A molecular recognizing system of serotonin in rat fetal axonal growth cones: uptake and high affinity binding

Magnetic field exposure during gestation: pineal and cerebral cortex serotonin in the rat

Extremely low frequency (ELF) magnetic fields seem to have a reproducible influence on cells in transitional states, such as cells during the embryonic and early postnatal periods. Intense and continuous serotonergic synaptic growth is present during the first 2 weeks of postnatal development, paralleled by 5-HT content in the brain, so, the effect of ELF on 5-HT content in the cerebral cortex and pineal gland was determined in growing rats exposed during pregnancy, and in normal controls. The results showed a significant 5-HT increase at birth, 15 and 21 days, in the cerebral cortex. No differences were found in the pineal gland. These short MF exposures had a long term effect on cerebral cortex 5-HT, possibly starting since the fetal period. The relevance of the present findings are discussed as related to the serotonin trophic role on the brain cortex.

Serotonergic receptors in the brain of in utero undernourished rats

In this study, we report that 5-HT(1A) receptors are already present in fractions of axonal growth cones, from the normal rat fetal brain (E-17). Also, in utero undernourished (UN) rat pups at birth show a noteworthy enhancement in the B(max) of [3H]5-hydroxytryptamine (5-HT) and [3H]8-hydroxy-(2-N,N-dipropilamin)-tetralin (([3H])8-OH-DPAT), in the brainstem and cerebral cortex up to the second week after birth. Afterwards, there is a significant decrease in the binding of these ligands. [125I]Cyanopindolo binding in the cerebral cortex only showed a decrease in the same period. An elevation of brain serotonin in both regions was also present. These findings together, suggest that the mechanisms of regulation of serotonergic receptors' expression during the period studied, may not depend on the amount of neurotransmitter in the synaptic cleft, because in the early UN brain it would be expected only a lower receptor's density due to the chronic serotonin increase. On this basis, we propose that developmental activation of brain serotonin biosynthesis observed in early UN animals may disrupt the mechanism regulating the expression of 5-HT receptors during development.

Neither increased nor decreased availability of cortical serotonin (5HT) disturbs barrel field formation in isocaloric undernourished rat pups

Serotonin (5HT) is expressed transiently in primary sensory areas of the rat neocortex during the establishment of the thalamo-cortical topography and somatotopy. The precise role of 5HT during the specification of neocortical areas is still uncertain. We evaluated the effects of increasing and decreasing cortical serotonin concentrations on the specification of the barrel cortex using a rat model of isocaloric undernutrition. This manipulation increases brain 5HT levels during brain development. Undernourished animals were also treated with p-clorophenylalanine; an inhibitor of 5HT synthesis. Barrels representing the head were readily seen at postnatal day 5 in control and p-clorophenylalanine treated rats. In contrast, undernourished rats treated or not with p-clorophenylalanine showed no barrels representing the head but until postnatal day 7. Chromatographic analyses demonstrated that the concentration of cortical 5HT increased by 50% in undernourished pups during barrel field formation. Control and undernourished animals treated with p-clorophenylalanine had a significant reduction (90%) of 5HT in the cortex. The overall geometry of the barrel field and of individual barrels was similar among animal groups. Our results support that 5HT plays a small role in triggering and timing barrel field somatotopy.

Isolation and characterization of detergent-resistant microdomains responsive to NCAM-mediated signaling from growth cones

It is still largely unclear how cell adhesion molecule (CAM)-mediated signaling evokes responses from the growth cone cytoskeleton. Here we used TX-114 extraction of growth cones followed by equilibrium gradient centrifugation to isolate subfractions of detergent-resistant microdomains (DRMs) that could be structurally and functionally distinguished on the basis of localization and activation of components of CAM-mediated signaling pathways. DRMs enriched in cholesterol, caveolin, NCAM140, GPI-linked NCAM120, fyn, and GAP-43, all conventional markers of microdomains or rafts, were located in areas 2 and 3 of the gradient. Coimmunoprecipitation of specific components of CAM signaling pathways by GAP-43 then identified distinct subpopulations of DRMs. GAP-43 from area 2 DRMs coprecipitated GPI-linked NCAM120 and was inactive, i.e., PKC phosphorylation had not been stimulated. In contrast the GAP-43 from area 3 DRMs coprecipitated both transmembrane NCAM140 and caveolin and was active, i.e., highly phosphorylated by PKC. A different subset of DRMs from both area 2 and area 3 contained fyn that could not be coprecipitated with GAP-43 antibodies. In this case area 2 DRMs contained activated fyn that was phosphorylated on Y415. In contrast area 3 DRMs contained inactive fyn. Hence fyn and GAP-43, both targets of NCAM signaling, are located in distinct populations of DRMs, and their activated forms are reciprocally distributed on the gradient. A detergent-resistant membrane fraction recovered from area 4 was enriched in NCAM140, phosphorylated GAP-43, and actin, but not cholesterol, caveolin, or fyn. Immunoelectron microscopy revealed that phosphorylated GAP-43 was localized where the membranes and F-actin interacted. Our results provide evidence for NCAM-mediated signaling in DRMs and suggest that the DRMs responsible for fyn and PKC/GAP-43-mediated NCAM signaling are structurally distinct and differentially distributed in growth cones.

