Fluorescence and electron microscopic studies of the early development of the substantia nigra and area ventralis tegmenti in the fetal rabbit

The role of mesocorticolimbic dopamine in regulating interactions between drugs of abuse and social behavior

The use of addictive drugs can have profound short- and long-term consequences on social behaviors. Similarly, social experiences and the presence or absence of social attachments during early development and throughout life can greatly influence drug intake and the susceptibility to drug abuse. The following review details this reciprocal interaction, focusing on common drugs of abuse (e.g., psychostimulants, opiates, alcohol and nicotine) and social behaviors (e.g., maternal, sexual, play, aggressive and bonding behaviors). The neural mechanisms underlying this interaction are discussed, with a particular emphasis on the involvement of the mesocorticolimbic dopamine system.

Prenatal cocaine exposure specifically alters spontaneous alternation behavior

Our laboratory has previously characterized a rabbit model of gestational cocaine exposure in which permanent alterations in neuronal morphology, cell signaling and psychostimulant-induced behavior are observed. The cellular and molecular neuroadaptations produced by prenatal cocaine occur in brain regions involved in executive function and attention, such as the anterior cingulate and medial prefrontal cortices. Therefore, in the present study, we have measured the effects of prenatal cocaine exposure on specific behavioral tasks in adult offspring whose mothers were treated with cocaine (3mg/kg, twice a day, E16-E25). We assessed non-spatial, short-term memory in a two-object recognition task and found no deficits in memory or exploratory behaviors in cocaine-exposed offspring in this paradigm. We also evaluated a different memory task with a more robust attentional component, using spontaneous alternation in a Y maze. In this task, young adult rabbits exposed to cocaine prenatally exhibited a significant deficit in performance. Deficits in spontaneous alternation can be induced by a wide variety of behavioral and cognitive dysfunctions, but taken together with previous findings in this and other animal models, we hypothesize that prenatal exposure to cocaine alters highly specific aspects of cognitive and emotional development.

Cocaine effects on the developing brain: current status

The present paper reports on the results obtained in a rabbit model of prenatal cocaine exposure that mimics the pharmacokinetics of crack cocaine in humans, and relates these findings to studies in other species including humans. A general finding is that prenatal exposure to cocaine during neurogenesis produces dysfunctions in signal transduction via the dopamine D(1) receptor and alterations in cortical neuronal development leading to permanent morphological abnormalities in frontocingulate cortex and other brain structures. Differences in the precise effects obtained appear to be due to the dose, route and time of cocaine administration. Related to these effects of in utero cocaine exposure, animals demonstrate permanent deficits in cognitive processes related to attentional focus that have been correlated with impairment of stimulus processing in the anterior cingulate cortex. The long-term cognitive deficits observed in various species are in agreement with recent reports indicating that persistent attentional and other cognitive deficits are evident in cocaine-exposed children as they grow older and are challenged to master more complex cognitive tasks.

Dopaminergic neurons associate with blood vessels in neural transplants

Neural transplantation is an attractive strategy for diseases that result in focal neurodegeneration such as Parkinson's disease, where there is a selective loss of dopaminergic neurons in the substantia nigra of the midbrain. A major drawback to its application, however, is the poor survival of donor dopaminergic neurons. While neurons probably depend on host-derived substances delivered by either diffusion or the establishment of functional vascular connections, the relative importance of each delivery mechanism is not known. We investigated the topography of transplants of embryonic mesencephalic tissue and describe the spatial relationships between transplanted dopaminergic neurons, the host brain, and in-growing blood vessels. Results indicate that transplant vascularization shares features with developmental patterns of brain vascularization. Moreover, the topographical distribution of dopaminergic neurons reflected their proximity to the host brain as well as their distance from vascular elements. Zonal analysis revealed that the majority of dopaminergic neurons were found at or near the host-transplant interface at 1 week after transplantation. Nearest neighbor analysis demonstrated a descending exponential gradient of dopaminergic neurons as a function of their distance from vessels at the same time point. These patterns became more marked with time. Results suggest that rates and patterns of vascularization may be important determinants in the long-term survival of dopaminergic neurons.

Development of oculomotor axon projections in the chick embryo

The pattern of innervation of the extraocular muscles is highly conserved across higher vertebrate species and mediates sophisticated visuomotor processes. Defects in oculomotor development often lead to strabismus, a misalignment of the eyes that can cause partial blindness. Although it has been intensively studied from a clinical perspective, relatively little is known about how the system develops embryonically. We have therefore mapped the development of the oculomotor nerve (OMN) in chick embryos by using confocal microscopy. We show that OMN development follows a series of stereotyped steps that are tightly regulated in space and time. The OMN initially grows past three of its targets to innervate its distal target, the ventral oblique muscle, only later forming branches to the more proximal muscles. We have also investigated spatiotemporal aspects of the unusual contralateral migration of a subpopulation of oculomotor neurons by using molecular markers and have found the semaphorin axon guidance molecules and their receptors, the neuropilins, to be expressed in discrete subnuclei during this migration. Finally, we have created an embryological model of Duane retraction syndrome (DRS), a form of strabismus in which the OMN is believed to innervate aberrantly the lateral rectus, the normal target of the abducens nerve. By ablating rhombomeres 5 and 6 and hence the abducens, we have mimicked a proposed oculomotor deficit occurring in DRS. We find that the absence of the abducens nerve is not sufficient to produce this inappropriate innervation, so other factors are required to explain DRS.

Descending supraspinal pathways in amphibians: III. Development of descending projections to the spinal cord in Xenopus laevis with emphasis on the catecholaminergic inputs

In developmental stages of the clawed toad, Xenopus laevis, we describe the ontogeny of descending supraspinal connections, catecholaminergic projections in particular, by means of retrograde tracing techniques with dextran amines. Already at embryonic stages (stage 40), spinal projections from the reticular formation, raphe nuclei, Mauthner neurons, vestibular nuclei, the locus coeruleus, the interstitial nucleus of the medial longitudinal fasciculus, the posterior tubercle, and the periventricular nucleus of the zona incerta are well developed. At the beginning of the premetamorphic period (stage 46), spinal projections arise from the suprachiasmatic nucleus, the torus semicircularis, the pretectal region, and the ventral telencephalon. After stage 48, tectospinal and cerebellospinal projections develop, with spinal projections from the preoptic area following at stage 51. Rubrospinal projections are present at stage 50. During the prometamorphic period, spinal projections arise in the nucleus of the solitary tract, the lateral line nucleus, and the mesencephalic trigeminal nucleus. With in vitro double-labeling methods, based on retrograde tracing of dextran amines in combination with tyrosine hydroxylase (TH) immunohistochemistry, we show that at stage 40/41, catecholaminergic (CA) neurons in the posterior tubercle are the first to project to the spinal cord. Subsequently, at stage 43, new projections arise in the periventricular nucleus of the zona incerta and the locus coeruleus. The last CA projection to the spinal cord originates from neurons in the nucleus of the solitary tract at the beginning of prometamorphosis (stage 53). Our data show a temporal, rostrocaudal sequence in the development of the CA cell groups projecting to the spinal cord. Moreover, the early appearance of CA fibers, preterminals and terminal-like structures in dorsal, intermediate, and ventral zones of the embryonic spinal cord, suggests an important role for catecholamines during development in nociception, autonomic functions, and motor control at the spinal level.

