Dopamine-Releasing Action of 6R-l-erythro-Tetrahydrobiopterin: Analysis of Its Action Site Using Sepiapterin

Abstract: Recently, we reported that 6 R - l - erythro -tetrahydrobiopterin (6 R -BH₄), a natural cofactor for hydroxylases of tyrosine and tryptophan, has a monoamine-releasing action independent of its cofactor activity. Here we attempted to determine whether 6 R -BH₄ acts inside the cell or from the outside of the cell by using brain microdialysis in the rat striatum. For this purpose, sepiapterin, an immediate precursor of 6 R -BH₄ in the salvage pathway, was used to selectively increase the intracellular 6 R -BH₄ levels. Dialytic perfusion of sepiapterin increased tissue levels of reduced biopterin (mainly 6 R -BH₄) but not the extracellular levels. Administration of sepiapterin increased the extracellular levels of 3,4-dihydroxyphenylalanine (DOPA) (an index of in vivo tyrosine hydroxylase activity) and of dopamine (DA) (an index of in vivo DA release). Either of the increases was eliminated after pretreatment with a tyrosine hydroxylase inhibitor α-methyl- p -tyrosine. Administration of 6 R -BH₄ increased extracellular levels of reduced biopterin, DOPA, and DA. After pretreatment with α-methyl- p -tyrosine, the increase in DOPA levels was abolished, but most of the increase in DA levels persisted. The increase in DA levels also persisted after pretreatment with nitric oxide synthase inhibitors. These data demonstrate that 6 R -BH₄ stimulates DA release directly, independent of its cofactor action for tyrosine hydroxylase and nitric oxide synthase, by acting from the outside of neurons.     

Interactive effects of nicotine and MPTP on striatal tetrahydrobiopterin in mice

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) is a neurotoxin known to cause dopamine (DA) neuron degeneration, while the psychoactive compound nicotine is known to excite DA neurons. Tetrahydrobiopterin is the cofactor for tyrosine hydroxylase (TOH) in the regulation of DA biosynthesis. The present study investigated the interactions between nicotine and MPTP on striatal biopterin, DA and TOH activity in BALB/c mice. The results indicated that both acute and chronic nicotine administrations at various concentrations significantly increased biopterin and DA levels in the striatum, while MPTP markedly decreased these measures. Pretreatment with nicotine at a dose having no significant effect alone, partially protected against MPTP's toxicity on biopterin and DA. Increasing the dose of nicotine did not have a further protective action. The toxicity of MPTP on TOH was also prevented by nicotine. Further, the above effects of nicotine were probably mediated through the cholinergic nicotinic receptors since mecamylamine reversed the effects of nicotine. These results suggest that nicotine interacts with the dopaminergic system probably at the level of DA biosynthesis through activating TOH and its coenzyme tetrahydrobiopterin.     

Subcellular distribution of biopterin in rat brain: the biochemical basis of its stability

Rat brain biopterin, the hydroxylase cofactor, was observed to distribute equally across regional subcellular fractions, rather than to codistribute neuronally with tyrosine and tryptophan hydroxylases for which it functions. Over a 24 h period with light/dark phasing, which some groups have shown to result in cycling of biopterin levels in striate and certain other regions, only the biopterin associated with the crude nuclear fraction of the striate (not associated with neurotransmitter synthesis) demonstrated a diurnal cycle. The selectivity of this perturbation response to the striate nuclear fraction suggests that (1) multiple subcellular loci of biopterin might exist independently in rat brain neurons and (2) the pterin's availability for neurotransmitter biosynthesis is limited beyond its apparent regional concentration. The demonstration of multiple independent sources of neuronal biopterin may be relevant to understanding why regional levels have been so resistant to efforts at pharmacological manipulation (only amphetamine and CRF have changed striate biopterin levels). It also shows that changes in regional hydroxylase cofactor levels may not be related to neurotransmitter synthesis, but instead may result from another presently unknown demand for the cofactor at a disparate neuronal site.     

