Compensatory regulation of dopamine after ablation of the tyrosine hydroxylase gene in the nigrostriatal projection

The tyrosine hydroxylase (TH; EC 1.14.16.2) is a rate-limiting enzyme in the dopamine synthesis and important for the central dopaminergic system, which controls voluntary movements and reward-dependent behaviors. Here, to further explore the regulatory mechanism of dopamine levels by TH in adult mouse brains, we employed a genetic method to inactivate the Th gene in the nigrostriatal projection using the Cre-loxP system. Stereotaxic injection of adeno-associated virus expressing Cre recombinase (AAV-Cre) into the substantia nigra pars compacta (SNc), where dopaminergic cell bodies locate, specifically inactivated the Th gene. Whereas the number of TH-expressing cells decreased to less than 40% in the SNc 2 weeks after the AAV-Cre injection, the striatal TH protein level decreased to 75%, 50%, and 39% at 2, 4, and 8 weeks, respectively, after the injection. Thus, unexpectedly, the reduction of TH protein in the striatum, where SNc dopaminergic axons innervate densely, was slower than in the SNc. Moreover, despite the essential requirement of TH for dopamine synthesis, the striatal dopamine contents were only moderately decreased, to 70% even 8 weeks after AAV-Cre injection. Concurrently, in vivo synthesis activity of l-dihydroxyphenylalanine, the dopamine precursor, per TH protein level was augmented, suggesting up-regulation of dopamine synthesis activity in the intact nigrostriatal axons. Collectively, our conditional Th gene targeting method demonstrates two regulatory mechanisms of TH in axon terminals for dopamine homeostasis in vivo: local regulation of TH protein amount independent of soma and trans-axonal regulation of apparent L-dihydroxyphenylalanine synthesis activity per TH protein.     

Dynamics of tyrosine hydroxylase mediated regulation of dopamine synthesis

Tyrosine hydroxylase's catalysis of tyrosine to dihydroxyphenylalanine (DOPA) is the highly regulated, rate-limiting step catalyzing the synthesis of the catecholamine neurotransmitter dopamine. Phosphorylation, cofactor-mediated regulation, and the cell's redox status, have been shown to regulate the enzyme's activity. This paper incorporates these regulatory mechanisms into an integrated dynamic model that is capable of demonstrating relative rates of dopamine synthesis under various physiological conditions. Most of the kinetic equations and substrate parameters used in the model correspond with published experimental data, while a few which were not available in literature have been optimized based on explicit assumptions. This kinetic pathway model permits a comparison of the relative regulatory contributions made by variations in substrate, phosphorylation, and redox status on enzymatic activity and permits predictions of potential disease states. For example, the model correctly predicts the recent observation that individuals with haemochromatosis and having excessive iron accumulation are at increased risk for acquiring Parkinsonism, a defect in neuronal dopamine synthesis (Bartzokis et al., 2004; Costello et al., 2004). Alpha synuclein mediated regulation of tyrosine hydroxylase has also been incorporated in the model, allowing an insight into the over-expression and aggregation of alpha synuclein in Parkinson's disease. Action Editor: Upinder Bhalla     

Differential regulation of somatodendritic and nerve terminal dopamine release by serotonergic innervation of substantia nigra

Nigrostriatal dopaminergic neurons release dopamine from dendrites in substantia nigra and axon terminals in striatum. The cellular mechanisms for somatodendritic and axonal dopamine release are similar, but somatodendritic and nerve terminal dopamine release may not always occur in parallel. The current studies used in vivo microdialysis to simultaneously measure changes in dendritic and nerve terminal dopamine efflux in substantia nigra and ipsilateral striatum respectively, following intranigral application of various drugs by reverse dialysis through the nigral probe. The serotonin releasers (+/-)-fenfluramine (100 micro m) and (+)-fenfluramine (100 micro m) significantly increased dendritic dopamine efflux without affecting extracellular dopamine in striatum. The non-selective serotonin receptor agonist 1-(m-chlorophenyl)-piperazine (100 micro m) elicited a similar pattern of dopamine release in substantia nigra and striatum. NMDA (33 micro m) produced an increase in nigral dopamine of a similar magnitude to mCPP or either fenfluramine drug. However, NMDA also induced a concurrent increase in striatal dopamine. The D2 agonist quinpirole (100 micro m) had a parallel inhibitory effect on dopamine release from dendritic and terminal sites as well. Taken together, these data suggest that serotonergic afferents to substantia nigra may evoke dendritic dopamine release through a mechanism that is uncoupled from the impulse-dependent control of nerve terminal dopamine release.     