Prenatal cocaine exposure produces consistent developmental alterations in dopamine-rich regions of the cerebral cortex

Administration of cocaine to pregnant rabbits produces robust and long-lasting anatomical alterations in the dopamine-rich anterior cingulate cortex of offspring. These effects include increased length and decreased bundling of layer III and V pyramidal neuron dendrites, increases in parvalbumin expression in the dendrites of interneurons, and increases in detectable GABAergic neurons. We have now examined multiple cortical regions with varying degrees of catecholaminergic innervation to investigate regional variations in the ability of prenatal cocaine exposure to elicit these permanent changes. All regions containing a high density of tyrosine hydroxylase-immunoreactive fibers, indicative of prominent dopaminergic input, exhibited alterations in GABA and parvalbumin expression by interneurons and microtubule-associated protein-2 labeling of apical dendrites of pyramidal neurons. These regions included the medial prefrontal, entorhinal, and piriform cortices. In contrast, primary somatosensory, auditory and motor cortices exhibited little tyrosine hydroxylase staining and no measurable cocaine-induced changes in cortical structure. From these data we suggest that the presence of dopaminergic afferents contributes to the marked specificity of the altered development of excitatory pyramidal neurons and inhibitory interneurons induced by low dose i.v. administration of cocaine in utero.

Effects of prenatal exposure to cocaine on the developing brain: anatomical, chemical, physiological and behavioral consequences

Earlier studies of human infants and studies employing animal models had indicated that prenatal exposure to cocaine produced developmental changes in the behavior of the offspring. The present paper reports on the results obtained in a rabbit model of in utero exposure to cocaine using intravenous injections (4 mg/kg, twice daily) that mimic the pharmacokinetics of crack cocaine in humans. At this dose, cocaine had no effect on the body weight gain of dams, time to delivery, litter size and body weight or other physical characteristics of the offspring. In spite of an otherwise normal appearance, cocaine-exposed neonates displayed a permanent impairment in signal transduction via the D1 dopamine receptor in caudate nucleus, frontal cortex and cingulate cortex due to an uncoupling of the receptor from its associated Gs protein. This uncoupling in the caudate nucleus was shown to have behavioral consequences in that young or adult rabbits, exposed to cocaine in utero, failed to demonstrate amphetamine-elicited motor responses normally seen after activation of D1 receptors in the caudate. The cocaine progeny also demonstrated permanent morphological abnormalities in the anterior cingulate cortex due to uncoupling of the D1 receptor and the consequent inability of dopamine to regulate neurite outgrowth during neuronal development. Consistent with the known functions of the anterior cingulate cortex, adult cocaine progeny demonstrated deficits in attentional processes. This was reflected by impairment in discrimination learning during classical conditioning that was due to an inability to ignore salient stimuli even when these were not relevant to the task. The impairment in discrimination learning also occurred in an instrumental avoidance task and could be shown to be due to an impairment of cingulothalamic learning-related neuronal coding. It was proposed that the selective loss of D1-related neurotransmission in the anterior cingulate cortex prevented an appropriate activation of GABA neurons and thus a loss of inhibitory regulation that is necessary for processes involved in associative attention. Taken together, these findings suggest that the uncoupling of the D1 receptor from its G protein may be the fundamental source of the anatomic, cognitive and motor disturbances seen in rabbits exposed to cocaine in utero. Moreover, the long-term cognitive and motor deficits observed in the rabbit model are in agreement with the recent reports indicating that persistent attentional and other behavioral deficits may be evident in cocaine-exposed children as they grow older and are challenged to master more complex cognitive tasks.

New evidence for neurotransmitter influences on brain development

The early appearance of monoamine systems in the developing mammalian CNS suggests that they play a role in neural development. We review data from two model systems that provide compelling new evidence of this role. In one model system-in utero exposure to cocaine-specific and robust alterations are seen in dopamine-rich areas of the cerebral cortex, such as the anterior cingulate cortex: D1 receptor-G protein coupling is greatly reduced, the GABAergic system is altered and pyramidal dendrites undergo excessive growth. In a second model system-a transgenic mouse line in which the gene that encodes monoamine oxidase A (MAOA) is disrupted, resulting in excessively high 5-HT levels-barrels fail to form in the developing somatosensory cortex. Both models reveal the effects of very early manipulation of monoamines on forebrain development, and the long-term anomalies that persist into adulthood.

Ultrastructure of developing substantia nigra in humans

Electron microscopy of the maturing neurons and developing and maturing synapses in the substantia nigra of 14 human embryos/foetuses of 8-24 weeks of gestation are reported. At 8 weeks, cells were immature with very little cytoplasm and cellular organelles. Contact sites of processes appeared more electron dense than the other areas. At 12 weeks, many of the cells had acquired more cytoplasm and cellular organelles and could be identified as neurons. Asymmetric synapses with clear, round synaptic vesicles also were identifiable at this age. Such synapses, first to appear in the developing substantia nigra, are reported to be formed by recurrent collateral nigro-striatal fibres. Substance P fibres from the striatum also are contributing to this type of synapse. At 15-16 weeks, not only was the number of such synapses increased, but many appeared morphologically mature. Symmetric synapses having clear round vesicles along with a few dense core vesicles also appeared at this stage, suggesting striatal input. By 24 weeks of gestation, most of the neurons had cytological features comparable to that of the mature neurons. There was an increase in the total number of synapses and the individual variety from 15 to 24 weeks of gestation. The present study indicates that synaptogenesis starts at 8 weeks and continues beyond 24 weeks of gestation.

Migration of dopaminergic neurons in the embryonic mesencephalon of mice

Migration of dopamine (DA)-containing neurons and its guiding cues were histologically examined in the embryonic mesencephalon of normal mice. Cells immunoreactive (ir) for tyrosine hydroxylase (TH), a DA-synthesizing enzyme, were first detected on embryonic day 10 (E10) in the medio-basal part of the mesencephalon and were distributed throughout the entire length of the ventral mesencephalic wall at E12. By E14, TH-ir cells were located laterally along the ventral pial surface to form the primordia of the substantia nigra. Experiments with a single injection of bromodeoxyuridine, a thymidine analog, demonstrated that cells generated in the ventricular surface of the ventral mesencephalon at E11 migrated ventrally and then moved laterally to form the substantia nigra and the ventral tegmental area. Electron microscopic examination of the ventral mesencephalon of E12 mice disclosed that in the dorsal part ventrally migrating immature neurons made close contacts with the processes of radial glial cells. The expression of tenascin was transiently seen on radial glial processes between E10 and E13 coincident with the period of the ventral migration of mesencephalic DA neurons. By double immunostaining of E13 mesencephalon, ventrally migrating TH-ir cells were seen to be apposed to tenascin-bearing radial glial processes. On the other hand, laterally migrating neurons in the basal part of the mesencephalon were observed by electron microscopy to contact with tangentially arranged nerve fibers which were immunopositive for the 160 kDa neurofilament polypeptide at the light microscopic level from E10. Double immunostaining of E13 mesencephalon demonstrated that laterally migrating TH-ir cells were intermingled among neurofilament-ir fiber bundles. The cells of origin of the tangential nerve fibers were detected in the lateral part of the mesencephalon, when a fluorescent dye, 1,1'-dioctadecyl-3,3,3',3'-tetramethyl-indocarbocyanine perchlorate (DiI) was injected into the basal part of the mesencephalon of fixed E12 mice. The present results suggest that guiding cues of the radial migration of mesencephalic DA neurons represent processes of radial glial cells which express tenascin. On the other hand, tangentially arranged nerve fibers originating from the lateral part of the mesencephalon may provide a scaffolding along which the mesencephalic DA neurons subsequently migrate laterally to form the ventral tegmental area and the substantia nigra.