PRIMARY CULTURES OF DISSOCIATED SYMPATHETIC NEURONS : II. Initial Studies on Catecholamine Metabolism

Initial studies are reported on the catecholamine metabolism of low-density cultures of dissociated primary sympathetic neurons. Radioactive tyrosine was used to study the synthesis and breakdown of catecholamines in the cultures. The dependence of catecholamine synthesis and accumulation on external tyrosine concentration was examined and a concentration which is near saturation, 30 µM, was chosen for further studies. The free tyrosine pool in the nerve cells equilibrated with extracellular tyrosine within 1 h; the total accumulation of tyrosine (free tyrosine plus protein, catecholamines, and metabolites) was linear for more than 24 h of incubation. Addition of biopterin, the cofactor of tyrosine hydroxylase, only slightly enhanced catecholamine biosynthesis by the cultured neurons. However, addition of reduced ascorbic acid, the cosubstrate for dopamine β-hydroxylase, markedly stimulated the conversion of dopamine (DA) to norepinephrine (NE). Phenylalanine, like tyrosine, served as a precursor for some of the DA and NE produced by the cultures, but tyrosine always accounted for more than 90% of the catecholamines produced. The DA pool labeled rapidly to a saturation level characteristic of the age of the culture. The NE pool filled more slowly and was much larger than the DA pool. The disappearance of radioactive NE and DA during chase experiments followed a simple exponential curve. Older cultures showed both more rapid production and more rapid turnover of the catecholamines than did younger cultures, suggesting a process of maturation.     

Brain nitric oxide synthase is a biopterin- and flavin-containing multi-functional oxido-reductase.

Brain nitric oxide synthase is a Ca2+/calmodulin-regulated enzyme which converts L-arginine into NO. Enzymatic activity of this enzyme essentially depends on NADPH and is stimulated by tetrahydrobiopterin (H4biopterin). We found that purified NO synthase contains enzyme-bound H4biopterin, explaining the enzymatic activity observed in the absence of added cofactor. Together with the finding that H4biopterin was effective at substoichiometrical concentrations, these results indicate that NO synthase essentially depends on H4biopterin as a cofactor which is recycled during enzymatic NO formation. We found that the purified enzyme also contains FAD, FMN and non-heme iron in equimolar amounts and exhibits striking activities, including a Ca2+/calmodulin-dependent NADPH oxidase activity, leading to the formation of hydrogen peroxide at suboptimal concentrations of L-arginine or H4biopterin.     

Activation of neuronal nitric-oxide synthase by the 5-methyl analog of tetrahydrobiopterin. Functional evidence against reductive oxygen activation by the pterin cofactor.

Tetrahydrobiopterin ((6R)-5,6,7,8-tetrahydro-L-biopterin (H4biopterin)) is an essential cofactor of nitric-oxide synthases (NOSs), but its role in enzyme function is not known. Binding of the pterin affects the electronic structure of the prosthetic heme group in the oxygenase domain and results in a pronounced stabilization of the active homodimeric structure of the protein. However, these allosteric effects are also produced by the potent pterin antagonist of NOS, 4-amino-H4biopterin, suggesting that the natural cofactor has an additional, as yet unknown catalytic function. Here we show that the 5-methyl analog of H4biopterin, which does not react with O2, is a functionally active pterin cofactor of neuronal NOS. Activation of the H4biopterin-free enzyme occurred in a biphasic manner with half-maximally effective concentrations of approximately 0.2 microM and 10 mM 5-methyl-H4biopterin. Thus, the affinity of the 5-methyl compound was 3 orders of magnitude lower than that of the natural cofactor, allowing the direct demonstration of the functional anticooperativity of the two pterin binding sites of dimeric NOS. In contrast to H4biopterin, which inactivates nitric oxide (NO) through nonenzymatic superoxide formation, up to 1 mM of the 5-methyl derivative did not consume O2 and had no effect on NO steady-state concentrations measured electrochemically with a Clark-type NO electrode. Therefore, reconstitution with 5-methyl-H4biopterin allowed, for the first time, the detection of enzymatic NO formation in the absence of superoxide or NO scavengers. These results unequivocally identify free NO as a NOS product and indicate that reductive O2 activation by the pterin cofactor is not essential to NO biosynthesis.     

