Endogenous serotonin release from the dopamine-deficient striatum of the weaver mutant mouse

In addition to an altered dopaminergic input, the striatum of the weaver mutant mouse (wv/wv) has increased serotonin tissue content and uptake compared to the wild-type mouse (+/+). To gain information regarding the functional status of serotonergic inputs to thewv/wv striatum, endogenous serotonin release fromwv/wv and +/+ striatum was measured under basal conditions as well as in the presence of fenfluramine or elevated concentrations of potassium (K⁺). Fractional basal release of serotonin from the +/+ striatum was significantly greater than that from thewv/wv striatum. In the presence of K⁺, evoked release (stimulated release minus basal release) was greater from the +/+ striatum than from thewv/wv striatum. In the presence of fenfluramine, evoked serotonin release was greater from thewv/wv striatum compared to the +/+ striatum. These data are consistent with the involvement of an additional transmitter(s) in modulating serotonin release to a greater extent in thewv/wv than the +/+ striatum. The data on fenfluramine-stimulated serotonin release suggest that the additional serotonin content found in thewv/wv striatum is in a releasable pool but that striatal serotonin release might be attenuated more inwv/wv than in +/+ mice.     

How does the unicellular <Emphasis Type="Italic">Tetrahymena</Emphasis> utilise the hormones that it produces? Paying a visit to the realm of atto-and zeptomolar concentrations

Changes in the hormone content of Tetrahymena pyriformis GL were investigated during histamine, serotonin or insulin treatment at concentrations of 10⁻⁶M to 10⁻²¹M for 30 min. The immunologically demonstrable hormone content was studied by using specific antibodies, flow cytometry and confocal microscopy. Histamine at the higher ranges elevated the serotonin content of Tetrahymena, whereas serotonin at the lower ranges (down to 10⁻²¹M) decreased its histamine levels. Insulin did not affect its serotonin content, whereas serotonin increased its insulin content at each concentration studied (down to 10⁻²¹M). Insulin between 10⁻⁶M and 10⁻²¹M increased the hista-mine levels of Tetrahymena, although histamine influenced its insulin level only at 10⁻⁶M. Our results call attention to the presence of hormonal interactions even at “low” levels of phylogeny and to the extreme sensitivity of the hormone receptors of Tetrahymena. These data might explain (1) the requirement of Tetrahymena for (vertebrate) hormone production and hormone receptors and (2) the way that it uses these hormones under natural conditions.This work was supported by the National Research Fund (OTKA-T-037303), Hungary.     

Biosynthesis of serotonin in Raphé nuclei of rat brain: effect of p-chlorophenylalanine

The activity of tryptophan hydroxylase (EC 1.99.1.4) in the region of the raphé nuclei of rat brain was higher than that of any other brain area. The content of serotonin and the rate of serotonin synthesis were also highest in the raphé nuclei. Following the administration of p-chlorophenylalanine the injection of tryptophan and pargyline increased the content of serotonin in the region of the raphé nuclei of rat brain. The results suggest that the raphé nuclei retained the capacity to hydroxyl-late tryptophan to some extent after the injection of p-chlorophenylalanine.     

RAT BRAIN SYNAPTIC VESICLES: UPTAKE SPECIFICITIES OF [3H]NOREPINEPHRINE AND [3H]SEROTONIN IN PREPARATIONS FROM WHOLE BRAIN AND BRAIN REGIONS1

