The onset of synapse formation in spinal cord cultures as studied by electron microscopy

Cytonemes with complex geometries and composition extend into invaginations of target cells

Cytonemes are specialized filopodia that mediate paracrine signaling in Drosophila and other animals. Studies using fluorescence confocal microscopy (CM) established their general paths, cell targets, and essential roles in signaling. To investigate details unresolvable by CM, we used high-pressure freezing and EM to visualize cytoneme structures, paths, contents, and contacts. We observed cytonemes previously seen by CM in the Drosophila wing imaginal disc system, including disc, tracheal air sac primordium (ASP), and myoblast cytonemes, and identified cytonemes extending into invaginations of target cells, and cytonemes connecting ASP cells and connecting myoblasts. Diameters of cytoneme shafts vary between repeating wide (206 ± 51.8 nm) and thin (55.9 ± 16.2 nm) segments. Actin, ribosomes, and membranous compartments are present throughout; rough ER and mitochondria are in wider proximal sections. These results reveal novel structural features of filopodia and provide a basis for understanding cytoneme cell biology and function.

An electron microscopic study of the development of synapses in cultured fetal mouse cerebrum continuously exposed to xylocaine

Explants of fetal mouse cerebral cortex, continuously exposed to the local anesthetic Xylocaine from the time of explantation to the time of fixation, were examined in the electron microscope to determine whether morphologically normal synapses and potentially functional interneuronal synaptic networks can form in the absence of electrical impulse activity. Morphological differentiation of complex synaptic networks proceeds normally, and the drug does not alter the fine structure of the formed synapses. These observations are consonant with the electrophysiological data which show that the potential for complex bioelectric activity can develop in the absence of its expression. The development and maturation of functional synaptic networks, then, is not contingent upon prior electrical impulse activity. These data support the concept that organized neuronal assemblies are formed in forward reference to their ultimate function.

The astroglial cell that guides nerve fibers from growth cone to synapse in organotypic cultures of the fetal mouse spinal cord

We present electron microscopic and autoradiographic studies done using organotypic cultures of spinal cord explants excised from 15 days of gestation mouse embryos. Nerve fibers growing from the spinal cord explant carry at their tips immature mitotic astrocytic cells that lead their growth cones. These glial cells divide only during the active phase of neuronal growth, and correspond ultrastructurally to radial glia. They provide a specific cellular substrate for neuronal growth. Some growth cones form axoglial synapses with smooth membranes of immature glial cells. In contrast, maturing glial cells sprout cytoplasmic processes that tightly wrap individual growth cones and effectively arrest their growth. Next, the processes gather nerve endings into islets and nerve fibers into bundles. After internalizing nerve endings, the glial processes withdraw, bringing the endings into contact with each other. The direct neuronal appositions lead to the transformation of growth cones into presynaptic endings, signaled by their collection of presynaptic vesicles. Clustering of the vesicles at presynaptic axoglial or axodendritic membranes indicates the onset of synaptogenesis-completed by differentiation of spinous and compound synapses. Concomitant with the progress of synaptogenesis, astrocytic investment within the neuropil progressively diminishes. The differentiating astrocytic processes show secretory and tethering activity toward nerve fibers and their endings. Our observations demonstrate that astroglial cells-depending on their developmental stage-first promote and then arrest neuronal growth, and induce synaptogenesis. Thus, at any time, the growing nerve fibers are not only supported but also controlled by the astroglial cells.

Development of specific synaptic network functions in organotypic central nervous system (CNS) cultures: implications for transplantation of CNS neural cells in vivo

This article provides a broad overview of the significant roles that morphophysiologic analyses of organotypic cultures of neural tissues explanted in vitro-initiated during the 1950s-have played in stimulating the more recent development of techniques for transplantation of neural cells and tissues into specific regions of the central nervous system (CNS) in vivo. The demonstrations by Crain and co-workers in the 1950s and 1960s that fetal rodent and human CNS neurons can continue to develop a remarkable degree of mature structure and function during many months of complete isolation in culture provided crucial evidence that development of many organotypic properties of nerve cells is regulated by epigenetic factors that ensure rather stereotyped expression despite wide variations in environmental conditions. These in vitro studies strongly suggested that fetal neural cells should, indeed, be capable of even more highly organotypic development after transplantation in vivo, as has been elegantly demonstrated by many of the successful CNS transplantation studies reviewed here.

Synaptic inputs on rat brainstem motoneurones in organotypic slice culture

To study the formation of target specific afferents on brain stem motoneurones of the rat, we used an organotypic co-culture of embryonic rat (E18) brain stem explants containing the facial or hypoglossal motor nuclei together with a tongue explant. The brain stem explants also contained known dorsal premotor structures such as lateral reticular nuclei and vestibular or spinal trigeminal nuclei. In cultures maintained in vitro for over 3 weeks, silver impregnation studies identified neurones in the dorsal sensory structures with axons arborizing within the motor nucleus. A double fluorescent labelling procedure demonstrated that axons originating from dorsal sensory regions come in close contact with identified motoneurones. Electrical stimulation of neurones in the dorsal regions induced monosynaptic and polysynaptic EPSPs and spikes in identified motoneurones together with muscle contraction. This work demonstrates that premotor structures in slice cultures develop organotypic functional synaptic connections with embryonic brain stem motoneurones.