Biosynthesis of Biopterin by Rat Brain

Abstract: A method for the determination of [¹⁴C]biopterin biosynthesis from [¹⁴C]guanosine-5'-triphosphate by a desalted preparation from rat striatum, based on sequential reverse-phase and cation-exchange high performance liquid chromatography, is described. Synthesis of reduced forms of biopterin by this striatal extract was found to be dependent on enzymatic activity, guanosine-5'-triphosphate, magnesium ions, and a reduced pyridine nucleotide. As demonstrated by the technique of isotope dilution, isotope trapping, 6-lactyl-7,8-dihydropterin (sepiapterin) was found to be an intermediate in biopterin biosynthesis that is catalyzed by the striatal extract. Rat brain was also shown to synthesize biopterin in vivo from intraventricularly administered [¹⁴C]guanosine or sepiapterin. Intraventricular injection of sepiapterin increased dihydro- and 5,6,7,8-tetrahydrobiopterin levels in rat brain by more than eightfold. The temporal relationship between the appearance of dihydro- and 5,6,7,8-tetrahydrobiopterin following intraventricular injection of sepiapterin suggests that dihydrobiopterin is the immediate product of sepiapterin reduction which is then reduced further to the functional cofactor 5,6,7,8-tetra-hydrobiopterin. Therefore, in contrast to previous reports, the biosynthesis of biopterin by rat brain does not appear to differ from that occurring in other, nonneural tissues.     

Analysis of Plasma Biopterin Levels in Psychiatric Disorders Suggests a Common BH<Subscript>4</Subscript> Deficit in Schizophrenia and Schizoaffective Disorder

Tetrahydrobiopterin (BH₄) is an essential cofactor for amine neurotransmitter synthesis. BH₄ also stimulates and modulates the glutamatergic system, and regulates the synthesis of nitric oxide by nitric oxide synthases. A connection between BH₄ deficiencies and psychiatric disorders has been previously reported; major depression and obsessive-compulsive disorder have been found in subjects with a BH₄ deficiency disorder and more recently we have observed a robust plasma deficit of biopterin (a measure of BH₄), in a large group of schizophrenic patients compared to control subjects. To extend our previous finding in schizophrenia, we analyzed plasma biopterin levels from patients with schizoaffective and bipolar disorders. A significant difference in biopterin was seen among the diagnostic groups (P < 0.0001). Post hoc analyses indicated significant biopterin deficits relative to the normal control group for the schizoaffective group, who had biopterin levels comparable to the schizophrenic group. Bipolar disorder subjects had plasma biopterin levels that were higher that the schizoaffective disorder group and significantly higher than the schizophrenic group. The demonstrated significant biopterin deficit in both schizophrenia and schizoaffective disorder, may suggest an etiological role of a BH₄ deficit in these two disorders, via dysregulation of neurotransmitter systems.     

Effects of Cold Exposure on Rat Adrenal Tyrosine Hydroxylase: An Analysis of RNA, Protein, Enzyme Activity, and Cofactor Levels

Long-term cold exposure (5-7 days) is known to induce concomitant increases in the levels of adrenomedullary tyrosine hydroxylase (TH) RNA, protein, and enzyme activity. In this report, we compare the time courses of these changes and investigate the effects of cold exposure on the levels of biopterin, the cofactor required for tyrosine hydroxylation. After only 1 h of cold exposure, TH mRNA abundance increased 71% compared with nonstressed controls. Increases in total cellular TH RNA levels were maximal (threefold over control values) within 3-6 h of cold exposure and remained elevated throughout the duration of the experiment (72 h). TH protein levels increased rapidly after 24 h of cold exposure and reached a maximal value threefold above that of controls at 48-72 h. Despite the relatively rapid and large elevations in TH RNA and protein content, only modest increases in TH activity were detected during the initial 48 h of cold exposure. Adrenomedullary biopterin increased rapidly after the onset of cold exposure, rising to a level approximately twofold that of the nonstressed controls at 24 h, and remained at this level throughout the duration of the stress period. Taken together, the results of this time course study indicate that cold-induced alterations in adrenal TH activity are mediated by multiple cellular control mechanisms, which may include pre- and posttranslational regulation. Our findings also suggest that cold stress-induced increases in the levels of the TH cofactor may represent another key event in the sympathoadrenal system's response to cold stress.     