Postnatal maturation of GABA-immunoreactive neurons of rat medial prefrontal cortex

A light microscopic immunocytochemical approach has been used to examine the distribution and maturation of gamma-aminobutyric acid- (GABA) containing cells in rat medial prefrontal cortex (mPFC) at progressive postnatal stages. Between P1 and P5, labeled cells in the cortical plate show less differentiated morphological characteristics when compared to cells in the deeper laminae. By P10, however, most labeled cells in superficial laminae show more differentiated characteristics with some having a distinctive multipolar appearance. Between P1 and P5, there is a significant increase (50%) in the density of GABA-containing cells in the superficial laminae, while concurrently there is an overall decreases in the subjacent deeper laminae. As the cortex continues to expand, there is a corresponding decrease in the density of GABA-immunoreactive cells in the outer two-thirds of the cortical mantle until approximately P15, stabilizing at 20-25 cells/100,000 microns2 for all laminae. Between P1 and P15, there is also a significant increase (133%) in the average size of labeled cells, followed by a gradual decrease of 30% between P15 and P41. During P1-7, there is a marked increase in the density of labeled axosomatic terminals in both the superficial (200%) and deep laminae (116%). In the superficial layers, however, the density of labeled terminals again increases by 86% between P12 and P18. In general, the present findings are consistent with the idea that there is a progressive maturation of the intrinsic GABAergic system in rat mPFC in a classic "inside-out" pattern, and this involves extensive postnatal changes occurring during the first 3 postnatal weeks.

Development of catecholamine systems in the brain of the lizard Gallotia galloti

For a better insight into general and derived traits of developmental aspects of catecholaminergic (CA) systems in amniotes, we have studied the development of these systems in the brain of a lizard, Gallotia galloti, with tyrosine hydroxylase (TH)- and dopamine (DA) immunohistochemical techniques. Two main groups of TH-immunoreactive (THi) perikarya appear very early in development: one group in the midbrain which gives rise to the future ventral tegmental area, substantia nigra and retrorubral cell groups, and another group in the tuberomammillary hypothalamus. Somewhat later in development, TH/DA-immunoreactive cells are observed in the thalamus, rostrodorsal hypothalamus and spinal cord, and, with another delay, in the suprachiasmatic nucleus, the periventricular organ, and the pretectal posterodorsal nucleus. CA cell groups that appear rather late in development include the cells in the olfactory bulb, the locus coeruleus and the caudal brainstem. As expected, the development of immunoreactive fibers stays behind that of the cell bodies, but reaches the adult-like pattern just prior to hatching. The present study revealed considerable variation in the relation between the state of cytodifferentiation and first expression of TH/DA immunoreactivity between CA cell groups. Catecholamine cells in the midbrain and tuberomammillary hypothalamus are still migrating, immature (absence of dendrites) and express only TH immunoreactivity at the time of first detection. Cells which appear at later developmental stages lie already further away from the ventricle, possess two or more dendritic processes, and generally express both TH- and DA immunoreactivity.

Neural xenotransplantation: reconstruction of neuronal circuitry across species barriers

Selective replacement of degenerated neurons in the adult brain with allogeneic fetal neuroblasts is a promising therapeutic modality for human neurodegenerative diseases, but is confounded with practical and potential ethical problems. To evaluate the potential of xenogeneic donors as a cell source for neural transplantation, we have critically examined the available experimental evidence in animal models pertaining to the survival, integration and function of xenogeneic fetal neuroblasts in the host brain. A statistical meta-analysis across multiple studies revealed that immunologically-related transplantation parameters (immunosuppression and donor-host phylogenetic distance) were the main determinants of neural xenograft survival. The immunological basis for xenograft rejection is reviewed in the context of novel immunoprotection strategies designed to enhance xenograft survival. Furthermore, the evidence for behavioral recovery based on anatomical and functional integration of neural xenografts in the host brain is examined with an awareness of developmental considerations. It is concluded that neural xenotransplantation offers a unique opportunity for effective neuronal replacement with significant potential for clinical use.

Ontogenic development of brain asymmetry in dopaminergic neurons

In the present study the right-left brain asymmetry of central dopamine (DA) systems during postnatal brain development is evaluated. DA and dihydroxyphenylacetic acid (DOPAC) levels increased from neonatal to adult life in both the forebrain and mesencephalon. This increase was not similar in the right and left brain sides. From neonatal life to adulthood a fall was observed in (a) DA percentage in the DA high-brain side in the mesencephalon and (b) DOPAC percentage in the DOPAC high-brain side in both the forebrain and mesencephalon. The percentage of lateralized rats (more than 65% of DA or DOPAC levels in either brain side) also decreased during ontogeny. Thus, biochemical lateralization decreases during ontogeny. The right-left brain correlation for DA level and DA turnover was used to evaluate the inter-hemispheric regulation of dopaminergic systems. The correlation coefficient was near to 0 during postnatal life and around -0.8 during adulthood in both forebrain and mesencephalon. Taken together, these data suggest that the ontogenic decrease of in brain asymmetry for DA or DOPAC levels is related to the postnatal development of an inter-hemispheric regulatory system that control dopaminergic neurons activity.

Prenatal ontogeny of tyrosine hydroxylase gene expression in the rat ventral mesencephalon

We have examined the development of dopaminergic (DA) neurons in the embryonic mesencephalon with regard to the expression of the gene coding for tyrosine hydroxylase (TH). Mesencephalic DA neurons from rat embryos aged E13 to E21 were analyzed using a quantitative in situ hybridization protocol featuring a 35S-labeled RNA probe complimentary to TH mRNA. In the early-to-mid stage embryonic brains, the expression of the TH gene was examined relative to the position of individual, migrating DA cells in the caudal-rostral and dorsal-ventral axes of the mesencephalon. In the later embryonic subjects, neurons were analyzed according to their position in one of the midbrain DA nuclei. The ontogeny of TH gene expression in the rat mesencephalon exhibited two phases: during the early phase (E13-E15), we observed major fluctuations in the level of TH gene expression accompanying the differentiation and maturation processes of the DA cells. Later, in the mid-to-late gestation fetus (E18-E21), TH gene expression generally stabilized as TH mRNA-expressing neurons reached their final anatomical positions within the mesencephalic DA complex. Our data demonstrate the complex dynamics which characterize the ontogeny of TH gene expression in the prenatally developing mesencephalon, and suggest a connection between the maturational level of DA neurons and the expression of the key gene regulating their principle neurotransmitter.

