Skip to Content
MilliporeSigma
HomeProtein ExpressionDopamine, Norepinephrine, and Ephinephrine Synthesis

Dopamine, Norepinephrine, and Ephinephrine Synthesis

Phenylalanine is an essential amino acid that is converted to tyrosine primarily in the liver by phenylalanine hydroxylase. Blood borne tyrosine, derived from dietary proteins and from phenylalanine metabolism, enters the brain by a low affinity amino acid transport system. Tyrosine in brain extracellular fluid is taken up into catecholamine neurons by high and low affinity amino acid transporters. The relative circulating levels of tyrosine and phenylalanine can affect central catecholamine metabolism, as these amino acids compete for transport into the brain, and for transport into the neuron. Due to a phenylalanine deficiency in phenylketonuria, there is an impaired ability to convert phenylalanine to tyrosine, so that in this condition there is an elevated level of phenylalanine in the blood and in brain extracellular fluid. Phenylalanine is a relatively weak substrate for tyrosine hydroxylase, but its presence in high concentrations inhibits hydroxylation of tyrosine by tyrosine hydroxylase.

The conversion of tyrosine to dihydroxyphenylalanine (L-DOPA) is catalyzed by tyrosine hydroxylase in the cytosol. This is normally the rate-limiting step in catecholamine biosynthesis, so that pharmacological blockade of this enzyme has profound effects on catecholamine formation. However, it is possible for any of the reactions to be rate-limiting in certain pharmacological or pathological situations. Tyrosine hydroxylase has a relatively high degree of substrate specificity. Tyrosine availability does not normally influence the rate of tyrosine hydroxylation in vivo, but when the neuronal system is activated, or has a high basal firing rate (eg. mesoprefrontal dopamine neurons), tyrosine levels can alter the rate of conversion to L-DOPA. Increased impulse flow can lead to short term activation of tyrosine hydroxylase, which appears to involve phosphorylation of the regulatory domain by protein kinases to produce an activated form of tyrosine hydroxylase with a lower Km for its pterin cofactor and a higher Ki for catecholamine (product inhibition). In addition, activation or blockade of autoreceptors can alter the rate of tyrosine hydroxylation. In primates, but not rodents, multiple tyrosine hydroxylase mRNAs are produced through alternative mRNA splicing from a single primary transcript. The rate of decline of catecholamine levels following inhibition of tyrosine hydroxylase provides an index of turnover.

Aromatic amino acid decarboxylase catalyzes the cytosolic conversion of L-DOPA to dopamine, although all naturally occurring aromatic L-amino acids are substrates for the enzyme. The enzyme so rapidly decarboxylates L-DOPA that the levels of the amino acid are relatively low, and supplying the enzyme with additional substrate can lead to increased product formation, which is the basis of L-DOPA treatment for Parkinsonâ s disease. The accumulation of DOPA following inhibition of aromatic amino acid decarboxylase provides an index of synthesis rate.

Dopamine-β-hydroxylase is located inside amine storage vesicles of norepinephrine neurons. Dopamine is actively transported from the cytoplasm into the vesicles. As the enzyme is a copper containing protein, its activity can be inhibited by copper chelating agents, such as diethyldithiocarbamate and FLA-63. Inhibition of the enzyme effectively reduces tissue norepinephrine levels. The enzyme does not have a high degree of substrate specificity.

The occurrence of phenylethanol-amine-N-methyltransferase is largely restricted to the adrenal medulla, but with detectable levels in association with epinephrine neurons in brain. Inhibition of enzyme activity decreases epinephrine biosynthesis. There is, however, a less specific N-methyl-transferase present in many tissues. While there may be soluble phenylethanolamine-N-methyl-transferase in the cytoplasm, there is good evidence for a particulate location of the enzyme, probably associated with the granule or vesicle membrane.

The Table below contains accepted modulators and additional information. For a list of additional products, see the 
"Similar Productssection below.