Developmental impairment of auditory evoked N1/P2 component in rats undernourished in utero: its relation to brain serotonin activity

In utero undernourishment produces an elevation of L-tryptophan and serotonin in the brain, including the auditory cortex (A1), such changes seem to be related to an increase in the free fraction (FFT) of plasma L-tryptophan that is transported into the brain through the blood-brain barrier, where it is taken up by serotonergic neurons for serotonin synthesis. Our observations support that FFT has a positive correlation with L-tryptophan (L-Trp) and serotonin levels in the auditory cortex (r=0.95 and 0.82, respectively). Interestingly, a decreased intensity dependence of the auditory evoked N1/P2 component was found in gestationally undernourished animals during their postnatal development. The N1/P2 component had a negative correlation (r=0.81) with A1 serotonin, such that it reflects changes in the neurotransmitter concentration. The present observations suggest a relevant role of serotonin in modulating the activity of the auditory cortex. Since the N1/P2 component is mainly associated with the activity of A1 neurons, it may well be that perception of auditory information is impaired during this developmental period, in the early undernourished animals, possibly affecting cognitive processes. This may be relevant to humans since low birth weight babies that also suffered gestational undernourishment (fetal-placental insufficiency) present an increase in plasma FFT from birth up to 3 months of age. These findings support that the plasma FFT and the intensity dependence of the auditory evoked N1/P2 component relate one another and may be markers of changes of the brain serotonergic activity.

Neurochemical changes in brain serotonin neurons in immature and adult offspring prenatally exposed to cocaine

The present study investigates the age-dependent effects of prenatal cocaine exposure on changes in the neurochemical and functional status of brain serotonin neurons. Pregnant rats were administered either saline or (-)cocaine HCl (15 mg/kg, subcutaneously), twice daily from gestational days 13 through 20. Neurochemical changes in frontal cortex, hypothalamus, hippocampus, striatum and midbrain of prepubescent and adult offspring were determined by measuring: (1) the content of serotonin (5-HT) and its major metabolite 5-hydroxyindolacetic acid (5-HIAA), and (2) the ability of the serotonin releasing drug p-chloroamphetamine (PCA) to reduce brain serotonin levels. Brain catecholamine content was determined in progeny for comparative purposes. Prior to maturation, prenatal exposure to cocaine did not alter basal levels of brain 5-HT or 5-HIAA in any brain region examined. However, in adult progeny prenatally exposed to cocaine, basal 5-HT content was significantly reduced in the frontal cortex (-32%) and hippocampus (-40%), suggesting maturation-dependent effects of prenatal cocaine exposure on brain 5-HT neurons. Consistent with the maturational onset of changes in 5-HT, striatal dopamine was significantly reduced (-10%) by prenatal exposure to cocaine only in adult offspring. Reductions in 5-HT in most brain regions, produced by pharmacological challenge with p-chloroamphetamine (PCA), were comparable in prenatal saline versus cocaine offspring. One notable exception was the markedly greater reduction (-40%) in 5-HT in the midbrain of immature offspring prenatally exposed to cocaine, suggesting alterations in midbrain 5-HT neurons prior to maturation. Overall, these data demonstrate prenatal cocaine exposure produces region-specific changes in 5-HT neurons in offspring with some deficits occurring only following maturation.

Prenatal cocaine exposure potentiates 5-HT(2a) receptor function in male and female rat offspring

We have reported previously prenatal cocaine-induced functional deficits in serotonergic terminals, and gender-specific supersensitivity of postsynaptic 5-HT(1A) receptor-mediated hormone responses in offspring. This study investigates the effects of prenatal exposure to cocaine on postsynaptic 5-HT(2A) receptor-mediated responses in prepubescent male and female offspring. Pregnant rats were administered saline or (-)cocaine (15 mg/kg, s.c., b.i.d) from gestational day 13 through 20. Changes in 5-HT(2A) receptor function in offspring were assessed by differences in the ability of DOI [4-iodo, 2,5-dimethoxyphenyl-isopropylamine; 2. 0 mg/kg, s.c.] to elevate plasma levels of the hormones ACTH, corticosterone and renin. Basal hormone levels in male and female progeny were unaffected by prenatal cocaine exposure. However, prenatal exposure to cocaine significantly potentiated the magnitude of the ACTH response to DOI in both male (+19%) and female (+43%) progeny. Similarly, the DOI-induced elevation of plasma renin was markedly potentiated in male (+51%) and female (+83%) cocaine-exposed offspring. Although DOI significantly elevated corticosterone levels in both male and female offspring, the magnitude of corticosterone responses was not altered by prenatal exposure to cocaine. Densities of agonist ((125)I-DOI)-labeled receptors in hypothalamus and cortex were unaltered by prenatal exposure to cocaine. These data indicate prenatal cocaine-induced supersensitivity of postsynaptic 5-HT(2A) receptor function in male and female offspring without changes in receptor density. Synapse: 35:163-172, 2000.