Embryonic development of the antennal lobes of a hemimetabolous insect, the cockroach Periplaneta americana: light and electron microscopic observations

In the hemimetabolous insect Periplaneta americana, the adult-like organization of the primary olfactory centers, the antennal lobes, is established during the approximately 31 days of embryogenesis. This report describes the temporal sequence of developmental events as viewed in the light and electron microscope by means of histological stains and by DiI labeling of antennal receptor axons with subsequent photoconversion. Glomeruli, characteristic differentiations of the antennal lobe neuropil, are first observed on day 19; their development, which is not synchronous in the various parts of the antennal lobe, lasts until about day 22. From day 10 on, glial cells begin to form a narrow boundary layer between the soma cortex and the central neuropil. They exhibit a lengthening of their processes in parallel with the formation of glomeruli. Marked proliferation or migration of these glial cells into the neuropil between glomeruli has not been observed. Antennal receptor axons could be labeled from stage 15 on. They terminate in an elongated growth cone with numerous filopodia. From day 18 on, some of these become bent or show an initial bifurcation. From day 22 on, the first afferent axons develop an adult-like arborization pattern. Synaptic contacts between receptor axons and unidentified neurons were observed as early as stages 16 and 19, in which the axons still have a growth cone-like form. In stage 27, in which the fibers have adult-like arborizations, many output contacts and few input contacts were found.

Structure and plasticity of newly formed adult synapses: a morphometric study in the rat hippocampus

Increasing evidence suggests that synaptic structure represents a plastic feature of the neuron, although the plastic nature of newly formed and existing adult synapses has not yet been fully characterized. Following ipsilateral entorhinal cortical lesions, the rat dentate gyrus offers an excellent model for studying synaptogenesis and plasticity in the adult central nervous system. Unilateral entorhinal lesions were performed in young adult male rats. Synaptic counts and structural features were quantified at 3, 6, 10, 15, and 30 days post-lesion. The lesions resulted in an 88% synaptic loss in the denervated dentate middle molecular layer, which was followed by a period of rapid synaptogenesis. Synaptic element size decreased during the period of maximal synaptogenesis, which was associated with a peak in the presence of non-vesicular and perforated synapses. Following this period, synapses showed a gradual increase in the size of their pre- and postsynaptic elements. These data support the suggestion that newly formed adult synapses have smaller synaptic components than existing adult synapses (resembling synapses seen during development), and increase in size over time with usage. The results are discussed in terms of synaptic structural development and plasticity in the adult central nervous system.

Development of the principal sensory nucleus of the trigeminal nerve of the rat and evidence for a transient synaptic field in the trigeminal sensory tract

The early development of the principal sensory nucleus of the trigeminal nerve (PSN) was examined to determine whether spatiotemporal patterns of synaptogenesis coincide with patterns in neuronal generation, migration, and death. The morphogenesis of PSN neurons during the period from G16 to P14 was studied with a Golgi method. Prenatally, PSN neurons had dendrites that extended into the sensory tract of the trigeminal nerve (s5), and from as early as G18, these dendrites were studded with spines. The dendrites in the s5 degenerated or regressed in the early postnatal period so that the s5 was free of dendrites by P14. The development of anti-synapsin I immunoreactivity was traced from G14 to P10. Immunoreactive puncta (synaptic boutons) appeared in the medial third of the s5 transiently between G18 and P5. On the other hand, puncta in the PSN did not appear until G20, at which time they were confined to the lateral margin of the PSN. By P0, puncta were distributed throughout the PSN. Cytochrome oxidase activity in the PSN was low and unpatterned prenatally. Postnatally, cytochrome oxidase activity intensified and a segmented pattern of barreloids appeared in the ventral PSN on the day of birth. By P5, the complete pattern of barreloids, spanning the full width of the ventral PSN, was evident. The development of cytochrome oxidase activity in the PSN followed the lateral-to-medial gradient of synaptogenesis revealed by the development of synapsin 1 immunoreactivity. This gradient is opposite of that for neuronal generation, migration, and death. Moreover, the s5 serves as a transient synaptic field.

Neuronal firing patterns of organotypic rat spinal cord cultures in normal and in ACTH/alpha-MSH(4-10) analog (BIM 22015)-supplemented medium

The spontaneous and evoked electrical patterns of spinal cord explants from 13- to 14-day old rat fetuses grown from 2 to 8 weeks in vitro were compared when fed either with a standard or with an adrenocorticotropic hormone/alpha-melanocyte stimulating hormone (4-10) analog (BIM 22015)-supplemented medium. Standard and BIM 22015-treated cultures developed similar patterns of extracellularly recorded activity which consisted of mostly phasic but also tonic discharges. The standard cultures when treated by BIM 22015 in acute experiments (100 micrograms/ml) showed a decrease in their frequency of discharges which fired in a regular tonic pattern. These effects were neither age- nor dose-dependent but were increased in Ca2+ free medium. The ventral cord neurons chronically fed with BIM 22015 showed a strongly bursting pattern resembling strychnine-induced synchronized bursts. Both these effects, inhibitory (acute) and excitatory (chronic), of the BIM upon spinal cord cultured ventral horn neurons are discussed as possible calcium-dependent phenomena.

An Organotypic Spinal Cord - Dorsal Root Ganglion - Skeletal Muscle Coculture of Embryonic Rat. II. Functional Evidence for the Formation of Spinal Reflex Arcs In Vitro

