Growing tips of embryonic cerebellar axons in vivo

Mechanisms of Axon Elongation Following CNS Injury: What Is Happening at the Axon Tip?

After an injury to the central nervous system (CNS), functional recovery is limited by the inability of severed axons to regenerate and form functional connections with appropriate target neurons beyond the injury. Despite tremendous advances in our understanding of the mechanisms of axon growth, and of the inhibitory factors in the injured CNS that prevent it, disappointingly little progress has been made in restoring function to human patients with CNS injuries, such as spinal cord injury (SCI), through regenerative therapies. Clearly, the large number of overlapping neuron-intrinsic and -extrinsic growth-inhibitory factors attenuates the benefit of neutralizing any one target. More daunting is the distances human axons would have to regenerate to reach some threshold number of target neurons, e.g., those that occupy one complete spinal segment, compared to the distances required in most experimental models, such as mice and rats. However, the difficulties inherent in studying mechanisms of axon regeneration in the mature CNS in vivo have caused researchers to rely heavily on extrapolation from studies of axon regeneration in peripheral nerve, or of growth cone-mediated axon development in vitro and in vivo. Unfortunately, evidence from several animal models, including the transected lamprey spinal cord, has suggested important differences between regeneration of mature CNS axons and growth of axons in peripheral nerve, or during embryonic development. Specifically, long-distance regeneration of severed axons may not involve the actin-myosin molecular motors that guide embryonic growth cones in developing axons. Rather, non-growth cone-mediated axon elongation may be required to propel injured axons in the mature CNS. If so, it may be necessary to use other experimental models to promote regeneration that is sufficient to contact a critical number of target neurons distal to a CNS lesion. This review examines the cytoskeletal underpinnings of axon growth, focusing on the elongating axon tip, to gain insights into how CNS axons respond to injury, and how this might affect the development of regenerative therapies for SCI and other CNS injuries.

Components of Endocannabinoid Signaling System Are Expressed in the Perinatal Mouse Cerebellum and Required for Its Normal Development

Endocannabinoid (eCB) signaling system (ECS), encompassing cannabinoid receptors and enzymes involved in the synthesis and degradation of the endogenous cannabinoid signaling lipids, is highly expressed in the cerebellar cortex of adult humans and rodents. In addition to their well-established role in neuromodulation, eCBs have been shown to play key roles in aspects of neurodevelopment in the fore- and mid-brain, including neurogenesis, cell migration, and synapse specification. However, little is known about the role of ECS in cerebellar development. In this study, we conducted immunohistochemical characterization of ECS components through key stages of cerebellar development in mice using antibodies for 2-arachidonoylglycerol (2-AG) synthetizing and degrading enzymes and the major brain cannabinoid receptor, cannabinoid receptor 1 (CB1), in combination with cerebellar cell markers. Our results reveal a temporally, spatially, and cytologically dynamic pattern of expression. Production, receptor binding, and degradation of eCBs are tightly controlled, thus localization of eCB receptors and the complementary cannabinoid signaling machinery determines the direction, duration, and ultimately the outcome of eCB signaling. To gain insights into the role of eCB signaling in cerebellar development, we characterized gross anatomy of cerebellar midvermis in CB1 knock-out (CB1 KO) mice, as well as their performance in cerebellar-influenced motor tasks. Our results show persistent and selective anatomic and behavioral alterations in CB1 KOs. Consequently, the insights gained from this study lay down the foundation for investigating specific cellular and molecular mechanisms regulated by eCB signaling during cerebellar development.

Cellular Mechanisms Involved in Cerebellar Microzonation

In the last 50 years, our vision of the cerebellum has vastly evolved starting with Voogd's (1967) description of extracerebellar projections' terminations and how the projection maps transformed the presumptive homogeneity of the cerebellar cortex into a more complex center subdivided into transverse and longitudinal distinct functional zones. The picture became still more complex with Richard Hawkes and colleagues' (Gravel et al., 1987) discovery of the biochemical heterogeneity of Purkinje cells (PCs), by screening their molecular identities with monoclonal antibodies. Antigens were expressed in a parasagittal pattern with subsets of PCs either possessing or lacking the respective antigens, which divided the cerebellar cortex into precise longitudinal compartments that are congruent with the projection maps. The correlation of these two maps in adult cerebellum shows a perfect matching of developmental mechanisms. This review discusses a series of arguments in favor of the essential role played by PCs in organizing the microzonation of the cerebellum during development (the "matching" hypothesis).

Specific labeling of climbing fibers shows early synaptic interactions with immature Purkinje cells in the prenatal cerebellum

During development, growing axons must locate target cells to form synapses. This is not easy, since target cells are also growing and even actively migrating. In some brain regions, such axons have been reported to wait for the timing when target cells become mature, without invading their target region. However, in the cerebellum climbing fibers (CFs), major afferent axons, arrive near their target neurons, Purkinje cells, when the neurons are still actively migrating. We, therefore, examined whether synaptic contacts are established at such early stages. To specifically label CFs, we introduced by in utero electroporation a mixture of genes encoding for Ptf1a-enhancer-driven Cre recombinase and Cre-dependent fluorescent protein into the mouse hindbrain at embryonic day (E) 10.5 and observed them during development. The earliest stages at which labeled CFs were observed in the cerebellar primordium were E15.5-E16.5. These fibers were fasciculated in the dorsal region and entered the cerebellar primordium. Some fibers defasciculated and reached the caudal region. At E17.5 and E18.5, fasciculated fibers were also found in the mantle region, and some grew toward the surface of the primordium to penetrate a mass of Purkinje cells. Interestingly, as early as E16.5, labeled fibers were found to run in close apposition to Purkinje cell dendrites and to express a presynaptic marker. These observations suggest that CFs form synapses with Purkinje cells as soon as the fibers enter the cerebellum.