Substrate-mediated enhancement of phosphorylated tyrosine hydroxylase in nigrostriatal dopamine neurons: evidence for a role of alpha-synuclein

Tyrosine hydroxylase (TH) protein, phosphorylated at serine-40, serine-31 and serine-19, and enzyme catalytic activity were compared under basal conditions and in activated nigrostriatal dopamine (NSDA) neurons of wild-type and homozygous alpha-synuclein knockout mice. Mice were injected with the D2 antagonist raclopride to stimulate NSDA neuronal activity in the presence or absence of supplemental l-tyrosine. There was no difference in phosphorylated TH levels or TH catalytic activity between wild-type and alpha-synuclein knockout mice under basal conditions or following raclopride-induced acceleration of NSDA activity. In wild-type animals, tyrosine administration potentiated the raclopride-induced increase in phosphorylated TH and enzyme activity. However, tyrosine administration did not enhance phosphorylated TH levels or enzyme catalytic activity in raclopride-stimulated NSDA neurons in alpha-synuclein knockout mice. These findings suggest that alpha-synuclein plays a role in the ability of tyrosine to either enhance TH phosphorylation or hinder TH inactivation during accelerated neuronal activity. The present study supports the hypothesis that alpha-synuclein functions as a molecular chaperone protein that regulates the phosphorylation state of TH in a substrate and activity-dependent manner.     

Tyrosine hydroxylase and regulation of dopamine synthesis

Tyrosine hydroxylase is the rate-limiting enzyme of catecholamine biosynthesis; it uses tetrahydrobiopterin and molecular oxygen to convert tyrosine to DOPA. Its amino terminal 150 amino acids comprise a domain whose structure is involved in regulating the enzyme’s activity. Modes of regulation include phosphorylation by multiple kinases at four different serine residues, and dephosphorylation by two phosphatases. The enzyme is inhibited in feedback fashion by the catecholamine neurotransmitters. Dopamine binds to TyrH competitively with tetrahydrobiopterin, and interacts with the R domain. TyrH activity is modulated by protein–protein interactions with enzymes in the same pathway or the tetrahydrobiopterin pathway, structural proteins considered to be chaperones that mediate the neuron’s oxidative state, and the protein that transfers dopamine into secretory vesicles. TyrH is modified in the presence of NO, resulting in nitration of tyrosine residues and the glutathionylation of cysteine residues.     

Divergence in enzyme regulation between Caenorhabditis elegans and human tyrosine hydroxylase, the key enzyme in the synthesis of dopamine

TH (tyrosine hydroxylase) is the rate-limiting enzyme in the synthesis of catecholamines. The cat-2 gene of the nematode Caenorhabditis elegans is expressed in mechanosensory dopaminergic neurons and has been proposed to encode a putative TH. In the present paper, we report the cloning of C. elegans full-length cat-2 cDNA and a detailed biochemical characterization of the encoded CAT-2 protein. Similar to other THs, C. elegans CAT-2 is composed of an N-terminal regulatory domain followed by a catalytic domain and a C-terminal oligomerization domain and shows high substrate specificity for L-tyrosine. Like hTH (human TH), CAT-2 is tetrameric and is phosphorylated at Ser35 (equivalent to Ser40 in hTH) by PKA (cAMP-dependent protein kinase). However, CAT-2 is devoid of characteristic regulatory mechanisms present in hTH, such as negative co-operativity for the cofactor, substrate inhibition or feedback inhibition exerted by catecholamines, end-products of the pathway. Thus TH activity in C. elegans displays a weaker regulation in comparison with the human orthologue, resembling a constitutively active enzyme. Overall, our data suggest that the intricate regulation characteristic of mammalian TH might have evolved from more simple models to adjust to the increasing complexity of the higher eukaryotes neuroendocrine systems.     

ser31 tyrosine hydroxylase phosphorylation parallels differences in dopamine recovery in nigrostriatal pathway following 6‐OHDA lesion