Electrical properties of motoneurons, muscle fibres and dorsal root ganglion (DRG) cells were studied in an organotypic coculture of embryonic rat spinal cord, dorsal root ganglia and skeletal muscle. The motoneurons were identified by their morphology and position in culture. Their size and input conductance were significantly larger than those of spinal interneurons. Intracellular current injection evoked action potentials in all motoneurons, but only evoked stable repetitive firing patterns in some. Excitability was correlated to somatic size and the rate of spontaneous excitatory input. It is suggested that the somatic growth and the increase in excitability is regulated by the excitatory afferents. The motoneurons showed spontaneous excitatory and inhibitory postsynaptic potentials and action potentials which disappeared with the application of various agents known to inhibit excitability or excitatory synaptic transmission. Excitatory and inhibitory postsynaptic potentials (EPSPs and IPSPs respectively) were distinguished by their shape, reversal potential and pharmacology. IPSPs could be depolarizing or hyperpolarizing in different cells. A higher percentage of cells with hyperpolarizing IPSPs was found in older cultures and in the presence of skeletal muscle, suggesting a reversal of the polarity of IPSPs with development. The spontaneous muscle contractions observed in the cultures could be due either to innervation, spontaneous oscillations of the membrane potential, or electrical coupling between neighbouring fibres. A small percentage of DRG cells showed spontaneous action potentials, all of which were found in cultures with spontaneous muscle contractions. The electrical stimulation of DRG afferents evoked mono- and polysynaptic EPSPs in motoneurons, endplate potentials and muscle contractions. The stimulation of the ventral horns evoked endplate potentials and muscle contractions via mono- or polysynaptic pathways. Together these results indicate that appropriate and functional contacts were established in the culture between myotubes and DRG cells, between DRG cells and motoneurons, and between motoneurons and muscle fibres.

An Organotypic Spinal Cord - Dorsal Root Ganglion - Skeletal Muscle Coculture of Embryonic Rat. I. The Morphological Correlates of the Spinal Reflex Arc

The cytoarchitecture of a spinal cord - dorsal root ganglion - skeletal muscle tissue coculture system was investigated at the level of the light microscope using a number of different staining techniques. In these cultures central synapses between dorsal root ganglion (DRG) cells and interneurons in the ventral spinal cord and between DRG cells and motoneurons were visualized by parvalbumin immunostaining and by intracellular horseradish peroxidase (HRP) filling of DRG cells. Skeletal muscle fibres regenerated in vitro first into multinucleated myotubes, and around day 8 in vitro into well differentiated muscle fibres with regular cross-striation. At the same time newly formed motor endplates could be visualized using acetylcholinesterase staining. The axons of motoneurons could be traced retrogradely by local application of HRP to the regenerated muscle fibres. The motor axons sometimes gave off collaterals reminiscent of Renshaw collaterals at about 300 microm from the axon hillock. Intracellular filling to motoneurons with HRP revealed that only a minority of the motoneurons within a culture had reached their appropriate target. Comparing the dendrograms of the motoneurons which had innervated muscles to those which had not suggested that motoneurons innervating muscle tissue had more complex dendritic trees and larger somata than those which did not innervate muscle tissue. Peripheral neurites of parvalbumin-immunoreactive DRG cells coiling around regenerated muscle fibres could be demonstrated in these cultures. These probably correspond to that part of the sensory muscle spindle apparatus which developed in vivo. However, only a few of the several hundred DRG cells found in every culture were parvalbumin-immunoreactive, suggesting that the actual number of Ia and II afferents within the population of DRG cells in culture is very small. This study demonstrates that all the neural elements necessary for the segmental spinal reflexes develop and can be maintained for several weeks in vitro.

Expression of the growth cone specific epitope CDA 1 and the synaptic vesicle protein SVP38 in the developing mammalian cerebral cortex

CDA 1 is a novel antigen that within the brain is present specifically in neuronal growth cones. Electron microscope immunohistochemistry and subcellular fractionation showed the CDA 1 epitope to be on a cytosolic molecule. In cultured neurons, it is abundant in growth cones and not detectable in neurites or cell bodies. The development of the rat cerebral cortex was investigated by using the monoclonal antibody to CDA 1 and an antibody to SVP38, the synaptic vesicle glycoprotein. CDA 1 immunoreactivity in the rat cerebral cortex peaks just before birth and disappears by postnatal day 12, a few days before the major increase in the number of mature synapses. In contrast, SVP38 is expressed in parallel with the appearance of mature synapses. CDA 1 and SVP38 thus are markers of growth cones and synapses, respectively. Their expression during development reflects some of the structural and functional changes that occur during synapse formation.

Primary dissociated cell culture of fetal rat central nervous tissue. I. Immunocytochemical and ultrastructural studies of cell development and synaptogenesis

We have tried to establish a method of primary dissociated cell culture of the central nervous system (CNS) for successful development of large numbers of synapses and myelinated axons. Cerebra from 18-day-old fetal rats were enzymatically dissociated into single cells and plated onto poly-D-lysine-precoated coverslips at high cell density. With the progress of cell maturation, mixed neuronal and non-neuronal cell processes grew heavily and piled up on each other, making three-dimensional structures which corresponded to 'neuropil' in vivo. Within these structures we could observe not only many mature neurons and remarkable synaptogenesis but also many myelinated axons. The synapses were mainly axo-dendritic but axo-somatic synapses were also occasionally observed. Although most of the axon terminals contained many round clear vesicles which were about 30 nm in diameter, some of them contained both round clear vesicles and 50 nm in diameter vesicles with electron-dense cores. Also a small number of large electron-dense core vesicles (about 130 nm in diameter) were found in the perikarya of mature neurons. The numerous synapse formations observed in 3-dimensional structures suggest that neurons can remain in a stable state and carry out an active metabolism through neurotransmitters. So these structures are considered to provide a favorable microenvironment for both synaptogenesis and myelinogenesis.

Electron microscopic study of cardiac ganglia in human fetuses

The early events in the development of the heart ganglia and nerves in human fetuses ranging from 5 to 12 weeks of gestation age were studied by transmission electron microscopy. The first neuroblasts in the atrial mesenchyme differ from surrounding cells in the presence of short cisternae of rough endoplasmic reticulum and in the absence of glycogen particles. The most valuable criterion for identification of neuroblasts is the presence of contacts with preganglionic nerve terminals. Only ganglia composed of compact aggregations of neuronal cells and nerve terminals have a complete glial sheath. The first signs of synapse formation were seen in 5-week-old fetuses; well developed synapses with many synaptic vesicles were found from the 8th week of gestation onwards. These were predominantly axodendritic synapses. It is proposed that synaptogenesis begins with the appearance of osmiophilic zones at the sites of interneuronal contacts, then synaptic vesicles move by axonal transport to reach the preformed specialized junctions and stop in axonal presynaptic varicosities.

