The monoamines in molluscs. II. Dopamine and neurotransmission. Cardiac dopaminergic innervation in Helix pomatia (author's transl)]

In the molluscs, dopamine is very probably a chemical transmitter at the level of both the central nervous system and certain peripheral structures. The heart of Helix pomatia does not have any intrinsic innervation, but it receives extrinsic innervation from fibres coming from the visceral nerve. Formaldehyde fluorescence histochemistry localizes the cardiac catecholamines in some of these fibres and in their endings. However, dopamine, which dominates, does not seem to be a transmitter involved in cardioregulation in the same way as 5-hydroxytryptamine. The quantities of active dopamine (stimulants) cannot be compared with those required for a neurotransmitter. This is also true for noradrenaline. Dopamine more certainly plays a role at the metabolic and tropic level by acting within a more or less short period as a regulator of cellular activity and contractility. The Helix heart is a suitable model for future research in this field.     

Relationship Between Phenolamines and Catecholamines During Rat Brain Embryonic Development In Vivo and In Vitro

p-Octopamine and phenylethanolamine are present in the embryonic rat brain earlier than catecholamines. These phenolamines are localized mainly in the hypothalamus, where the level of p-octopamine is very high. The parallel developmental study of the activities of dopamine beta-hydroxylase, 3,4-dihydroxyphenylalanine decarboxylase, tyrosine hydroxylase, and monoamine oxidase shows that phenolamines are present in significant amounts in the hypothalamus until tyrosine hydroxylase and monoamine oxidase become catalytically active. The culture of embryonic hypothalamus at different ages shows that no tyrosine hydroxylase and monoamine oxidase activities can be detected if the tissue is cultured before 15 days. This clearly indicates that all the enzymes related to catecholamine biosynthesis are not triggered at the same time during the development of the rat brain. These results are discussed on the basis of the physiological importance of phenolamines in mammals and of the use of the developing rat brain as a model for the study of the onset of the catecholaminergic system and the decline of the octopamine.     

Effect of testosterone and 6-hydroxydopamine treatment on the metabolism of catecholamine and 5-hydroxytryptamine in methylcholanthrene-induced prostate carcinoma of rats.

The precursors tyrosine and tryptophan as well as the synthesizing and deaminating enzymes of catecholamines have been identified in methylcholanthrene-induced prostatic carcinoma of rats. Tyrosine hydroxylase, monoamine oxidase, catechol O-methyltransferase, dopamine, 5-hydroxytryptamine, and 5-hydroxyindoleacetic acid seemed to be neoplastic in origin, since electron microscopic studies failed to reveal the presence of any neuronal elements in this squamous epithelial cell carcinoma. Castration of rats significantly reduced the activity of tyrosine hydroxylase and the levels of tyrosine, dopamine, tryptophan, 5-hydroxytryptamine, and 5-hydroxyindoleacetic acid in prostate tumors. The changes appeared to be androgen specific since reintroduction of testosterone restored several of these biochemical parameters virtually to control limits. Chemical sympathectomy induced by 6-hydroxydopamine failed to alter monoamine metabolism; however, the prostatic tumor grown in 6-hydroxydopamine-treated rats showed significantly (32%) less necrosis than those grown in normal animals.     

Peripheral secretion and inactivation of catecholamines (adrenaline, noradrenaline, dopamine)]

