of manipulating intracellular 'free' iron levels on enzyme activity was analyzed by administration of iron chelators. Desferrioxamine (DFO) suppressed the intracellular enzyme activity. Salicylaldehyde isonicotinoyl hydrazone (SIH) also suppressed enzyme activity, but stimulated it when administered in the Fe-bound form. Hemin also stimulated enzyme activity, which progressively increased over several hours to more than sixfold the initial level. DFO and SIH inhibited the hemin stimulatory effect when administered simultaneously with hemin. Both suppression and stimulation with these chelators took place without a significant decrease or increase in the amount of enzyme. These results indicate that there was an inadequate supply of Fe2+ in the cells to support full activity of tryptophan hydroxylase.

A continuous fluorescence assay for tryptophan hydroxylase

A continuous fluorometric assay for tryptophan hydroxylase activity based on the different spectral characteristics of tryptophan and 5-hydroxytryptophan is presented. Hydroxylation of tryptophan at the 5-position results in a large increase in the fluorescence of the molecule. The assay selectively monitors the fluorescence yield of 5-hydroxytryptophan by exciting the reaction mix at 300 nm. The rate of increase of the emission signal was found to be directly proportional to the enzyme concentration. Inner filter effects due to quinonoid dihydropterin accumulation were eliminated by the inclusion of a thiol reductant. Activity measured using this assay method was found to be the same as that determined by established discontinuous HPLC assay methods. The application of the assay to routine activity measurements and to steady-state determinations with the substrates tryptophan and tetrahydropterin is described.

Advances in the molecular characterization of tryptophan hydroxylase

The neurotransmitter serotonin has been implicated in numerous physiological functions and pathophysiological disorders. The hydroxylation of the aromatic amino acid tryptophan is rate-limiting in the synthesis of serotonin. Tryptophan hydroxylase (TPH), as the rate-limiting enzyme, determines the concentrations of serotonin in vivo. Relative serotonin concentrations are clearly important in neural transmission, but serotonin has also been reported to function as a local antioxidant. Identification of the mechanisms regulating TPH activity has been hindered by its low levels in tissues and the instability of the enzyme. Several TPH expression systems have been developed to circumvent these problems. In addition, eukaryotic expressions systems are currently being developed and represent a new avenue of research for identifying TPH regulatory mechanisms. Recombinant DNA technology has enabled the synthesis of TPH deletions, chimeras, and point mutations that have served as tools for identifying structural and functional domains within TPH. Notably, the experiments have proven long-held hypotheses that TPH is organized into N-terminal regulatory and C-terminal catalytic domains, that serine-58 is a site for PKA-mediated phosphorylation, and that a C-terminal leucine zipper is involved in formation of the tetrameric holoenzyme. Several new findings have also emerged regarding regulation of TPH activity by posttranslational phosphorylation, kinetic inhibition, and covalent modification. Inhibition of TPH by L-DOPA may have implications for depression in Parkinson's disease (PD) patients. In addition, TPH inactivation by nitric oxide may be involved in amphetamine-induced toxicity. These regulatory concepts, in conjunction with new systems for studying TPH activity, are the focus of this article.

Expression and characterization of the catalytic core of tryptophan hydroxylase

Wild type rabbit tryptophan hydroxylase (TRH) and two truncated mutant proteins have been expressed in Escherichia coli. The wild type protein was only expressed at low levels, whereas the mutant protein lacking the 101 amino-terminal regulatory domain was predominantly found in inclusion bodies. The protein that also lacked the carboxyl-terminal 28 amino acids, TRH102-416, was expressed as 30% of total cell protein. Analytical ultracentrifugation showed that TRH102-416 was predominantly a monomer in solution. The enzyme exhibited an absolute requirement for iron (ferrous or ferric) for activity and did not turn over in the presence of cobalt or copper. With either phenylalanine or tryptophan as substrate, stoichiometric formation of the 4a-hydroxypterin was found. Steady state kinetic parameters were determined with both of these amino acids using both tetrahydrobiopterin and 6-methyltetrahydropterin.