First month of development of fetal neurons transplanted as a cell suspension into the adult CNS

It has been demonstrated elsewhere that fetal thalamic tissue, when transplanted as a cell suspension into the excitotoxically neuron-depleted adult somatosensory thalamus, can grow, differentiate, and receive projections from host afferents. In the present study, we used the same paradigm to analyse the transplanted neurons during their morphogenesis, i.e. during the first month after transplantation. Using various anatomical criteria, at the light and electron microscope levels, we compared the development of transplanted neurons with the normal ontogeny of homologous neuronal populations. Confined solely to the mechanically lesioned area during implantation at seven days post-grafting, the transplant increased in size to occupy most of the previously neuron-depleted area by the third week after grafting. The final size of the transplant thus depended upon the size of the lesion. At seven days post-grafting, the neurons were small in size and the cellular density was high. At this immature stage few synaptic contacts were visible and the ultrastructure was characterized by large extracellular spaces. At 10 days post-grafting, the size of the neurons had increased and the cellular density had decreased. Both an extensive dendritic proliferation and a simultaneous active synaptogenesis could also be observed. All these events continued to evolve and during the third week the neuropil progressively acquired more mature ultrastructural characteristics. Synaptic contacts exhibiting characteristics comparable to those observed in the intact thalamus also became more numerous. At 20 days post-grafting, axonal myelination had started, the development of the graft apparently stopped and the various criteria had stabilized. Until that developmental stage, growth of grafted neurons compared to that of normal thalamic ones. At later stages, however, grafted neurons failed to grow larger and did not reach the size of the homologous population in the adult animal. It seems, therefore, that transplants of thalamic fetal neurons can be used as a tool with which to study thalamic neuronal development, within definable limits.

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 distribution and movement of organelles in maturing growth cones: correlated video-enhanced and electron microscopic studies

The morphology of growth cones from identified neurons of Aplysia californica was analysed both with video-enhanced contrast differential-interference contrast (VEC-DIC) microscopy, and through serial electron microscopic reconstructions of the same growth cones. The largest structures seen in the living growth cones, the large irregular refractile bodies (LIRBs), were shown in electron micrographs to be unique structures, composed predominantly of dense-core vesicles but including mitochondria and smooth membrane profiles. The LIRBs were stratified in the growth cones, occurring predominantly in sections distant from the substrate and relatively devoid of microtubules. VEC-DIC observations showed that LIRBs formed in the peripheral regions of the organelle-rich central growth cone, and grew in size through fusion with other LIRBs, accumulating into a large central mass in more proximal regions. The distribution of microtubules and LIRBs and the movements of LIRB suggest that there is an overall circulatory pattern in the growth cones, with the delivery of new vesicles occurring at distal areas close to the substrate, and the accumulation and retrograde processing of organelles occurring in more proximal areas away from adhesive contacts.

Dendritic RNA and postsynaptic density formation in chick cerebellar synaptogenesis

In order to investigate the ribosomal origin of the postsynaptic densities during chick cerebellar maturation, a new procedure for synaptosomal preparation was implemented. Samples from embryonic chick cerebellar cortex, from 14 to 20 days of development and young adult chicks, were initially mechanically dissociated after treatment with 1.25% trypsin for 10 min; with this procedure we were able to obtain a dendritic suspension from which an enriched synaptosomal fraction was prepared in a discontinuous Ficoll sucrose gradient. RNA and protein values determined from the synaptosomal fractions showed the following variations: from 46.3 ng RNA/mg of wet weight at day 14 to 616.7 ng RNA/mg of wet weight at day 18; in young adult chicks, the average was 242 ng RNA/mg of wet weight. RNA/protein ratio varied from 78.9 micrograms RNA/mg protein at day 16 to 329.8 micrograms RNA/mg protein at day 18; in the young adult chick, this ratio decreased to 68.4 micrograms RNA/mg protein. The highest value of RNA was obtained at day 18 of chick embryo development coinciding with the maximum period of synaptic formation and consequently of the PSDs. These results seem to reinforce the hypothesis of the ribosomal origin of the PSDs.

Expression and assembly of the erythroid membrane-skeletal proteins ankyrin (goblin) and spectrin in the morphogenesis of chicken neurons

The membrane-skeleton of adult chicken neurons in the cerebellum and optic system is composed of polypeptides structurally and functionally related to the erythroid proteins spectrin and ankyrin, respectively. Neuronal spectrin comprises two distinct complexes that share a common alpha subunit (Mr 240,000) but which have structurally distinct polymorphic subunits (beta' beta spectrin; Mr 220/225,000; gamma spectrin, Mr 235,000); the brain-specific form (alpha gamma spectrin or fodrin) and an erythrocyte-specific form (alpha beta' beta spectrin). Two structurally related isoforms of ankyrin have also been identified and are termed alpha (Mr 260,000) and beta (Mr 237,000) ankyrin. Immunofluorescence demonstrates that the variants of spectrin and ankyrin, respectively, have different distributions within neurons. On the one hand, alpha gamma spectrin and beta ankyrin are present throughout the neuron, in the perikaryon, dendrites, and axon, whereas alpha beta' spectrin and alpha ankyrin are localized exclusively in the perikaryon and dendrites where they are actively segregated from alpha gamma spectrin and other components of axonal transport. This asymmetric distribution of spectrin and ankyrin isoforms is established in distinct stages during neuronal morphogenesis. Early in cerebellar and retinal development, alpha gamma spectrin is expressed in mitotic cells. Subsequently beta ankyrin and alpha gamma spectrin are coexpressed in postmitotic cells and gradually accumulate on the plasma membrane in a uniform pattern throughout the neuron during the phase of cell growth. At the onset of synaptogenesis and the cessation of cell growth, their levels of synthesis decline sharply while the assembled proteins remained as stable membrane components. Concomitantly, there is a dramatic induction in the accumulation of alpha ankyrin and alpha beta' spectrin, whose assembly is limited to the plasma membrane of the perikarya and dendrites. These results demonstrate that two successive, developmentally regulated programs of ankyrin and spectrin expression and patterning on the plasma membrane are involved in the assembly of the spectrin-based asymmetry in the neuronal membrane-skeleton, and that their asymmetric distribution is actively maintained throughout the life of the neuron.

