Axon guidance by gradients of a target-derived component

Development of neural connections between visual cortex and transplanted lateral geniculate nucleus in rats

The development of neural connections between transplanted lateral geniculate nucleus (LGN) and host visual cortex (VC) was studied in slice preparations obtained from rat brain in which a fetal (embryonic day 15-17) rat LGN was transplanted to the white matter underlying the VC of a neonate rat (postnatal day 0-1). Placing a fluorescent dye (DiI) in the transplant of the fixed slices revealed that retrogradely labeled cortical cells projecting to the transplant were broadly distributed through layers II to VI at 1 week after transplantation. Three weeks after transplantation, these cells were virtually confined to layer VI. Likewise, anterograde labeling showed that cells in the transplant sent axons up to layer I with a few branches at 1 week after transplantation, while the axons were found to terminate at layer IV with many arborizations at 3 weeks after transplantation. These observations were supported by electrophysiological studies. Analysis of the antidromic responses of the cortical cells to stimulation of the transplant showed that the efferent cells projecting to the transplant were broadly distributed in layers II-VI at 1 week after transplantation, while they were virtually restricted to layer VI at 3 weeks after transplantation. Current source-density analysis of the field potentials and intracellular analysis of the synaptic potentials in the cortical cells demonstrated that geniculocortical connections were broadly established in layers II-VI at 1 week after transplantation, and were localized to layer IV and VI at 3 weeks after transplantation. These results suggest that the development of neural connections between transplanted LGN and host VC is characterized by an initial broad distribution of afferent and efferent connections without laminar specificity, and by later selection of appropriate connections to yield lamina-specific connections comparable to those in normal adult VC.

Topographic maps and molecular gradients

Topographically organized patterns of connectivity occur throughout the central and peripheral nervous systems. It is commonly supposed that gradients of recognition molecules underlie this form of synaptic specificity. Recent studies have led to new ideas about how such gradients might arise in the retinotectal system, and initiated molecular analyses of position-dependent gene expression in the peripheral motor system.

Pathfinding at the mammalian optic chiasm

Axons of retinal ganglion cells in the eye form a system of retinal projections, which carry information about the world around us to targets in the brain for processing. Recent work combining video imaging technology, manipulations of mouse embryos in vivo, and molecular approaches have begun to shed light on how this major sensory pathway in the mammalian brain comes about during embryonic development.

Behavior of fish retinal growth cones encountering chick caudal tectal membranes: a time-lapse study on growth cone collapse

In a cross species in vitro assay, growth cones from fish temporal retina elongating on laminin lanes were observed with time-lapse videomicroscopy as they encountered lanes and territories that carried membrane fragments from the chick caudal tectum. Caudal tectal membranes of adult fish and embryonic chick are known to possess a repellent guiding component for temporal retinal axons. The caudal membranes of chick exert a particularly strong influence on fish temporal axons. Contacts with chick caudal membranes by just a few filopodia and parts of the lamellipodia evoked a turning response away from the membrane lane of the entire growth cone. Contacts by filo- and lamellipodia over the entire circumference of the growth cone, however, caused invariably growth cone collapse and retraction. During growth cone turning and collapse and retraction, filopodia remained in contact with the tectal membrane fragments, suggesting strong membrane-filopodia adhesion simultaneous to growth cone repulsion by the repellent guiding component.

Formation of specific efferent connections in organotypic slice cultures from rat visual cortex cocultured with lateral geniculate nucleus and superior colliculus

Cells in the cerebral cortex project to many distant regions in the brain. Each cortical target receives input from a specific population of cells which have a characteristic morphology and which are located in a distinct cortical layer. In an attempt to learn about the mechanisms by which this stereotypic output pattern is generated during development, we have studied the formation of cortical projections in an in vitro system. Slices from developing rat visual cortex were cocultured with slices from the superior colliculus, the major target of cells in layer 5, and the lateral geniculate nucleus, the major target of cells in layer 6. Cortical neurons which established connections with tectal and thalamic explants were retrogradely labelled with fluorescent dyes. It was found that, in vitro, different populations of neurons project to these two targets, and that the laminar position and cellular morphology of the projecting cells were similar to their in vivo counterparts. These specific connections were established when the target explants were placed either next to the white matter or next to the pial side of cortical slice cultures. The axons of cells projecting to ectopic positioned explants reoriented their trajectories and grew through the cortical grey matter directly towards their targets. Thus subcortical targets exert an orienting effect specifically on their innervating cells and attract growing axons of the appropriate cells at a distance. These results suggest that different targets release different molecules that act selectively on specific populations of neurons. Therefore, chemotropic guidance is likely to play a significant role in the development of specific connections between cortical neurons and their target areas.