Expression of serotonin transporter protein in developing rat brain

Serotonin transporter (5-HTT), a transmembrane protein, has been shown in adult brain to be distributed not only on synaptic terminals but to a great extent on axons as well. Here we report the ontogeny of 5-HTT and its relationship with serotonin (5-HT) neurons using established 5-HTT and 5-HT antibodies. Both 5-HTT- and 5-HT-immunostaining (-im) appear in 5-HT neurons at embryonic day 12 (E12) in rostral raphe nuclei (RRN). Soon after appearing, 5-HTT-im is highly expressed on axons, similar to adult expression. However, in contrast to adult, 5-HTT-im also outlines the soma-dendrites. Rich 5-HTT-im appears along the entire length of projecting axons, extending to the growth tip. In the next 2 days, intensive 5-HTT-im axons from RRN travel a course preferentially in the floor plate and later, the medial forebrain bundle trajectory. A group of new 5-HT-im neurons and 5-HTT-im axons appear at E13 in caudal raphe nuclei. At E16-18, taking the exact trajectory course of 5-HT axons, 5-HTT-im axons reach ganglionic eminence, olfactory bulb, and cortex and disperse into many brain regions in E18-20. No 5-HTT-im cell bodies were seen in nigral, locus ceruleus, or hypothalamus. However, the transient expression of 5-HTT on non-serotonergic system was seen in cortical and striatal neuroepithelia at E12 and sensory thalamic pathways at P0-P10. Prominent 5-HTT-im fibers in thalamocortical bundles project from sensory thalamic nuclei through reticular nucleus, internal capsule bundle and form barrels in somatosensory cortices. No 5-HTT-im was seen in glia-like cells using currently available antibody. These observations indicate that 5-HTT is: (a) associated preferentially with 5-HT neurons in brainstem, (b) temporally co-expressed with 5-HT in 5-HT neurons, (c) expressed on axons prior to synaptical sites at target neurons, which strongly indicates a volumic (extrasynaptic) transmission, (d) expressed in non-5-HT neurons within a specific window, which may affect the development of the systems "borrowing" the 5-HT. The early appearance of 5-HTT may also endow functionality as well as vulnerabilities of 5-HT, sensory thalamic, and cortical neurons to 5-HTT targeting drugs during pregnancy and after birth.

Activity of sialidases in fetal brain axonal growth cones and during postnatal development

In the present work the cytosolic, membrane-bound and the total activities of brain sialidases were measured in fetal axonal growth cone particles and in various brain regions during brain development. The developmental profile showed an important activity in the prenatal and perinatal periods as well as in specific differentiating structures like the axonal growth cones from the fetal brain. Interestingly membrane-bound activity was higher than the cytosolic activity, starting from 50-60% at birth and increasing thereafter. Cytosolic activity was almost at adult levels at birth and did not show a further significant increase thereafter. Our results strongly suggest the commitment of membrane-bound sialidase activity in early neurodifferentiating phenomena like axogenesis, probably regulating the turnover of glycoconjugates like gangliosides at the presynaptic period, since high activity was observed in neuroblast's derived membranes and in the perinatal period.

Free tryptophan as an indicator of brain serotonin synthesis in infants

This study confirms observations made in a former study of plasma of preterm and term newborn infants with intrauterine malnutrition during the first month of life and extends to the lactational period. The free fraction of L-tryptophan, the precursor amino acid of brain serotonin synthesis, is significantly elevated up to 3 months of age. According to previous results, which demonstrated that L-tryptophan and serotonin synthesis are increased in the brain of gestationally malnourished rats, the present data in humans malnourished early in life strongly suggest that the elevation of the free fraction of L-tryptophan in plasma provides an increased amount of the precursor molecule to pass across the blood-brain barrier and activates the synthesis of brain serotonin. Because serotonin has been found to have a possible neurotrophic role in the fetal brain, any alteration of its metabolism in this period could reflect as a permanent change in brain neurogenesis. The data suggest that the free fraction of plasma L-tryptophan may be an indirect marker of changes in brain serotonin synthesis in these patients. Additional data on the functional relevance of the brain serotonergic system in humans are required to support this hypothesis.