Inhibition of Tyrosine Hydroxylase by R and S Enantiomers of Salsolinol, 1-Methyl-6,7-Dihydroxy-1,2,3,4- Tetrahydroisoquinoline

Salsolinol is one of the dopamine-derived tetrahydroisoquinolines and is synthesized from pyruvate or acetaldehyde and dopamine. As it cannot cross the blood-brain barrier, salsolinol as the R enantiomer in the brain is considered to be synthesized in situ in dopaminergic neurons. Effects of R and S enantiomers of salsolinol on kinetic properties of tyrosine hydroxylase [tyrosine, tetrahydrobiopterin:oxygen oxidoreductase (3-hydroxylating); EC 1.14.16.2], the rate-limiting enzyme of catecholamine biosynthesis, were examined. The naturally occurring cofactor of tyrosine hydroxylase, L-erythro-5,6,7,8-tetrahydrobiopterin, was found to induce allostery to the enzyme polymers and to change the affinity to the biopterin itself. Using L-erythro-5,6,7,8-tetrahydrobiopterin, tyrosine hydroxylase recognized the stereochemical structures of the salsolinols differently. The asymmetric center of salsolinol at C-1 played an important role in changing the affinity to L-tyrosine. The allostery of tyrosine hydroxylase toward biopterin cofactors disappeared, and at low concentrations of biopterin such as in brain tissue, the affinity to the cofactor changed markedly. A new type of inhibition of tyrosine hydroxylase, by depleting the allosteric effect of the endogenous biopterin, was found. It is suggested that under physiological conditions, such a conformational change may alter the regulation of DOPA biosynthesis in the brain.     

Effects of thyrotropin releasing hormone and its analogue, DN 1417, on biopterin concentration and tryptophan hydroxylation in rat raphe slices

The effects of subchronic administration of thyrotropin releasing hormone (TRH) and its analogue, gamma-butyrolactone-gamma-carbonyl-L-histidyl-L-prolinamide citrate (DN 1417), on serotonin biosynthesis in situ were investigated in tissue slices of the midbrain raphe of rats. TRH or DN 1417 (10 mg/kg per day intraperitoneally) were administered to male Wistar rats for ten days. At twenty four hr after the last injection, tissue slices of the midbrain raphe were prepared and the rate of serotonin biosynthesis was estimated by measuring formation of 5-hydroxytryptophan (5-HTP) from tryptophan during inhibition of aromatic L-amino acid decarboxylase using high-performance liquid chromatography with fluorescence detection. Total biopterin content was determined by a specific radioimmunoassay. 5-HTP formation was decreased 22% and 29%, and total biopterin content 69% and 72%, in TRH- and DN 1417-treated rats, respectively. However, tryptophan concentration in raphe slices did not change. In contrast, the Vmax of tryptophan hydroxylase in the homogenate of the raphe nucleus in the presence of a saturating concentration of (6R)-L-erythro-tetrahydrobiopterin, the naturally occurring pterin cofactor, was significantly increased after repeated administration of TRH or DN 1417. These results indicate that reduction of in situ serotonin biosynthesis in tissue slices from the rats treated with TRH or DN 1417 subchronically contray to the increase in in vitro tryptophan hydroxylase may result from the decrease of the biopterin cofactor, and that changes in concentrations of the biopterin cofactor may play a regulatory role in serotonin biosynthesis in vivo under certain conditions.     