In spite of the biochemical relationship between catecholamines (E,NE,DA), the unity of the adrenergic system is only apparent; catecholamines are present in numerous pools, which exhibit different anatomical and cellular localizations, secretory patterns, control of release, physiological functions, inactivation schemes and metabolic behaviour. The main sources of catecholamines in the periphery are the orthosympathetic nervous system, which is permanently active in maintaining homoeostasy, and the adrenal medulla, an essential element in the struggle against stress. In addition to these large pools, catecholamines are found also in extra adrenal chromaffin tissue and in sympathetic ganglions; the latter represents a potential store of amines, whilst ganglionic dopamine-rich interneurones are important links in the regulation of orthosympathetic activity. Rather than by a topographic distinction, it seems more satisfactory to classify the catecholamines spread in adrenergic fields into a small number of pools possessing their own physiological functions and inactivation patterns. Two main pools of catecholamines in the periphery may be described: The functional pool, represented by those catecholamines already released, or able to be released; in this pool are found plasma and adrenal medullary catecholamines and NE from sympathetic nerve endings. The tissue pool, consisting of the synthesis and storage compartments, which are poorly penetrated by plasma pool with respect to their high possibilities for synthesis and storage. Catecholamines from cellular bodies and axons of sympathetic neurons and a part of the adrenal medullary amines may be related to it. Two other pools of catecholamines have to be reported: a potential extrachromaffin pool, which is apparently negligible in the physiological state, but able to exhibit its synthetic and secretory capacities in particularly critical situations; an intraganglionic dopamine pool, which plays a modulator role in ganglionic synaptic transmission; its mode of secretion and inactivation are not necessarily the same as those of the above pools. To such a physiological diversity, specific regulatory processes, correspond the aim of which is, to stop physiological activity of released catecholamines, by means of physical and chemical inactivating mechanisms; to limit the amount of released product by local control of the neuromediator outflow; to minimize losses of active compound by neuronal and cellular uptake and perhaps by sulfoconjugation; to destroy the excess of synthesized or reabsorbed amines when tissue or neuronal concentration becomes too high (tissue metabolism).     

Ultrastructural and morphometric characteristics of cardiomyocyte mitochondriomes of several invertebrate species. II. Heart ventricle cardiomyocyte mitochondriome of several gastropod mollusks

The mitochondrial ultrastructure in ventricle cardiomyocytes of three gastropod molluscs (Clione limacina, Helix pomatia, Lymnaea stagnalis) has been studied. Mitochondria in cardiomyocytes of these molluscs are connected by intermitochondrial contacts of the same morphology as intermitochondrial contacts in vertebrate cardiomyocytes. Their numbers in cardiomyocytes of the above molluscs being, respectively, 61, 35.1 and 29.2 contacts per 100 mitochondria. In Clione limacina cardiomyocyte contractile elements located on the periphery of cell occupy 21.1% of the cytoplasm volume. Mitochondria form a core making large dense central accumulations taking up 54.9% of the cytoplasm volume. Numerous mitochondria have vesicular or tubular cristae and light matrix. Unlike cardiomyocytes of Clione limacina, in Helix pomatia and Lymnaea stagnalis contractile material predominates in cardiomyocytes occupying 43.7% and 49.2% of the cytoplasm volume, respectively. Mitochondria located on the periphery and in the center of cardiomyocytes in Lymnaea stagnalis and Helix pomatia occupy 31 and 32.5% of the cytoplasma volume, respectively. Mitochondria in cardiomyocytes of both these molluscs have plastic cristae and dense matrix. The differences in cardiomyocyte mitochondriom organization in the studied molluscs can be explained by different functional heart loading in these due to different levels of their locomotor activity.     

Iron Deficiency Alters the Day‐Night Variation in Monoamine Levels in Mice

Monoamine metabolism in the central nervous system is altered by dietary iron deficiency, with a stronger effect seen during the active than rest span of the circadian cycle. In this report, we examined changes in intracellular and extracellular monoamine levels, synthetic enzymes, transporter and receptor densities, and responses to amphetamine‐induced dopamine (DA) efflux in iron‐deficient and iron‐sufficient mice. Extracellular striatal DA levels were 15–20% higher in all groups during the active dark phase compared to the inactive light phase, with correspondingly lower dopamine transporter (DAT) and higher tyrosine hydroxylase levels. Iron deficiency decreased DAT density by 20% and 28% in the light and dark phases, respectively, and elevated the DOPAC/DA ratio only in the dark, indicating that iron deficiency does interact with the normal diurnal cues for cyclicity. Enhanced DA efflux after amphetamine stimulation indicates no limitation on monoamine synthesis and release and is consistent with altered synaptic efficacy and perhaps recycling of DA in iron deficiency. These experimental findings provide new evidence that brain iron insufficiency does have a differential effect on the DA system at different biological times of the day and night and may be causally related to the phasic motor symptoms observed in Restless Legs Syndrome.     