Development of tyrosine hydroxylase-, dopamine- and dopamine β-hydroxylase-immunoreactive neurons in a teleost, the three-spined stickleback

The development of catecholaminergic neuronal systems in the brain of a teleost, the three-spined stickleback, was studied through embryonic to early larval stages by immunocytochemistry using specific antibodies against dopamine, tyrosine hydroxylase and dopamine beta-hydroxylase. By analysing the spatiotemporal patterns of development for the catecholaminergic nuclei, possible homologies with nuclei in amniote brains have been identified. The noradrenergic neurons in the isthmus region of the rostral rhombencephalon originate in the same manner as the A4-A7 + subcoeruleus group in mammals. Their developmental characteristics show the largest similarities with the subcoeruleus group of birds and mammals, although some features are shared with developing A6 (locus coeruleus) neurons. Catecholaminergic neurons never appear during development in the ventral mesencephalon of the three-spined stickleback. A group of large dopaminergic neurons that accompany the cerebrospinal fluid (CSF)-contacting neurons follows the border between the hypothalamus and the ventral thalamus into the caudal hypothalamus, where they are continuous with the dopaminergic neurons in the posterior tuberculum. They are thus topologically comparable with the dopaminergic neurons of the zona incerta in mammals. The dopaminergic CSF-contacting neurons that line the median, lateral and posterior recesses of the third ventricle do not contain tyrosine hydroxylase-immunoreactivity at any developmental stage. This indicates that they take up and accumulate exogenous dopamine or L-dihydroxyphenylalanine, and do not synthesize dopamine from tyrosine at any developmental stage. Tyrosine hydroxylase-immunoreactive neurons appear in the pineal organ on the day of hatching (120 h post-fertilization). They were still observed in 240-h-old larvae, but are absent in the pineal organ of adult sticklebacks. The initial appearance and subsequent differentiation of catecholaminergic neurons in the stickleback embryo follow essentially the same spatial and temporal pattern as in amphibian, avian and mammalian embryos. This observation supports the hypothesis that morphologically, topologically and chemically similar monoaminergic neurons in different vertebrate classes are homologous.

Development of dopaminergic neurons in the human substantia nigra

A series of 29 human embryonic brains were examined in order to characterize the ontogeny of dopaminergic neurons within the developing substantia nigra. Embryos from Postconception Weeks 4.0 to 11.2 (last menstrual period 6.0-13.2) were studied. Immunohistochemical staining was performed using a polyclonal antibody to tyrosine hydroxylase. Tyrosine hydroxylase-like immunoreactivity was first seen in cells of the ventral mesencephalon at 6.5 weeks adjacent to the ventricular zone. Ventral migration of TH-positive cells began at 6.7 weeks. Neural process extension was first identified in tyrosine hydroxylase-positive neurons at 8.0 weeks. The ascending nigrostriatal bundle was also first demonstrated at 8.0 weeks. Tyrosine hydroxylase containing neurites were seen initially in the developing putamen at 9.0 weeks. Only a few tyrosine hydroxylase-positive cells remained adjacent to the ventricular zone at Week 10.0 and all had disappeared from the ventricular zone by 11.2 weeks. At this latter stage, a large number of dopaminergic cells had elaborated neural processes. The sequence of developmental events of human mesencephalic dopaminergic neurons is similar to the equivalent period of ontogeny in other mammals. The duration of the developmental period is, however, significantly protracted.

Early phenotype expression of cortical neurons: evidence that a subclass of migrating neurons have callosal axons

The use of [3H]thymidine labeling in combination with various axonal transport tracers has revealed that a subset of migrating neurons in the fetal monkey cerebrum issue axons to the opposite cerebral hemisphere while still migrating to their final positions in the cortical plate. Other cortical neurons with the same "birthdate" (i.e., that underwent their last round of DNA synthesis on the same day) are not retrogradely labeled by tracer injections of the opposite hemisphere. These findings suggest that the cardinal distinction between projection and local circuit neurons may be specified in postmitotic neurons before they acquire their final positions in the cortex.

Fine structure of synaptogenesis in the vertebrate central nervous system

This article reviews studies of the formation of synaptic junctions in the vertebrate central nervous system. It is focused on electron microscopic investigations of synaptogenesis, although insights from other disciplines are interwoven where appropriate, as are findings from developing peripheral and invertebrate nervous systems. The first part of the review is concerned with the morphological maturation of synapses as described from both qualitative and quantitative perspectives. Next, epigenetic influences on synaptogenesis are examined, and later in the article the concept of epigenesis is integrated with that of hierarchy. It is suggested that the formation of synaptic junctions may take place as an ordered progression of epigenetically modulated events wherein each level of cellular affinity becomes subordinate to the one that follows. The ultimate determination of whether a synapse is maintained, modified or dissolved would be made by the changing molecular fabric of its junctional membranes. In closing, a hypothetical model of synaptogenesis is proposed, and an hierarchial order of events is associated with a speculative synaptogenic sequence. Key elements of this hypothesis are 1) epigenetic factors that facilitate generally appropriate interactions between neurites; 2) independent expression of surface specializations that contain sufficient information for establishing threshold recognition between interacting neurites; 3) exchange of molecular information that biases the course of subsequent junctional differentiation and ultimately results in 4) the stabilization of synaptic junctions into functional connectivity patterns.

The pre- and postnatal development of the dopaminergic cell groups in the ventral mesencephalon and the dopaminergic innervation of the striatum of the rat

In the adult rat the striatum is a compartmentalized structure, which is reflected in the inhomogeneous distribution of dopamine. As a first step to test the hypothesis that dopamine plays an organizational role in the development of the striatum, the ontogeny of the dopaminergic system was studied in detail with immunocytochemical methods employing antibodies against dopamine. Rat embryos, fetuses, pups and adults were perfusion-fixed with glutaraldehyde on all prenatal days from E11 onward, postnatally on P2, P4, P6, P7, P8, P13, P14, P20, P21, and in adult age. On E13 the first dopaminergic cells are detected in the ventral prosencephalon. On E14 two dopaminergic cell groups are present in the ventral mesencephalon, and fibres of these cells reach the ventrolateral part of the ganglionic eminence. In the next two days both the cell groups and their projections rapidly increase in size. On E17 the afferent dopaminergic fibres to the striatum become aligned and form huge bundles that are closely associated with the fascicles of the internal capsule. Rostrally, the development of the striatal dopaminergic innervation shows a clear ventrolateral to dorsomedial gradient, whereas more caudally the dopaminergic fibres innervate the striatum from a ventromedial position. The lateral parts of the otherwise compact mesencephalic cell groups consist of loosely arranged cells. From E17 onward these cells become arranged into a dorsal and a ventral group. Just before birth, on E21, the primordia of the dopaminergic cell groups in the substantia nigra pars compacta and pars reticulata can be observed. On E19 several centres with extensive fibre ramifications along the dorsolateral margin of the caudate putamen represent the first signs of the inhomogeneous distribution of dopaminergic fibres in the dorsal striatum seen during the next two weeks. In the following pre- and postnatal days these so-called dopaminergic "patches" also appear more medially. By the third postnatal week most of the patches are no longer detectable, and only the most dorsolaterally located ones, i.e. in the region where they first were detected on E19, remain visible through to the adult stage. Prenatally, no varicosities can be observed in the dopaminergic fibres. The first varicosities appear after birth. Their number increase rapidly during the first and second postnatal weeks and reaches near adult levels on P20. The development of the striatal dopaminergic innervation, and that of the "patches" in particular, is discussed in relation to the development of the mesencephalic dopaminergic cell groups.(ABSTRACT TRUNCATED AT 400 WORDS)

