Tyrosine dopamine biosynthesis

Figure 4. DDC (A), serotonin (B), and tyrosine hydroxylase (C) immunore-activity in the posterior region of a wild-type Drosophila ventral ganglion. Tyrosine hydroxylase (TH) encodes the rate-limiting step in dopamine biosynthesis and is a marker for dopamine cells. B and C are the same CNS assayed for both serotonin and TH. M, medial dopamine neurons VL, ventrolateral serotonin neurons DL, dorsolateral dopamine neurons. Short unmarked arrows in C show vacuolated cells that do not contain DDC immunoreactivity. The immunoreactivity in these cells may represent a nonspecific cross-reactivity of the rat TH antibody. The length bar in A is 50 pM. The images are confocal projections generated on a Molecular Dynamics-2000 confocal laser scanning microscope.

Morphine and codeine biosynthesis (Samuelsson, 1999 Herbert et al., 2000 Novak et al., 2000) Studies on the biosynthesis of morphine have been carried out mainly on cell cultures mainly of Coptis japonica and species of Thalictrum. Two enzymes (tyrosine decarboxylase and phenolase) catalyze the formation of dopamine from one molecule tyrosine. Dopamine is also the key intermediate in the biosynthesis of mescaline. 

Borges CR, Geddes T, Watson JT, Kuhn DM. 2002. Dopamine biosynthesis is regulated by S-glutathionylation. Potential mechanism of tyrosine hydroxylast inhibition during oxidative stress. J Biol Chem 277 48295 -8302. 

Andersson et al (1998) show marked inhibition of tyrosine hydroxylase (TH), the rate-limiting enzyme in dopamine biosynthesis in the striatum and hippocampus after intracranial injections of PAH mixtures. Inhibition of TH can lead to reductions in striatal dopamine (Stephanou et al, 1998 Andersson et al, 1998), which may also contribute to the suppression in motor activity (Saunders et al, 2006). 

Original evidence for the formation of NADA from arachidonic acid and dopamine or tyrosine (Huang et al. 2002) suggested a biosynthetic pathway common to that of the recently discovered arachidonoyl amino acids (Huang et al. 2001), i.e. from the direct condensation between arachidonic acid and dopamine, or, alternatively, from the condensation between arachidonic acid and tyrosine followed by the transformation of N-arachidonoyl-tyrosine into NADA by the enzymes catalysing dopamine biosynthesis from tyrosine. Preliminary data have shown, however, that NADA cannot be produced from either N-arachidonoyl-tyrosine or N-arachidonoyl-L-DOPA either in vitro, in brain homogenates, or in vivo, and that the lipid formed from tyrosine and arachidonic acid is not NADA (M.J. Walker and V. Di Marzo, unpublished observations). Clearly, further studies are needed to understand the biosynthetic mechanism for this putative endocannabinoid. 

In addition to its other functions BH4 enhances the release of dopamine and serotonin in the rat striatum when administered locally through the dialysis membrane. The enhancement of dopamine release persisted even when dopamine biosynthesis or dopamine reuptake was completely blocked, but it was abolished when hlockers of voltage-dependent Na" " or Ca " " channels were administered with BH4. Further experiments using selective inhibitors of tyrosine, TH, and NOS demonstrated that BH4 stimulates dopamine release directly, independent of its cofactor action on TH and NOS, by acting from the outside of neurons. The exact mechanism is not entirely clear but it has been shown that arginine also induces a concentration-dependent increase of dopamine release in the superfusate of rat striatum slices, and that it is dependent on the presence of BH4. ... 

L-Tyrosine metabohsm and catecholamine biosynthesis occur largely in the brain, central nervous tissue, and endocrine system, which have large pools of L-ascorbic acid (128). Catecholamine, a neurotransmitter, is the precursor in the formation of dopamine, which is converted to noradrenaline and adrenaline. The precise role of ascorbic acid has not been completely understood. Ascorbic acid has important biochemical functions with various hydroxylase enzymes in steroid, dmg, andhpid metabohsm. The cytochrome P-450 oxidase catalyzes the conversion of cholesterol to bUe acids and the detoxification process of aromatic dmgs and other xenobiotics, eg, carcinogens, poUutants, and pesticides, in the body (129). The effects of L-ascorbic acid on histamine metabohsm related to scurvy and anaphylactic shock have been investigated (130). Another ceUular reaction involving ascorbic acid is the conversion of folate to tetrahydrofolate. Ascorbic acid has many biochemical functions which affect the immune system of the body (131). 

Tyrosine hydroxylase (TH) is an enzyme that catalyzes the hydroxylation of tyrosine to 3,4-dihydroxypheny-lalanine in the brain and adrenal glands. TH is the rate-limiting enzyme in the biosynthesis of dopamine. This non-heme iron-dependent monoxygenase requires the presence of the cofactor tetrahydrobiopterin to maintain the metal in its ferrous state. 

TABLE 23-3 Examples of proteins regulated by phosphorylation Enzymes involved in neurotransmitter biosynthesis Tyrosine hydroxylase Tryptophan hydroxylase Neurotransmitter receptors Adrenergic receptors Dopamine receptors Opioid receptors Glutamate receptors Many others... 

These patients suffer from a genetic defect of dopamine synthesis, caused by reduced GTP cyclohydrolase activity. This enzyme is rate-limiting in the biosynthesis of tetra-hydrobiopterin, a cofactor of the dopamine-synthesizing enzyme tyrosine hydroxylase (see Fig. 40-2). 