Abbreviations

CGS19281A: 4,9-Dihydro-7-methoxy-3H-pyrido[3,4b]indole
FLA-63: bis-(4-Methyl-1-homopiperazinylthiocarbonyl)-disulphide
FLA-57: 4-Methyl-homopiperazine-1-dithiocarboxylic acid
LY-134046: 8,9-Dichloro-2,3,4,5-tetrahydro-1H-2benzazepine
NSD 1015: m-Hydroxybenzylhydrazine
SKF 29661: 7-(Aminosulfonyl)-1,2,3,4-tetrahydroisoquinoline
SKF 64139: 7,8-Dichloro-1,2,3,4-tetrahydroisoquinoline

Similar Products
Loading

References

1.
Berry MD, Juorio AV, Li X-, Boulton AA. 1996. Aromaticl-amino acid decarboxylase: A neglected and misunderstood enzyme. Neurochem Res. 21(9):1075-1087. https://doi.org/10.1007/bf02532418
2.
Cooper J, Bloom F, Roth R. 2003. The Biochemical Basis of Neuropharmacology. New York: Oxford University Press.
3.
Eisenhofer G, Kopin IJ, Goldstein DS. 2004. Catecholamine Metabolism: A Contemporary View with Implications for Physiology and Medicine. Pharmacol Rev. 56(3):331-349. https://doi.org/10.1124/pr.56.3.1
4.
Elsworth JD, Roth RH. 1997. Dopamine Synthesis, Uptake, Metabolism, and Receptors: Relevance to Gene Therapy of Parkinson's Disease. Experimental Neurology. 144(1):4-9. https://doi.org/10.1006/exnr.1996.6379
5.
Esbenshade TA, Browman KE, Bitner RS, Strakhova M, Cowart MD, Brioni JD. 2008. The histamine H3receptor: an attractive target for the treatment of cognitive disorders. 154(6):1166-1181. https://doi.org/10.1038/bjp.2008.147
6.
Fitzpatrick PF. The Aromatic Amino Acid Hydroxylases.235-294. https://doi.org/10.1002/9780470123201.ch6
7.
Flatmark. 2000. Catecholamine biosynthesis and physiological regulation in neuroendocrine cells. 168(1):1-17. https://doi.org/10.1046/j.1365-201x.2000.00596.x
8.
Kumer SC, Vrana KE. Intricate Regulation of Tyrosine Hydroxylase Activity and Gene Expression. Journal of Neurochemistry. 67(2):443-462. https://doi.org/10.1046/j.1471-4159.1996.67020443.x
9.
Lehnert H, Wurtma RJ. 1993. Amino Acid Control of Neurotransmitter Synthesis and Release: Physiological and Clinical Implications. Psychother Psychosom. 60(1):18-32. https://doi.org/10.1159/000288676
10.
Nagatsu T, Ichinose H. 1999. Regulation of pteridine-requiring enzymes by the cofactor tetrahydrobiopterin. Mol Neurobiol. 19(1):79-96. https://doi.org/10.1007/bf02741379
11.
Robertson SD, Matthies HJG, Galli A. 2009. A Closer Look at Amphetamine-Induced Reverse Transport and Trafficking of the Dopamine and Norepinephrine Transporters. Mol Neurobiol. 39(2):73-80. https://doi.org/10.1007/s12035-009-8053-4
12.
Sloley B, Juorio A. 1995. Monoamine Neurotransmitters in Invertebrates and Vertebrates: An Examination of the Diverse Enzymatic Pathways Utilized to Synthesize and Inactivate Blogenic Amines.253-303. https://doi.org/10.1016/s0074-7742(08)60528-0
13.
Stefano G, Kream R. Endogenous morphine synthetic pathway preceded and gave rise to catecholamine synthesis in evolution (Review). Int J Mol Med. https://doi.org/10.3892/ijmm.20.6.837
14.
THÖNY B, AUERBACH G, BLAU N. 2000. Tetrahydrobiopterin biosynthesis, regeneration and functions. 347(1):1-16. https://doi.org/10.1042/bj3470001
15.
Tokita S, Takahashi K, Kotani H. 2006. Recent Advances in Molecular Pharmacology of the Histamine Systems: Physiology and Pharmacology of Histamine H3 Receptor: Roles in Feeding Regulation and Therapeutic Potential for Metabolic Disorders. J Pharmacol Sci. 101(1):12-18. https://doi.org/10.1254/jphs.fmj06001x4
16.
Zigmond MJ. 1994. Chapter 15 Chemical transmission in the brain: homeostatic regulation and its functional implications.115-122. https://doi.org/10.1016/s0079-6123(08)60776-1
Sign In To Continue

To continue reading please sign in or create an account.

Don't Have An Account?