A fraction containing neurotransmitter storage vesicles was isolated from rat whole brain and brain regions, and the uptakes of [³H]norepinephrine and [³H]serotonin were determined in vitro. Norepinephrine uptake in vesicle preparations from corpus striatum was higher than in prep arations from cerebral cortex, and uptake in vesicles from the remainder (midbrain + brainstem + cerebellum) was intermediate. The K_m for norepinephrine uptake was the same in the three brain regions, but the regions differed in maximal uptake capacity by factors which paralleled total catecholamine concentration rather than content of norepinephrine alone. Intracisternal administration of 6-hydroxydopamine, but not of 5,6-dihydroxytryptamine, reduced vesicular norepinephrine uptake, and pretreat-ment with desmethylimipramine (which protects specifically norepinephrine neurons but not dopamine neurons from the 6-hydroxydopamine) only partially prevented the loss of vesicular norepinephrine uptake. These studies indicate that uptake of norepinephrine by rat brain vesicle preparations occurs in vesicles from norepinephrine and dopamine neurons, but probably not in vesicles from serotonin neurons. Uptake of serotonin by brain vesicle preparations exhibited time, temperature and ATP-Mg²⁺ requirements nearly identical to those of norepinephrine uptake. The affinity of serotonin uptake matched that of serotonin for inhibition of norepinephrine uptake, and the maximal capacity was the same for serotonin as for norepinephrine. Norepinephrine, dopamine and reserpine inhibited serotonin uptake in a purely competitive fashion, with K_is similar to those for inhibition of norepinephrine uptake. Whereas 5,6-dihydroxytryptamine treatment reduced synaptosomal serotonin uptake but not vesicular serotonin uptake, 6-hydroxydopamine reduced vesicular serotonin uptake in the absence of reductions in synaptosomal serotonin uptake. Thus, in this preparation, serotonin appears to be taken up in vitro into catecholamine vesicles, rather than into serotonin vesicles.     

Die Bildung von Serotonin in Juglans regia L.

Summary The serotonin content of growing fruits and of germinating seeds of Juglans regia has been studied. In the embryo 0.4–0.6 mg serotonin/g FW were found; in contrast no serotonin was detectable in the fleshy pericarp and in the seed coat. Serotonin was also not detectable in leaves, stems and roots of the adult plant. Most of the serotonin found in the embryo is formed after abscission of the seeds. During the synthesis of serotonin there are no dramatic changes in the chemical composition of the seeds (Tables 3–5).The formation of serotonin could be followed in isolated cotyledons and under sterile conditions. This serotonin formation is stimulated by exogenous tryptophan (Fig. 2). That tryptophan acts as a precursor of serotonin could be demonstrated with labelled DL-tryptophan (benzene ring ¹⁴C) (U). The possibility of stimulating serotonin formation in isolated cotyledons by the addition of tryptophan is limited to a certain stage of development and cannot be observed with material from fully matured seeds (Fig. 3).No serotonin was found in callus tissue and adventitious roots formed by isolated cotyledons; all the serotonin remained in the cotyledons. This was also the case in young seedlings, in which only the cotyledons showed the characteristic high serotonin content, whereas leaves, stems and roots contained no serotonin (Table 6).From these data we conclude that serotonin formation in the embryo of Juglans regia is not a special type of nitrogen storage but a way of ammonia detoxification in which ammonia from protein amino acid degradation is incorporated into serotonin via tryptophan.     

Effect of Serotonin on Development of the Luteinizing Hormone-Releasing Hormone System in Wistar Rat Embryos

The work studied effect of serotonin on development of the system of luteinizing hormone-realizing hormone (LHRH) in rats at the prenatal period. LHRH-neurons located along its migration pathway were revealed immunocytochemically at the 18th day of embryonal development (E18 and so on) after serotonin synthesis inhibition by daily intraperitoneal injections of n-chlorophenylalanine from E11 to E17 (experimental group). In control animal group, the saline was injected. The percent content of LHRH-neurons located in the forebrain rostral part was higher in the experimental group as compared to control. The opposite quantitative ratio of neurons was observed in the more caudal (hypothalamic) area. This indicates deceleration of the LHRH-neuronal migration under conditions of serotonin deficit. Study of the LHRH-neuron differentiation showed that in the experimental group the neuron optical density correlating with the LHRH content in the cell decreased as compared to the control group both in males and in females. The size of LHRH-neurons on n-chlorophenylalanine administration decreased, but only in females. Thus, serotonin affects both migration and differentiation of LHRH-neurons.     