Dendritic development and preferential growth into synaptogenic fields: a quantitative study of Golgi-impregnated spinal motor neurons

Branching patterns of dendrites may be modulated by the way in which dendritic growth cone filopodia come into initial synaptic relationships with afferent axons. This synaptotropic hypothesis of dendritic branching predicts that dendritic growth will be directed preferentially into regions containing numerous prospective presynaptic elements. The developing mouse spinal cord provides a natural experiment to test this prediction, because synapses are found exclusively within the marginal zones bordering the motor columns during the early (E11-14) period of synaptogenesis. During this time, therefore, most motor dendritic growth would be expected to be directed laterally or ventrally into the marginal zones, whereas internally directed growth should become more prevalent later, when synaptogenesis begins to take place within the intermediate zone, i.e., the motor columns proper. A computer-assisted three dimensional reconstruction system has been used to test these expectations in Golgi preparations of developing mouse (C57BL/6J) spinal cords ranging in age from E13 through P1. Mean dendritic lengths and branch densities are significantly greater for marginal zone dendrites than for intermediate zone dendrites at early ages (E13-14), but there are no significant differences in these measures at later stages of development (P0,1). These findings are interpreted as meaning that motor dendritic growth is initially biased into the marginal zone by synaptogenic afferents and that this preferential distribution is progressively lost as synapses develop within the intermediate zone to attract or to stabilize internally directed dendritic growth. Thus the findings of this study are consistent with predictions of the synaptotropic hypothesis of dendritic branching.

Early ontogeny of catecholaminergic structures in the sheep brain. Immunohistochemical study

The localization of tyrosine hydroxylase was studied in the brain of sheep foetus during early ontogeny using immunohistochemistry. The first immunoreactive neurons appeared very early since they were found on day 30 of pregnancy in the medioventral part of the mesencephalic flexure. The distribution of the different catecholaminergic groups of neurons was similar to the adult's after 75 days of pregnancy. The latest groups to appear was the A12 group. Comparison of the development of the sheep foetus with rodents or primates, more commonly studied, is difficult because of its different development. It seems, however, that catecholaminergic structures appear earlier in sheep and rodents than in human. Considering the early appearance of these transmitters in the central nervous system, their role on brain development has to be studied in the future.

Comparative anatomy of the ventromedial mesencephalic tegmentum in the rat, cat, monkey and human

The five component nuclei of the ventromedial mesencephalic tegmentum (VMT) were studied on Nissl stained serial sections of the brain stem of rat, cat, monkey (Macaca nemestrina) and human. Models of the VMT nuclei were constructed to compare their size, shape and disposition across species. For each nucleus in each species the following were calculated: the volume, the number of neurons, the size distribution of neurons, the mean soma size and the packing density of neurons. The morphology of the cells in the different nuclei is also described. The parabrachial pigmented nucleus (PBP) forms, on average, 51% of the VMT volume and cell number. The paranigral nucleus (PN) and the central linear nucleus (LC) formed 19% and 14% of the VMT volume and cell number respectively. The relatively small, but compact interfascicular nucleus (IF) was on average 9% of the VMT volume and cell number and the rostral linear nucleus (LR) formed its remaining 7%. However, in different species the relative prominence varies between species. Thus PBP is the largest of the VMT nuclei in the monkey, PN is particularly well developed in the human, IF contains a particularly large number of cells in the rat, and LR and LC are strongly developed in the cat. This study presents a cytoarchitectonic description of the five nuclei in each species. The distinctive cytoarchitectonic appearance of each nucleus suggests that their functions may differ. This possibility, which is strengthened by evidence that the projections of the VMT nuclei are differential, may need to be considered in the interpretation of the results of experimental investigations using stimulation and/or lesion experiments in the VMT region and in the interpretation of pathological findings in the human brain.

Aromatic L-amino acid decarboxylase in the rat brain: immunocytochemical localization during prenatal development

Immunocytochemically labeled cells containing the enzyme aromatic L-amino acid decarboxylase were localized in the brain of rat embryos at gestational age E15-E19. Cell groups that contained aromatic L-amino acid decarboxylase but lacked either the enzyme tyrosine hydroxylase or the indolamine serotonin were referred to as "D" groups. Anatomical landmarks, cytoarchitectonic structure and histochemical staining for acetylcholinesterase were used to delineate the position of "D" groups. In the E15 embryo three "D" groups existed. The first to appear, named D1, was located in the spinal cord and had been demonstrated before. A large "D" cell cluster was found in the walls of the central forebrain deep to the hypothalamic sulcus. This group distributed dorsally in the ventral dorsal thalamic region and ventrally in the dorsal hypothalamus. The rostral-most "D" group, D14, occurred in the ventral telencephalon just medial to fibers of the nigrostriatal projection. D14 was the smallest of the early groups. In E16 and E17 embryos dorsal di- and mesencephalic "D" groups were first detected. During the course of ontogeny a considerable increase of immunoreactive cells occurred and segregation of the large central forebrain cluster into several rostrally and laterally distributed "D" groups took place. Some "D" groups that occur in the adult brain were not present in the E19 embryo. This study provides a first report of the localization of several unique cell groups in the brain of rat embryos and their appearance at different stages of gestation. It also gives further support to the notion that variations of aromatic L-amino acid decarboxylase staining intensities may be characteristic of different monoamine neurons.

Ventral tegmental area of the rabbit brain: a developmental Golgi study

The ventral tegmental area (VTA) of the rabbit mesencephalon was examined with Golgi-Cox impregnation at neonatal (days 3-21 of age) and young adult (6-12 months of age) stages of development. Neurons in the dorsal midline were small, with sparsely-branched, vertically-oriented dendrites. Neurons in the ventral midline were medium-sized, oval cells with sparse, vertically-oriented dendrites, and multipolar cells with more abundant diffusely-oriented dendrites. Neurons in the medial zone of the VTA, between the midline and the exiting III nerve fibers, were oval in shape, medium in size, and possessed vertical dendritic arborizations of greater size and extent of branching than those in the dorsal midline. Lateral neurons, found among III nerve fibers, were medium-sized and possessed dendritic trees that were specifically oriented in a vertical or horizontal plane, or were diffusely-branched with more abundant arborizations than their specifically oriented counterpart. Very small neurons with short, single branches were scattered among all regions of the VTA. The major cell types showed a similar pattern of dendritic maturation. At 3-9 days of age, the dendrites were generally short, spiny and poorly branched. From days 9-21, the branches increased in number and length, spines were lost, and these neurons rapidly approached adult size and form. The neurons of VTA appear isodendritic in form, and developed in a pattern consistent with other areas of reticular formation, suggesting that VTA may be part of the reticular core of the brain stem.(ABSTRACT TRUNCATED AT 250 WORDS)

Isthmic origin of neurons of the rat substantia nigra

This study provides new data on the time of origin, the generation site and the migration route of the young neurons of the substantia nigra of the rat during embryogenesis. The neurons of the substantia nigra are generated on day 12, 13, 14 and 15 of gestation. They settle following a light spatiotemporal rostrocaudal gradient from day 12 to 15. The neurons of the substantia nigra are generated at two different points of the basal plate at the level of the fovea isthmi (meso-isthmic junction) and migrate in radial pattern as two definite streams toward the ventral mesencephalon. From this point they move rostralwards along the surface towards their final site. The main findings of this work are the disclosure that the neurons of the substantia nigra are generated in the region of the isthmus rhombencephali and that its cells do not migrate between existing cells of the mesencephalic tegmentum but first migrate ventralwards in a radial pattern and then rostrally towards their definite site. Numerous neurons of the basal mesencephalon and of the midline structures of the caudal mesencephalon are apparently derived from the region of the fovea isthmi.