Early nutritional changes modify the kinetics and phosphorylation capacity of tryptophan-5-hydroxylase

Gestational malnutrition induces an acceleration of the serotonin biosynthetic pathway in the developing brain with an increase in brain L-tryptophan (L-Trp), tryptophan-5-hydroxylase (TrpOH) activity and serotonin content. In the present work we report results on the possible mechanism of TrpOH activation. Kinetic experiments were done with different L-Trp concentrations in the rat brain at different ages. Also various phosphorylating conditions of the enzyme were tested in order to compare its activation in developmentally malnourished and normal brains. The results showed lower Km values and no changes in the Vmax in the malnourished as compared to controls. Interestingly, in the malnourished group, TrpOH showed an increased activity under the phosphorylating conditions employed. We propose that in the activation of brain TrpOH by developmental malnutrition, not only is an elevation of L-Trp involved, but also a change in the enzyme itself reflected in a higher affinity for L-Trp and in a greater response to phosphorylation. This allows us to propose the possibility that early chronic malnutrition induces structural changes in the enzymatic molecule.

Prenatal methamphetamine attenuates serotonin mediated renin secretion in male and female rat progeny: evidence for selective long-term dysfunction of serotonin pathways in brain

In adult rats, methamphetamine produces biochemical alterations in brain serotonin (5-HT) neurons. Since 5-HT is critical to the development of fetal 5-HT neurons and target tissues, we hypothesized that in utero exposure to methamphetamine could result in long-term alterations in postnatal 5-HT systems. Pregnant Sprague-Dawley rats, administered either saline or (+/-)methamphetamine (5 mg/kg, s.c., b.i.d.) from gestational day 13 to 20, were divided into three treatment groups: Saline-injected/Ad Lib Fed (VEH); Saline-injected/Pair Fed (PF); and methamphetamine injected (METH). Prenatal methamphetamine exposure did not alter litter size, gender number, or progeny birth weights. Functional alterations in serotonergic systems were determined in postnatal day (PD) 70 male progeny and in PD 30 female progeny by measuring changes in 5-HT mediated increases in plasma hormones following a single injection of the 5-HT releaser p-chloroamphetamine (PCA; 8 mg/kg). Prenatal methamphetamine produced long-term marked (-30 to -62%) attenuation of plasma renin responses to PCA in male and female progeny. In contrast, no alterations were observed in the ACTH, corticosterone, or prolactin responses to PCA in male and female progeny. Prenatal methamphetamine did not alter basal levels of any hormones measured regardless of gender. No significant differences were observed in the density of cortical or hypothalamic 5-HT uptake sites, or in the density of cortical 5-HT1 or 5-HT2 receptors in male progeny. The lack of significant differences in cortical 5-HT uptake sites observed between PF and METH treated dams 2 days post-parturition indicates that methamphetamine was not neurotoxic to the pregnant dams. These data, which demonstrate longterm postnatal deficits in 5-HT mediated renin secretion, suggest selective functional alterations of brain 5-HT systems in male and female progeny exposed in utero to methamphetamine.

Prenatal cocaine produces deficits in serotonin mediated neuroendocrine responses in adult rat progeny: evidence for long-term functional alterations in brain serotonin pathways

Cocaine produces biochemical alterations in brain serotonin (5-HT) neurons. Since 5-HT is critical to the development of fetal 5-HT neurons and target tissues, we hypothesized that in utero exposure to cocaine could result in long-term alterations in postnatal 5-HT systems. Pregnant Sprague-Dawley rats were administered either saline or (-)cocaine (15 mg/kg, s.c., b.i.d.) from gestational day 13 to 20. Prenatal cocaine exposure did not alter litter size, gender number, or progeny birth weights. Functional alterations in serotonergic systems were determined in postnatal day (PD) 70 male progeny by measuring changes in 5-HT mediated plasma hormones following a single 8 mg/kg injection of the 5-HT releaser p-chloroamphetamine (PCA). Cocaine exposed male progeny exhibited significant reductions in adrenocorticotropic hormone (ACTH, -43%) and renin (-62%) responses to PCA. However, no alterations were observed in the corticosterone or prolactin response to PCA. In utero exposure to cocaine did not alter basal levels of ACTH, renin, corticosterone, or prolactin. There were no significant differences in the density of either hypothalamic or cortical 5-HT uptake sites. Likewise, there were no significant differences in the densities of any of the 5-HT1 receptor subtypes or in the density of 5-HT2 receptors in cortex. These data, which provide the first demonstration of deficits in 5-HT mediated neuroendocrine function in adult progeny following in utero exposure to cocaine, indicate long-term functional alterations of brain 5-HT systems.