Developmental regulation of sensory axon regeneration in the absence of growth cones

The actin filament (F-actin) cytoskeleton is thought to be required for normal axon extension during embryonic development. Whether this is true of axon regeneration in the mature nervous system is not known, but a progressive simplification of growth cones during development has been described and where specifically investigated, mature spinal cord axons appear to regenerate without growth cones. We have studied the cytoskeletal mechanisms of axon regeneration in developmentally early and late chicken sensory neurons, at embryonic day (E) 7 and 14 respectively. Depletion of F-actin blocked the regeneration of E7 but not E14 sensory axons in vitro. The differential sensitivity of axon regeneration to the loss of F-actin and growth cones correlated with endogenous levels of F-actin and growth cone morphology. The growth cones of E7 axons contained more F-actin and were more elaborate than those of E14 axons. The ability of E14 axons to regenerate in the absence of F-actin and growth cones was dependent on microtubule tip polymerization. Importantly, while the regeneration of E7 axons was strictly dependent on F-actin, regeneration of E14 axons was more dependent on microtubule tip polymerization. Furthermore, E14 axons exhibited altered microtubule polymerization relative to E7, as determined by imaging of microtubule tip polymerization in living neurons. These data indicate that the mechanism of axon regeneration undergoes a developmental switch between E7 and E14 from strict dependence on F-actin to a greater dependence on microtubule polymerization. Collectively, these experiments indicate that microtubule polymerization may be a therapeutic target for promoting regeneration of mature neurons.

Regulation of pontine neurite morphology by target-derived signals

The molecular cues that regulate neurite morphology within the target environment are key to the formation of complex neural circuitry. During development of the ponto-cerebellar projection, pontine fibers sprout and form elaborate arbors within the inner cerebellar layer prior to arrival of their target cells, the cerebellar granule neurons. Here, we describe the biochemical fractionation of two granule neuron-derived factors that stimulate elaboration of pontine neurites. These factors were identified using a dissociated pontine bioassay and biochemically fractionated from granule cell (GC) conditioned medium (GCCM). One of the factors, STIM1, is a protein with a molecular weight greater than 30 kDa that is distinct from known neurotrophins. The other, STIM2, is a small, protease-resistant molecule with an estimated molecular weight below 1 kDa. We show that these factors stimulate pontine neurite elongation both independently and cooperatively and thus may contribute to the formation of elaborate pontine arbors within the cerebellar cortex.

Morphology of developing olfactory axons in the olfactory bulb of the rabbit (Oryctolagus cuniculus): a Golgi study

Transient expression of axon collaterals plays an important role in enabling neurons to find appropriate targets during development. In the olfactory bulb, the numbers of both sensory neurons and their targets, the glomeruli, increase markedly during the postnatal period. In the present study, the morphology of developing olfactory axons in the olfactory bulb of 1-21-day-old rabbits was analyzed using stereological methods and the rapid Golgi technique. The findings demonstrated a change in axon morphology from the olfactory nerve layer to the glomeruli suggestive of a sequence in axon development. In the olfactory nerve layer, axons typically had knob-like growth cones and a few collateral branches. Close to glomeruli, axons increased in thickness, formed rather complex and irregular growth cones, and typically gave off many collaterals. Within glomeruli, the axons formed terminal branches and boutons. Extraglomerular branches were apparently removed once axons had entered a glomerulus, insofar as these branches often displayed morphological signs of degeneration. In contrast, collateral branches ending in the same glomerulus remained, indicating that formation of collaterals may assist olfactory axons in locating glomerular targets.

Axon guidance of outgrowing corticospinal fibres in the rat

This review is concerned with the development of the rat corticospinal tract (CST). The CST is a long descending central pathway, restricted to mammals, which is involved both in motor and sensory control. The rat CST is a very useful model in experimental research on the development of fibre systems in mammals because of its postnatal outgrowth throughout the spinal cord as well as its experimental accessibility. Hence mechanisms underlying axon outgrowth and subsequent target cell finding can be studied relatively easily. In this respect the corticospinal tract forms an important example and model system for the better understanding of central nervous system development in general.

Dynamic behavior of the ends of growing parallel fibers in early postnatal rat cerebellum

The molecular layer of the cerebellum contains parallel fibers, the axons of granule neurons. We have examined the morphology and behavior of parallel fiber growth cones in the early postnatal rat cerebellum using the fluorescent tracer DiI. Parallel fiber growth cones distributed into three categories based on size and shape: short torpedo-like, long torpedo-like, and lamellopodial in form. The torpedo-like growth cones were modified by the addition of lamellopodia and/or filopodia, and the lamellopodial growth cones were often decorated with a filopodium. These three different growth cone morphologies were found throughout the growing region of the molecular layer. The nascent axons elaborated by premigratory granule neurons differed form the longer axons of more developed neurons in that they often had forked growth cones and extensive lamellopodial decoration along the axon shaft. Growth cones in living slices closely resembled those observed in the fixed preparations. The living growth cones exhibited frequent lamellopodial rearrangement and a side-to-side headwaving movement. The axon proximal to the growth cone was also dynamic. The axons curved and undulated, and mobile swellings formed along the axon shaft. These observations show that the growth cones of parallel fibers are similar to growth cones described for axons in other developing systems in terms of size, morphological characteristics, and dynamic behavior.

Transient synaptic redundancy in the developing cerebellum and isostatic random stacking of hard spheres

We propose an automaton for the simulation of the distribution of the number of climbing fibers (CF) making synapses on each Purkinje cell (PC) at the maximum of the synaptic redundancy that exists transiently in the newborn cerebellum. This automaton is based on the hypothesis that the synaptic maximum is limited by topological constraints and can be described by an isostatic random stacking of hard spheres. There is convincing agreement between the simulated distribution of the number of CF axons per Purkinje cell and the distribution experimentally obtained by electrophysiological techniques.