Structure/function analysis of the domains required for the multimerisation of phenylalanine hydroxylase

Phenylalanine hydroxylase (PAH) exists as an equilibrium of dimers and tetramers. However, there is little information concerning the inter- or intra-molecular interactions required for enzyme quaternary structure. It is predicted that the formation of a PAH tetramer will require at least two points of contact per enzyme subunit. Sequence analysis has suggested the existence of a C-terminal domain with characteristics of a leucine zipper or a variant of this called a coiled-coil. By deletion of 24 amino acids from the C-terminus or conversion of leucine 448 to an alanine residue, we have shown that this putative leucine zipper/coiled-coil domain is involved in the assembly of an active enzyme tetramer from dimers. The removal of this C-terminal domain of PAH reduces enzyme activity but does not abolish it. Furthermore, we report that an alanine 447 to aspartate mutation associated with phenylketonuria may affect subunit assembly which suggests the formation of enzyme tetramers is physiologically relevant. Our analysis of subunit interactions in vivo, show that in the absence of the C-terminal coiled-coil domain, dimers can form and this is only possible when the N-terminal domain is present. This provides the first evidence that N-terminal domain is required for multimerisation. We propose that the N-terminal regulatory domain in conjunction with the C-terminal coiled-coil domain, mediates the formation of fully active enzyme tetramers.

Carboxyl terminal deletion analysis of tryptophan hydroxylase

Tryptophan hydroxylase (TPH) catalyzes the rate-limiting step in the synthesis of serotonin and participates (in a non-rate-limiting fashion) in melatonin biosynthesis. In rabbit, TPH exists as a tetramer of four identical 51007 dalton (444 amino acids) protein subunits. An intersubunit binding domain responsible for tetramer formation of TPH was identified by assessing the role of a carboxyl terminal leucine heptad and 4-3 hydrophobic repeat. These repeats are conserved in all of the aromatic amino acid hydroxylases and have been shown to be required for the assembly of tyrosine hydroxylase tetramers. Polymerase chain reaction was utilized to create three TPH carboxyl terminal deletions (C delta8, C delta12 and C delta17) that sequentially remove members of the leucine heptad and 4-3 hydrophobic repeat. Each deletion and full-length recombinant TPH was expressed in bacteria to obtain soluble enzyme extracts for subsequent activity and structural analysis. It was found that removal of 8, 12 or 17 amino acids from the carboxyl terminus of TPH did not significantly alter enzymatic activity when compared to full-length recombinant TPH. However, the macromolecular structure of the deletions was dramatically affected as determined by dimeric and monomeric profiles on size exclusion chromatography. It can be concluded that amino acids 428-444 (the C-terminal 17 amino acids) comprise an intersubunit binding domain that is required for tetramer formation of TPH, but that tetramer assembly is not essential for full enzymatic activity.

SP-22 is a thioredoxin-dependent peroxide reductase in mitochondria

SP-22 is a mitochondrial antioxidant protein in bovine adrenal cortex. The protein is homologous to thioredoxin peroxidase and other antioxidant proteins. It protects radical-sensitive enzymes from oxidative damage by a radical-generating system (Fe2+/dithiothreitol) in the presence of a small amount of serum. In this study we purified a second mitochondrial protein with Mr 11,777, which cooperates with SP-22 to protect glutamine synthetase and other proteins from Fe2+/dithiothreitol-mediated damage. Without SP-22, the protein had no protecting activity. We determined amino acid and nucleotide sequences of the protein and its cDNA, respectively, and found that it was a protein of the thioredoxin family. The protein, designated as mt-Trx (mitochondrial thioredoxin), had a presequence composed of 59 amino acids that seemed to be a mitochondrial targeting signal. Mitochondrial extract prepared from adrenal cortex contained NADPH-dependent 5,5'dithiobis(2-nitrobenzoic acid) (Nbs2) reductase activity. The enzyme was thought to have thioredoxin reductase activity, since the Nbs2-reducing activity was stimulated by mt-Trx. We partially purified the Nbs2 reductase from bovine adrenocortical mitochondria. In the presence of the partially purified reductase, mt-Trx, and NADPH, SP-22 showed the activity to protect oxyhemoglobin against ascorbate-induced damage. Furthermore, with the three protein components (Nbs2 reductase, mt-Trx, and SP-22) NADPH was oxidized in the presence of hydrogen peroxide or tert-butyl hydroperoxide. The oxidation of NADPH was concomitant with the disappearance of an equimolar amount of hydrogen peroxide. Without any one of the protein components no hemoglobin-protecting and peroxide-dependent NADPH-oxidizing activities were observed. From these results we concluded that SP-22 is thioredoxin-dependent peroxide reductase or so-called thioredoxin peroxidase in mitochondria from the adrenal cortex.

