Biosynthesis of N-Acetyldopamine and N-Acetyloctopamine by Schistocerca gregaria Nervous Tissue

N-Acetyltyramine, N-acetyldopamine and N-acetyloctopamine were the major products when either L-[3H]tyrosine or [3H]tyramine were incubated with thoracic ganglia of the desert locust, Schistocerca gregaria. No label was incorporated into L-DOPA under these conditions, although 2-3% of the radioactivity could be recovered in dopamine and octopamine. Addition of the aromatic amino acid decarboxylase inhibitor, 3-hydroxybenzylhydrazine (NSD 1015), prevented the formation of N-acetylcompounds from L-[3H]tyrosine, without resulting in an accumulation of label in L-DOPA. In contrast, incubation of samples of haemolymph with L-[3H]tyrosine resulted in the recovery of 7% of label in L-DOPA, which was increased to 17% in the presence of NSD 1015. These results provide evidence that the initial step in the synthesis of dopamine and octopamine by S. gregaria nervous tissue is the conversion of L-tyrosine to tyramine, which is subsequently metabolised to N-acetyltyramine, N-acetyldopamine or N-acetyloctopamine.     

Characterization of the tyraminergic system in the central nervous system of the locust,Locusta migratoria migratoides

Tyramine occurs in the central nervous system (CNS) of the migratory locust,Locusta migratoria migratoides. The distribution of tyramine within the CNS does not parallel that of octopamine. Tyramine is synthesised from tyrosine in the presence of tyrosine decarboxylase. A second decarboxylase in the CNS is active against 5HTP and DOPA. The locust ganglia incorporate tyramine by high- and low-affinity uptake processes that appear to be independent of dopamine and octopamine. Depolarisation of the locust ganglia by high potassium concentration results in calcium-dependent release of incorporated [³H]tyramine.     

Determination of reactive oxygen species associated with the degeneration of dopaminergic neurons during dopamine metabolism

Abstract

Oxidative stress is believed to be an important mechanism underlying dopamine-induced neuronal damage. This study provides X-band electron spin resonance (ESR) spectroscopic evidence for reactive oxygen species (ROS) generation during dopamine metabolism. The authors induced excess dopamine metabolism in the mouse striatum by bathing it in tyramine-containing perfusate using microdialysis. The addition of tyramine to the perfusate raised the levels of extracellular dopamine and hydrogen peroxide significantly. The ESR signal from hydroxy-TEMPO decayed during tyramine perfusion and treatment with a monoamine-oxidase inhibitor or radical scavenger suppressed the signal decay. Decreases in the number of tyrosine hydroxylase-immunopositive fibres and in dopamine concentration after tyramine perfusion were observed. Moreover, the tyramine-perfused mice showed a marked methamphetamine-induced rotational response. Notably, these effects of tyramine were suppressed by the simultaneous perfusion of hydroxy-TEMPO. These findings indicate that the ROS generation, which was monitored by hydroxy-TEMPO, caused oxidative damage to the dopaminergic neurons.     

Cytochrome P450 mediates dopamine formation in the brain in vivo

The cytochrome P450-mediated synthesis of dopamine from tyramine has been shown in vitro. The aim of the present study was to demonstrate the ability of rat cytochrome P450 (CYP) 2D to synthesize dopamine from tyramine in the brain in vivo. We employed two experimental models using reserpinized rats with a blockade of the classical pathway of dopamine synthesis from tyrosine. Model A estimated dopamine production from endogenous tyramine in brain structures in vivo (ex vivo measurement of a tissue dopamine level), while Model B measured extracellular dopamine produced from exogenous tyramine (an in vivo microdialysis). In Model A, quinine (a CYP2D inhibitor) given intraperitoneally caused a significant decrease in dopamine level in the striatum and nucleus accumbens and tended to fall in the substantia nigra and frontal cortex. In Model B, an increase in extracellular dopamine level was observed after tyramine given intrastructurally (the striatum). After joint administration of tyramine and quinine, the amount of the dopamine formed was significantly lower compared to the group receiving tyramine only. The results of the two complementary experimental models indicate that the hydroxylation of tyramine to dopamine may take place in rat brain in vivo, and that CYP2D catalyzes this reaction.     