Distribution of corticotropin-releasing factor and calcitonin gene-related peptide in the developing mouse cerebellum

Corticotropin-releasing factor (CRF)-like immunoreactive (IR) fibers were investigated ontogenically in the mouse cerebellum. CRF-IR was detected in the climbing fiber and mossy fibers as in other species. In addition, CRF-IR dense fiber plexuses were detected from postnatal day (PD) 2 to 9, in the developing Purkinje cell layer of the vermal lobules, paraflocculus, flocculus and crus 1 ansiform lobule, gradually forming a pericellular nest around the Purkinje cell somata. Immunoelectron-microscopical analysis showed that dense fibers made synaptic contacts with the Purkinje cell somata on PD 7. In the lobules mentioned above, CRF-IR dense fibers showed parasagittal banded patterns. Calcitonin gene-related peptide (CGRP)-IR showed similar fiber bands at these stages. Interestingly, these two patterns of peptidergic fiber bands were complementary in distribution. From around PD 9, CRF-IR fibers lost the immunoreactive dots in the Purkinje cell layer. Immunoreactivity at this stage was observed in the axons projecting to the molecular layer, and thin CRF-IR fibers began to appear in the neighboring area. Numerous typical climbing fiber-like CRF-IR fibers were found throughout the cerebellar cortex from PD 16 to adult. The inferior olivary complex (the origin of climbing fibers) appears to be the origin of these dense fiber plexuses as CRF-IR cells were already present from PD 2 in the dorsal cap nucleus, beta subnucleus and caudomedial part of the accessory olivary nucleus. No neurons containing both CRF and CGRP immunoreactivities were observed. These results suggest that CGRP- and CRF-IR developing climbing fibers innervate different compartments of Purkinje cells, especially in the vestibular cerebellar cortex in mice. Furthermore, CRF-IR fibers gradually changed to become typical climbing fibers, while CGRP-IR disappeared altogether.

Corticospinal axons and mechanism of target innervation in rat lumbar spinal cord

The aim of the present study is to investigate the mechanism by which outgrowing rat corticospinal (CS) axons innervate their spinal gray target areas. This study was carried out with the use of anterogradely transported horseradish peroxidase or 1,1-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) after application in the sensorimotor cortex of rat pups varying in age between 5 days postnatal (P5) and 10 days postnatal (P10). The CS axons of neurons situated in the sensorimotor cortex have reached the ventral most parts of the dorsal funiculus at mid-lumbar spinal cord levels at the fifth postnatal day (P5). After a waiting period of 2 days some CS fibers change their direction and directly enter the adjacent spinal gray target areas. One day later, i.e., P8, CS target innervation by the formation of collateral branches can be observed. Finally, the development of collaterals by interstitial budding from their parent axons appears to be the major, but not the exclusive, mechanism by which CS axons innervate the lumbar spinal gray matter target area.

Development of corticotectal synaptic terminals in the cat: a quantitative electron microscopic analysis

We studied the development of corticotectal synaptic terminal boutons and synapses by making injections of wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP) into area 17 of visual cortex in kittens ranging from newborn to 12 weeks of age and in adults. The location and extent of the injection site, and labeled corticotectal axon terminals in the superficial layers of the superior colliculus were demonstrated histochemically with the cobalt-glucose oxidase diaminobenzidine reaction. During the first 2 weeks after birth, the majority of labeled profiles resembled axonal growth cones, or structures intermediate in morphology between growth cones and synaptic terminals, while very few corticotectal axon terminals forming well-defined synaptic contacts were observed. Labeled synaptic terminals in kittens at 1 and 2 weeks of age were small, contained very few synaptic vesicles, which were usually restricted to the contact zone, and exhibited few mitochondria. By 4 and 6 weeks after birth, a well-developed population of synaptic terminals was established; however, growth cones and intermediate profiles were still numerous. At 8 weeks of age synaptic terminals were morphologically mature, and growth cone-like profiles were no longer observed. To study quantitative changes in synapse development we used the disector method to obtain unbiased estimates of the density and number of corticotectal synaptic terminals and synapses; both the density and number of terminals and synapses increased steadily throughout postnatal development. These results suggest that the corticotectal projection develops by the progressive elaboration of synapses, as opposed to synapse overproduction and subsequent elimination.

Evidence of early topographic organization in the embryonic olivocerebellar projection: a model system for the study of pattern formation processes in the central nervous system

Many projection systems within the peripheral and central nervous system are topographically organized, and it has become increasingly clear that interactions which occur during development determine the projection patterns these systems exhibit in the adult. The olivocerebellar system was chosen as a model system for this study of afferent pattern formation because it has several characteristics which lend themselves to a study of this type. Applications of horseradish peroxidase were made to both the cerebellar primordium and to the inferior olive of embryonic and neonatal mice using an in vitro perfusion system to support the tissue during the transport period. Fibers labeled after restricted olivary applications are limited to particular mediolateral regions of the cerebellum. Similarly, olivary cells retrogradely labeled after discrete cerebellar applications are restricted to particular olivary subdivisions. The results indicate that the olivocerebellar projection displays elements of topographic organization as early as E15 and that the pattern displayed is roughly comparable to that of the adult mammal. The observed trajectories of olivocerebellar fibers and their concomitant association with both Purkinje and cerebellar nuclear cells during embryonic development suggests a role for either or both cell types in the pattern formation process.

The innervation of calcitonin gene-related peptide to the Purkinje cells and granule cells in the developing mouse cerebellum