Variation in ITGB3 has sex-specific associations with plasma lipoprotein(a) and whole blood serotonin levels in a population-based sample

A recent genome-scan identified the Leu33Pro polymorphism in the 3 integrin (ITGB3) gene as a quantitative trait locus for whole blood serotonin level in a large Hutterite pedigree. Because both the Leu33Pro polymorphism and the serotonin system have been implicated in cardiovascular disease (CVD) risk and treatment response, we studied additional variation in ITGB3 and its relationship to intermediate phenotypes associated with CVD in the same population. We examined associations between 15 single nucleotide polymorphisms (SNPs) across ITGB3 and five CVD-related traits in the Hutterites: plasma levels of high density lipoprotein-cholesterol (HDL-c), triglycerides (TG), low density lipoprotein-cholesterol (LDL-c), and lipoprotein(a) [Lp(a)] and blood pressure or hypertension. Seven of these SNPs in ITGB3 were associated with whole blood serotonin. Among the intermediate CVD-related phenotypes, only Lp(a) was associated with multiple ITGB3 SNPs, five of which were also associated with serotonin. A sex-stratified analysis revealed that the association between ITGB3 and Lp(a) is present only in females, whereas the association between ITGB3 and serotonin is concentrated in males. Our results suggest that variation in ITGB3 in addition to Leu33Pro could contribute to susceptibility to CVD and serotonin in a sex-specific manner.     

Effect of steroid hormones on serotonin,norepinephrine and epinephrine contents in the pineal-paraphyseal complex of the soft-shelled turtle (Lissemys punctata punctata)

Summary Steroids (testosterone, oestrogen, progesterone, corticosterone, dexamethasone and deoxycorticosterone) were administered intramuscularly (0.1 mg · 100 g bw^-1) on seven consecutive days to juvenile male soft-shelled turtles. Serotonin, norepinephrine and epinephrine contents of the pineal-paraphyseal complex were measured spectrofluorometrically 24 h after the last injection. Testosterone and oestrogen decreased serotonin, norepinephrine and epinephrine levels. Progesterone treatment resulted in an increase of serotonin level and a fall in norepinephrine and epinephrine levels. Corticosterone treatment caused an increase of serotonin level and a decrease of norepinephrine and epinephrine levels. Dexamethasone failed to alter serotonin content, increased norepinephrine and decreased epinephrine levels. Deoxycorticosterone decreased serotonin and elevated epinephrine content.Abbreviations 5-HIAA 5-hydroxyindole-acetic acid - 5-MTOH 5-methoxytryptophol - ANOVA analysis of variance; bw body weight - COMT catecholamine-o-methyl transferase - E epinephrine - HIOMT hydroxyindole-o-methyl transferase - MAO monoamine oxidase - MS mean sum of squares - NAT N-acetyltransferase - NE norepinephrine - SR synaptic ribbon - SS sum of squares - SV source of variation     

Modulation of swimming behavior in the medicinal leech

Expression of swimming in the medicinal leech (Hirudo medicinalis) is modulated by serotonin, a naturally occurring neurohormone. Exogenous application of serotonin engenders spontaneous swimming activity in nerve-cord preparations. We examined whether this activity is due to enhanced participation of swim motor neurons (MNs) in generating the swimming rhythm. We found that depolarizing current injections into MNs during fictive swimming are more effective in shifting cycle phase in nerve cords following serotonin exposure. In such preparations, the dynamics of membrane potential excursions following current injection into neuronal somata are substantially altered. We observed: 1) a delayed outward rectification (relaxation) during depolarizing current injection, most marked in inhibitory MNs; and 2) in excitor MNs, an enhancement of postinhibitory rebound (PIR) and afterhyperpolarizing potentials (AHPs) following hyperpolarizing and depolarizing current pulses, respectively. In contrast, we found little alteration in MN properties in leech nerve cords depleted of amines. We propose that enhanced expression of swimming activity in leeches exposed to elevated serotonin is due, partly, to enhancement of relaxation, PIR and AHP in MNs. We believe that as a consequence of alterations in cellular properties and synaptic interactions (subsequent paper) by serotonin, MNs are reconfigured to more effectively participate in generating and expressing the leech swimming rhythm.Abbreviations AHP Afterhyperpolarizing potential - DCC Discontinuous current clamp - DE Dorsal excitor motor neuron - DI Dorsal inhibitor motor neuron - IPSP Inhibitory postsynaptic potential - MN Motor neuron - PIR Postinhibitory rebound - VE Ventral excitor motor neuron - VI Ventral inhibitor motor neuron     

Monoamine and Tissue Fluid Levels in Contused Spinal Cord of Sheep

Methods are described for the determination of sheep spinal cord tissue fluid content and norepinephrine, serotonin, and dopamine concentrations after experimental injury. The amount of tissue fluid varied in different regions of sheep spinal cord following injury. Norepinephrine and serotonin wet weight concentrations were corrected for this variation in tissue fluid. Corrected norepinephrine wet weight cord concentrations did not change up to 3 hr after injury. Levels of serotonin at 60 min after injury were similar to controls. Dopamine was not detected in sheep spinal cord. α-Methyl tyrosine significantly reduced fluid in the spinal cord at 75 min after injury. Hinwood B. G. et al. Monoamine and tissue fluid levels in contused spinal cord of sheep. J. Neurochem. 35, 786–791 (1980).     