Bisbenzylisoquinoline alkaloids in Berberis cell cultures

Callus cultures of 34 Berberis cell lines representing 33 species were screened for alkaloids using TLC and HPLC. Jatrorrhizine was always found to be a major constituent; two B. stolonifera lines were the richest in bisbenzylisoquinolines. The new alkaloid 2-norberbamunine was isolated from cultures of B. stolonifera V29 together with berbamunine, aromoline, berbamine, isotetrandrine and jatrorrhizine. The time course of bisbenzylisoquinoline accumulation was studied in B. stolonifera V29 suspension cultures and it was found that the concentrations of these alkaloids rose throughout the cell growth phase.     

Antioxidant effects of dopamine and related compounds.

The antioxidant and free radical scavenging effects of dopamine, noradrenaline, tyramine, and tyrosine were investigated and compared with alpha-tocopherol. The antioxidant effect of dopamine and its related compounds on peroxidation of linoleic acid were in the order of dopamine > alpha-tocopherol = tyramine > tyrosine > noradrenaline as measured by the thiocyanate method. These amine compounds had reducing power, and a scavenging effect on reactive oxygen species, i.e., superoxide anion and hydroxyl radical. The results for reducing power and scavenging effect of these amine compounds had a similar trend as their inhibition of linoleic acid peroxidation. The antioxidant activity of these amine compounds in soybean oil was also evaluated by the Rancimat method. The induction time to reach 100 meq/kg peroxide value (POV) of soybean oil for dopamine, alpha-tocopherol, tyramine, tyrosine, noradrenaline, and control were 9.0, 8.2, 8.0, 6.4, 4.6, and 4.3 h, respectively. The antioxidant efficacy of amine compounds seems to be correlated with the numbers of hydroxy groups and their position on the phenolic ring.     

The effects of 5-hydroxytryptophan and 5-hydroxytryptamine on dopamine synthesis and release in rat brain striatal synaptosomes.

The effects of 5-hydroxytryptophan (5-HTP) and serotonin (5-HT) on dopamine synthesis and release in rat brain striatal synaptosomes have been examined and compared to the effects of tyramine and dopamine. Serotonin inhibited dopamine synthesis from tyrosine, with 25% inhibition occurring at 3 μM-5-HT and 60% inhibition at 200 μM. Dopamine synthesis from DOPA was also inhibited by 5-HT, with 30% inhibition occurring at 200 μ. At 200 μM-5-HTP, dopamine synthesis from both tyrosine and DOPA was inhibited about 70%. When just the tyrosine hydroxylation step was measured in the intact synaptosome, 5-HT, 5-HTP, tyramine and dopamine all caused significant inhibition, but only dopamine inhibited soluble tyrosine hydroxylase [L-tyrosine 3-monooxygenase; L-tyrosine, tetrahydropteridine oxygen oxidoreductase (3-hydroxylating); EC 1.14.16.2] prepared from lysed synaptosomes. Particulate tyrosine hydroxylase was not inhibited by 10 μM-5-HT, but was about 20% inhibited by 200 μM-5-HT and 5-HTP. At 200 μM both 5-HT and 5-HTP stimulated endogenous dopamine release. These experiments suggest that exposure of dopaminergic neurons to 5-HT or 5-HTP leads to an inhibition of dopamine synthesis, mediated in part by an intraneuronal displacement of dopamine from vesicle storage sites, leading to an increase in dopamine-induced feedback inhibition of tyrosine hydroxylase, and in part by a direct inhibition of DOPA decarboxylation.     

Stress response in Drosophila melanogaster strain inactive with decreased tyramine and octopamine contents

Juvenile hormone hydrolysis, tyrosine decarboxylase activity, dopamine content and fitness (viability and fertility) were studied under normal and stress conditions in the adults of Drosophila melanogaster inactive strain carrying a mutation that decreases tyrosine decarboxylase activity and results in the lower contents of tyramine and octopamine. A sexual dimorphism of tyrosine decarboxylase activity, dopamine level and survival under heat stress in inactive flies was found. inactive adults showed higher dopamine levels and lower survival levels under heat stress as compared to wild type (Canton S) adults. Juvenile hormone degradation is decreased in young and increased in mature inactive females as compared to wild type. Fertility of the inactive strain did not differ from that of wild type strain under normal conditions, but after heat exposure the dynamics of its restoration was different. inactive females were found to develop the stress reaction, with juvenile hormone degradation, tyrosine decarboxylase activity, dopamine content and fertility levels used as the reaction indicators.     

Potential effects of tyramine on the transition to reproductive workers in honeybees (Apis mellifera L.)