Effect of Experimental Diabetes on the Catecholamine Metabolism in Rat Brain

The levels of epinephrine, norepinephrine, and dopamine and the activities of tyrosine hydroxylase and monoamine oxidase were estimated in four regions of rat brain during alloxan-induced hyperglycemia and insulin-induced hypoglycemia. Catecholamine levels were estimated by HPLC, and the insulin levels were quantified by radioimmunoassay. The results demonstrated significant increases in the activities of the metabolizing enzymes and levels of catecholamines during experimental conditions. The levels of catecholamines were highest in the cerebral hemispheres, the region associated with high activities of the metabolizing enzymes. Insulin-induced hypoglycemia caused a decrease in the activities of the metabolizing enzymes followed by their recovery within 2 h.     

High resolution spatial distribution of neuropeptides by MALDI imaging mass spectrometry in the terrestrial snail, Helix pomatia

Imaging mass spectrometry (IMS) is a powerful technique that combines the chemical and spatial analysis of surface materials. It allows spatial localization of peptides, proteins or lipids that are recorded in parallel without the need of a label. It is currently one of the most rapidly developing techniques in the proteomics toolbox. In the present study, accurate mass matrix-assisted laser desorption/ionization imaging mass spectrometry (MALD IMS) was used for direct molecular mapping of nervous tissue at micrometer spatial resolution. Cryosections of the whole brain of the terrestrial snail, Helix pomatia, were placed on indium-tin-oxide (ITO)-coated conductive glass slides and covered with a thin layer of α-cyano-4-hydroxycinnamic acid (CHCA) matrix by electro spray deposition. High-resolution molecular ion maps of well-known neuropeptides, such as FMRFamide were constructed. FMRFamide is known to exert powerful modulatory effect on synaptic transmission in molluscs. FMRFamide was predominantly localized in the cluster of neurons in the pro-, meso- and postcerebral regions of cerebral ganglia, pedal ganglia and right parietal ganglia of the central nervous system. Our present study, using MALDI IMS confirmed the distribution of FMRFamide containing cells in the Helix central nervous system previously detected by antibody dependent immunohistochemistry.     

Deranged Tyrosine Metabolism in Cirrhosis

In normal individuals, the main route for tyrosine degradation is the hepatic pathway tyrosine→4-hydroxyphenylpyruvic acid→homogentisic acid→CO₂. Quantitatively minor pathways, in large part extrahepatic, are: tyrosine→tyramine→octopamine and tyrosine→dopa→catecholamines.In cirrhosis, the main hepatic pathway is blocked to varying degrees at the first three stages. This appears to be due to lack of activity of the enzymes tyrosine transaminase, PHPA oxidase, and HGA oxidase, the first step being rate limiting. Hypertyrosinemia and tyrosine intolerance result.With the main hepatic pathway partially blocked, an abnormally large amount of tyrosine passes into the normally minor extrahepatic pathway leading to the false neurotransmitters tyramine and octopamine. Overproduction of these amines ensues and they accumulate in the body fluid.The false neurotransmitters can displace catecholamines from their storage sites in the peripheral and central nervous system, and thereby disrupt adrenergic processes in arterioles, kidneys, and brain. Their accumulation in cirrhotic patients may play a role in the pathogenesis of hepatic encephalopathy, hepatorenal syndrome, and hyperdynamic circulation.     

AN INHERITED DEFICIENCY IN NORADRENALINE BIOSYNTHESIS IN THE BRINDLED MOUSE

—A reduction in central and peripheral synthesis of noradrenaline has been demonstrated in mice hemizygous for the X-linked brindled (Mo^br) mutant in the mouse. The results are consistent with defective hydroxylation of dopamine to NA, arising either as a result of a primary genetic defect in the enzyme dopamine-β-hydroxylase or from the presence of a highly specific inhibitor of this enzyme in mutant mice. Associated with this deficiency of noradrenaline are an increase in the activity of tyrosine hydroxylase in the central nervous system and an increase in the active uptake of tyrosine (and other amino acids sharing a common uptake mechanism with tyrosine) across the blood-brain barrier.     

