RELATIONSHIP BETWEEN THE RATE OF AXOPLASMIC TRANSPORT AND SUBCELLULAR DISTRIBUTION OF ENZYMES INVOLVED IN THE SYNTHESIS OF NOREPINEPHRINE

The net rate of proximo-distal transport of tyrosine hydroxylase, dopamine β-hydroxylase, DOPA decarboxylase and choline acetyltransferase was determined by measuring the accumulation of these enzymes proximal to a ligature of the rat sciatic nerve. The rate of accumulation was constant for at least 12 h. For the enzymes involved in the biosynthesis of norepinephrine the rate of transport was correlated to their subcellular distribution and a close correlation between these two parameters was found. Dopamine β-hydroxylase, an enzyme mainly localized in the particulate fraction of the sciatic nerve, showed the fastest rate of transport (1·94 mm/h) whereas DOPA decarboxylase, exclusively located in the high-speed supernatant fluid, gave the slowest (0·63 mm/h) rate of transport. Tyrosine hydroxylase, predominantly located in the non-particulate fraction of the sciatic nerve was transported much slower (0·75 mm/h) than dopamine β-hydroxylase but still significantly (P < 0.005) faster than DOPA decarboxylase. The subcellular distribution of dopamine β-hydroxylase in ganglia did not differ significantly (0·45 > P > 0·40) from that in the sciatic nerve, but in nerve endings a greater proportion of dopamine β-hydroxylase was localized in particulate fractions. Tyrosine hydroxylase and DOPA decarboxylase were found exclusively in the non-particulate fractions of ganglia. In the nerve endings of the effector organs a small but consistent portion of tyrosine hydroxylase was found in particulate fractions, whereas DOPA decarboxylase was exclusively localized in the high-speed supernatant fluid.     

NORADRENALINE METABOLIZING ENZYMES IN NORMAL AND SYMPATHETICALLY DENERVATED VAS DEFERENS

—A surgical technique for sympathetically denervating the vas deferens has been evaluated biochemically. A slight fall in soluble muscle protein content and no significant change in DNA content of the operated vas deferens were found. This indicates that the surgical procedure causes only a slight degree of tissue damage and may be useful for investigating the cellular localization and properties of noradrenaline metabolizing enzymes. In three species examined (rat, guinea pig and rabbit), monoamine oxidase activity of the vas deferens fell by approximately 50 per cent after denervation. The time course of the fall in monoamine oxidase activity of rat vas deferens was parallel to that of the disappearance of noradrenaline suggesting that this proportion of the total enzyme activity had a neuronal localization. The remaining enzyme activity is presumably located extraneuronally. Significant falls in catechol-O-methyl transferase activity were found in rat and rabbit vas deferens after denervation but not in guinea pig. The rabbit and rat vas deferens had respectively approximately 60 and 30 per cent of the catechol-O-methyl transferase activity associated with the sympathetic nerves. A complete loss of DOPA decarboxylase and tyrosine hydroxylase activities occurred in rat vas deferens after denervation, suggesting that these noradrenaline synthesizing enzymes have an entirely neuronal localization.     

Adrenergic enzymes in cultured mouse neuroblastoma: absence of detectable aromatic-L-amino-acid decarboxylase.

The relative activities of tyrosine hydroxylase, aromatic-l -amino-acid decarboxylase and dopamine beta-hydroxylase were established in a number of clones of neuroblastoma cells isolated from the uncloned mouse C-1300 tumor. One clone, NBD-2, was chosen for further analysis on the basis of its relatively high activities of tyrosine hydroxylase and dopamine beta-hydroxylase. The levels of these enzymes, and monoamine oxidase and catechol O-methyltransferase, were at least 20-80 fold lower in the neuroblastoma culture than in mouse superior cervical ganglion. More importantly, aromatic-l -amino-acid decarboxylase activity was not even detectable in any neuroblastoma clone examined. Based on the relative sensitivities of the tyrosine hydroxylase and aromatic-l -amino-acid decarboxylase assays and on the ratio of these two enzymes in the mouse ganglion, decarboxylase activity is more than 10 fold lower in the cultured cells than would be predicted on the basis of tyrosine hydroxylase activity. Dialysis and mixing studies with neuroblastoma extracts and partially purified aromatic-l -amino-acid decarboxylase did not reveal the presence of any endogenous inhibitors that could account for the low level of decarboxylase activity in the cultured cells. During growth of the neuroblastoma cells to confluency, only one enzyme, monoamine oxidase, exhibited an elevated specific activity on the basis of cell number. However, when based on the amount of protein, the specific activity of all measurable enzymes increased in culture-because cell protein decreased 5 fold during growth to confluency. These findings are discussed with respect to individual cell function.     