Effects of serotonin on the cardio-circulatory system of the European eel (Anguilla anguilla) in vivo

The effects of serotonin on continuously recorded cardiac parameters (heart rate, cardiac output, cardiac stroke volume), ventral and dorsal aortic blood pressures, branchial and systemic vascular resistances were investigated in the European eel in vivo. Intravenous administration of serotonin (30 g · kg^–1) caused a marked bradycardia (45%) and a simultaneous decrease in cardiac output (50%), ventral (35%) and dorsal (50%) aortic blood pressures. Branchial resistance was markedly increased (60%) and systemic resistance decreased (30%). Cardiac stroke volume remained unchanged. The effects of serotonin on cardiac mained unchanged. The effects of serotonin on cardiac parameters were suppressed either by methysergide or a bilateral section of the cardiac vagus. Bradycardia could then be regarded as the consequence of a vagal mechanism triggered by serotonin action on central methysergide-sensitive serotonergic receptors. No inotropic effect of serotonin was observed. This lack of myocardiac contractility modification is discussed. The serotonin-mediated branchial vasoconstriction was attenuated by vagotomy, whereas the residual increase in branchial resistance (40%) was suppressed by methysergide. The serotonin-mediated branchial vasoconstriction could be the consequence of both a passive mechanism (compliance) caused by the decrease in cardiac output and an active mechanism involving methysergide-sensitive serotonergic receptors of the branchial vasculature. A possible involvement of this vasomotor effect in gill oxygen uptake is discussed. The serotonin-induced systemic vasodilation was insensitive either to cardiac vagotomy or to 5-HT_1/2, 5-HT₃ and 5-HT₄ receptor antagonists, suggesting the involvement of a local mechanism which remains to be assessed.Abbreviations CSV cardiac stroke volume - DAP dorsal aortic pressure - HR heart rate - QC cardiac output - VAP ventral aortic pressure - VR _b branchial vascular resistance - VR _s systemic vascular resistance - VR _t total vascular resistance - 5-HT 5-Hydroxytryptamine serotonin - RBI Research Biochemical Incorporated, metoclopramide HCl     

Salt stress‐induced seedling growth inhibition coincides with differential distribution of serotonin and melatonin in sunflower seedling roots and cotyledons

Indoleamines regulate a variety of physiological functions during the growth, morphogenesis and stress‐induced responses in plants. Present investigations report the effect of NaCl stress on endogenous serotonin and melatonin accumulation and their differential spatial distribution in sunflower (Helianthus annuus) seedling roots and cotyledons using HPLC and immunohistochemical techniques, respectively. Exogenous serotonin and melatonin treatments lead to variable effect on hypocotyl elongation and root growth under NaCl stress. NaCl stress for 48 h increases endogenous serotonin and melatonin content in roots and cotyledons, thus indicating their involvement in salt‐induced long distance signaling from roots to cotyledons. Salt stress‐induced accumulation of serotonin and melatonin exhibits differential distribution in the vascular bundles and cortex in the differentiating zones of the primary roots, suggesting their compartmentalization in the growing region of roots. Serotonin and melatonin accumulation in oil body rich cells of salt‐treated seedling cotyledons correlates with longer retention of oil bodies in the cotyledons. Present investigations indicate the possible role of serotonin and melatonin in regulating root growth during salt stress in sunflower. Effect of exogenous serotonin and melatonin treatments (15 μM) on sunflower seedlings grown in the absence or presence of 120 mM NaCl substantiates their role on seedling growth. Auxin and serotonin biosynthesis are coupled to the common precursor tryptophan. Salt stress‐induced root growth inhibition, thus pertains to partial impairment of auxin functions caused by increased serotonin biosynthesis. In seedling cotyledons, NaCl stress modulates the activity of N‐acetylserotonin O‐methyltransferase (HIOMT; EC 2.1.1.4), the enzyme responsible for melatonin biosynthesis from N‐acetylserotonin.     