GTP cyclohydrolase I is coinduced in hepatocytes stimulated to produce nitric oxide

GTP cyclohydrolase I is the rate-controlling enzyme in the production of tetrahydrobiopterin (BH(4)), an essential cofactor for nitric oxide (NO) synthase. Here we show that GTP cyclohydrolase I mRNA was present in unstimulated hepatocytes and was up-regulated 2- to 3-fold concurrently with iNOS induction induced in vivo by LPS injection and in vitro by stimulation with LPS and inflammatory cytokines tumor necrosis factor alpha, interleukin-1 beta, and interferon-gamma. Hepatocyte GTP cyclohydrolase I enzyme activity increased 2-fold in vivo after LPS. This coinduction of GTP cyclohydrolase I resulted in increased total intracellular biopterin which supported induced NO synthesis. The addition of a GTP cyclohydrolase I inhibitor to the stimulated hepatocytes decreased intracellular biopterin levels and resulted in a decrease in NO production. The results show that GTP cyclohydrolase I is up-regulated by certain acute inflammatory conditions. Further, the results indicate that biopterin is essential as a cofactor for induced NO synthase activity in hepatocytes.     

A tetrahydrobiopterin radical forms and then becomes reduced during Nomega-hydroxyarginine oxidation by nitric-oxide synthase

Nitric-oxide synthases are flavoheme enzymes that catalyze two sequential monooxygenase reactions to generate nitric oxide (NO) from l-arginine. We investigated a possible redox role for the enzyme-bound cofactor 6R-tetrahydrobiopterin (H4B) in the second reaction of NO synthesis, which is conversion of N-hydroxy-l-arginine (NOHA) to NO plus citrulline. We used stopped-flow spectroscopy and rapid-freeze EPR spectroscopy to follow heme and biopterin transformations during single-turnover NOHA oxidation reactions catalyzed by the oxygenase domain of inducible nitric-oxide synthase (iNOSoxy). Significant biopterin radical (>0.5 per heme) formed during reactions catalyzed by iNOSoxy that contained either H4B or 5-methyl-H4B. Biopterin radical formation was kinetically linked to conversion of a heme-dioxy intermediate to a heme-NO product complex. The biopterin radical then decayed within a 200-300-ms time period just prior to dissociation of NO from a ferric heme-NO product complex. Measures of final biopterin redox status showed that biopterin radical decay occurred via an enzymatic one-electron reduction process that regenerated H4B (or 5MeH4B). These results provide evidence of a dual redox function for biopterin during the NOHA oxidation reaction. The data suggest that H4B first provides an electron to a heme-dioxy intermediate, and then the H4B radical receives an electron from a downstream reaction intermediate to regenerate H4B. The first one-electron transition enables formation of the heme-based oxidant that reacts with NOHA, while the second one-electron transition is linked to formation of a ferric heme-NO product complex that can release NO from the enzyme. These redox roles are novel and expand our understanding of biopterin function in biology.     

Tyrosine hydroxylase binds tetrahydrobiopterin cofactor with negative cooperativity, as shown by kinetic analyses and surface plasmon resonance detection.