Changes in enzyme patterns produced by high potassium concentration and dibutyryl cyclic AMP in organ cultures of sympathetic ganglia

—Preliminary experiments had shown that acetylcholine, the putative mediator of trans-synaptic induction of tyrosine hydroxylase (TH) and dopamine β-hydroxylase (DBH) in vivo, did not lead to an increase in these enzyme activities in mouse superior cervical ganglia kept in organ culture. It was the aim of the present study to evaluate whether increases in tyrosine hydroxylase and dopamine β-hydroxylase evoked by other stimuli such as potassium or dibutyryl cyclic AMP in such an in vitro system are representative for in vivo trans-synaptic induction where changes in the levels of enzymes involved in norepinephrine synthesis or degradation are strictly confined to TH and DBH. In the presence of elevated concentrations of potassium or 5 mm dibutyryl cyclic AMP under organ culture conditions TH and DBH as well as DOPA decarboxylase and monoamine oxidase were significantly (P < 0.025) increased. The increase in total activities of TH and DBH were completely, those of DOPA decarboxylase and monoamine oxidase partially, inhibited by cycloheximide. In the presence of high concentrations of potassium, the total protein content of the ganglia was 28 per cent higher than in culture controls while dibutyryl cyclic AMP had no significant effect. Cycloheximide alone caused the protein content to fall to 70 per cent of that in control cultures. The loss of protein in the presence of cycloheximide was not accompanied by a simultaneous loss of TH, DOPA decarboxylase or monoamine oxidase, but DBH was decreased. Potassium was shown to increase the incorporation of [³H]leucine into TCA-insoluble protein during an early culture period but dibutyryl cyclic AMP showed no such effect. An increase in the rate of incorporation of [³H]leucine into protein was seen in both the control and elevated potassium cultures after 48 h. This increase did not occur in the presence of dbcAMP. The difference in enzyme patterns under conditions of elevated potassium and dibutyryl cyclic AMP and the fact that no changes in the levels of endogenous cyclic AMP were observed during exposure to 54 mm -potassium for a time period sufficient to initiate changes ultimately leading to elevated TH levels argues against the mediation of the potassium-induced enzyme increases by cAMP. Since changes in enzyme patterns caused by potassium and dbcAMP were not similar to patterns seen in vivo under conditions of trans-synaptic induction we conclude that use of this system as an in vitro model for in vivo trans-synaptic induction necessitates great caution.     

AXONAL TRANSPORT OF PHENYLETHANOLAMINE-N-METHYLTRANSFERASE IN TOAD SCIATIC NERVE

—The presence of phenylethanolamine-N-methyltransferase (EC 2.1.1.-) and dopamine-β-hydroxylase (EC 1.14.2.1) activities was demonstrated in the sciatic nerve of the toad, Bufo marinus. The rates of accumulation of phenylethanolamine-N-methyltransferase (PNMT) and dopamine-β-hydroxylase (DBH) proximal to a ligation of the sciatic nerve were studied. DBH accumulated proximal to the ligation at a more than 10-fold faster rate than PNMT. By measuring the rate of loss of enzyme activity distal to a ligation, an estimate of per cent clearance of each enzyme was made. Based on the per cent of enzyme activity free to move, the absolute transport rates for each enzyme were estimated to be: PNMT, 3.6 mm/24 h; DBH, 102 mm/24 h. PNMT activity (89 per cent) was recovered in the soluble fraction of sciatic nerve homogenates with no change occurring in the subcellular distribution of the enzyme proximal to ligations. In contrast, 43 per cent of DBH activity was found in the soluble fraction of sciatic nerve homogenates; but a disproportionate increase in paniculate DBH activity was found proximal to sciatic nerve ligations. Reduction of toad body temperature to 4°C resulted in a complete but totally reversible block of the axonal transport of both PNMT and DBH.     