The ultrastructure of the central nervous system neurons and synapses in the edible snail under a high concentration of potassium ions]

The morphometric and electron microscopic results on neuronal and synaptic ultrastructure of central nervous system of Helix pomatia snail, incubated in vitro in media with high potassium ion concentration are represented in the present paper. The activation of glial cells is revealed with its close attachment to neurons. The energization of neuronal mitochondria and signs of cytoplasmatic oedema are clearly visible. The penetration of glial endings in the large neuronal branches and the synaptic vesicles confluence in neuronal endings are found.     

免疫细胞内源性儿茶酚胺的免疫调节作用

机体内儿茶酚胺（catecholamines,CAs）包括去甲肾上腺素（norepinephrine,NE）、肾上腺素（epinephrine,E）和多巴胺（dopamine,DA）。CAs由神经元和内分泌细胞合成和分泌,其主要功能是调节心血管、呼吸和消化等内脏活动。近三十年来的研究说明,CAs也参与调控机体的免疫功能,但CAs的这种免疫调节作用一般视为神经和内分泌系统调节的介导作用。然而,近年来的研究发现,免疫细胞也能合成CAs,这是对传统观念的一种补充和提高。免疫细胞内存在经典的CAs代谢途径,既有合成CAs的酪氨酸羟化酶（tyrosine hydroxylase,TH）又有降解CAs的单胺氧化酶（monoamine oxidase,MAO）和儿茶酚氧位甲基移位酶（catechol-O-methyl transferase,COMT）。免疫细胞合成的内源性CAs可以调控细胞的增殖、分化、凋亡和细胞因子生成等多种免疫功能。CAs的这些作用可能主要通过自分泌或旁分泌途径作用于免疫细胞上相应受体和细胞内环磷酸腺苷（cyclicAMP,cAMP）实现。细胞内氧化应激机制可能也参与免疫细胞内源性CAs的免疫调节作用。此外,一些自身免疫性疾病如多发性硬化、风湿性关节炎可能也与免疫细胞内CAs的代谢异常有关。上述发现不仅为免疫系统有可能成为除神经和内分泌系统以外的第三个CA能系统提供了证据,而且为免疫系统内源性CAs的功能意义拓展了认识。     

Peripheral distribution of a neuropeptide recognized by an antiserum raised against the mammalian CRF41, in the mollusc Helix pomatia

Immunocytochemical methods using an antiserum raised against ovine corticoliberin revealed perikarya and processes in the central and peripheral nervous system of the Pulmonate Gastropod Helix pomatia. The coexistence of immunoreactive nerve fibres and primary sensory neurons in the intestinal wall and in the tentacles appeared particularly significant. The distribution of this peptide suggests that it could act as a sensory neurotransmitter at the central and peripheral levels.     

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.     

Catecholamines up integrates dopamine synthesis and synaptic trafficking

The highly reactive nature of dopamine renders dopaminergic neurons vulnerable to oxidative damage. We recently demonstrated that loss-of-function mutations in the Drosophila gene Catecholamines up (Catsup) elevate dopamine pools but, paradoxically, also confer resistance to paraquat, an herbicide that induces oxidative stress-mediated toxicity in dopaminergic neurons. We now report a novel association of the membrane protein, Catsup, with GTP cyclohydrolase rate-limiting enzyme for tetrahydrobiopterin (BH(4)) biosynthesis and tyrosine hydroxylase, rate-limiting enzyme for dopamine biosynthesis, which requires BH(4) as a cofactor. Loss-of-function Catsup mutations cause dominant hyperactivation of both enzymes. Elevated dopamine levels in Catsup mutants coincide with several distinct characteristics, including hypermobility, minimal basal levels of 3,4-dihydroxy-phenylacetic acid, an oxidative metabolite of dopamine, and resistance to the vesicular monoamine transporter inhibitor, reserpine, suggesting that excess dopamine is synaptically active and that Catsup functions in the regulation of synaptic vesicle loading and release of dopamine. We conclude that Catsup regulates and links the dopamine synthesis and transport networks.     