The present study analyzed the ontogeny of calcitonin gene-related peptide-like immunoreactive (CGRP-IR) structures in the mouse cerebellum. No CGRP-IR neurons were detected at any stage, but three types of CGRP-IR fibers were seen: (1) CGRP-IR dense fiber plexuses which appeared transiently in the developing cerebellum, (2) thin varicose fibers, and (3) mossy fiber-like fibers. The CGRP-IR dense fiber plexuses appeared in the developing Purkinje cell layer at postnatal day 2. From postnatal days 6 to 11, these fibers formed pericellular nests around Purkinje cells. After that stage, these fibers rapidly disappeared and no such plexuses were seen in the adult cerebellum. CGRP-IR fiber plexuses were not evenly distributed, and they had a parasagittal banded pattern in the frontal sections. These plexuses existed in the region of all vermis, crus 1 of the ansiform lobe, simplex lobule, and flocculus, while the other lobules were devoid of such fibers. Under electron microscopy, these CGRP-IR fibers were seen to make synaptic contacts with somatic spines of Purkinje cells, suggesting that CGRP-IR plexuses were closely related to the developing Purkinje cells. Mossy fiber-like CGRP-IR fibers appeared in the granular layer on postnatal day 2, and increased in number to reach a peak on postnatal day 12. Thereafter, they decreased slightly to reach a plateau on postnatal day 30. Under electron microscopy these CGRP-IR fibers were revealed to be the mossy fibers which regulated the granule cells. Thin varicose CGRP-IR fibers were rarely seen at birth, but on postnatal day 8, many fibers appeared in all layers and increased by postnatal day 30. They distributed equally throughout the cerebellar cortex with a slight predominance in density in the molecular and Purkinje cell layer. Immunoelectron microscopic analysis showed that these fibers made synaptic contacts with small dendrites in the molecular layer.

Multimorphic growth cones in the embryonic medicinal leech: relationship between shape changes and outgrowth transitions

Comparative studies of growth cone morphology may provide insight into the mechanisms underlying motility and navigation in vivo. Here we analyzed the morphology of a unique set of growth cones in the embryonic medicinal leech, Hirudo medicinalis. The comb or C-cell is a transient cell found as a bilateral pair in each midbody segment. Early in development, from embryonic day (E)7 to E11, each C-cell adds and orients about 70 parallel growth cones that remain relatively nonmotile until E12 when rapid process outgrowth is initiated. Individual C-cells from E10 to E14 were injected with Lucifer yellow and growth cones were traced with a camera lucida. Growth cone morphology was quantified from the drawings. Lamellar regions increased in area with age and change in extension rate. Young, relatively nonmotile growth cones had numerous short filopodia in many orientations, while at highly motile stages filopodial number decreased, length increased, and orientation became more restricted in the direction of outgrowth. Thus, while filopodia were distributed symmetrically, such that the average filopodial angle was predictive of the direction of outgrowth at all stages, younger (relatively nonmotile) growth cones project more filopodia in many directions than do older more motile growth cones. These results suggest that: (1) alterations in morphology may reflect developmentally regulated changes in extension and the local environment, (2) these growth cones maintain a large area for environmental sampling as they increase extension rate, even as filopodia become more restricted in orientation, and (3) C-cell growth cones might progressively alter their affinity for local cellular cues as they initiate rapid and directed outgrowth. The C-cell of embryonic leech may provide a relatively simple system in which to test these ideas experimentally.

Transient retinal axon collaterals to visual and somatosensory thalamus in neonatal hamsters

We have studied the postnatal development of individual axons in the optic tract and thalamus of the Syrian hamster, concentrating attention on retinal ganglion cell axons that make a transient projection to the main somatosensory nucleus, the ventrobasal complex. We bulk-filled axons with horseradish peroxidase in hemithalami maintained en bloc, in vitro. After processing and reaction with diaminobenzidine, we reconstructed individual axons from serial sections. In hamsters and other rodents, the optic tract is composed of superficial and internal components, either or both being possible sources of the retino-ventrobasal projection. Both project to the midbrain, but in normal adults only the superficial optic tract maintains collaterals in the thalamus. We found that the axons of the internal component bear numerous transient thalamic collaterals on postnatal days 0, 1, and 2, and some of these extend into the ventrobasal complex. Axons in the superficial optic tract also bear collaterals on days 0 to 2, but these are confined to the superficial half of the dorsal lateral geniculate nucleus. Thus the transient retino-ventrobasal projection comprises solely transient collaterals originating from axon trunks in the internal optic tract. On days 1 and 2, some collaterals from the superficial optic tract appear to have begun to arborize in the lateral geniculate nucleus. In contrast, collaterals from internal optic tract axons to the ventrobasal complex branch little if at all as they traverse the lateral geniculate nucleus, and at no time prior to their elimination do they develop an appreciable terminal arbor. These long collaterals often terminate in growth cones that include lamellopodia. Our HRP-impregnation method also revealed some transient non-retinofugal axons that pass medially from the ventral lateral geniculate nucleus to the ventrobasal complex but then return without terminating or branching. By day 4, they are absent, as are collaterals from the internal optic tract to the ventrobasal complex.

Regenerating axons from adult chick retinal ganglion cells recognize topographic cues from embryonic central targets

We investigated whether regenerating mature axons recapitulate embryonic features essential to successful reconnectivity within the injured nervous system. Strips from embryonic and adult chick retinae were cultured, and outgrowing axons were examined morphometrically and immunohistochemically. In addition, the target-recognition properties of adult neurites were analyzed. Regenerating adult axons elongate on a poly-L-lysine/laminin substratum with a speed about one order of magnitude slower than that of embryonic axons. Morphologically, adult axonal tips differ dramatically from embryonic growth cones in that they possess only filopodial extensions whereas embryonic growth cones possess both lamellipodial and filopodial processes. Both embryonic and adult neurites express the growth-associated protein GAP-43. When cultured on alternating stripes of anterior and posterior embryonic tectal membranes, both adult and embryonic retinal axons distinguish between the two membrane preparations. Our results demonstrate that during axonal regeneration the mature neurons express embryonic properties that are involved in the recognition of tectal positional cues.

Light and electron microscopical visualization of anterogradely labelled corticospinal growth cones using a new combination of HRP staining techniques

Up until now, the ultrastructural visualization of growth cones of developing long fibre tracts could only be achieved by horseradish peroxidase (HRP) application 'en route', resulting in axonal damage, which in turn may affect growth cone morphology. Besides, this technique results in labelling of passing fibres, thus hampering the identification of axon origin as well as the interpretation of growth cone configuration. In the present investigation a new combination of HRP staining and intensification techniques is presented which makes it possible to visualize anterogradely labelled corticospinal growth cones over long distances in developing rat spinal cord at the light as well as the electron microscopical level. HRP was applied to the originating cells of the corticospinal tract, located in the sensorimotor cortex, and after 24 h was visualized using a procedure which essentially consists of 3 subsequent steps: first a tetramethylbenzidine (TMB)/ammoniumheptamolybdate (AHM) reaction; second diaminobenzidine (DAB)/nickel (Ni) stabilization and finally glucose oxidase intensification. As was verified at the EM level, the staining procedure here described reveals a complete intense black staining of HRP-labelled growth cones of outgrowing corticospinal axons. Therefore, the method described here guarantees a correct analysis of growth cone morphology at the light microscopical and the ultrastructural level. The present procedure is especially valuable in studying the development of long central nervous fibre systems.