LEVELS OF NOREPINEPHRINE AND DOPAMINE IN MOUSE BRAIN REGIONS FOLLOWING MICROWAVE INACTIVATION-RAPID POST-MORTEM DEGRADATION OF STRIATAL DOPAMINE IN DECAPITATED ANIMALS

—The effects of 2 methods of killing on norepinephrine and dopamine in mouse brain regions were examined. One method utilized decapitation, while the other method utilized heating with microwave irradiation concentrated on the head. The norepinephrine and dopamine contents of the cerebellum, medulla-pons, midbrain, diencephalon, hippocampus, corpus striatum, and cerebral cortex were determined by methods using liquid chromatography with electrochemical detection. Dopamine content in striatum was also quantitated by the method of gas chromatography with mass fragmentography. A significantly lower value for decapitated animals, as compared to the microwave heated group, was found only for dopamine exclusively in the striatum. Activities of the enzymes tyrosine hydroxylase, DO PA decarboxylase, monoamine oxidase, and catechol-o-methyltransferase in the striatum were also examined. These enzymes were totally inactivated by the microwave heating, except catechol-o-methyltransferase which was decreased approx 80%. These results support either (1) the existence of a substantial pool of dopamine in the striatum with a very rapid turnover rate or (2) a decapitation-related release and destruction of striatal dopamine. Measurements of 3-methoxytyramine in the striatum exhibit post-mortem increases corresponding to the decreases of dopamine. Use of the rapid tissue enzyme inactivation technique suggests that in vivo levels of this O-methylated dopamine metabolite are an order of magnitude lower than the results normally obtained after killing by decapitation.     

A study of selected catecholamine metabolizing enzymes: a comparison of depressive suicides and alcoholic suicides with controls

—The regional distributions of monamine oxidase (MAO) (EC 1.4.3.4), catechol-O-methyltransferase (COMT) (EC 2.1.1.6), tyrosine hydroxylase (TH) (EC 1.14.3.2), and dopamine-β-hydroxylase (DBH) (EC 1.14.2.1) have been examined in human brains obtained at autopsy from persons who died of natural causes (controls), and from persons who committed suicide and were further categorized as suffering from affective disorder (depression) or from alcoholism. Post mortem animal studies showed no changes in MAO or COMT activities in rabbit brain or in DBH activity in rat brain when the intact bodies were left at room temperature up to 24 h. TH activity in rabbit brains, however, began to decline immediately after death and after 24 h at room temperature it was approximately 48 per cent of the fresh brain level. There was no significant variation in activity of COMT, TH and DBH in human brain attributable to age or sex. MAO activities in the 60–70 yr decade were 34 per cent higher than in the 30–40 yr decade. MAO activities were highest in the hypothalamus and substantia nigra, TH activities were highest in substantia nigra, putamen and head of caudate, and DBH activities were greatest in tegmentum of pons and hypothalamus. Only minimal regional differences in COMT activities were observed. No significant differences were found between enzyme activities in brain areas of controls and suicides with the possible exception of TH in the substantia nigra, where the depressive suicides (but not the alcoholics) showed greater activity (P < 0·02). These findings appear not to support the catecholamine hypothesis of affective disorder.     

Concomitant elevation of tyrosine hydroxylase and dopamine beta-hydroxylase by cyclic AMP in cultured mouse neuroblastoma cells.

The effects of cyclic AMP analogues and of phosphodiesterase inhibitors were investigated in neuroblastoma cells (NBD-2) cloned from the C-1300 tumor. 8Br-cAMP and phosphodiesterase inhibitors that elevated cAMP induced large (greater than 15 fold) and specific increases in tyrosine hydroxylase and dopamine beta-hydroxylase activity. In contrast, catechol O-methyltransferase, monoamine oxidase and aromatic-l -amino-acid decarboxylase were unaffected by the cAMP altering drugs. Similarly, AChE was unaffected and only a small increase in choline acetyltransferase (3 fold) was observed. The increases in tyrosine hydroxylase and dopamine beta-hydroxylase were similar with respect to dose response relationships and with respect to time course of onset. Only those phosphodiesterase inhibitors that elevated cAMP (papaverine and Ro20-1724 as opposed to theophylline) were effective in elevating tyrosine hydroxylase and dopamine beta-hydroxylase. Further, the doses optimal for elevating cAMP coincided with the optimal doses for elevating the two enzymes. Theophylline had no influence either upon NBD-2 cell cAMP levels or upon tyrosine hydroxylase and dopamine beta-hydroxylase activity. The changes in protein synthesis rates produced by the cAMP altering drugs were temporally distinct from the changes in either tyrosine hydroxylase or dopamine beta-hydroxylase. These results suggest that the intracellular messenger compound cAMP is involved in the specific regulation of both tyrosine hydroxylase and dopamine beta-hydroxylase in adrenergic cells.     