The possible roles of the monoaminergic system in the feeding of the snail Helix pomatia

The possible role of serotonin and dopamine in the feeding of Helix pomatia was studied applying immunocytochemical, biochemical, and behavioral techniques as well as bioassay experiments. Immunocytochemistry showed that dopamine-containing (thyrosin-hydroxylase-immunoreactive) neuronal elements of the crop and the gizzard belong to the intrinsic part, whereas serotonin-containing (serotonin-immunoreactive) neuronal elements belong to the extrinsic part of the gastrointestinal nervous system. Bioassay studies on the spontaneous contractions of the crop and the gizzard showed that dopamine affected only the longitudinal muscle contractions by increasing both the tonus and contractility, whereas serotonin was effective on both the longitudinal and circular muscle contractions. Serotonin increased the tonus and contractility of longitudinal muscles in the crop but decreased them in the gizzard. Serotonin decreased the tonus and contractility of the circular muscles in the crop but increased them in the gizzard. Serotonin effects on the circular muscle of the gizzard were concentration dependent between a range of 10(-5) M-3 x 10(-5) M. HPLC measurements of monoamines in starved and satiated animals showed that the concentration of both dopamine and serotonin significantly decreased in both the CNS and different parts of the gastrointestinal tract of satiated animals, suggesting a significant monoamine liberation during feeding. The injection of monoamines (10(-3) and 10(-2) M) into the body cavity of starved animals showed that only dopamine was able to induce feeding whereas serotonin increased the general activity of the animals suggesting that the initiation of feeding is rather dopamine than serotonin dependent.     

Neurogenic contractile activity of the penis retractor muscle of Helix pomatia L.

Using convential mechanical and electromyographic recording methods 2 distinct types of neurogenically elicited activity can be observed in the penis retractor muslce (PRM) of Helix pomatia: (1) rhythmic, phasic contractions correlated with single or a few compound action potentials and (2) intervening, strong, prolonged contractions accompanied by sustained, high frequency electrical muscle activity. The 2 distinct types of muscle activity which seem to play a part in the normal behaviour of the PRM in the intact animal are mediated by both the central nervous system and peripheral neurons. While central neuronal structures are involved in causing the strong, prolonged contractions, the phasic activity is initiated by peripheral neuronal structures located at the proximal end of the PRM. There is evidence that the transmission of the excitation at the neuromuscular level of central and peripheral origin is mediated by ACh.     

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.     

Dopamine and norepinephrine uptake and metabolism by astroglial cells in culture

Primary cultures of normal astroglia started from the cerebral hemispheres of neonatal rats took up dopamine (DA) and norepinephrine (NE) in the concentration range of 10^?7 to 10^?4M and metabolized each to their respective principal central nervous system products by the actions of both catechol-0-methyl transferase and monoamine oxidase. At 10^?7M, uptake of ³H labelled DA and NE was inhibited by omission of Na⁺, addition of ouabain or lowered temperatures. Uptake at 10^?4M was considerable but was Na⁺-independent. Only Na⁺-independent uptake was seen in primary cultures started from the meninges of neonatal rats. These data suggest that astroglial cells in the CNS have a high affinity uptake system for catecholamines, and such uptake is followed by catecholamine metabolism.     

Evidence for a functional coupling between dopamine reuptake and tyrosine hydroxylation in striatal nerve terminals

In rat striatal synaptosomes incubated with [¹⁴C]tyrosine, the evolution of ¹⁴CO₂, taken as a measure of dopamine synthesis, was inhibited by exogenous dopamine and by the dopaminergic receptor agonist ADTN. The inhibition was not counteracted by dopaminergic receptor antagonists (haloperidol, sulpiride, pimozide or domperidone). Instead, it was prevented by dopamine uptake blockers, suggesting that dopamine and ADTN (a substrate of the dopamine carrier) acted once inside the nerve endings and not through activation of autoreceptors on their external membrane. The dopamine uptake inhibitors nomifensine, benztropine and cocaine increased ¹⁴CO₂ evolution from incubated striatal synaptosomes. Depolarization with KCl also increased dopamine synthesis and this action was potentiated when the reuptake of the released catecholamine was prevented by carrier blockers. The rate of dopamine synthesis was lowered when synaptosomal dopamine was raised upon incubation with monoamine oxidase inhibitors or with l-DOPA. The inhibition was counteracted by dopamine reuptake blockers. The data suggest that dopamine synthesis in striatal nerve endings is under the inhibitory control of the transmitter recaptured following release.