Light and serotonin interact in affecting the circadian system of Aplysia

Summary The eye of the marine mollusk Aplysia californica contains a photo-entrainable circadian pacemaker that drives an overt rhythm of spontaneous compound action potentials. The current study evaluated the influence of serotonin on light-induced phase shifts of this ocular rhythm. The application of serotonin in combination with light was found to have profound and interactive effects on the magnitude of the resulting phase shifts. Further, the phase shifts that resulted from the interaction between light and serotonin appeared to be phase dependent, i.e., the application of serotonin inhibited the phase shifting effects of light during one part of the circadian cycle but enhanced them during another. Finally, the results show that the interaction between light and serotonin is dependent upon the sequence in which these two treatments are paired. These data, coupled with previous findings, suggest that serotonin may act to modulate light's phase shifting effects on the ocular pacemaker in Aplysia.Abbreviations CAP compound action potential - ASW artificial sea water - CT circadian time - 5-HT serotonin     

Comparison of the effect of hormones on the hormone synthesis of Tetrahymena in medium or salt solution

Tetrahymena pyriformis was maintained in TYM (tryptone‐yeast medium) as well as in Losina salt solution. One hour treatment of 10^?15 M histamine, serotonin or insulin was given before the histamine, serotonin, triiodothyronine and adrenocorticotropin contents of the cells were measured by flow cytometry after immunocytochemical staining. Maintenance in salt solution increased the hormone level in the cells, and use of the treatment hormone treatments further increased the endogenous hormone content relative to that in medium. The cells in salt mimic better the natural conditions, which means that the effects of hormones under more natural conditions are expressed to a greater extent than the exogenously given hormones in TYM typically used under laboratory conditions. Intercellular hormonal communication between the cells of a Tetrahymena population might assist in the survival of the individual cells.     

Measurement of 5-hydroxytryptamine and 5-hydroxyindoleacetic acid in cultured rat mesencephalic neurons by high-performance liquid chromatography with electrochemical detection

An HPLC method with electrochemical detection for the simultaneous measurement of serotonin (5-hydroxytryptamine) and 5-hydroxyindoleacetic acid in primary mesencephalic cell culture is described. The serotonin and 5-hydroxyindoleacetic acid cell content was measured on different days of growth in vitro; after twelve days in culture the amounts of serotonin and 5-hydroxyindoleacetic acid detected were 916.0 ± 70.2 and 215.8 ± 15.5 pg per well, respectively. The heterogeneity of neurons in our cultures and their capacity to take up serotonin were assessed by measuring the amounts of exogenous serotonin taken up in the presence of different monoamine uptake inhibitors. This method, sensitive and reliable, can represent a valid alternative to the use of labelled compounds.     

Serotonin modulates Arabidopsis root growth via changes in reactive oxygen species and jasmonic acid–ethylene signaling

Serotonin (5‐hydroxytryptamine) is a bioactive indoleamine with neurotransmitter function in vertebrates, which represents an emerging signaling molecule in plants, playing key roles in the development and defense. In this study, the role of reactive oxygen species (ROS) and jasmonic acid (JA)–ethylene (Et) signaling in root developmental alterations induced by serotonin was investigated. An Arabidopsis thaliana mutant defective at the RADICAL‐INDUCED CELL DEATH1 (RCD1) locus was resistant to paraquat‐induced ROS accumulation in primary roots and showed decreased inhibition or root growth in response to serotonin. A suite of JA‐ and Et‐related mutants including coronatine insensitive1, jasmonic acid resistant1 (jar1), etr1, ein2 and ein3 showed tolerance to serotonin in the inhibition of primary root growth and ROS redistribution within the root tip when compared with wild‐type (WT) seedlings. Competence assays between serotonin and AgNO₃, a well‐known blocker of Et action, showed that primary root growth in medium supplemented with serotonin was normalized by AgNO_3, whereas roots of eto3, an Et overproducer mutant, were oversensitive to serotonin. Comparison of ROS levels in WT, etr1, jar1 and rcd1 primary root tips using the ROS‐specific probe 2′,7′‐dichlorofluorescein diacetate and confocal imaging showed that serotonin inhibition of primary root growth likely occurs independently of its conversion into melatonin. Our results provide compelling evidence that serotonin affects ROS distribution in roots, involving RCD1 and components of the JA–Et signaling pathways.     