Compensatory mechanisms in dopamine (DA) signaling have long been proposed to delay onset of locomotor symptoms during Parkinson's disease progression until ~ 80% loss of striatal DA occurs. Increased striatal dopamine turnover has been proposed to be a part of this compensatory response, but may occur after locomotor symptoms. Increased tyrosine hydroxylase (TH) activity has also been proposed as a mechanism, but the impact of TH protein loss upon site‐specific TH phosphorylation in conjunction with the impact on DA tissue content is not known. The tissue content of DA was determined against TH protein loss in the striatum and substantia nigra (SN) following 6‐hydroxydopamine lesion in the medial forebrain bundle in young Sprague–Dawley male rats. Although DA predictably decreased in both regions following 6‐hydroxydopamine, there was a significant difference in DA loss between the striatum (75%) and SN (40%), despite similar TH protein loss. Paradoxically, there was a significant decrease in DA against remaining TH protein in striatum, but a significant increase in DA against remaining TH in SN. In the SN, increased DA per remaining TH protein was matched by increased ser31, but not ser40, TH phosphorylation. In striatum, both ser31 and ser40 phosphorylation decreased, reflecting decreased DA per TH. However, in control nigral and striatal tissue, only ser31 phosphorylation correlated with DA per TH protein. Combined, these results suggest that the phosphorylation of ser31 in the SN may be a mechanism to increase DA biosynthesis against TH protein loss in an in vivo model of Parkinson's disease.

     

Limited regulation of somatodendritic dopamine release by voltage-sensitive Ca channels contrasted with strong regulation of axonal dopamine release

The mechanism underlying somatodendritic release of dopamine (DA) appears to differ from that of axon-terminal release. Specifically, somatodendritic DA release in the substantia nigra pars compacta (SNc) persists in low extracellular Ca2+ concentrations that are insufficient to support axonal release in striatum, suggesting that limited Ca2+ entry is necessary to trigger somatodendritic release. Here, we compared the role of voltage-dependent Ca2+ channels in mediating DA release in striatum versus SNc using specific blockers of N-, P/Q-, T-, R- and L-type Ca2+ channels individually and in combination. Release of DA evoked by a single stimulus pulse in the dorsal striatum and SNc of guinea-pig brain slices was monitored in real time using carbon-fiber microelectrodes with fast-scan cyclic voltammetry. Single-pulse evoked DA release was shown to be independent of regulation by concurrently released glutamate or GABA acting at ionotropic receptors in both regions. Under these conditions, striatal DA release was completely prevented by an N-type channel blocker, omega-conotoxin GVIA (100 nm), and was decreased by 75% by the P/Q-type channel blocker omega-agatoxin IVA (200 nm). Blockade of T-type channels with Ni2+ (100 microm) or R-type channels with SNX-482 (100 nm) decreased axonal release in striatum by 25%, whereas inhibition of L-type channels with nifedipine (20 microm) had no effect. By contrast, none of these Ca2+-channel blockers altered the amplitude of somatodendritic DA release in the SNc. Even a cocktail of all blockers tested did not alter release-signal amplitude in the SNc, although the duration of the release response was curtailed. The limited involvement of voltage-dependent Ca2+ channels in somatodendritic DA release provides further evidence that minimal Ca2+ entry is required to trigger the release process, compared with that required for axon-terminal release.     

Synaptic regulation of somatodendritic dopamine release by glutamate and GABA differs between substantia nigra and ventral tegmental area

Midbrain dopamine (DA) cells of the substantia nigra pars compacta (SNc) and the ventral tegmental area (VTA) exhibit somatodendritic release of DA. To address how somatodendritic release is regulated by synaptic glutamatergic and GABAergic input, we examined the effect of ionotropic-receptor antagonists on locally evoked extracellular DA concentration ([DA]o) in guinea pig midbrain slices. Evoked [DA]o was monitored with carbon-fiber microelectrodes and fast-scan cyclic voltammetry. In SNc, evoked [DA]o was 160% of control in the presence of the AMPA-receptor antagonist, GYKI-52466, or the NMDA-receptor antagonist, AP5. Similar increases were seen with the GABAA-receptor antagonist, picrotoxin, or the GABA(B)-receptor antagonist, saclofen. The increase seen with GYKI-52466 was prevented when both picrotoxin and saclofen were present, consistent with normal, AMPA-receptor mediated activation of GABAergic inhibition. The increase with AP5 persisted, however, implicating NMDA-receptor mediated activation of another inhibitory circuit in SNc. In the VTA, by contrast, evoked [DA]o was unaffected by GYKI-52466 and fell slightly with AP5. Neither picrotoxin nor saclofen alone or in combination had a significant effect on evoked [DA]o. When GABA receptors were blocked in the VTA, evoked [DA]o was decreased by 20% with either GYKI-52466 or AP5. These data suggest that in SNc, glutamatergic input acts predominantly on GABAergic or other inhibitory circuits to inhibit somatodendritic DA release, whereas in VTA, the timing or strength of synaptic input will govern whether the net effect on DA release is excitatory or inhibitory.     