Neurochemical Changes in Murine Trisomy 16: Delay in Cholinergic and Catecholaminergic Systems

Abstract: Two strains of Mus musculus musculus , C57BL/6J and CD-1, and Mus musculus poschiavinus , the tobacco mouse, were used to study the effects of increased gene dosage of mouse chromosome 16 (MMU 16). A developmental delay has been found in the brains of murine trisomy 16 (Ts 16) fetuses. Both the brain weight (in all three strains) and DNA content (in CD-1) were reduced, while protein content was unchanged in Ts16 compared to normal littermates. The daily increments of weight and protein (except in M. m. poschiavinus ) were significantly greater in Ts16. The activities of choline acetyltransferase and acetylcholinesterase and nuscarinic receptor binding were reduced. Their daily increments were also reduced to less than 56% that of littermates in Ts16 brains. The rate limiting enzymes of Catecholaminergic neurons, tyrosine hydroxylase and do-pamine β-hydroxylase, and the concentration of catecholamines in the brains of Ts16 animals were lower. The activities of three other Catecholaminergic enzymes, DOPA decarboxylase, catechol O -methyltransferase, and monoamine oxidase, were generally elevated in Ts16 brain, as were their daily increments. These observations indicate a significant developmental alteration in the maturation of the trisomic brain and suggest future avenues for defining the effect of increased gene dosage of MMU 16 in the CNS.     

STOP-FLOW ANALYSIS OF THE AXONAL TRANSPORT OF DOPA DECARBOXYLASE (EC 4.1.1.26) IN RABBIT SCIATIC NERVES

The axonal transport of DOPA-decarboxylase (EC 4.1.1.26) was investigated in rabbit sciatic nerves by means of in vitro stop-flow techniques. Enzyme activity accumulated just proximal to a region that was locally cooled to 5°C in nerves that were elsewhere incubated at 37°C. The accumulation of enzyme activity was linear with time and corresponded to an average orthograde transport velocity of 11 mm/day. Retrograde transport was not detected. When nerves that had been locally cooled for 3 h were rewarmed, the accumulated enzyme activity moved distally along them as a wave with a narrow range of velocities. The front of this wave traveled at a rate of about 150mm/day, and the mean velocity of the wave was about 120 mm/day. These values are much lower than those previously obtained for tyrosine hydroxylase (EC 1.14.16.2), dopamine-β-hydroxylase (EC 1.14.2.1) and norepinephrine in similarly designed experiments. Thus DOPA-decarboxylase appeared to be transported at intermediate velocities, and, since the mean velocity of the moving fraction was about 11 times the average velocity, it is ljkely that only 9% of the enzyme was undergoing transport at any given moment.     

Regional development of catecholamine biosynthesis in rat brain

Abstract— The ontogenetic development of norepinephrine and dopamine and their associated biosynthetic and degradative enzymes was investigated in five anatomical regions of the rat brain. Clear regional differences were found in the development of both norepinephrine and tyrosine hydroxylase (EC 1.14.3.1). In the case of both norepinephrine and tyrosine hydroxylase, brainstem structures achieved adult levels well before forebrain structures. The development of DOPA decarboxylase (EC 4.1.1.26), monoamine oxidase (EC 1.4.3.4) and catechol-0-methyl transferase (EC 2.1.1.6) did not appear to differmarkedly from area to area. Further analysis of the data revealed that in forebrain structures both the amines and the biosynthetic enzymes developed concurrently. By contrast, in the brainstem structures, there was a dissociation of amine and enzyme development with development of tyrosine hydroxylase, in particular, markedly preceding that of norepinephrine and of DOPA decarboxylase. The bases for both the lower amine levels in the infant brain and the regional developmental differences are discussed in relation to the anatomical organization of the central catecholamine-containing neurons.     

5-HYDROXYTRYPTAMINE AND NORADRENALINE IN THE HIPPOCAMPAL REGION: EFFECT OF TRANSECTION OF AFFERENT PATHWAYS ON ENDOGENOUS LEVELS, HIGH AFFINITY UPTAKE AND SOME TRANSMITTER-RELATED ENZYMES

The monoaminergic fibres enter the hippocampal formation through a dorsal and a ventral route. The dorsal route consisting of fimbria, fornix superior and cingulum, was estimated to supply about 75% of the 5-HT fibres and 40% of the noradrenaline containing (NA) fibres. The ventral route, allegedly passing through the amygdaloid area, accounts for the rest. The cingulum bundle contributes a definite part of the 5-HT fibres but very few of the NA fibres. No evidence was found for an intrinsic origin of monoaminergic fibres in the hippocampal region. Monoamine oxidase and catechol-O-methyltransferase showed no change following the lesions and are considered to be localized predominantly outside the aminergic neurones. The results on DOPA decarboxylase indicate that about 50% of the enzyme is situated outside 5-HT and NA nerves. Glutamic acid decarboxylase did not decrease even after transection of the ventral route, substantiating the earlier conclusion that this enzyme is situated in intrinsic neurones in the hippocampal region. For choline acetyltransferase and AChE the dorsal route was confirmed to be the only quantitatively important way of access. None of the enzymes studied, nor the uptake activities, were affected by cervical sympathectomy.     