Transitional elements with characteristics of both growth cones and presynaptic terminals observed in cell cultures of cerebellar neurons

As growth cones interact with targets, they become presynaptic terminals by losing growth cone characteristics and acquiring presynaptic characteristics. Results presented here show that transitional elements can be identified in cell cultures of rat cerebellum, which have some characteristics of both growth cones and presynaptic terminals. During the first week in culture, slender growth cones have fine filopodia. Subsequently, many growth cones in contact with the polylysine substrate spontaneously enlarge and become non-motile. In transitional elements, the synaptic vesicle protein p65 extends into the peripheral domain and in some cases, extends into filopodia. Many of these transitional elements have active filopodia but show no movement over the substrate for periods of up to nine days. These transitional elements have lost the actin-rich peripheral domain of the growth cone but retain actin labelling in the filopodia. With electron microscopy, transitional elements were seen to contain accumulations of synaptic vesicles at the site of contact with the substrate. Electron microscopic immunocytochemistry showed these synaptic vesicles labelled for p65 with silver-developed gold particles. Thus, transitional elements have characteristics of both growth cones and presynaptic terminals, suggesting that they may also have functional attributes of both growth cones and presynaptic elements.

Retinal axon pathfinding in the optic chiasm: divergence of crossed and uncrossed fibers

In the developing mammalian visual system, retinal fibers grow through the optic chiasm, where one population crosses to the opposite side of the brain and the other does not. Evidence from labeling growing retinal axons with the carbocyanine dye Dil in mouse embryos indicates that the two subpopulations diverge at a zone along the midline of the optic chiasm. At the border of this zone, crossed fibers grow directly across, whereas uncrossed fibers turn back, developing highly complex terminations with bifurcating and wide-ranging growth cones. When one eye is removed at early stages, uncrossed fibers from the remaining eye stall at the chiasm midline. These results suggest that crossed and uncrossed retinal fibers respond differently to cues along the midline of the chiasm and that the uncrossed fibers from one eye grow along crossed fibers from the other eye, both guidance mechanisms contributing to the establishment of the bilateral pattern of visual projections in mammalian brain.

Early climbing fiber interactions with Purkinje cells in the postnatal mouse cerebellum

The time and place of initial contacts between afferent axons and their target cells are not known for most regions of the mammalian CNS. To address this issue, we have selectively visualized afferent climbing fiber axons together with their synaptic targets, Purkinje cells, in postnatal mouse cerebellum. Climbing fibers were orthogradely labeled by injection of rhodamine isothiocyanate into their brainstem source, the inferior olivary nucleus. Purkinje cells were localized with an antibody to a calcium-binding protein, calbindin D-28k (CaBP), in the same section or in adjacent sections. A novel view of the olivocerebellar projection and the morphology of climbing fiber arbors prior to the well-known "nest" stage has emerged from this analysis. At birth, climbing fibers project into the zone of Purkinje cells, before these cells have aligned into a monolayer. During this phase, climbing fibers have simple morphologies consisting of relatively unbranched terminal arbors and small tapered growing tips. Purkinje cells are arranged 3-6 cells deep and have tufted dendrites and relatively smooth somata. By postnatal days 3-4, climbing fibers branch over several adjacent Purkinje cell perikarya, which are still organized in a band several cells thick. From postnatal days 5-7, when climbing fibers subsequently make focused nests on individual cells, Purkinje somata are smoother and form a more distinct monolayer. Up to this time, however, climbing fibers continue to associate with Purkinje perikarya, even though Purkinje cell dendrites have emerged and branched extensively. By postnatal days 8-10, climbing fiber terminals climb onto the trunk of the relatively mature Purkinje dendritic tree. At birth, mossy fibers originating from the pontine nuclei resemble immature climbing fibers in that they also have a simple unbranched morphology and growing tips, but project only so far as the internal granule cell layer. Occasional individual fibers reach into the Purkinje zone both at postnatal day 0 and postnatal day 4, confirming that the fibers formerly described as "combination fibers" (Mason and Gregory, S4. J. Neurosci, 4:1715-1735) can be mossy in origin. These data demonstrate that climbing fibers project among Purkinje cells earlier than suspected, before these afferents begin to arborize and form pericellular nests. Our observations are not in accord with the view derived from autoradiographic tracing studies that as in other cortical areas, climbing afferents wait in the vicinity of Purkinje cells in the early neonatal period, then advance onto these cells in synchrony with Purkinje cell alignment into a monolayer and dendritic maturation.(ABSTRACT TRUNCATED AT 400 WORDS)

Ontogenesis of enkephalinergic afferent systems in the opossum cerebellum

Enkephalin (ENK) immunoreactive climbing fibers, mossy fibers and a beaded plexus of axons are present in the adult opossum's cerebellar cortex. We have used the indirect antibody peroxidase-antiperoxidase technique to study the ontogeny of enkephalinergic axons in the cerebellum of pouch young opossums from postnatal day (PD) 1 to PD 83. On PD 1, ENK axons are present in the intermediate layer of the cerebellar anlage. At PD 18, after a period of 'waiting', ENK fibers form clusters throughout the cerebellar cortex primarily within the nascent Purkinje cell layer. By PD 40, axon terminals with a climbing fiber phenotype circumscribe Purkinje cells; immature mossy fiber rosettes are present within the internal granule cell layer. A third axon phenotype, beaded ENK fibers can be distinguished on PD 68. Between PD 40 and PD 68, the distributions of ENK climbing and mossy fibers overlap in vermal lobules II-VIII and X, whereas in the hemispheres climbing fibers predominate. However, by PD 83, ENK positive climbing fibers are no longer evident in lateral folia. These results indicate that early arriving ENK axons are present before the differentiation of their cellular targets. Further, a transient appearance of ENK in discrete populations of developing climbing fibers suggests several developmental events: (1) cell death in the inferior olive, (2) collateral regression, or (3) a transient expression of this peptide, that may be characteristic of this chemically defined system of axons.