Relationships between synaptic junctions, puncta adhaerentia and the spine apparatus at neocortical axo-spinous synapses. A serial section study

A total of 80 cotical axo-spinous synaptic junctions were reconstructed from serial sections and about 100,000 were analyzed in single sections. Special attention was paid to the occurrence of puncta adhaerentia associated with perforated, annulate or horseshoe-shaped (= complex) synaptic junctions and to the presence and proximity of the spine apparatus. Further evidence is presented that the spine apparatus has no relationship to simple (round or oval) synaptic specializations, but is present in association with at least 91% of complex junctions. The spine apparatus points towards the punctum adhaerens which in at least 71% of cases seems to be an integral part of the complex synapse. Direct continuity was found between the dense material of the spine apparatus and the punctum adhaerens. It is suggested, in accordance with other recent studies, that expansion of the synaptic active zone occurs by the addition and transformation of puncta adhaerentia. The spine apparatus may participate in this dynamic process as a possible donor of specific postsynaptic proteins.

The patterns of expression of two ankyrin isoforms demonstrate distinct steps in the assembly of the membrane skeleton in neuronal morphogenesis

We have identified in chicken neurons two membrane-bound isoforms of goblin (ankyrin), the specific membrane attachment protein for spectrin in avian erythrocytes, which exhibit distinct patterns of expression and assembly during neuronal morphogenesis. Early in cerebellar and retinal development, neither goblin isoform is detected in mitotic cells. Subsequently, beta-goblin (Mr 237,000) is expressed in postmitotic cells, and gradually accumulates with alpha gamma (brain) spectrin on the neuronal plasma membrane during the phase of cell growth. At the onset of synaptogenesis and the cessation of cell growth, their levels of synthesis decline sharply while the assembled proteins remain as stable membrane components. Concomitantly, there is a dramatic induction in the accumulation of alpha-goblin (erythroid goblin; Mr 260,000) and alpha beta (erythroid) spectrin, whose assembly is limited to the plasma membrane of perikarya and dendrites.

The effects of taxol on embryonic chick tectum maintained in culture: an electron microscope study

Tectal explants from chick embryos, established in culture for 2-3 weeks, were exposed to taxol-enriched media for 1-7 days, fixed, and studied by transmission electron microscopy. Taxol treatment resulted in no apparent disruption of the overall integrity of the organization of the explants nor in grossly increased cell death, but caused marked abnormalities of cytoskeletal elements. Intermediate filaments were increased in number in both neuronal and glial cells and very large numbers of microtubules were present, some aligned below the plasma membrane but most as components of large bundles in neuronal cell bodies and processes. Some such microtubules were associated with a network of intermicrotubule substance, consisting of 10-nm filaments running parallel to the microtubules, in hexagonal arrays surrounding individual microtubules, together with a very fine amorphous or filamentous component which was drawn into thread-like structures that linked the larger filaments to one another and formed the sides of the hexagons. Taxol treatment also resulted in the formation of concentric rings of microtubules separated by cylindrical sheets of electron-dense material. These observations extend previous descriptions of the effects of taxol on cytoskeletal elements, add to growing evidence for heterogeneity of microtubules within neurons, and suggest that taxol may be useful in studies of the functions of cytoskeletal elements and of microtubule heterogeneity in neurons.

Synaptic remodelling during development and maturation: junction differentiation and splitting as a mechanism for modifying connectivity

Morphological variation of the synaptic active zone during later development and maturation (15-224 days) has been studied in the molecular layer of the rat occipital cortex. Both E-PTA stained and osmicated tissue have been used. In the E-PTA stained material the degree of specialization of the presynaptic thickening is directly related to junction length. Junctions with well-developed dense projections (Types A and B) are longest and continue to increase in length with maturation, suggesting that active remodelling of the synaptic apposition is an ongoing process. The presence of perforated junctions, possessing two or more regions with specializations of different maturity and different curvature, raises the possibility that these junctions may arise by the addition and differentiation of new paramembranous material at an existing junction. In osmicated tissue, presynaptic terminals possessing multiple active zones have been quantitated. The maturational increase in number of simple perforated junctions (Type 1), is paralleled by a smaller increase in the number of multiple perforated junctions (Type 2). A spine apparatus is frequently observed in these perforated terminals, suggesting that it is intimately involved in the reorganization. The direction of curvature of the closely apposed junctions is predominantly negative (indenting the postsynaptic process). Other types of arrangement, with separate postsynaptic processes, are described (Types 3-5), and micrographs suggestive of sequential stages in pre- and postsynaptic terminal splitting are presented. The total length of the postsynaptic thickening of perforated terminals is twice the mean synaptic length of non-perforated terminals, again suggestive that duplication of the active zone may have occurred. Division of existing synaptic terminals by duplication and subsequent splitting would readily account for the increased dendritic spinal numbers seen in Golgi preparations of animals raised under enriched conditions. This would be a straight-forward mechanism by which reinforcement of neuronal connections could occur in response to use.