Kinetic studies of tetrameric recombinant human tyrosine hydroxylase isoform 1 (hTH1) have revealed properties so far not reported for this enzyme. Firstly, with the natural cofactor (6R)-Lerythro-5,6,7, 8-tetrahydrobiopterin (H4biopterin) a time-dependent change (burst) in enzyme activity was observed, with a half-time of about 20 s for the kinetic transient. Secondly, nonhyperbolic saturation behaviour was found for H4biopterin with a pronounced negative cooperativity (0.39 < h < 0.58; [S]0.5 = 24 +/- 4 microM). On phosphorylation of Ser40 by protein kinase A, the affinity for H4biopterin increased ([S]0.5 = 11 +/- 2 microM) and the negative cooperativity was amplified (h = 0.27 +/- 0.03). The dimeric C-terminal deletion mutant (Delta473-528) of hTH1 also showed negative cooperativity of H4biopterin binding (h = 0.4). Cooperativity was not observed with the cofactor analogues 6-methyl-5,6,7,8-tetrahydropterin (h = 0.9 +/- 0.1; Km = 62.7 +/- 5.7 microM) and 3-methyl-5,6,7, 8-tetrahydropterin (H43-methyl-pterin)(h = 1.0 +/- 0.1; Km = 687 +/- 50 microM). In the presence of 1 mM H43-methyl-pterin, used as a competitive cofactor analogue to BH4, hyperbolic saturation curves were also found for H4biopterin (h = 1.0), thus confirming the genuine nature of the kinetic negative cooperativity. This cooperativity was confirmed by real-time biospecific interaction analysis by surface plasmon resonance detection. The equilibrium binding of H4biopterin to the immobilized iron-free apoenzyme results in a saturable positive resonance unit (DeltaRU) response with negative cooperativity (h = 0.52-0.56). Infrared spectroscopic studies revealed a reduced thermal stability both of the apo-and the holo-hTH1 on binding of H4biopterin and Lerythro-dihydrobiopterin (H2biopterin). Moreover, the ligand-bound forms of the enzyme also showed a decreased resistance to limited tryptic proteolysis. These findings indicate that the binding of H4biopterin at the active site induces a destabilizing conformational change in the enzyme which could be related to the observed negative cooperativity. Thus, our studies provide new insight into the regulation of TH by the concentration of H4biopterin which may have significant implications for the physiological regulation of catecholamine biosynthesis in neuroendocrine cells.     

Influence of Substrate and Tissue Manganese on the IAA-Oxidase System in Cotton

Tissue manganese was found to influence the indoleacetic acid (IAA) system of cotton over a wide range of concentrations. The cofactor and inhibitor activities of the IAA-oxidase system were affected as the concentration of manganese in the tissue was varied. Maximum inhibitor activity was found in leaf extracts from the plants grown in 0.5 mg/l manganese (Hoagland's level). The inhibitor activity decreased in the leaf extracts of plants grown at concentrations of manganese either higher or lower than 0.5 mg/l. Abnormally high IAA-oxidase activity was found in the leaves of plants grown in deficient levels of manganese (<0.0005, 0.005 mg/l) and the extracts from plants in the <0.0005 mg/l Mn treatment showed IAA-oxidase cofactor activity.     

Role of bound zinc in dimer stabilization but not enzyme activity of neuronal nitric-oxide synthase

Nitric-oxide synthases (NOS) are homodimeric proteins and can form an intersubunit Zn(4S) cluster. We have measured zinc bound to NOS purified from pig brain (0.6 mol/mol of NOS) and baculovirus-expressed rat neuronal NOS (nNOS) (0.49 +/- 0.13 mol/mol of NOS), by on-line gel-filtration/inductively coupled plasma mass spectrometry. Cobalt, manganese, molybdenum, nickel, and vanadium were all undetectable. Baculovirus-expressed nNOS also bound up to 2. 00 +/- 0.58 mol of copper/mol of NOS. Diethylenetriaminepentaacetic acid (DTPA) reduced the bound zinc to 0.28 +/- 0.07 and the copper to 0.97 +/- 0.24 mol/mol of NOS. Desalting of samples into thiol-free buffer did not affect the zinc content but completely eliminated the bound copper ( or =75%) of the bound zinc was released from baculovirus-expressed rat nNOS by p-chloromercuriphenylsulfonic acid (PMPS). PMPS-treated nNOS was strongly (90 +/- 5%) inactivated. To isolate functional effects of zinc release from other effects of PMPS, PMPS-substituted thiols were unblocked by excess reduced thiol in the presence of DTPA, which hindered reincorporation of zinc. The resulting enzyme contained 0.12 +/- 0.05 mol of zinc but had a specific activity of 426 +/- 46 nmol of citrulline.mg(-1).min(-1), corresponding to 93 +/- 10% of non-PMPS-treated controls. PMPS also caused dissociation of nNOS dimers under native conditions, an effect that was blocked by the pteridine cofactor tetrahydrobiopterin (H(4)biopterin). H(4)biopterin did not affect zinc release. Even in the presence of H(4)biopterin, PMPS prevented conversion of NOS dimers to an SDS-resistant form. We conclude that zinc binding is a prerequisite for formation of SDS-resistant NOS dimers but is not essential for catalysis.     