Immunohistochemical localization and radioenzymatic measurements of serotonin (5-hydroxytryptamine) in hearts of Aplysia and several bivalve mollusks

Summary Serotonin immunoreactivity was localized in hearts of the opisthobranch gastropod, Aplysia californica (sca hare) and several species of bivalve mollusks, the heterodonts, Mercenaria mercenaria (quahog or cherry stone clam), Protothaca staminea (little neck clam), and the pteriomorphs, Hinnites multirugosus (rock scallop), Crassostrea virginica (eastern oyster), Mytilus edulis (eastern mussel), and Geukensia demissa (ribbed mussel). In addition, serotonin was assayed in the ventricles, auricles and heart-associated tissues in A. californica, M. mercenaria, H. multirugosus, and G. demissa with a sensitive radioenzymatic assay. Serotonin concentrations and the density of innervation were significantly higher in members of the subclass Heterodonta compared to the subclass Pteriomorpha. Serotonin immunoreactivity was observed in all species surveyed except G. demissa, which also contained relatively low concentrations of serotonin. Varicose fibers presumably corresponding to release sites were localized in the ventricles, auricles, and the auricular-ventricular valves. We hypothesize that in the species where serotonin-immunoreactive fibers are present, serotonin serves to modulate cardiac myogenic activity. The significance of the observed distribution and concentration of serotonin to the physiological effects of serotonin on cardiac function in these species is discussed.     

Induction of serotonin biosynthesis is uncoupled from the coordinated induction of tryptophan biosynthesis in pepper fruits (<Emphasis Type="Italic">Capsicum annuum</Emphasis>) upon pathogen infection

It has been suggested that serotonin biosynthesis is regulated by tryptophan decarboxylase (TDC) in plants. To determine if TDC plays a rate-limiting role in serotonin biosynthesis, two TDC genes, PepTDC1 and PepTDC2, were cloned from pepper (Capsicum annuum L.) fruits infected with anthracnose fungus and their expression was then examined in various organs, including fruit that had been treated with the fungus or various chemicals. PepTDC1 expression was highly induced in pepper fruits after treatment with fungus and ethylene, while PepTDC2 was constitutively expressed at low levels in all pepper tissues. Additionally, predominant induction of PepTDC1 mRNA and TDC enzyme activity was detected in the unripe-green fruit, but not in the ripe-red fruit upon pathogen infection. Higher expression of TDC in unripe-green fruit was closely associated with increased levels of tryptamine, serotonin, and serotonin derivatives. However, unlike the enhanced serotonin synthesis, tryptophan levels responded unchanged when challenged with the pathogen in both the unripe-green fruit and the ripe-red fruit. Expression of two key tryptophan biosynthetic genes, anthranilate synthase (ASα) and tryptophan synthase (TSβ), remained unchanged in response to treatment. Also, anthranilate synthase enzyme activity remained steady regardless of pathogen infection. Taken together, these results suggest that the synthesis of serotonin was regulated by the induction of TDC without a simultaneous increase in tryptophan levels in pepper fruits.     

Effects of monorecessive and double recessive mutations affecting coat color on the monoamine content of the brain of the American mink (<Emphasis Type="Italic">Mustela vison</Emphasis> Schreber, 1777)

The effects of mutations affecting the coat color on the dopamine, noradrenaline, and serotonin contents of the hypothalamus and brainstem of the American mink have been studied. The sample comprised standard (+/+) and mutant minks, including the monorecessive pastel (b/b), silver-blue (p/p), and white hedlund (h/h) and the combination double recessive sapphire (a/a p/p) and pearl (k/k p/p) ones. The dopamine content of the brainstem of the monorecessive pastel (b/b) and silver-blue (p/p) minks has been found to be higher than in standard (+/+) minks. Conversely, the homozigosity for two coat color loci in double recessive pearl minks (k/k p/p) significantly decreases the noradrenaline and serotonin contents of the hypothalamus. In addition, monorecessive and double recessive minks differ from each other in the serotonin contents of the midbrain and medulla.