Cytodifferentiation and synaptogenesis in the neostriatum of fetal and neonatal rhesus monkeys

Cytodifferentiation and synaptogenesis in the neostriatum (caudate nucleus and putamen) were analyzed by the Golgi impregnation method and electron microscopy in 14 fetuses and 8 postnatal rhesus monkeys. During the second fetal month the neostriatum consists primarily of simple, mostly bipolar, immature cells and a small number of undefined profiles ending with growth cones. The first morphologically defined synapses appear in the putamen at embryonic day 60 ( E60 ) and in the head of the caudate nucleus at E65 . Synaptic density in both structures is less than one per 1000/micron2 of neuropil at this stage; synapses are characterized by asymmetric junctions between axonal profiles and immature dendritic shafts, accumulation of an intermembrane web and aggregation of round clear vesicles in presynaptic profiles. During the third fetal month neuronal cell bodies and glial cells enlarge, and axonal and dendritic processes in Golgi preparations become more complex. Although the basic morphology of synapses remains unchanged, their density increases to 9/1000 micron2 in the putamen and 3.7/1000 micron2 in the caudate. During the fourth fetal month the four principal cell classes of the neostriatum emerge. Spines on the shafts of dendrites are followed closely by the appearance of axospinous synapses. Synaptic density in the putamen is still significantly higher (10.1/1000 micron2) than in the caudate (5.4/1000 micron2), but by the end of the fifth fetal month ( E150 ) it is the same (80/1000 micron2) in both structures. A dramatic increase in synaptic density to 125/1000 micron2 occurs before term ( E165 ) with the emergence of the first asymmetric synapses as well as symmetric synapses with flat or pleomorphic vesicles that terminate predominately on dendritic shafts. Synaptic density continues to increase after birth, reaching a plateau of approximately 190/1000 micron2 at the end of the first postnatal month. Throughout postnatal development the proportions of symmetric and asymmetric synapses on the smooth dendritic shafts undergo systematic fluctuations which may reflect the ingrowth of various afferents as well as local cytological differentiation including the formation of cellular compartments.

Segregation of two spectrin forms in the chicken optic system: a mechanism for establishing restricted membrane-cytoskeletal domains in neurons

The chicken optic system contains a brain-specific form of spectrin (alpha gamma-spectrin or fodrin) as a major membrane-associated, axonally transported cytoskeletal protein. We show here that the chicken optic system also contains an erythrocyte-specific form of spectrin (alpha beta' beta-spectrin), which has a more restricted distribution; it is confined to the plasma membrane of dendrites and cell bodies of retinal ganglion cells, is absent from the optic nerve fibers, and is not axonally transported from the retina into the optic nerve. During development of the optic system, the expression of alpha gamma-spectrin is constitutive in all cell types. On the other hand, the accumulation of alpha beta' beta-spectrin is detected in only the ganglion cells, and at a time in development which coincides with the phase of synaptogenesis. These results indicate the existence of a developmentally regulated mechanism that topologically segregates the erythroid and brain forms of spectrin from each other, and the former from axonal transport, and suggest that erythroid spectrin may be involved in establishing restricted membrane-cytoskeletal domains in neurons during synaptogenesis, and maintaining them in the adult cell.

Ultrastructural studies on synaptic formations in dissociated fetal mouse brain cultures

Sequential electron microscopic studies of cultures of neurons derived from dissociated fetal mouse brain on the eleventh day of gestation revealed the formation of well-developed synapses during the second and third weeks of growth in vitro. Synaptic junctions were associated with synaptic vesicles nd dense synaptic membranes. Dense-core vesicles were also observed frequently in presynaptic terminals.

Axonal proteins of presynaptic neurons during synaptogenesis

Changes occur in the synthesis and axonal transport of neuronal proteins in dorsal-root ganglia axons as a result of contact with cells from the spinal cord during synapse formation. Dorsal-root ganglia cells were cultured in a compartmental cel culture system that allows separate access to neuronal cell bodies and their axons. When cells from the ventral spinal cord were cultured with the dorsal-root ganglia axons, synapses were established within a few days. Metabolic labeling and two-dimensional electrophoresis revealed that four of more than 300 axonal proteins had changed in their expression by the time synapses were established. The highly selective nature of these changes suggests that the proteins involved may be important in the processes of axon growth and synapse formation and their regulation by the regional environment.

Development of apparent presynaptic elements formed in response to polylysine coated surfaces

Formation of apparent presynaptic elements on polylysine-coated surfaces was examined with both scanning and transmission electron microscopy. Neurons from 2- or 8-day-old rat cerebellums were used in dissociated cell cultures as a source of growing neurites. An apparent presynaptic element is a defined swelling on a neurite with 40 nm diameter vesicles accumulated at the membrane which has a slight thickening. Apparent presynaptic elements do not have a normal postsynaptic element. In place of the postsynaptic element was the polylysine-coated surface of a large diameter Sepharose bead. The first apparent presynaptic elements were seen at 2 h of incubation, suggesting that morphologically identifiable synapses may form in this short a time. The number of apparent presynaptic elements on beads increased from 2 h to 24 h incubation and decreased from 5 to 9 days incubation. At all times non-neuronal cells grew up on to the beads and often covered both neurites and apparent presynaptic elements. In the longer incubations degenerating apparent presynaptic elements were seen engulfed by non-neuronal cells, suggesting that non-neuronal cells may have the ability to remove presynaptic elements that are not functioning. The number of synaptic vesicles per apparent presynaptic elements increased continuously between 2 h and 9 day incubation, eventually surpassing the number of synaptic vesicles seen in other presynaptic elements in cultures. This result suggests that an interaction between presynaptic and postsynaptic elements may be necessary to limit the number of synaptic vesicles found in presynaptic elements. Cultures grown for only 5 days in vitro (DIV) and incubated for 1 day with coated beads had the most apparent presynaptic elements, while those at 28 DIV and incubated for 1 day had the least. In the cultures at 5 DIV, neurons formed many apparent presynaptic elements, but these neurons could form only a very few normal synapses between themselves. Thus the beginning of the formation of synaptic contacts may depend on the availability of future postsynaptic elements and not on the lack of future presynaptic elements.