Intracellular Fe is usually tightly regulated, being bound by ferritin in an insoluble ferrihydrite core, and impaired Fe homeostasis has been linked to Parkinson s disease and Alzheimer s disease. A consistent neurochemical abnormality in Parkinson s disease is degeneration of dopaminergic neurons relating to a reduction of striatal dopamine levels. As tyrosine hydroxylase (Fig. 24) (494), an Fe enzyme, catalyzes the formation of l-DOPA, the rate-limiting step in the biosynthesis of dopamine, the disease can be considered as a tyrosine... 

In addition to their well known role in protein structure, amino acids also act as precursors to a number of other important biological molecules. For example, the synthesis of haem (see also Section 5.3.1), which occurs in, among other tissues, the liver begins with glycine and succinyl-CoA. The amino acid tyrosine which maybe produced in the liver from metabolism of phenylalanine is the precursor of thyroid hormones, melanin, adrenaline (epinephrine), noradrenaline (norepinephrine) and dopamine. The biosynthesis of some of these signalling molecules is described in Section 4.4. 

Another strategy of some interest is to deplete biogenic amines such as OA by inhibiting their biosynthesis. Inhibitors of such enzymes in the biosynthetic pathway as aromatic amino acid decarboxylase which converts tyrosine to tyramine, or dopamine 3 -hydroxylase which converts tyramine to OA are known and have interesting effects in insects (e.g. see 52,53)t but a discussion of this area lies outside the scope of this paper. Nevertheless, it is a particularly interesting one since these or related enzymes are also needed to produce catecholamines for cuticular sclerotiza-tion, thus offering dual routes to the discovery of compounds with selectively deleterious actions on insects. 

The general scheme of the biosynthesis of catecholamines was first postulated in 1939 (29) and finally confirmed in 1964 (Fig. 2) (30). Although not shown in Figure 2, in some cases the amino acid phenylalanine [63-91-2] can serve as a precursor it is converted in the liver to (-)-tyrosine [60-18-4] by the enzyme phenylalanine hydroxylase. Four enzymes are involved in E formation in the adrenal medulla and certain neurons in the brain tyrosine hydroxylase, dopa decarboxylase (also referred to as L-aromatic amino acid decarboxylase), dopamine-P-hydroxylase, and phenylethanolamine iV-methyltransferase. Neurons that form DA as their transmitter lack the last two of these enzymes, and sympathetic neurons and other neurons in the central nervous system that form NE as a transmitter do not contain phenylethanolamine N-methyl-transferase. The component enzymes and their properties involved in the formation of catecholamines have been purified to homogeneity and their properties examined. The human genes for tyrosine hydroxylase, dopamine- 3-oxidase and dopa decarboxylase, have been cloned (31,32). It is anticipated that further studies on the molecular structure and expression of these enzymes should yield interesting information about their regulation and function. 

The most abundant alkaloid in Coryphantha macromeris, normacromerine, has been shown to originate from tyrosine (330). Tyramine and JV-methyltyramine are efficiently incorporated into normacromerine while octopamine and dopamine are poor precursors. Norepinephrine, epinephrine, normetanephrine, and meta-nephrine have all been shown to be biosynthetically incorporated into normacromerine, and they have also been shown to be naturally occurring trace intermediates in this cactus species (331, 334). Normacromerine is only slowly converted to macromerine in C. macromeris (332). The results indicate that alternative pathways to normacromerine exist precise conclusions regarding the biosynthesis of normacromerine must await further studies. 

The secretion of epinephrine by the adrenal medulla is controlled directly by nerve impulses and also by the other stress hormones, namely, corticosteroids. This is illustrated in Figure 16.11. Nerve impulses have a major stimulatory effect on tyrosine and dopamine hydroxylases, whereas glucocorticoids have a major effect on phenylethanolamine methyltransferase. Tyrosine hydroxylase is considered the rate-controlling enzyme in the biosynthesis... 

Figure 16.11 Control of catecholamine biosynthesis in the adrenal medulla. TH, tyrosine hydroxylase DBH, dopamine hydroxylase PNMT, phenylethanolamine methyl-transferase ACTH, adrenocorticotropic hormone. The heavy arrows indicate major sites of regulation. (Reproduced by permission from Axelrod, J. Reisine TD. Stress hormones their interaction and regulation. Science 224 452-459, 1984.)...

BA biosynthesis begins with the conversion of tyrosine to both dopamine and 4-hydroxyphenylacetaldehyde by a lattice of decarboxylations, orfho-hydroxylations, and deaminations.1 The aromatic amino acid decarboxylase (TYDC) that converts tyrosine and dopa to their corresponding amines has been purified, and several... 

Histamine, serotonin and the catecholamines (dopamine, epinephrine and norepinephrine) are synthesized from the aromatic amino acids histidine, tryptophan and phenylalanine, respectively. The biosynthesis of catecholamines in adrenal medulla cells and catecholamine-secreting neurons can be simply summarized as follows [the enzyme catalysing the reaction and the key additional reagents are in square brackets] phenylalanine — tyrosine [via liver phenylalanine hydroxylase + tetrahydrobiopterin] —> i.-dopa (l.-dihydroxyphenylalanine) [via tyrosine hydroxylase + tetrahydrobiopterin] —> dopamine (dihydroxyphenylethylamine) [via dopa decarboxylase + pyridoxal phosphate] — norepinephrine (2-hydroxydopamine) [via dopamine [J-hydroxylasc + ascorbate] —> epinephrine (jV-methyl norepinephrine) [via phenylethanolamine jV-methyltransferase + S-adenosylmethionine]. 

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