A chimeric tyrosine/tryptophan hydroxylase. The tyrosine hydroxylase regulatory domain serves to stabilize enzyme activity

The neurotransmitter biosynthetic enzymes, tyrosine hydroxylase (TH), and tryptophan hydroxylase (TPH) are each composed of an amino-terminal regulatory domain and a carboxyl-terminal catalytic domain. A chimeric hydroxylase was generated by coupling the regulatory domain of TH (TH-R) to the catalytic domain of TPH (TPH-C) and expressing the recombinant enzyme in bacteria. The chimeric junction was created at proline 165 in TH and proline 106 in TPH because this residue is within a conserved five amino-acid span (ValProTrpPhePro) that defines the beginning of the highly homologous catalytic domains of TH and TPH. Radioenzymatic activity assays demonstrated that the TH-R/TPH-C chimera hydroxylates tryptophan, but not tyrosine. Therefore, the regulatory domain does not confer substrate specificity. Although the TH-R/TPH-C enzyme did serve as a substrate for protein kinase (PKA), activation was not observed following phosphorylation. Phosphorylation studies in combination with kinetic data provided evidence that TH-R does not exert a dominant influence on TPH-C. Stability assays revealed that, whereas TH exhibited a t1/2 of 84 min at 37 degrees C, TPH was much less stable (t1/2 = 28.3 min). The stability profile of TH-R/TPH-C, however, was superimposable on that of TH. Removal of the regulatory domain (a deletion of 165 amino acids from the N-terminus) of TH rendered the catalytic domain highly unstable, as demonstrated by a t1/2 of 14 min. The authors conclude that the regulatory domain of TH functions as a stabilizer of enzyme activity. As a corollary, the well-characterized instability of TPH may be attributed to the inability of its regulatory domain to stabilize the catalytic domain.

Regulation and crystallization of phosphorylated and dephosphorylated forms of truncated dimeric phenylalanine hydroxylase

Phenylalanine hydroxylase is regulated in a complex manner, including activation by phosphorylation. It is normally found as an equilibrium of dimeric and tetrameric species, with the tetramer thought to be the active form. We converted the protein to the dimeric form by deleting the C-terminal 24 residues and show that the truncated protein remains active and regulated by phosphorylation. This indicates that changes in the tetrameric quaternary structure of phenylalanine hydroxylase are not required for enzyme activation. Truncation also facilitates crystallization of both phosphorylated and dephosphorylated forms of the enzyme.

Characterization of yellowfin tuna (Thunnus albacares, Scombroidei) tryptophan hydroxylase

Tryptophan hydroxylase (EC 1.14, 16.4) was purified from yellowfin tuna liver and properties of this enzyme were compared with those of tryptophan hydroxylase from some other species (mouse mastocytoma and rat brain-stem). The molecular weight of the yellowfin tuna enzyme was estimated to be about 280,000 Da. This value is similar to that for the enzymes from mouse mastocytoma and rat brain-stem. On SDS-polyacrylamide gel electrophoresis analysis, yellowfin tuna enzyme was estimated to be about 96,000 Da. This value is different from that for the enzymes from mouse mastocytoma (53,000 Da) and rat brain-stem (59,000 Da) and suggests that yellowfin tuna enzyme may be a dimer of identical subunits of Mr 96,000 Da.

Tryptophan hydroxylase: purification by affinity chromatography on calmodulin-sepharose

Tryptophan hydroxylase (EC 1.14.16.4; L-tryptophan, tetrahydropteridine: oxygen oxidoreductase (5-hydroxylating)) from rat mesencephalic tegmentum has been purified by sequential chromatography on Blue-Sepharose, DE-52, and calmodulin-Sepharose. The hydroxylase is excluded from Blue-Sepharose and is eluted from DE-52 with a step-wise NaCl gradient. Tryptophan hydroxylase binds to calmodulin-Sepharose in the presence of calcium and is eluted with either EGTA or calmodulin itself, but not with tryptophan. The purification scheme is rapid (5-6 h) and yields an enzyme with a specific activity of 225 nmol 5-HTP/mg min, representing a 400-fold purification with 7% recovery. The tryptophan hydroxylase preparation was judged to be > 95% pure using the present isolation procedure.

Stimulation of tryptophan hydroxylase production in a serotonin-producing cell line (RBL2H3) by intracellular calcium mobilizing reagents

RBL2H3 cells showed a remarkable increase in their level of tryptophan hydroxylase (up to 25-fold), the rate-limiting enzyme in serotonin biosynthesis, by stimulation with intracellular calcium mobilizers A23187, thapsigargin, and tBuBHQ as well as by stimulation with an antigen in the presence of IgE. The increase in the enzyme protein was visualized by Western blot analysis using anti-tryptophan hydroxylase antiserum. The enzyme turnover (Hasegawa et al., FEBS Lett., 368 (1995) 151-154) was not slowed down during the rise in tryptophan hydroxylase. Actinomycin D prevented the stimulation-induced elevation of the enzyme. These findings strongly suggest that this stimulation was achieved by the accelerated biosynthesis of tryptophan hydroxylase.