Stability of enzymes in post-mortem rat brain.

Enzyme activities were measured in rat brains kept at room temperature for various intervals after death by decapitation. Tytosine hydroxylase, monoamine oxidase, choline acetyltransferase, and acetylcholinesterase show a substantial decline in activity over 14h reaching 64, 78, 60 and 58%, respectively. of the zero-time activity. DOPA decarboxylase, glutamic acid decarboxylase, lactate dehydrogenase, Na-K-ATPase and Mg-ATPase show less than a 15% decline in activity. The activities of most of the enzymes studied show little change time period when human brain specimens are likely between the 6th and 14th hour after death, the to be obtained for biochemical studies     

A Simple Radioenzymatic Method to Measure Picogram Amounts of DOPA in Brain and Biological Fluids

A simple radioenzymatic method for the determination of DOPA is described. The method is based on the conversion of DOPA to 3-O-[methyl-³H]DOPA by catechol-O-methyltransferase in the presence of S-adenosyl-[methyl-³H]methionine and purification of the labelled product by Sephadex G10 and Dowex 50 W × 4 ion exchange resin. The method has been applied to the assay of endogenous DOPA in different brain areas and to measuring DOPA accumulation after inhibition of aromatic amino acid DOPA decarboxylase.     

EVIDENCE FOR EXTRANORADRENERGIC DOPAMINE-β-HYDROXYLASE ACTIVITY IN RAT SALIVARY GLAND

—Three days after superior cervical ganglionectomy of adult Sprague-Dawley rats, the levels of endogenous norepinephrine, the uptake process for [³H]norepinephrine and the activity of tyrosine hydroxylase decreased 99 per cent in the ipsilateral salivary gland. In contrast, the activity of dopamine-β-hydroxylase and DOPA decarboxylase fell to 30 per cent of the activity of the contralateral innervated gland. Examination of the cofactor requirements, the characteristics of activation by cupric ion and the immunologic identity of this residual hydroxylase activity indicated that it was authentic dopamine-β-hydroxylase. The residual dopamine-β-hydroxylase in the denervated gland had the same subcellular distribution as the enzyme in the innervated salivary gland. Procedures that caused atrophy or hypertrophy of the acinar cells did not affect the total content of dopamine-β-hydroxylase in the denervated salivary gland. Chemical sympathectomy with 6-hydroxy-dopamine caused a 40 per cent decrement in the serum levels of dopamine-β-hydroxylase but a 30 per cent increase in its activity in the denervated salivary gland. Although denervation caused a complete loss of endogenous norepinephrine in the salivary gland, it resulted in only a 15 per cent decrement in the levels of endogenous octopamine and β-phenylethanolamine, two other products of dopamine-β-hydroxylase.     

REGIONAL DISTRIBUTION OF ENZYMES ASSOCIATED WITH NEUROTRANSMISSION BY MONOAMINES, ACETYLCHOLINE AND GABA IN THE HUMAN BRAIN

Abstract— The activities of tyrosine hydroxylase (T-OH). DOPA decarboxylase (DDC). dopamine-β-hydroxylase (DβH). monoamine oxidase (MAO), choline acetyltransferase (ChAT), acetylcholinesterase (AChE), l -glutamic acid decarboxylase (GAD) and the concentrations of DNA and RNA were measured in 13–20 areas of post-mortem brain tissue from neurologically and psychiatrically normal individuals. Emphasis has been put on regional distribution rather than establishing normal values and detailed comparisons have been made with previously published work on the normal human brain. Despite expressing all results relative to an internal reference point there was substantial inter-brain variability. There was no apparent relation between age, sex, medication, cause of death or time lag between death and dissection and any of the enzyme activities. Enzyme activities were fairly evenly distributed throughout cerebral cortex whereas clear differences existed along the rostro-caudal axis of the brain. It is hoped that this paper, with its companion paper on amine and metabolite concentrations, will be useful as a reference work for investigators of the chemical pathology of the human brain.     