Tyrosine hydroxylase and tryptophan hydroxylase activities and its cofactor biopterin level in brain regions of the rolling mouse: The influence of thyrotropin releasing hormone

Biopterin, the cofactor for tyrosine hydroxylase and tryptophan hydroxylase, was decreased in caudate nucleus, hypothalamus and cerebellum of the rolling mouse. Though there were not significant differences of tyrosine hydroxylase and tryptophan hydroxylase activities between the rolling and normal control mouse in the hypothalamus, the rolling showed significant increase of biopterin concentration and tyrosine hydroxylase activity after administration of thyrotropin releasing hormone (TRH). These results suggest that ataxic gait of the rolling mouse may be partly due to some abnormalities of catecholaminergic neurons, especially noradrenergic neurons, and that TRH may improve the abnormalities of catecholaminergic neurons. The changes of biopterin concentration by TRH administration indicate that biopterin may be a regulatory factor in catecholamine biosynthesis.     

Inactivation of Tryptophan Hydroxylase by Nitric Oxide: Enhancement by Tetrahydrobiopterin

Abstract: Tryptophan hydroxylase, the initial and rate-limiting enzyme in the biosynthesis of the neurotransmitter serotonin, is inactivated by the nitric oxide generators sodium nitroprusside, diethylamine/nitric oxide complex, and S -nitroso- N -acetylpenicillamine. Physiological concentrations of tetrahydrobiopterin, the natural and endogenous cofactor for the hydroxylase, significantly enhance the inactivation of the enzyme caused by each of these nitric oxide generators. The substrate tryptophan does not have this effect. The chemically reduced (tetrahydro-) form of the pterin is required for the enhancement, because neither biopterin nor dihydrobiopterin is effective. The 6 S -isomer of tetrahydrobiopterin, which has little cofactor efficacy for tryptophan hydroxylase, does not enhance enzyme inactivation as does the natural 6 R -isomer. A number of synthetic, reduced pterins share with tetrahydrobiopterin the ability to enhance nitric oxide-induced inactivation of tryptophan hydroxylase. The tetrahydrobiopterin effect is not prevented by agents known to scavenge hydrogen peroxide, superoxide radicals, peroxynitrite anions, hydroxyl radicals, or singlet oxygen. On the other hand, cysteine partially protects the enzyme from both the nitric oxide-induced inactivation and the combined pterin/nitric oxide-induced inactivation. These results suggest that the tetrahydrobiopterin cofactor enhances the nitric oxide-induced inactivation of tryptophan hydroxylase via a mechanism that involves attack on free protein sulfhydryls. Potential in vivo correlates of a tetrahydrobiopterin participation in the inactivation of tryptophan hydroxylase can be drawn to the neurotoxic amphetamines.     

Enhancing Effect of Manganese on L-DOPA-Induced Apoptosis in PC12 Cells

L-DOPA and manganese both induce oxidative stress-mediated apoptosis in catecholaminergic PC12 cells. In this study, exposure of PC12 cells to 0.2 mM MnCl2 or 10-20 microM L-DOPA neither affected cell viability, determined by the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay, nor induced apoptosis, tested by flow cytometry, fluorescence microscopy, and the TUNEL technique. L-DOPA (50 microM) induced decreases in both cell viability and apoptosis. When 0.2 mM MnCl2 was associated with 10, 20, or 50 microM L-DOPA, a concentration-dependent decrease in cell viability was observed. Apoptotic cell death also occurred. In addition, manganese inhibited L-DOPA effects on dopamine (DA) metabolism (i.e., increases in DA and its acidic metabolite levels in both cell lysate and incubation medium). The antioxidant N-acetyl-L-cysteine significantly inhibited decreases in cell viability, apoptosis, and changes in DA metabolism induced by the manganese association with L-DOPA. An increase in autoxidation of L-DOPA and of newly formed DA is suggested as a mechanism of manganese action. These data show that agents that induce oxidative stress-mediated apoptosis in catecholaminergic cells may act synergistically.