Development of the serotonergic system in the rat embryo: an immunocytochemical study

The development of central serotonergic neurons has been examined immunocytochemically utilizing an antiserum to serotonin (5-HT). Cells of the B4-B9 complex are first detected early on embryonic day 13 (E13; 7 mm crown rump length, CRL) and increase rapidly in number through E15 when they appear as bilateral columns situated from just caudal to the mesencephalic flexure to the pontine flexure. Aggregation of cells into subgroups is apparent soon after 5-HT neurons leave the ventricular zone, allowing the identification of certain subdivisions of the B4-B9 complex long before they assume their adult locations. The initial detection of 5-HT immunoreactive cells in the medulla occurs 1-2 days after the appearance of cells in the B4-B9 complex, although it has been reported that the time of origin of medullary raphe neurons (B1-B3) occurs before that of raphe neurons in the midbrain and pons (B4-B9). The first medullary 5-HT neurons, comprising the B3 subdivision occur ventro-laterally on E14 (10-11 mm CRL) at least 1-2 days before midline 5-HT neurons are visualized in the B1 and B2 groups. Thus, in contrast to cells in the B4-B9 complex, medullary 5-HT neurons complete much of their migration before they can be detected immunocytochemically, indicating that the time of onset of transmitter synthesis and storage may differ during differentiation of cells sharing a common neurotransmitter phenotype. The formation of ascending 5-HT fiber projections occurs rapidly from cells of the B4-B9 complex. Within 24 hours after the initial detection of 5-HT fiber immunoreactivity in such cells at E13, their axons are seen entering the caudal diencephalon (E14). These fibers have traversed the diencephalon and floor of the telencephalon by E15-E16 and reach the frontal neocortical pole by E17. The main ascending bundle of 5-HT axons courses through the diencephalon in the vicinity of the medial forebrain bundle, although some fibers also diverge and travel along certain pre-existing non-5HT pathways. However, examples are also found of acute directional changes in 5-HT fiber growth which do not appear to be associated with pre-formed non-5HT pathways. The pattern of ascending fiber outgrowth suggests a priority routing system which provides certain regions with 5-HT axons in a preferential sequence irrespective of the distance of these areas from 5-HT cell groups or from major bundles of ascending 5-HT fibers.

Hormonal and humoral influences on brain development

This review discusses evidence for neurotransmitters as developmental signals in such ontogenic processes as neural tube formation (neurulation), germinal cell proliferation, and neuronal and glial differentiation during brain organogenesis, as well as evidence for other roles of these neurotransmitters in non-neuronal tissues of vertebrates and invertebrates. Evidence also is presented for hormonal regulation of brain development during postnatal neurogenesis and for interrelationships which may link neurotransmitters and hormones in a humoral milieu, providing a variety of control mechanisms for the central and peripheral nervous system during key phases of their development. Given the evidence for neurotransmitters and hormones as coordinating influence on neural ontogeny, it is possible that drugs, stress, and environmental influences may have the ability to perturb particular aspects of these developmental systems if present during those "critical periods" when such humoral influences are important for normal ontogeny.

The postnatal development of the substantia nigra: a light and electron microscopy study

The early postnatal development of neurons, dendrites and synaptic connectivity in kitten substantia nigra (SN) was studied by light and electron microscopy. The compact and reticular divisions of the SN are present at birth but boundaries are indistinct. Most nigral neurons stain deeply in routine histological sections and their diameters increase slightly with age. Ultrastructurally, cell bodies are characterized by eccentrically located and often invaginated nuclei surrounded by cytoplasm rich in well-formed organelles. Axosomatic synapses are infrequent and cell surfaces are enveloped by glial processes. Immature dendritic features, including growth cones and filiform processes, are commonly observed during the first 10 days. Gradually the dendritic profiles elongate and thicken and contours become smoother, retaining only scattered spinelike appendages. Clear examples of the three synaptic types described in cat are found in newborn kittens, but immature terminals contain fewer synaptic vesicles and mitochondria. Approximately 90% of synapses present at birth in both nigra subdivisions are Type I, which contain large pleomorphic vesicles and contact dendrites symmetrically. Asymmetrical contacts characterize most of the remaining definable synapses. The postnatal increase in synaptic connectivity, which was estimated from random photographs of pars reticulata neuropil, is twofold during the first 50 days of life. Initially young dendrites are enveloped by glia and then gradually become ensheathed by axon terminals. Synaptogenesis in pars reticulata reflects the postnatal increase of neostriatal inputs to this subdivision and can be correlated with functional changes in strionigral connectivity.

A review of the neuroembryology of monoamine systems

The technique of monoamine histofluorescence has been used successfully for neuroembryologic studies in a number of species ranging from amphibia to the human. Monoamine systems can be visualized early, often before final cell division and migration have taken place. Neuronal cell bodies are seen before axon terminals. Unlike the adult animal, preterminal axons can often be visualized, even in the untreated animal. Anatomical studies have shown major analogies in most of the species studied. CA-containing neuronal cell bodies are restricted to the brainstem and hypothalamus. Those neurons containing 5-HT are largely restricted to the brainstem raphe, although other cell groups may take up 5-HT, or related compounds, under experimental conditions. Monoamine nerve terminals are found throughout the entire nervous system, with some of the regions of highest density being the hypothalamus and striatum. Dynamic studies have indicated that biochemical differentiation precedes morphologic maturity, often by a long period of time. Although attempts have been made to determine a specific role of monoamines in the complex programs of neurogenesis, there is little specific data currently available.