Regulation of retinal dopamine biosynthesis and tyrosine hydroxylase activity by light

Dopamine (DA)-containing neurons of the rat retina are apparently activated transsynaptically by photic stimulation. Exposure of dark-adapted rats to light increases retinal DA biosynthesis and metabolism. Associated with the light-evoked increase of DA biosynthesis is a rapid activation of tyrosine hydroxylase (TH), the rate-limiting enzyme of catecholamine biosynthesis. The activation of TH is characterized by an increased affinity of the enzyme for the pteridine cofactor. Because TH in dark-adapted retinas is apparently not saturated with cofactor, the light-evoked increase of affinity is probably responsible for the observed stimulation of DA biosynthesis. Cyclic AMP (cAMP)-dependent protein phosphorylation in vitro activates TH extracted from dark-adapted retinas, and phosphorylation-induced TH activation is very similar and not additive with light-evoked activation of the enzyme. Incubation of viable cell suspensions of dissociated retinas with 8-bromo cAMP also activates TH, which indicates the availability of sufficient cAMP-dependent protein kinase in the proper subcellular compartment to regulate the enzyme in situ. The DA-containing neurons of the rat retina are tonically inhibited in darkness, and evidence is presented that this tonic inhibition involves direct synaptic input to the DA neurons from gamma-aminobutyric acid-containing amacrine cells. The DA-containing neurons are also subject to feedback inhibition through DA receptors, and to modulation by alpha 2-adrenergic receptors.     

Short-term regulation of tyrosine hydroxylase in tonically-active and in tonically-inactive dopamine neurons: effects of haloperidol and protein phosphorylation

Dopamine (DA)-containing neurons of retina were employed as an experimental model for studying the short-term regulation of tyrosine hydroxylase (TH) in tonically-active and tonically-inactive neurons. These DA-containing neurons are trans-synaptically activated by light. Two mechanisms have been observed in this system for regulation of TH activity. A short-term activation of TH that is characterized by a decreased apparent Km for pteridine cofactors occurs in response to rapid increases of neuronal activity. A second mechanism occurs in response to prolonged, tonic changes of neuronal activity and is characterized by changes of Vmax. Both the Km changes and Vmax changes represent changes of specific activity of TH rather than enzyme induction. To determine the effects of short-term increases of neuronal activity on TH in tonically-active and tonically-inactive neurons, the effects of acute administration of haloperidol were examined in rats that were continuously light-exposed or light-deprived for 4 days. Haloperidol increased TH activity in both light-exposed and light-deprived retinas. The drug elicited the same percent stimulation in both experimental conditions. However, because the basal activity of TH was higher in the light-exposed than the light-deprived retinas, the absolute increase of TH specific activity was greater in the light-exposed samples. The effect of protein phosphorylation on TH activity in extracts of chronically light-exposed or light-deprived retinas was also examined to determine if the differences in the response to haloperidol might be due to a difference in the amount of TH available for short-term activation. Phosphorylation by endogenous cyclic AMP-dependent protein kinase (APK) or by purified catalytic subunit of APK resulted in larger increases of TH specific activity in extracts of light-exposed retinas than in those of light-deprived retinas. As was observed for haloperidol-induced activation, the percent stimulation elicited by phosphorylation was similar in extracts of light-exposed and light-deprived retinas. These observations suggest that more enzyme is available for short-term activation in tonically-active neurons than in those that are tonically inactive. A hypothetical model is proposed in which TH exists in active and inactive forms, the ratio of which depends on the tonic level of neuronal activity.     