Morphology and position of growth cones in the developing Xenopus spinal cord

Axonal growth cones in longitudinal fiber tracts of the developing spinal cord of Xenopus were examined using electron microscopy. Fiber tracts of the spinal cord develop by the ingrowth of fibers, into pre-existing longitudinally oriented spaces between adjacent neuroepithelial cells of the neural tube. Growth cones seen among the neurites of the tracts were identified by their generally larger size (1.2 X 4.5 micrometer), bulbous and irregular outlines, and cytoplasmic components. Overall cytoplasmic density was usually less than that of surrounding neuroepithelial cells and axons. They contained few organelles, among them assorted clear and densecored vesicles, agranular reticulum, and occasional mitochondria and autographic vacuoles. Microtubules were rarely present. Growth cones appeared to conform in outline to the space which they occupied. Smaller extensions which resembled the filopodia described by others insinuated themselves among other elements of the fiber fascicles. The filopodia contained a fine granular or filamentous feltwork. Growth cones consistently appeared at the interface of other axons in the fascicle and the peripheral neuroepithelial endfeet. In longitudinal sections of fascicles containing more than one growth cone, the growth cones were layered in a pattern suggesting that new cones are added by pushing between the next youngest fibers and the peripheral neuroepithelial processes of the cord. The possible significance of this finding in the achievement of order in the spinal tracts is discussed.

The organization of the lateral posterior nucleus in neonatal golden hamsters

The present series of experiments was designeneonatal golden hamsters.

Detection and localization of 14-3-2 protein in primary cultures of embryonic rat brain

The development of embryonic rat brain in cell cultures was studied by an immunocytochemical method based on the detection of 14-3-2 protein (neuron-specific enolase or NSE), a neuron-specific protein. This protein was already present in undifferentiated neurons (less than 5 days in culture), being dispersed throughout the cytoplasm, though seemingly concentrated in the vicinity of polyribosomal structures. It was not found in nuclei, in mitochondria or in the Golgi apparatus. During neuron differentiation, the location of 14-3-2 protein was related to neurite development insofar as it was detected along the axon and even in what could be taken to be the presynaptic region of numerous interneuron contacts. In contact areas, a thickening of the junction membrane was observed but the presence of 14-3-2 protein was always unilateral demonstrating the absence of a true synapse and reflecting the halt in neurite development observed after 15 days in culture. The presence of 14-3-2 protein in the cell cultures was confirmed by a microcomplement fixation assay. The protein detected in cell cultures had the same immunological properties as that found in the 17-day-old embryo, but was slightly different from that found in adult rat brain. This observation can be confronted with the lack of neuron maturation in the immunocytochemical studies.

Quantitation of terminal parameters and their inter-relationships in maturing central synapses: a perspective for experimental studies

The development and maturation of synapses in the molecular layer of the occipital cortex of rats at 15, 20, 28, 75 and 224 days postnatal were examined and quantitative ultrastructural techniques were employed. The parameters evaluated display a diverse set of trends. A steady increase in mean terminal area is noted, the proportions of the smallest terminals declining progressively over this period. The mean length of the postsynaptic thickening fluctuates throughout the developmental series. A close association is found between terminal area and junction lengthlarger junction lengths being consistently associated with larger areas. Synaptic vesicle numbers within each terminal increase markedly between 15 and 28 days. There is an increase in the frequency of flat and positively curved junctions with increasing age, the bimodal distribution of negative and positive curvatures at 15 days being replaced by a normal distribution in the adult. When synaptic length is compared with curvature, flat junctions emerge as the longest and the most highly curved junctions as the shortest. The terminal areas of positive junctions are greater than those of negative ones. The consequences of these results for the flat disc model of synapses are discussed, and it is postulated that negatively curved synaptic junctions may be non-functional.

The time course of synapse formation of mouse neuroblastoma cells in monolayer cultures

Neuroblastoma cells grown on substrates in culture develop long processes and assume the morphology of normal neurons as judged light microscopically. The development of synapses in the cultured tissue is studied by periodic electron microscopic examination of the areas of contact between cells. The initial explants are free of any apparent synaptic contacts. After 48 h in culture, simple swellings or boutons are detected at the periphery of the cells or at the end of the fine processes. These initial synaptic profiles contain a few vesicles but lack mitochondria. The synaptic vesicles appear to originate from the smooth endoplasmic reticulum. Further explants remain primitive, only the number of vesicles in the cytoplasmic swellings or boutons increases. These clusters of vesicles are 40-60 nm in diameter and morphologically distinguishable from the synaptic vesicles of normal neurons. There are no postsynaptic folds or membrane thickenings. Specialized cell contacts between cells are also present.