Structure and function of the aromatic amino acid hydroxylases

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Elevated aromatic-L-amino acid decarboxylase in human carcinoid tumors

The carcinoid neoplasm is marked by excessive serotonin, synthesized by the conversion of tryptophan (Trp) to 5-hydroxytryptophan by tryptophan hydroxylase (TPH) (EC 1.14.16.4) and decarboxylation of 5-hydroxytryptophan by aromatic-L-amino acid decarboxylase (AAAD) (EC 4.1.1.28). Because almost no biochemical data were available on human carcinoid TPH and AAAD, we have characterized these enzymes as a preliminary step to developing mechanism-based agents selective against carcinoid tumors. TPH was detected in all fourteen carcinoids analyzed [Km = 185 +/- 17 microM (mean +/- SEM); Vmax = 2.4 +/- 1.2 nmol/hr/mg protein]. AAAD was detected in thirteen tumors (Km = 45 +/- 6.7 microM; Vmax = 11 +/- 2.0 nmol/min/mg protein). In a subset of hepatic metastatic tumors obtained with adjacent normal liver, the Km and Vmax of TPH (N = 6) and the Km of AAAD (N = 7) were comparable in both tissues. However, the Vmax of carcinoid AAAD was 50-fold higher (P < 0.002) than that in normal liver (13 +/- 3.1 vs 0.26 +/- 0.04 nmol/min/mg protein). Western immunoblot analysis indicated that AAAD polypeptide content of carcinoid tumor was > 20-fold higher than in adjacent normal liver. These results suggest that AAAD might be an appropriate target for enzyme-activated cytotoxic agents for carcinoid tumors.

Rapid turnover of tryptophan hydroxylase in serotonin producing cells: demonstration of ATP-dependent proteolytic degradation

A rapid and continuous proteolysis of tryptophan hydroxylase was demonstrated with two mast cell lines derived from rat basophilic leukemia cells (RBL2H3) and mouse mastocytoma (FMA3). Under conditions in which protein biosynthesis was arrested by administration of cycloheximide, the decay profile of tryptophan hydroxylase protein was traced by Western blot analysis. Incorporation of [35S]methionine and the chase experiment performed without interfering with the metabolic stage also showed that tryptophan hydroxylase had been cleaved rapidly. The half life of the enzyme was 11-15 min in RBL2H3 cells and 40-60 min in FMA3 cells, and the process was demonstrated to be dependent on intracellular ATP.

NF-Y activates mouse tryptophan hydroxylase transcription

Tryptophan hydroxylase catalyses the rate-limiting step in the biosynthesis of serotonin, a neurotransmitter which has been implicated in the etiologies of clinically important psychiatric illnesses. Tryptophan hydroxylase is expressed in a tissue-specific manner, but little is known about its transcriptional regulation. By analysing transcriptional activities of a set 5'-deletion constructs of promoter-reporter plasmids in P815-HTR mastocytoma cells, we found that transcription was activated by sequences between nucleotides -343 and -21. DNase I footprint analysis, using nuclear protein extracts from P815-HTR cells, revealed a protein-DNA interaction between nucleotides -77 and -46. A double stranded oligonucleotide, representing this binding site, specifically bound nuclear protein in a gel shift assay. Methylation interference analysis of this complex revealed that nuclear protein interacted with an inverted GGCCAAT element, which is a high-affinity binding motif for the transcription factor NF-Y (also known as CP1 or CBF). An NF-Y specific antibody abolished protein binding in a gel shift assay. Mutagenesis of specific base pairs abolished protein binding in vitro, and mutagenesis of the same base pairs in a reporter gene construct resulted in a 65% decrease in transcriptional activity. Our results suggest that the transcription factor NF-Y binds to a GGCCAAT motif in the tph proximal promoter and activates transcription.