Abstract.  To explore the role of brain tyramine in reproductive worker honeybees, its effects after injection and oral treatment on brain dopamine levels and ovarian development in queenless worker honeybees are determined. Both tyramine injection and oral treatment in 10-day-old queenless bees leads to tyramine transportation into the brain and significantly elevates brain dopamine levels as a function of the tyramine concentration. Ovarian diameters are significantly larger in 10-day-old queenless bees treated with tyramine compared with queenless bees of the same age without tyramine treatment. Results on yolk formation in the ovary support the finding of increased ovarian diameter, suggesting that oral tyramine treatment accelerates ovarian development through dopamine effects and/or direct effects of tyramine on the ovary in queenless bees. Thus, tyramine has potential effects on the enhancement of brain dopamine levels and the acceleration of ovarian development for the transition of normal workers to reproductive worker honeybees.     

Genetic Control of Biogenic-Amine Systems in Drosophila Under Normal and Stress Conditions

The contents of octopamine and its precursors (tyrosine and tyramine) were studied in adults of two lines of Drosophila virilis with contrasting stress responses. It was demonstrated that in individuals responding to stress by a hormonal stress reaction (line 101), the contents of octopamine and tyrosine are lower than in nonresponding flies (line 147). It was found that there is no difference between the lines in the level of tyramine under normal conditions. The dopamine response to stressor was also studied. Genetic analysis of these differences revealed that they are controlled by a single gene and that the gene is not sex-linked. The gene controlling the response was found to be linked to chromosome 6 of D. virilis.     

Monoamine oxidase A mediates iodotyrosine formation induced by monoamines in bovine thyroid particulate fraction

Monoamines are able to increase the thyroid iodine organification in vitro. A predominance of the A form of monoamine oxidase (MAO) has been previously demonstrated to exist in bovine thyroid tissue. In the present study we have investigated the form of MAO that could be involved in the iodotyrosine formation induced by tyramine, 5-hydroxytryptamine (5-HT) and beta-phenylethylamine (PEA) in a bovine thyroid subcellular fraction. The relative capacity of these monoamines to generate H2O2 and to incorporate iodine into tyrosine has also been studied. The MAO A inhibitor clorgyline (10(-9) M) produced a strong inhibition on the iodotyrosine formation induced by tyramine, 5-HT and PEA. In contrast, only a slight reduction was observed with deprenyl as MAO B inhibitor. Among the three monoamines, tyramine produced the highest H2O2 generation and iodotyrosine formation. The lowest Km value obtained was for 5-HT and the highest for PEA. Regarding the Vmax, the lowest value was for 5-HT and the highest for tyramine. The amount of iodine incorporated to tyrosine was not equivalent to the H2O2 generated by the monoamines nor to that exogenously added. Our results indicate that in bovine thyroid tissue mainly the A form of MAO is involved in the monoamine metabolism.     

Brain tyramine and reproductive states of workers in honeybees

To explore the role of tyramine in the transformation of reproductive states of honeybee workers, brain levels of tyramine and N-acetyltyramine were measured in both normal and queenless workers. Queenless workers had higher tyramine levels and lower N-acetyltyramine levels than normal workers did. Intermediate reproductive workers that were transferred into a normal colony from a queenless colony had intermediate levels of tyramine and N-acetyltyramine. Elevation of tyramine in the queenless workers occurred at an earlier adult stage than elevation of dopamine. Tyramine levels in intermediate reproductive workers returned to the levels seen in normal workers, but dopamine levels in intermediate reproductive workers remained elevated at the same level as in queenless workers. Thus, brain tyramine may be regulated by the colony condition with or without a queen. Injection of an amine uptake inhibitor, reserpine, depleted tyramine and elevated N-acetyltyramine. Distributions of tyramine and dopamine within the brain were distinctively different, whereas distributions of N-acetyltyramine and N-acetyldopamine were similar, suggesting that each functional amine is stored in specific neurosecretory cells and released to the relevant receptor sites but that metabolism into each N-acetylmetabolite is determined by diffusion.     