Direct binding of GTP cyclohydrolase and tyrosine hydroxylase: regulatory interactions between key enzymes in dopamine biosynthesis

The signaling functions of dopamine require a finely tuned regulatory network for rapid induction and suppression of output. A key target of regulation is the enzyme tyrosine hydroxylase, the rate-limiting enzyme in dopamine synthesis, which is activated by phosphorylation and modulated by the availability of its cofactor, tetrahydrobiopterin. The first enzyme in the cofactor synthesis pathway, GTP cyclohydrolase I, is activated by phosphorylation and inhibited by tetrahydrobiopterin. We previously reported that deficits in GTP cyclohydrolase activity in Drosophila heterozygous for mutant alleles of the gene encoding this enzyme led to tightly corresponding diminution of in vivo tyrosine hydroxylase activity that could not be rescued by exogenous cofactor. We also found that the two enzymes could be coimmunoprecipitated from tissue extracts and proposed functional interactions between the enzymes that extended beyond provision of cofactor by one pathway for another. Here, we confirm the physical association of these enzymes, identifying interacting regions in both, and we demonstrate that their association can be regulated by phosphorylation. The functional consequences of the interaction include an increase in GTP cyclohydrolase activity, with concomitant protection from end-product feedback inhibition. In vivo, this effect would in turn provide sufficient cofactor when demand for catecholamine synthesis is greatest. The activity of tyrosine hydroxylase is also increased by this interaction, in excess of the stimulation resulting from phosphorylation alone. Vmax is elevated, with no change in Km. These results demonstrate that these enzymes engage in mutual positive regulation.     

Mast cells express tyrosine hydroxylase and store dopamine in a serglycin-dependent manner

Here we show that mast cells contain dopamine and that mast cell activation causes dopamine depletion, indicating its presence within secretory granules. Dopamine storage increased during mast cell maturation from bone marrow precursors, and was dependent on the presence of serglycin. Moreover, the expression of tyrosine hydroxylase, the key enzyme in dopamine biosynthesis, was induced during mast cell maturation; histidine decarboxylase and tryptophan hydroxylase 1 were also induced. Mast cell activation caused a robust induction of histidine decarboxylase, but no stimulation of tyrosine hydroxylase or tryptophan hydroxylase 1 expression. The present study points toward a possible role of dopamine in mast cell function.     

Effects of haloperidol and melatonin on the in situ activity of nigrostriatal tyrosine hydroxylase in male Syrian hamsters

Haloperidol, an antipsychotic drug, was tested for its effects on the in situ activity of nigrostriatal and hypothalamic tyrosine hydroxylase, in control male Syrian hamsters and in those receiving a high daily dose of melatonin. After receiving daily ip injections (1.25 mg/kg ip) of haloperidol for 21 days, the animals were sacrificed and brain tissue collected for analysis of dopamine and metabolites by HPLC with electrochemical detection. In situ activity of tyrosine hydroyxlase (TH) activity was determined by measuring the accumulation of L-Dopa after administration of the L amino acid decarboxylase inhibitor, mhydroxybenzylhydrazine. Tissue content of dopamine and its metabolites, DOPAC and HVA, was depressed in striatum of animals receiving haloperidol, and tyrosine hydroxylase (TH) activity was significantly decreased 20-24 h after the last injection (from 1823 +/- 63 to 1139 +/- 85 pg l-dopa/mg tissue). The decrease in TH activity in striatum was significantly inhibited by daily injections of a high dose of melatonin (2.5 mg/kg ip) (from 1139 +/- 85 to 1560 +/- 116 pg L-dopa/mg tissue). In the substantia nigra and in the hypothalamus, on the other hand, haloperidol significantly increased the activity of tyrosine hydroxylase. Melatonin administration did not significantly influence TH activity in the substantia nigra, but inhibited TH activity in the hypothalamus and in the pontine brainstem. One explanation for these data is that chronic haloperidol administration in Syrian hamsters increases TH activity in hypothalamus and substantia nigra, but decreases TH activity in striatum by a mechanism involving D2 presynaptic receptors and a melatonin sensitive kinase which regulates TH phosphorylation.     

Involvement of tyrosine hydroxylase up regulation in dexamethasone-induced hypertension of rats

We investigated the effect of dexamethasone (DEX) on tyrosine hydroxylase (TH) mRNA level, and TH activity and catecholamine levels in the adrenal medulla of the rat. DEX (1 mg/kg/day, s.c.) was administered for 2 days, and a control group was given corn oil. DEX significantly increased systolic blood pressure. TH mRNA level, TH activity, epinephrine level, and norepinephrine level in the adrenal medulla of DEX-treated rats were significantly higher than those of control rats. Also, epinephrine and norepinephrine levels in plasma were significantly higher in DEX-treated rats than in controls. alpha-Methyl-p-tyrosine prevented the DEX-induced blood pressure increase. These results suggest that the catecholamine synthetic pathway may be involved in DEX-induced hypertension.