Axon outgrowth along segmental nerves in the leech. I. Identification of candidate guidance cells

We studied the development of the major extraganglionic components of the germinal plate in embryos of the glossiphoniid leech Helobdella triserialis to improve our understanding of the mechanism of segmental nerve formation. We examined the outgrowth of groups of axons from ganglionic neurons into the segmental nerves, the migration of peripheral neurons and epidermal specializations to their definitive sites, and the development of circular and longitudinal muscle fibers. We visualized axons, as well as neurons and epidermal specializations, by means of fluorescent cell lineage tracers injected earlier into blastomeres and muscle fibers by means of immunofluorescence. The development of cells in all groups was found to follow a stereotyped pattern. Axons of ganglionic neurons approach some identified peripheral neurons located along the segmental nerve paths but not, in general, epidermal specializations and muscle fibers. Near the somata of a subset of peripheral neurons they approach, axons cease or interrupt their growth. These findings identify a set of candidate guidance cells for axonal outgrowth in the leech, similar to those previously described in the developing nervous system of insects.

Synaptophysin expression during synaptogenesis in the rat cerebellar cortex

In order to study the mechanisms of synaptogenesis in the rat cerebellar cortex, a library of monoclonal antibodies has been generated against proteins of the isolated synapse. One recognizes a glycosylated 38 kDa protein that is concentrated in the synaptic vesicle fraction and resembles synaptophysin biochemically in its molecular weight, charge, and pattern of glycosylation. In the adult cerebellar cortex, the antisynaptophysin(mabQ155) immunoreactivity is codistributed with synapses. Immunoreactivity is strongest in the molecular layer where punctate deposits of reaction product outline the Purkinje cell dendrites. Discrete small profiles, consistent with the distribution of basket cell axon terminals, surround the Purkinje cells, and in the granular layer the synaptic glomeruli are intensely stained. There is no immunoreactivity in the white matter axon tracts. Electron microscope immunocytochemistry confirms the synaptic location of the antigen and suggests that the reaction product is associated with synaptic vesicles. Both round and flat vesicle populations are immunoreactive. Antisynaptophysin(mabQ155) has been used to follow synaptogenesis in the developing rat cerebellum. In the newborn rat (P0), despite the paucity of synapses, there is some specific immunoreactivity, especially in the subcortical white matter. Electron microscopy shows that the antigenicity is associated with vesicles within growth cones, filopodia, and immature axon profiles. During development, antisynaptophysin immunoreactivity increases progressively, along with the maturing cell populations, for both the granule cell-Purkinje cell and the mossy fiber-granule cell synapses. Quantitative biochemical analysis confirms the cytochemical results. These data suggest that neuronal growth cones express a synapse-specific antigen before complete morphological synapses are present.

Astrocytes and guidance of outgrowing corticospinal tract axons in the rat. An immunocytochemical study using anti-vimentin and anti-glial fibrillary acidic protein

In the present investigation the role of astrocytes and their precursors in guidance of outgrowing corticospinal tract axons in the rat is studied. Antibodies against glial fibrillary acidic protein and vimentin are used to analyse immunogen expression of glial cells, whereas the postnatal outgrowth of corticospinal tract axons through the spinal cord was studied using anterogradely transported horseradish peroxidase. The first, leading corticospinal tract axons, being the objective of the present study, are characterized by dilatations at their distal ends, the growth cones. Growth cones of pioneer corticospinal tract axons are randomly distributed in the presumptive corticospinal tract area of the ventral most part of the dorsal funiculus. A dramatic change in glial cell labelling is found from the majority being vimentin immunoreactive and glial fibrillary acidic protein-negative at birth to almost all being the reverse at the end of the fourth postnatal week. From double labelling experiments it can be concluded that the vimentin-glial fibrillary acidic protein transition occurs within astrocyte precursor cells. The absence of glial fibrillary acidic protein-immunoreactive glial cells during the outgrowth period of pioneer corticospinal tract axons indicates that they cannot play a role in the guidance of outgrowing corticospinal tract pioneer axons. Vimentin-immunoreactive glial cells are present throughout the presumptive corticospinal tract area at the time of arrival of the leading corticospinal tract fibres. The vimentin-immunoreactive glial cells, which themselves are orientated perpendicular to the outgrowing corticospinal tract axons, are mainly arranged in longitudinal tiers parallel to the rostrocaudal axis. Electron microscopically, growth cones of pioneer corticospinal tract axons frequently exhibit protrusions into vimentin-immunoreactive glial cell processes, suggesting an adhesive type of contact. Therefore, in addition to a positional role, vimentin-immunoreactive glial cells probably play a chemical role in guidance of pioneer corticospinal tract axons. A prominent vimentin-immunoreactive glial septum was noted during corticospinal tract outgrowth in the midline raphe of the medulla oblongata and spinal cord whereas it is absent in the decussation area of corticospinal tract fibres. After the first postnatal week the major vimentin-immunoreactive glial barrier either completely disappears (medullary levels) or gradually reduces to a minor glial fibrillary acidic protein-immunoreactive one (spinal cord levels).(ABSTRACT TRUNCATED AT 400 WORDS)

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 differential regulation of formation of chemical and electrical connections in Helisoma