Tryptophan hydroxylase can be present in mast cells and nerve fibers of the rat dura mater but only mast cells contain serotonin

Tryptophan hydroxylase-immunopositive (TPH-I) but not serotonin-I nerve fibers were observed in the rat dura mater. This tissue also contained numerous serotonin and TPH-I mast cells. The TPH appeared to be located in granules and/or enclosed in a juxta-nuclear organite. Westernblots showed that the TPH located in the dura mater is similar to the TPH of pineal gland but different from raphe TPH. According to the animal, both nerve fiber and mast cell TPH immunoreactivity was highly variable in intensity and in number of labelled elements. This variability might be due to the complex regulatory mechanisms of TPH as indicated by the presence of two types of mast cells.

Tetrahydro-6-biopterin is associated with tetrahydro-7-biopterin in primary murine mast cells

Murine bone marrow-derived mast cells proliferate in response to interleukin 3. In addition to 6-biopterin, 7-biopterin was identified in these cells by HPLC analysis of iodine oxidized extracts and by alkaline permanganate oxidation to the 6- and 7-carboxylic acids. 7-Biopterin comprised 31.9 (+/- 7.7)% of the total biopterin. It was absent in cells which were grown with of L-p-chlorophenylalanine, an inhibitor of tryptophan 5-mono-oxygenase. Both 6- and 7-biopterin were present in the cell as their tetrahydro forms. From these data we conclude that 7-biopterin, in contrast to e.g. brain tissue, regularly occurs as a normal metabolite in primary mast cells and that it is generated during hydroxylation of tryptophan.

Molecular cloning and characterization of cDNA encoding tryptophan hydroxylase from rat central serotonergic neurons

Tryptophan hydroxylase (TPH) from central serotonergic neurons in the dorsal raphe nucleus (DRN) and that from the endocrine pineal gland (PG) have been shown to exhibit difference biochemical characteristics. We further report here that the isoelectric point determined by chromatofocusing differs between TPH from the rat brainstem and PG. In addition, the levels of TPH mRNA are much greater in the PG than the DRN despite a higher enzymatic activity in the DRN. These data raise the question as to whether different forms of TPH may exist in the DRN and the PG. To address this question, we amplified TPH cDNAs by the polymerase chain reaction (PCR) using poly(A)+ RNA purified from both tissues. Several combinations of oligonucleotide primers encompassing different regions of the published coding sequence of rat pineal TPH were employed for this purpose. Subsequent analysis by gel electrophoresis and Southern blotting of PCR products indicated that DNA fragments of identical length were amplified from both sources. Furthermore, the nucleotide sequences of three independent subclones containing the putative full-length coding region of DRN TPH were determined and found to be identical to that of PG. In situ hybridization using the amplified cDNA as a probe demonstrated specific labeling within the DRN of the rat brain. These data support the hypothesis that tissue-specific differences in TPH characteristics result from differential post-translational events and clearly indicate that a TPH mRNA transcript identical in coding sequence to the PG form is expressed in the DRN.

Distinct forms of the protein kinase-dependent activator of tyrosine and tryptophan hydroxylases

Tyrosine and tryptophan hydroxylases are the key enzymes in the regulation of catecholamine and serotonin levels in neurons and other endocrine cells. Among the mechanisms proposed for the modulation of activity, phosphorylation of the enzyme is believed to be of functional significance with respect to the stimulus-response coupling, but the precise mechanism is unknown. Here, we show the existence of multiple, distinct forms of the 14-3-3 activator protein, a neuronal protein essential for activation of tyrosine and tryptophan hydroxylases by Ca2+/calmodulin-dependent protein kinase type II. Bovine brain 14-3-3 protein was resolved by reversed-phase chromatography into seven polypeptides (alpha to eta), all of which were active towards tryptophan hydroxylase when the renatured preparations were assayed in the presence of Ca2+, calmodulin and the protein kinase. Determination of the amino acid sequences of the beta and gamma chains and comparison of the sequences with the previously determined sequence of the eta chain revealed that these molecules are highly homologous, and share a common structural feature in containing an extremely acidic C-terminal region predicted as a domain for interaction with the phosphorylated hydroxylases. Northern blot analysis indicated that the beta, gamma and eta chain are expressed abundantly in the brain; however, these polypeptides appear to be expressed with different tissue specificities because gamma mRNA is found only in the brain, while lower levels of beta and eta mRNAs are detected in several other tissues. These findings suggest the involvement of a diverse family of the activator protein in the stimulus-coupled, Ca2(+)-dependent regulation of monoamine biosynthesis.