In vivo and in vitro development of serotonergic neurons

The monoamines are one of the earliest developing neurotransmitter systems in the mammalian brain. The first part of this paper describes the normal ontogeny of the serotonergic (5-HT) system in the rat brain as studied using long survival 3H-thymidine autoradiography (time of neuronal genesis, time of origin) and the Falck-Hillarp histofluorescence method, electron microscopy, and immunocytochemistry (anti-5-HT). Due to their early ontogeny relative to other brain regions, 5-HT neurons (as well as monoamine neurons in general) have been suggested to exert some type of "trophic" influence on brain development. Results of pharmacological experiments designed to inhibit 5-HT synthesis in the embryonic rat brain by maternal treatment with p-chlorophenylalanine (pCPA) at a time when this monoamine might exert such an influence are discussed with regard to effects on the time course of neuronal genesis (time of origin) of 5-HT neurons and their target cells. These results, which prompted us to propose that 5-HT might act as a "differentiation signal" for certain of its target cells, are now discussed in light of our more recent immunocytochemical-autoradiographic studies (anti-5-HT, 3H-thymidine) which morphologically demonstrate close associations between developing 5-HT neurons and proliferating neuroepithelial cells in the embryonic brain. Postnatal studies using this immunocytochemical-autoradiographic method also provide evidence for interactions of 5-HT axons with proliferating glioblasts in the developing cerebellum and with immature granule cells and their precursors in the hippocampus. These findings, in conjunction with the results of our pCPA experiments, further enhance the possibility that 5-HT neurons could exert an epigenetic influence on the development of less differentiated cells with which they come into contact. Finally, preliminary studies using dissociated cell cultures containing 5-HT neurons suggest that interactions between 5-HT neurons and glial elements may be important for the differentiation of these neurons in vitro. Whether 5-HT neurons in turn influence the development of glial or neuronal cells in these cultures remains to be determined. These studies are evaluated with regard to a possible pre-transmission role for 5-HT during key phases of neuronal and glial genesis.

Effects of chronic reserpine treatment on development of maturity of the putamen in fetal rabbits

Developing nigrostriatal axons and their perikarya have substantial quantities of dopamine (DA) before the axons reach their postsynaptic target. In order to investigate possible developmental effects of these stores of DA, we have depleted DA chronically during critical periods in the ontogeny of the nigrostriatal system. Reserpine (0.04-0.14 mg/kg/day) was given repeatedly to maternal rabbits for various periods starting before neuroblasts of the substantia nigra first exhibit fluorescence until 2 days before term when the fetuses were sacrificed. Reserpine crossed the placenta and depleted DA in the fetal putamens. Control fetuses had widespread fluorescent axons and terminals. Counts of mature axonal boutons in electron micrographs of the putamen of reserpine-treated fetuses showed that there were 4.3 +/- 0.6 SE/100 microns2, which is less than 1/2 the control value of 10.2 +/- 0.6 SE/100 microns2 (p less than 0.001). The neuropil of the putamen of the reserpine-treated fetus was also less mature; the relative volume occupied by growth cones (40.5% +/- 5.7 SE) was twice that of controls (20.6% +/- 2.4 SE) (p less than 0.005). Although it remains to be shown that the delayed development of both pre- and postsynaptic elements of the nigrostriatal system is specifically related to the known ability of reserpine to deplete DA, the results are consistent with the hypothesis that early stores of DA may be important in developing dopaminergic systems.

Topographic, morphologic and developmental characterization of the nucleus loci coerulei in the chicken. A Golgi and fluorescence-histochemical study

Golgi- and fluorescence-histochemical studies in the chicken shown the presence of a sharply delimited group of aminergic neurons beneath the floor of the fourth ventricle at the mesen-metencephalic boundary. According to the observations reported in other avian species a homology can be established between the mammalian locus coeruleus (LC) and this fluorescent cell mass of the chicken brainstem. Golgi studies revealed an isodendritic pattern of ramification of the neurons in this nucleus. In addition, a developmental study on the morphological maturation of the LC in the chick embryo was carried out by means of the histochemical-fluorescence method for biogenic amines and the rapid Golgi method. The time of the first onset of catecholamine synthesis and storage has been shown to correspond to the 9th day of incubation (stage HH 35), just when these cells display a well-established and peculiar dendritic pattern. All maturational events in the LC of the chick embryo thus occur earlier than in the fetal rat brain, the prenatal development of which is accomplished in a period of comparable length.

The time of genesis, embryonic origin and differentiation of the brain stem monoamine neurons in the rhesus monkey

Neurogenesis of the locus coeruleus (LC), substantia nigra (SN) and raphe nuclei (RN) was analyzed in autoradiograms prepared from postnatal rhesus monkeys that had been exposed to a pulse of [3H]thymidine on selected embryonic (E) days of the 165-day gestational period. Heavily labeled monoamine (MA) neurons were present only in monkeys exposed to the isotope between E27 and E36 with the peak around E30-E33. The majority of neurons generated on E30 eventually become situated in the medial part of the LC, whereas most cells of the lateral portion are generated on E32 and E33, indicating the existence of a mediolateral spatiotemporal gradient. Proliferation of neurons destined for the compact portion of the LC peaks around E32, whereas production of subcoeruleus cells proceeds more evenly throughout the E30-E33 period. SN neurons are generated between E36 and E43, with peak labeling around E38-E40, and no appreciable spatiotemporal gradients. Neurons of the ventral tegmental area are also generated between E38 and E43. Neurogenesis of the RN occurs between E28 and E43 with only a moderate rostrocaudal spatiotemporal gradient. Neurons of raphe dorsalis and centralis superior undergo final mitosis between E28 and E35, with the peak on E30, whereas cells of raphe magnus, pontis, obscurus and pallidus are produced between E35 and E43, with the peak between E38 and E40. In general, MA neurons that project to different targets may be produced simultaneously within each nucleus irrespective of any spatiotemporal gradients. Examination of another series of fetuses sacrificed at various short intervals after exposure to [3H]TdR revealed that all MA neurons arise in the ventricular zone with each MA nucleus being generated at a specific level of the brain stem. Postmitotic MA cells migrate to their final location along specific pathways, and settle in patterns corresponding to the sequence of their genesis. Morphometric analysis indicated that after reaching their final destinations, the somas and nuclei of all MA neurons grow according to the same tempo and sequence irrespective of the developmental schedules of their synaptic targets.

Fine structure of the nigrostriatal anlage in fetal rat brain by immunocytochemical localization of tyrosine hydroxylase

The developmental morphology and synaptic associations of neurons in the nigrostriatal anlage are examined by the electron microscopic immunocytochemical localization of tyrosine hydroxylase at embryonic (E) day 13.5 and 14.5 in rat brain. At E 13.5, immunoreactivity for the enzyme is localized throughout the cytoplasm of neuronal perikarya and processes including somatic, dendritic, and axonal growth cones. The cytoplasmic organelles in perikarya include primarily ribonucleic-protein particles, mitochondria and an immature Golgi apparatus. At E 14.5, the tyrosine hydroxylase labeled processes are detected in the lateral hypothalamus and ventrolateral caudate-putamen. The axonal processes showing immunoreactivity in the ventral mesencephalon and more rostral portions of the nigrostriatal bundle are frequently attached to unlabeled neurites by puncta adherentia. In the hypothalamus and caudate-putamen presumably transient synaptic junctions are also detected between the labeled axons and unlabeled neurons. The immature morphological features of neurons showing immunoreactivity for tyrosine hydroxylase thus indicate, that the biochemical differentiation of the nigrostriatal neurons precedes complete cytological differentiation.