Novel chemical and electrical connections form between neurons not normally connected in the buccal ganglia of the snail Helisoma. We examined the cellular and environmental conditions required for the formation of each type of connection. Previous work in situ showed that novel electrical connections could form in response to axotomy. We have now found that axotomy can evoke the formation of novel unidirectional chemical connections between neurons B5 and B4 in addition to a novel electrical connection. The novel chemical connections display all of the normal properties of chemical synapses in Helisoma ganglia. These connections, however, are transient in nature and break 4 days following axotomy. Previous work has shown that conjoint outgrowth is required for the formation of electrical connections. In cell culture we have investigated whether conjoint outgrowth is also required for chemical synaptogenesis. Using neurons B5 and B19 we have found that when neuron pairs make contact in cell culture, under conditions of synchronous neurite extension, both electrical and chemical synapses form. However, if one neuron has ceased extension prior to contact by a growing neuron, electrical synapses never form (Hadley et al., 1983, 1985) but chemical synapses do form. Furthermore, the addition of serotonin (10(-6) M) to culture medium to inhibit neurite extension of B19, but not that of B5, selectively prevents the formation of electrical connections while permitting the formation of chemical synapses. Thus, the timing of contact in relation to the state of neurite extension can specify the type of connection a given neuron can form.

Onset and development of intersegmental projections in the chick embryo spinal cord

The ontogeny of intersegmental (propriospinal) projections was studied in the chick embryo spinal cord between embryonic day 2.5 and day 6. Our goals were 1) to determine the earliest projections of intersegmental interneurons between specific spinal regions and to establish the cell types involved; and 2) to follow the ontogeny of these projections during the early formative stages of spinal cord development. Studies were carried out in vitro by using an isolated spinal cord/brainstem preparation. Horseradish peroxidase injections were made either uni- or bilaterally at various levels of the spinal cord along the rostrocaudal axis of the embryo. HRP histochemistry was done on Vibratome sections with diaminobenzidine as the chromogen. Following unilateral injections at day 2.5, labelled commissural interneurons were found contralaterally and were confined to the injected segment. Subsequently, labelled cells were found progressively further away from the injected segment. By day 4.5 reciprocal projections extended between lumbar and brachial regions. Interneurons with intersegmental axonal projections were often undifferentiated, consisting of primitive unipolar or bipolar cells with little, if any, dendritic development. In some cases migrating interneurons could be retrogradely labelled from two or three segments away from the location of their translocating cell body. Anterograde Golgi-like labelling of early undifferentiated cells revealed growing axons, axonal terminals, and growth cones. Five or six reasonably distinct classes of intersegmental interneurons were identified based on their location, axonal projections, and morphology of dendritic arbors. These appeared to be segmentally and bilaterally arranged along the rostrocaudal axis of the spinal cord. The axons of some of these types of interneurons exhibited preferences in their longitudinal projections within the ventral and ventrolateral marginal zone at the very onset of pathway formation. From the present observations it can be concluded that intersegmental connectivity precedes the development of ascending and descending supraspinal, as well as primary afferent connections in the chick embryo spinal cord.

Synaptic organization of anomalous retinal projections to the somatosensory and auditory thalamus: target-controlled morphogenesis of axon terminals and synaptic glomeruli

These experiments examine which morphological features of axon terminals and their synaptic glomeruli are determined by afferent axons, and which by their targets. In normal, adult hamsters, electron microscopy reveals that, with respect to multiple ultrastructural features, the terminals and synaptic glomeruli of retinal afferent axons in the dorsal lateral geniculate nucleus differ from those of ascending auditory and somatosensory afferents in the medial geniculate and ventrobasal nuclei, respectively. These features include: (1) the location of specific sensory axon terminals on the somata and dendrites of their targets neurons, (2) the constitutents of the glomeruli and their synaptic relationships, (3) the number of specific sensory terminal boutons per glomerulus, (4) bouton size, (5) the number of dendritic and somatic appendages contacted by each bouton, and (6) the mitochondrial morphology of the specific sensory afferent boutons. In order to ascertain which of these features are determined by afferent axons and which by their targets, we subjected newborn Syrian hamsters to surgical procedures known to produce permanent, abnormal retinal projections to the main thalamic auditory (medial geniculate) and somatosensory (ventrobasal) nuclei. When the animals were adults, we examined the terminals and synaptic glomeruli of abnormal retino-auditory and retino-somatosensory axons that were anterogradely labeled by intraocular injection of horseradish peroxidase. With respect to all of the preceding features except mitochondrial morphology, the terminals and synaptic glomeruli of retino-medial geniculate and retino-ventrobasal axons more nearly resembled those of normal, auditory and somatosensory afferent axons, respectively, than they did those of normal, retino-lateral geniculate axons. These results demonstrate that the differentiation of all the features that we have examined, except mitochondrial morphology, is determined by factors in target neurons or their environment. This finding suggests that the differentiation of morphological features involved in contacts among neurons (including the type, number and size of interconnected neuronal elements and the loci at which they contact each other) is responsive to interactions among the connected elements, or between neural elements and their environment (e.g., glia, extracellular matrix), whereas the differentiation of structures reflecting intrinsic functions of individual neuronal elements is not responsive to such interactions.

Axonal growth cones in the developing amphibian spinal cord

Axonal growth cones in the spinal cord of embryonic and larval Xenopus (stages 24-48) were filled with the anatomical tracer horseradish peroxidase (HRP). Growth cones of lateral and ventral marginal zones, including those of descending spinal and supraspinal pathways, were labeled by application of tracer to the caudal medulla or to one of several levels of the spinal cord. Central axons of sensory neurons were filled via their peripheral processes. Growth cone configuration varied widely but fell into five general categories: complex with both filopodia and veils, filopodia only, lamellipodia only, clavate, and fusiform. Several general patterns emerged from the distribution of these various configurations. Growth cones of younger animals generally were more complex than those of older ones. Growth cones closer to the leading edge of descending fiber bundles were more elaborate than those that followed. Growth cones of the dorsolateral fascicle, which carries ascending central processes of Rohon-Beard and sensory ganglion neurons, were very simple and followed a straight course rostrally, whereas those of descending axons of the lateral fiber areas were more complex and sometimes spread over almost the entire lateral marginal zone. Growth cones of Rohon-Beard central ascending axons were fusiform or clavate, while those of sensory ganglion axons showed several fine filopodia at their tips. Growth cones of both types of sensory axons change configuration as they approached the hindbrain, becoming more complex. This study demonstrates that the configurations of growth cones belonging to the same axonal pathway vary with age and with position along their routes, and that growth cones of different neuron classes exhibit characteristic ranges of morphological variation.