Characterization and chromosomal mapping of a cDNA encoding tryptophan hydroxylase from a mouse mastocytoma cell line

A cDNA library was constructed from RNA prepared from P815 mouse mastocytoma cells and screened for tryptophan hydroxylase. An essentially full-length clone that recognizes a major mRNA species of 1.9 kb in mastocytoma cell lines and in pineal gland, duodenum, and brainstem of the mouse was obtained. The predicted amino acid sequence of this mouse mastocytoma clone showed 97 and 87% identity, respectively, with tryptophan hydroxylase clones isolated from rat and rabbit pineal glands, but the mouse clone contains an unusual 3-amino-acid duplication near the N-terminus and lacks a phosphorylation site. A fragment of the cDNA produced an enzymatically active protein when expressed in Escherichia coli, thus demonstrating that the catalytic domain is included in the C-terminal 380 amino acids. The mouse tryptophan hydroxylase locus, termed Tph, was mapped by Southern blot analysis of somatic cell hybrids and by an interspecific backcross to a position in the proximal half of chromosome 7. Because TPH has been mapped to human chromosome 11, this assignment further defines regions of homology between these mouse and human chromosomes.

Molecular cloning of cDNA coding for brain-specific 14-3-3 protein, a protein kinase-dependent activator of tyrosine and tryptophan hydroxylases

The 14-3-3 protein is a family of acidic proteins present exclusively in the brain and is believed to have a function in monoamine biosynthesis because of its ability to activate tyrosine hydroxylase and tryptophan hydroxylase in the presence of Ca2+/calmodulin-dependent protein kinase type II. In this study, we resolved bovine brain 14-3-3 protein into seven polypeptide components by means of reversed-phase chromatography and determined the amino acid sequence of one of these components (eta chain) by cloning its cDNA from a bovine cerebellum cDNA library. The eta-chain mRNA is 1.8 kilobases long and encodes a polypeptide of 246 amino acids and Mr 28,221. Computer-assisted analysis of the sequence indicates that the eta chain exhibits no internal sequence repeats, nor does it have significant sequence similarity to other proteins with known amino acid sequence. However, the eta chain appears to consist of two structural regions that are distinguishable in their clearly different charge characteristics: the almost neutral amino-terminal region and the strongly acidic carboxyl-terminal region. The structural features of the eta chain and the domain organization of tyrosine and tryptophan hydroxylases suggest that the 14-3-3 protein binds to the regulatory domain of the phosphorylated hydroxylases through its acidic carboxyl-terminal region and activates the hydroxylases by inducing an active conformation.

Demonstration of non-neural tryptophan 5-mono-oxygenase in mouse intestinal mucosa

Tryptophan 5-mono-oxygenase was demonstrated and its activity was measured in mucosal extracts of the mouse digestive tract by means of highly sensitive h.p.l.c. detection. The intestinal enzyme was activated by anaerobic incubation with dithiothreitol, as are the enzymes from mouse mastocytoma cells and bovine pineal gland. The dithiothreitol-enhanced activity was highest at the proximal portion of colon followed by that at the duodenum, where the unenhanced activity/enhanced activity ratio was highest. The enzymic and immunochemical properties of the intestinal tryptophan 5-mono-oxygenase were similar to those of the mastocytoma enzyme. In contrast, the intestinal enzyme was immunochemically different from brain tryptophan 5-mono-oxygenase. The possibility that connective tissue and/or mucosal mast cells are responsible for some of the enzyme activity of the duodenal mucosa was ruled out by the demonstration of the activity in extracts from a mast-cell-deficient mutant mouse (W/Wv). The enzyme in the duodenum was found to reside between the upper villus region and the bottom of the crypt, suggesting that it is mainly of enterochromaffin cell and not of submucosal nerve plexus origin.

Full-length cDNA for rabbit tryptophan hydroxylase: functional domains and evolution of aromatic amino acid hydroxylases

A full-length cDNA for tryptophan hydroxylase was cloned from rabbit pineal body by screening an expression library with antibody against rat phenylalanine hydroxylase, which crossreacts with rabbit tryptophan hydroxylase. Clones producing immunoreactive material contain sequences homologous to, yet distinct from, phenylalanine hydroxylase. The rabbit cDNA hybridizes to mRNA in pineal body and brainstem but not in liver. Comparison of the rabbit tryptophan hydroxylase sequence with the sequences of phenylalanine hydroxylase and tyrosine hydroxylase demonstrates that these three biopterin-dependent aromatic amino acid hydroxylases are highly homologous, reflecting a common evolutionary origin from a single primordial genetic locus. The pattern of sequence homology supports the hypothesis that the carboxyl-terminal two-thirds of the molecules constitute the enzymatic activity cores, and the amino-terminal thirds of the molecules constitute domains for substrate specificity.