Incorporation of various putative precursors into cuticular 3,4-dihydroxyphenylacetic acid of adult Tenebrio molitor

Post-emergence levels of 3,4-dihydroxyphenylacetic acid (DOPAC) and ketocatechol were determined in cuticle from adult Tenebrio molitor. Possible pathways for biosynthesis of DOPAC were studied by comparing the incorporation of injected [U-¹⁴C]tyrosine, [7-¹⁴C]dopamine, [7-¹⁴C]DOPA, [7-¹⁴C]tyramine, [U-¹⁴C]p-hydroxyphenylpyruvic acid (p-HPPA) and [ring-³H]p-hydroxyphenylacetic acid (p-HPAA) into cuticular DOPAC during its period of maximal increase 1–3 days after adult emergence. Increased incorporation of [U-¹⁴C]tyrosine between days 0 and 3 suggests rapid de novo biosynthesis of DOPAC from this primary precursor. Of the putative intermediates tested, only p-HPPA had a pattern of incorporation similar to that seen with tyrosine. Since p-HPAA was poorly incorporated into both cuticle and DOPAC, a tentative pathway tyrosine → p-HPPA → 3,4-dihydroxyphenylpyruvic acid → DOPAC is proposed.     

effect of stress on levels of octopamine,dopamine and serotonin in the American cockroach (Periplaneta americana L.)

1. Various biogenic amines including octopamine, dopamine and serotonin, and their precursors and metabolites in haemolymph and the central nervous system from American cockroaches (Periplaneta americana L.) were measured using electrochemical detection.2. Octopamine was found in similar high relative abundances in haemolymph and the central nervous system.3. The amount of octopamine was much higher than that of tyramine and synephrine in haemolymph and thoracic nerve cord, whereas tyramine was at the highest level followed by octopamine and synephrine in the brain.4. Insects were stressed by vibrating at 100 or 1000 Hz, visually by flashing light at 4 Hz for 15 min or by immersing the insect in water at 60°C for 30 sec, which resulted in the elevation of octopamine, tyramine, synephrine and tyrosine levels in thoracic nerve cord.     

First evidence of a membrane‐bound,tyramine and β‐phenylethylamine producing,tyrosine decarboxylase in Enterococcus faecalis: A two‐dimensional electrophoresis proteomic study

The soluble and membrane proteome of a tyramine producing Enterococcus faecalis, isolated from an Italian goat cheese, was investigated. A detailed analysis revealed that this strain also produces small amounts of β‐phenylethylamine. Kinetics of tyramine and β‐phenylethylamine accumulation, evaluated in tyrosine plus phenylalanine‐enriched cultures (stimulated condition), suggest that the same enzyme, the tyrosine decarboxylase (TDC), catalyzes both tyrosine and phenylalanine decarboxylation: tyrosine was recognized as the first substrate and completely converted into tyramine (100% yield) while phenylalanine was decarboxylated to β‐phenylethylamine (10% yield) only when tyrosine was completely depleted. The presence of an aspecific aromatic amino acid decarboxylase is a common feature in eukaryotes, but in bacteria only indirect evidences of a phenylalanine decarboxylating TDC have been presented so far. Comparative proteomic investigations, performed by 2‐DE and MALDI‐TOF/TOF MS, on bacteria grown in conditions stimulating tyramine and β‐phenylethylamine biosynthesis and in control conditions revealed 49 differentially expressed proteins. Except for aromatic amino acid biosynthetic enzymes, no significant down‐regulation of the central metabolic pathways was observed in stimulated conditions, suggesting that tyrosine decarboxylation does not compete with the other energy‐supplying routes. The most interesting finding is a membrane‐bound TDC highly over‐expressed during amine production. This is the first evidence of a true membrane‐bound TDC, longly suspected in bacteria on the basis of the gene sequence.     

Changes in Levels of Dopamine and Tyramine in the Rat Caudate Nucleus Following Alterations of Impulse Flow in the Nigrostriatal Pathway

Following electric stimulation of the substantia nigra for 1 h there was a substantial increase in dopamine (DA) turnover in the rat caudate nucleus evidenced by an increase in its acid metabolite homovanillic acid (HVA). Concurrently there was an increase in striatal m-tyramine (mTA) and a substantial decrease in p-tyramine (pTA). Lesioning the substantia nigra to decrease impulse flow resulted in a buildup of striatal DA and mTA, but again a decrease in pTA. Following pretreatment with a tyrosine hydroxylase inhibitor, the effects of stimulation of the nigra on mTA were reversed, there being a significant decrease in this amine. The decrease of pTA in response was partially prevented by tyrosine hydroxylase inhibition. The effects of stimulation or substantia nigra lesions on pTA levels were reversed, however, by tyrosine hydroxylase inhibition, a significant increase in this amine being recorded. mTA and DA levels were largely unaffected by a combination of lesion and tyrosine hydroxylase inhibition. The results provide insight into the possible biosynthetic interrelationships between DA and the tyramine isomers in the rat caudate nucleus.     