Dynamics of behaviour during neuronal morphogenesis in culture

We report a developmental sequence in the type and frequency of behaviours of neurons differentiating in vitro. We characterised these changes with extensive analysis of time-lapse sequences from both the continuing cell line pheochromocytoma PC12 and primary mixed cell culture of cat and mouse central nervous system. PC12 cells activated by nerve growth factor (NGF) differentiate in a uniform and synchronous manner. This allowed the first quantification of changes in different neuron behaviours during morphogenesis. Shortly after NGF activation, PC12 cells are highly labile in morphology and exhibit a large variety of morphological behaviours. During the first week of differentiation, the frequency of these behaviours declines, and gross morphology becomes more stable. The frequency of neurite initiation after 1 week in NGF is one-seventh what it was after 2 days in NGF. Over the same period, neurite retraction declines to one-third, and somal migration ceases altogether. Growth-cone activity does not decline during development. These behaviour changes correlate with published data on the differentiation of the neurite cytoskeleton. A qualitatively similar ontogeny was noted in the differentiation of CNS neurons in mixed cell culture. Major differences occur in the relative timing of changes in behaviours. Mature, stable morphology is not detected in these cultures until 7 weeks in vitro.

The timing of granule cell differentiation and mossy fiber morphogenesis in the opossum

The timing of developmental events may be important for the orderly formation of neuronal interconnections. In the present study, the timing of granule cell migration is compared with the arrival and maturation of mossy fiber projections. The opossum was chosen as the experimental animal because its protracted postnatal development enables the examination of developmental sequences not as easily recognized in other more commonly used mammalian species. It is shown that all areas that project to the cerebellum as mossy fibers in the adult opossum do so by postnatal day (PD) 30. Their major target, the granule cells begin inward migration from the external germinal layer (EGL) prior to PD 30, but do not form a distinct internal granular layer (IGL) until PD 35. Migrating granule cells penetrate into the IGL deep to granule cells that have begun dendritic differentiation. By PD 50, Golgi impregnations reveal that many granule cells have numerous immature processes, somal spines and dendritic growth cones. After this age these structures are rare and the vast majority of granule cells exhibit short dendrites with digiform endings. Dendritic differentiation subsequent to PD 54 involves an increase in the length of the shaft and the further maturation of terminal digits. Also from Golgi material, immature mossy fiber endings can be identified in the IGL by PD 35 and exhibit mature characteristics at PD 73. Thus, the formation and maturation of granule cell dendrites and their afferents (mossy fibers) occur over an extended period of time (PD 35-73). Moreover, granule cells exhibit a sequence of development similar to that of Purkinje cells: early arrival of their primary afferent projections in the cerebellar anlage; a period of exuberant dendritic growth; and a protracted and overlapping period for dendritic and synaptic maturation.

Axon development in mouse cerebellum: embryonic axon forms and expression of synapsin I

A fundamental question in central nervous system development is the timing of synaptogenesis in relation to invasion of targets by afferent axons. A related question is how growth cones transform into synaptic terminals. These two aspects of axon maturation were examined in developing mouse cerebellum, by labeling single axons with horseradish peroxidase, to study their form and cytology, and by immunocytochemical staining of a synaptic vesicle antigen, synapsin I, a phosphoprotein found on synaptic vesicles in all mature CNS synapses. From embryonic day 16 to postnatal day 3, horseradish peroxidase-labeled afferent axons extend well into the cerebellum and have simple forms. At embryonic day 16, axon growing tips are synapsin I-negative. Synapsin I is first expressed at embryonic day 17, and by embryonic day 18, fibers are stained throughout the cerebellum. Synapsin I expression coincides with a general increase in synaptic specializations, although growing tips continue to have the cytology of growth cones. During the period that axons have primitive shapes, synapsin I is distributed throughout the terminal arbor, corresponding to the presence of small vesicles along neurite lengths, even at non-synaptic sites. After postnatal day 3, when synaptic terminals develop into stereotypic shapes and engage in characteristic synaptic relations, synapsin I is restricted to boutons. Thus, the synapse-specific protein synapsin I is expressed in fetal mouse brain, long before nerve endings have the structure and connections of adult brain. In cerebellar axons, the expression of this protein follows axon arrival, coincides with the appearance of elementary synapses, and accompanies the transformation of growing tips into stereotypic synaptic boutons. The time course of expression of synapsin I, a phosphoprotein that may be involved in synaptic efficacy, suggests that transmitter release may influence early axon-target cell interactions.

Disoriented pathfinding by pioneer neurone growth cones deprived of filopodia by cytochalasin treatment

A major question in developmental neurobiology is how developing nerve cells accurately extend processes to establish connections with their target cells. This problem involves both the nature of cues for growth cone guidance and also the question of how growth cones survey their environment for cues and respond by altering their direction of migration. The filopodia which normally extend from neuronal growth cones have been shown to affect growth cone steering in vitro and it has been proposed that they function in vivo in the detection of and response to guidance cues. This hypothesis could be tested in vivo if growth cones which normally have filopodia could be induced to migrate in their absence. The pair of Ti1 neurones are the first neurones to extend axons through the limb buds of embryonic grasshoppers. We report here an examination of the migration of Ti1 pioneer growth cones deprived of filopodia by culture in agents which disrupt actin microfilaments. Under these conditions, axons continue to extend but a large percentage of growth cones are highly disoriented. Our results indicate that Ti1 filopodia are not necessary for axonal elongation in vivo but that they are important for correctly oriented growth cone steering.