Enzymes Related to Monoamine Transmitter Metabolism in Brain Microvessels

The activities of tyrosine hydroxylase, aromatic L-aminoacid decarboxylase, monoamine oxidase, and catechol-O-methyltransferase were measured in microvessel (capillaries and venules), parenchymal arterioles, and pial vessels from rat brains, and the decarboxylase activity was compared in brain microvessels from rabbit, cat, dog, pig, cow, baboon, and man. Cranial sympathectomy was performed to estimate the neuronal contribution to the enzyme activities. All vascular regions had substantial activities of the various enzymes studied. The activity of aromatic L-aminoacid decarboxylase in cerebral microvessels was high in rat, dog, pig, cow, and man; intermediate in rabbit and cat; and low in baboon. In addition to this enzyme, cerebral microvessels also contained tyrosine hydroxylase and monoamine oxidase. Aromatic aminoacid decarboxylase and monoamine oxidase serve an enzymatic barrier function at the microvascular level, whereas the main function of tyrosine hydroxylase is probably to synthesize monoamines within nerve terminals that remain in close association with microvessels under the conditions used for preparation of the microvascular fraction. In larger intracerebral and pial vessels monoamine oxidase was present both in the wall itself and in perivascular sympathetic nerves; the remaining two enzymes had a primarily neuronal localization. The latter types of vessels also contained catechol-O-methyltransferase in their walls.     

DISTRIBUTION OF BIOGENIC AMINES AND RELATED ENZYMES IN THE RAT PITUITARY GLAND

Abstract— Biogenic amines and related enzymes were quantitatively measured in the pituitary gland of the rat. The sensitivity of the assays used allows the determinations to be performed in single pituitary lobes. Relatively high values of histamine and serotonin were found in all three lobes, with higher amounts in the posterior and intermediate lobes. Highest catecholamine concentrations were detected in the posterior lobe, and only very low amounts of dopamine were measured in the anterior lobe. Throughout the gland, norepinephrine concentrations were low, about one-tenth that of dopamine. Tryptamine could not be detected. High levels of A and B monoamine oxidase were found in all three pituitary lobes. Tyrosine hydroxylase activity was measured in the posterior and intermediate lobes, but was not detected in the anterior lobe. Tryptophan hydroxylase was present in all three pituitary lobes. A relatively low catechol- O -methyltransferase activity was found in the anterior lobe, and none was detected in the intermediate and posterior lobe. Choline acetyltransferase, dopamine-β-hydroxylase and phenylethanolamine- N -methyltransferase activities could not be detected.     

Role of tyrosine, DOPA and decarboxylase enzymes in the synthesis of monoamines in the brain of the locust

The metabolic transformation of tyrosine (TYR) by the decarboxylase and hydroxylase enzymes was investigated in the central nervous system of the locust, Locusta migratoria. It has been demonstrated that the key amino acids, 3,4-dihydroxyphenylalanine (DOPA), 5-hydroxytryptophan (5HTP) and tyrosine are decarboxylated in all part of central nervous system. DOPA and 5HTP decarboxylase activities show parallel changes in the different ganglia, but the rank order of the activity of TYR decarboxylase is different. Enzyme purification has revealed that the molecular weights of TYR decarboxylase and DOPA/5HTP decarboxylase are 370,000 and 112,000, respectively. The decarboxylation of DOPA by DOPA/5HTP decarboxylase is stimulated, whereas the decarboxylation of DOPA by TYR decarboxylase is inhibited in the presence of the cofactor pyridoxal-5'-phosphate. TYR hydroxylase could not be detected and 3H-TYR is found to be metabolised to tyramine (TA), but not to DOPA. The haemolymph contains a significant concentration of DOPA (120 pmol/100 microl haemolymph), and the ganglia incorporates DOPA from the haemolymph by a high affinity uptake process (K(M)=12 microM and V(max)=24 pmol per ganglion/10 min). Our results suggest that no tyrosine hydroxylase is present in the locust CNS and the DOPA uptake into the ganglia by a high affinity uptake process as well as the DOPA decarboxylase enzyme may be responsible for the regulation of the ganglionic dopamine (DA) level. Two types of decarboxylases exist, one of them decarboxylating DOPA and 5HTP (DOPA/5HTP decarboxylase), other decarboxylating TYR (TYR decarboxylase). The DOPA/5HTP decarboxylase enzyme present in the insect brain may correspond to the 5HTP/DOPA decarboxylase in vertebrate brain, whereas TYR decarboxylase is characteristic only for the insect brain.