Accumulation of tyrosol glucoside in transgenic potato plants expressing a parsley tyrosine decarboxylase

As part of the response to pathogen infection, potato plants accumulate soluble and cell wall-bound phenolics such as hydroxycinnamic acid tyramine amides. Since incorporation of these compounds into the cell wall leads to a fortified barrier against pathogens, raising the amounts of hydroxycinnamic acid tyramine amides might positively affect the resistance response. To this end, we set out to increase the amount of tyramine, one of the substrates of the hydroxycinnamoyl-CoA:tyramine N-(hydroxycinnamoyl)-transferase reaction, by placing a cDNA encoding a pathogen-induced tyrosine decarboxylase from parsley under the control of the 35S promoter and introducing the construct into potato plants via Agrobacterium tumefaciens-mediated transformation. While no alterations were observed in the pattern and quantity of cell wall-bound phenolic compounds in transgenic plants, the soluble fraction contained several new compounds. The major one was isolated and identified as tyrosol glucoside by liquid chromatography-electrospray ionization-high resolution mass spectrometry and NMR analyses. Our results indicate that expression of a tyrosine decarboxylase in potato does not channel tyramine into the hydroxycinnamoyl-CoA:tyramine N-(hydroxycinnamoyl)-transferase reaction but rather unexpectedly, into a different pathway leading to the formation of a potential storage compound.     

Inhibition of dihydropteridine reductase by catecholamines and related compounds

Catecholamines and related compounds, such as dopamine, 5- or 6-hydroxydopamine, N-methyldopamine, tyramine, octopamine, norepinephrine and epinephrine, inhibit human liver dihydropteridine reductase (NADH:6,7-dihydropteridine oxidoreductase, EC 1.6.99.10) noncompetitively with Ki values ranging from 7.0 X 10(-6) - 1.9 X 10(-4)M (I50 values = 2.0 X 10(-5) - 2.0 X 10(-4)M). The tyrosine analogs alpha-methyltyrosine and 3-iodotyrosine are weak inhibitors of this enzyme (I50 greater than 10(-3)M). The inhibitory effect of catecholamines is slightly decreased by O-methylation of one hydroxyl group, but is essentially abolished by total methylation. The inhibitory strength of the catecholamines and related compounds tested against this enzyme can be arranged in the following order: dopamine, 6-hydroxydopamine, 5-hydroxydopamine, N-methyldopamine greater than tyramine, 3-O-methyldopamine, 4-O-methyldopamine much greater than epinephrine, 3-O-methylepinephrine, norepinephrine, octopamine less than tyrosine much less than alpha-methyltyrosine, 3-iodotyrosine much less than homoveratrylamine. These results suggest that dopamine, norepinephrine and epinephrine may serve as physiological regulators of mammalian dihydropteridine reductase.     

Properties of an enzyme from bananas (Musa sapientum) which hydroxylates tyramine to dopamine

An enzyme system isolated from the pulp of banana fruit (Musa sapientum) was partially purified and characterized. The enzyme was capable of catalysing the hydroxylation of the monophenol, tyramine, to the diphenol, dopamine (3,4-dihydroxyphenylethylamine). Unlike some tyrosinases, the reaction was not stimulated by catalytic amounts of diphenolic reaction product. Ascorbic acid, however, reduced the initial lag period in the oxidation of tyramine, stimulated the reaction rate and promoted the accumulation of dopamine during the first few minutes of the reaction. The hydroxylation of tyramine was apparently dependent upon molecular oxygen. On the basis of these observations it is tentatively suggested that the enzyme is a tyramine hydroxylase which may be responsible for the formation of dopamine in the banana.     

BIOGENIC AMINE-MEDIATED ALTERATION OF PYRIDOXAL PHOSPHATE FORMATION IN RAT BRAIN

Abstract— DOPA, dopamine, norepinephrine, tyramine, serotonin, histamine and GABA inhibited pyridoxal kinase; whereas, tyrosine, 5-hydroxytryptophan, histidine, glutamic acid, hypotaurine and taurine were without inhibitory effects. Tetrahydroisoquinoline derivatives formed from Pictet-Spengler condensation between DOPA, dopamine and norepinephrine with pyridoxal and pyridoxal phosphate did not inhibit pyridoxal kinase. These results are interpreted to indicate that interaction of biogenic amines and pyridoxal kinase may alter the formation of pyridoxal phosphate which in turn may influence the activity of numerous pyridoxal phosphate dependent enzymatic reactions in brain.