Light-microscopic immunocytochemical localization of tyrosine hydroxylase in prenatal rat brain. I. Early ontogeny

The immunocytochemical localization of tyrosine hydroxylase is examined during early ontogeny in the fetal rat brain in order to determine the age of first detection and subsequent cellular localization of the enzyme and the developmental characteristics of the immature catecholaminergic neurons. Fetal atlases of the tyrosine hydroxylase-labeled neurons are presented at embryonic day (E) 12.5, 13.5, and 14.5. Tyrosine hydroxylase is first detected immunocytochemically at E 12.5. At this stage, the labeled neurons have completed final mitosis, but are still migrating and are cytologically immature. Tyrosine hydroxylase can also be detected in axons and axonal growth cones at this stage of development. The age of first immunocytochemical detection of the enzyme precedes the demonstration of catecholamine fluorescence by 1 to 2 days in certain nuclear groups. At later stages of development (E 13.5 and E 14.5), the major groups of perikarya and processes labeled for tyrosine hydroxylase have a distribution similar to that previously described by catecholamine fluorescence. At E 14.5, the perikarya undergo considerable changes in their cytology and exhibit the first dendrites immunocytochemically labeled for the enzyme. The first terminal fields are also detected in the rudimentary caudate-putamen at this stage.

Ontogeny of medullary raphe nuclei in the rabbit brain stem: a Golgi study

Nuclei raphe obscurus, pallidus, and magnus, found in the midline and paramedian regions of the medulla, were examined in rabbits between day 22 of gestation and adulthood. At day 22 of gestation (total gestation period of 32 days), the neurons were small with sparsely branched processes. Between day 26 of gestation and 6 days of age, the dendrites expanded, increased the number and length of their branches, and developed abundant spines. During this period, the cell bodies grew in size. From postnatal day 6 to adulthood, a mature pattern of dendritic branching was achieved, and the number of spines on the dendrites was reduced. Nuclei raphe obscurus, pallidus and magnus each possessed cells with unique morphological appearances early in ontogeny, but showed a similar pattern of enhanced dendritic branching with numerous spines through early neonatal development, followed by a reduction in the number and size of the spines. Despite the morphological heterogeneity of the medullary raphe nuclei, their general pattern of dendritic development is similar, suggesting that afferent connections to these nuclei may be formed during cellular maturation by a process similar to that described for the reticular formation and other central neurons.

Roles for serotonin in neuroembryogenesis

Possible non-transmitter roles for 5-HT in different phases of early neuroembryogenesis have been discussed based upon experimental evidence from the rat and chick. Fluorescence histochemical studies have demonstrated sites of uptake and synthesis of 5-HT in the chick embryo during the first few days of incubation. These sites are located in discrete regions of the notochord and floor plate of the neural tube as well as in extra-neural regions such as the somites and primitive gut. The 5-HT patterns are distinctly different from those observed for the uptake and synthesis of norepinephrine in embryos of the same age. Spatio-temporal changes in the distribution of these sites during closure of the neural tube suggest a role for 5-HT in various aspects of neural tube development. Moreover, the non-overlapping localization of 5-HT and norepinephrine raises the possibility that these two amines may exert different and perhaps cooperative influences on early neurogenic processes in the chick. In the rat, autoradiographic and biochemical studies concerning the consequences of 5-HT depletion in the embryo for development of different brain regions have provided evidence that 5-HT acts as a "differentiation signal" regulating the time of neuronal genesis in those cell populations which will eventually receive 5-HT innervation. Although the details of this system are as yet unknown, these studies suggest that 5-HT (and possibly the other monoamine transmitters) may actually "mold" the construction of their own circuitry during neurogenesis. Further, the ability of drugs and stress to interact with this process during that period of gestation when the monoamines are required as humoral signals suggests that maternal influences can interfere with ontogeny of this circuitry during pre- and possibly postnatal development. It is not yet clear whether the data in chicks and rats can be directly analogized from the one species to the other. Nevertheless, the evidence that sites of 5-HT uptake and/or synthesis are present during the earliest phases of neurogenesis in the chick and the observation that 5-HT depletion can alter the time of genesis of 5-HT target cells in the rat provide a new context for the consideration of possible actions of 5-HT prior to its role as a neurotransmitter substance.

Ultrastructural localization of acetylcholinesterase activity in primary cultures of rat substantia nigra

Ultrastructural localization of acetylcholinesterase activity was studied in primary cultures of the substantia nigra microdissected from newborn rat brains. Light microscopic observations were also made on the characteristics of dopamine neurones and acetylcholinesterase containing cells in these cultures. Ultrastructurally acetylcholinesterase activity was localized in the nuclear envelope and rough endoplasmic reticulum of neurones, which had deeply infolded, round or oval nucleus, a prominent Golgi apparatus and varying amounts of rough endoplasmic reticulum. In the neuropil acetylcholinesterase activity was seen within microtubules of neuronal processes and in the rough endoplasmic reticulum of dendrites. The enzyme activity was also demonstrated within the nuclear envelope and rough endoplasmic reticulum of probably capillary endothelial cells. Dopaminergic neurones were identified on the basis of the green catecholamine fluorescence they exhibited. Small dopaminergic neurones could be observed and there was indirect evidence that these cells did not stain for acetylcholinesterase.

Neuronal-vascular relationships in the raphe nuclei, locus coeruleus, and substantia nigra in primates

A fluorescence histochemical and electron microscopic study of the monoaminergic cell groups in the squirrel monkey and Rhesus monkey brains has revealed the direct apposition of blood vessels to perikarya and dendrites of monoaminergic neurons. Capillaries and small arterioles or venules, ranging from 8-50 microns in diameter, showed perikarya and dendrites abutting the basement membrane without evidence of glial interposition. This neuronal-vascular relationship was present in 20% to 30% of the small vessels in the serotonergic nuclei raphe dorsalis and centralis superior and in the noradrenergic locus coeruleus. Such contacts were clearly present but observed less frequently in the dopaminergic substantia nigra pars compacta and in the serotonergic nuclei raphe obscurus, pallidus, magnus, and pontis. We postulate that monoamine-containing neurons apposed to blood vessels in certain regions of the brain may be influenced directly by hormones or other substances in blood.

Development of the noradrenergic innervation of neocortex

The development of the noradrenaline (NA)-neuron innervation of rat neocortex was studied by fluorescence histochemistry, high affinity uptake of [3H-]NA, and biochemical assay of regional NA content. Fluorescence histochemistry indicates that NA axons enter areas of developing neocortex prenatally and the innervation matures rapidly during early postnatal life. Frontal and lateral neocortical areas are the first to be innervated followed by occipital and parietal areas. All cortical layers receive innervation. The distribution and density of neocortical NA innervation achieves the adult pattern by the end of the first postnatal week. High affinity uptake studies confirm the observations from fluorescence histochemistry and show a very rapid maturation of the NA axon innervation with adult levels of uptake occurring by postnatal day 9. Following birth, there is a brief rise in NA content from PO to P2 in all neocortical areas. NA content then drops to low levels in all areas by P4. This is followed by a gradual increase in NA content in all areas occuring over several months. This pattern of development of NA axon innervation of neocortex demonstrates that the density and distribution of NA axons in developing neocortex matures much earlier than shown in previous studies whereas the NA content of the developing axonal plexus achieves adult levels later in postnatal life.