Isolation of ribosome containing synaptosome subpopulation with active in vitro protein synthesis

Subpopulations of synaptosomes harvested from neonatal rat brain cortices revealed a differential ability to synthesize protein in vitro. Incubation of synaptosomes with radiolabeled leucine, followed by continuous sucrose gradient centrifugation produced an asymmetric shift in the radioactivity toward the higher density sucrose fractions. The bulk of the mitochondrial cytochrome c-oxidase activity was also found in these fractions, however, subfractionation studies of osmotically-lysed synaptosomes suggested that the newly-synthesized proteins reside in an osmotically sensitive, non-mitochondrial compartment. The ability of each subpopulation of synaptosomes to synthesize protein in vitro was assessed after their isolation from linear continuous sucrose gradients. There was an enrichment of highly active protein synthesizing particles in the "heavy" subpopulations of neonatal synaptosomes. The inhibitory effects of chloramphenicol and cycloheximide on the protein synthesis in these particles were similar to those of the original synaptosome fraction. Electron microscopic analysis revealed an increase in the numbers of ribosome-containing structures resembling dendritic and axonal growth cones.

Synaptogenesis in the cervical cord of the human embryo: sequence of synapse formation in a spinal reflex pathway

Synaptogenesis in the cervical cord was studied by light and electron microscopy in human embryos ranging from four to seven weeks of ovulation age. The stage of embryonic development was estimated on the basis of external morphology of embryos and histology of the eye ball with reference to Streeter's horizon. No synapses were found in the cervical cord of the embryo at Streeter's horizon XIV (8 mm; estimated ovulation age, 28-30 days). A small number of axodendritic synapses appear in the motor neuropil of the cervical cord at Streeter's horizon XVII (14 mm; estimated ovulation age, 34-36 days). Since no primary afferents are demonstrated to reach the motor neuropil at this stage (the premotile period), these synapses are considered to be formed between interneurons and motor neurons. On the other hand, the formation of synapses outside the motor neuropil of the cervical cord was recognized at Streeter's horizon XX (22 mm; estimated ovulation age, 40-42 days), which corresponded to the period of onset of the precocious reflex, but not by horizon XIX (18 mm; estimated ovulation age, 38-40 days). The first axosomatic synapses were found in the motor neuropil at Streeter's horizon XVII (estimated ovulation age, 34-36 days). The present study suggests that the formation of synapses between interneurons and dendrites of spinal motor neurons precedes that of synapses between interneurons and collaterals of primary afferents. This sequence of synaptogenesis is in agreement with that reported in earlier studies with silver stain methods.

Development of type I cells of the rabbit subclavian glomera (aortic bodies): a light, fluorescence and electron microscopic study

The embryogenesis of the subclavian glomera (aortic bodies) is controversial. Past investigators have attributed the development of the Type I cells to mesodermal and/or neural elements. Based on the results of the present light microscopic, fluorescence histochemical and electron microscopic study of rabbit aortic bodies from 16 days of gestation (term:31 days) to four days postpartum, it appears that the Type I glomus cell are derived from cells of neural crest origin. The subclavian anlage is associated with cells of neural crest origin. The subclavian glomus anlage is associated with cells of vagal origin throughout its development. Evidence of Type I cell development from pre-existing mesodermal condensations is not observed. Type I cells exhibit formaldehyde-induced-fluorescence by the twentieth day of gestation. Dense-cored cytoplasmic vesicles are apparent by the sixteenth day of gestation. The number of cytoplasmic vesicles increases steadily, but the greatest increase of vesicles is observed between the twenty-eighth day of gestation and birth. Primitive Type I glomus cells exhibit abundant polysomes and rough endoplasmic reticulum indicative of synthetic activity. Nerve terminals are apparent adjacent to Type I cells by the twentieth day of gestation, but synaptogenesis does not occur until sometime between the twenty-fourth and twenty-eighth days of gestation. Abundant vascularity, characteristic of chemosensory glomera, is not achieved until the twenty-eighth day of gestation.

Synaptogenesis in the basilar papilla of the chick

Synaptogenesis was studied in the basilar papilla of chicken embryos from days 7--21 of incubation. On the 9th day of incubation differentiating hair cells first appeared and a few growing nerve tips made contact with them, although no membrane specializations were apparent at this stage. Synaptic bodies associated with presynaptic membrane specializations were first observed on the 10th day. They lay opposite either supporting cells or afferent nerve processes; in the latter site slight membrane thickenings were occasionally found. During subsequent stages synaptic bodies and the surrounding vesicles increased in number. Synaptic bodies associated with presynaptic membrane specializations, but devoid of contact with afferent nerve endings, were often observed on the 14th day, whereas almost all the synaptic bodies associated with presynaptic specializations were in contact with afferent nerve processes by the 21st day. The efferent synapses were first recognized on the 14th day. These results suggest that in the hair cells of chicken basilar papilla the synaptic bodies and presynaptic membrane specializations appear first and after the synaptic sites are determined by the position of the synaptic bodies, the growing nerve tips seek out and establish synaptic contact at the pre-existing synaptic sites.

Synapse development within the spinal trigeminal nucleus

Pars interpolaris of the spinal trigeminal nucleus of kittens has been studied with the electron microscope at birth and at several subsequent ages during the first month of life. Attention has been given to ultrastructural maturational changes that occur in this neuropil, especially events in synaptogenesis. The results of this investigation include the following observations: (1) the neuropil, even at the earliest ages studied (three-hour-old kittens), is strikingly mature, necessitating a quantitative assessment in order to determine subtle developmental changes in synaptic patterns; (2) the number of axoaxonic contacts at birth are few, and their emergence is essentially a postnatal phenomenon; (3) it appears that the immature Gray type II or symmetrical synapse possesses distinct cleft material and dense, parallel membrane specializations. Synaptic vesicle accumulation at this contact appears to occur after the membrane specializations have formed. A previous study by Kerr26 has shown a reduced potential for primary afferent reorganization with the spinal trigeminal nucleus when kittens are subjected to trigeminal rhizotomy after three days of age. Our observations on the development of axoaxonic synaptic arrangements in the neonatal period may provide an explanation for these earlier results.