Morphological response of extending spinal neuritic growth cones to peripheral target tissue

Nerve fibers extend from spinal cord explants of larval frog in an enhanced and directed manner when cocultured with limb mesenchyme target tissue. In order to gain a better understanding of the events involved in target directed neurite extension, a detailed examination of the nerve growth cone was undertaken. The growth cones of spinal neurites that had elongated in the presence or absence of target tissue were examined by light and electron microscopy. Scanning electron microscopy revealed that growth cones of cord+limb cultures were elaborate in form with numerous and long filopodia, while those cultured in the absence of the target tissue appeared relatively simple with few, short filopodia. A morphological parallel existed between those growth cones that were cultured without the target and those in cord+limb cultures but which grew from the side of the cord explant away from the mesenchyme tissue. When examined with the transmission electron microscope, growth cones under target influence were organelle-rich in contrast to target-deprived growth cones, which lacked the extensive array of vesicles, endoplasmic reticulum, and filaments. When the attachment substratum of polylysine was substituted by collagen, the dramatic differences in growth cones were not realized, although enhanced, oriented growth still occurred in the presence of limb target tissue. It appears that growth cone morphology is a dynamic reflection of the growth effects elicited by a target tissue factor that in turn may be mediated by the nature of the extracellular environment.

Plasticity of neuronal connections in developing brains of mammals

Although mature nervous systems show substantial malleability following various surgical or environmental manipulations, developing brains show far more prominent plasticity, particularly in terms of morphological features. Neuronal circuits, for example, can be dramatically rewired following neonatal but not adult brain lesions. It remains unknown why neuronal circuits in developing brains show such remarkable plasticity. A number of anatomical and physiological studies suggest that there are transient projections in developing brains and they are eliminated by cell death and/or collateral elimination as development proceeds. This raises a possibility that aberrant projections observed following various surgical or environmental manipulations such as partial denervation, results from retention or stabilization of transient projections. However, evidence suggests that cell death does not play an important role in developmental fine-tuning of neuronal projections. Furthermore, although the elimination of axon collaterals takes place, individual neurons appear to elaborate axonal arbors in appropriate target areas, resulting in a net increase in the size of axonal arbor emerging from individual neurons. In accord with these observations, the number of synapses appear to increase during the period when axonal elimination proceeds. Taken together, reinforcement of appropriate projections rather than elimination of excessive connections plays a major role in developmental specification of neuronal connections. Appearance of aberrant projections after partial denervation may not be a consequence of disordered axonal growth, since they form topographic maps which precisely mirrors those for normal projections. They may be induced due to reinforcement of pre-existing neuronal connections rather than to construction of novel pathways. Observations of axonal morphology in denervated areas indicate that lesion-induced enlargement of projections is due to transformation of axonal morphology, from simple and poorly branched to multiply branched. Perhaps such simple and poorly branched axons in inappropriate target areas may represent ones in the course of elimination but they may serve as a source of sprouting when denervated. In other words, after total elimination of axons any surgical or environmental manipulation cannot induce enlargement of projections. The mechanisms underlying such modifiability of neuronal connections remains unclarified but possible participation of an activity-dependent competitive mechanism is discussed.

Changes in fiber organization within the chiasmatic region of mammals

Introduction

Classical views of the optic chiasm maintain four propositions about the retinofugal pathways: (1) each optic nerve contains a retinotopic representation of its respective retinal surface; (2) this retinotopic map in the nerve is the basis for the subsequent segregation of the decussating from the non-decussating fibers; (3) this retinotopy in the nerve is also the basis for the presence of retinotopy found within the half-retinal maps in the optic tracts; and (4) the half-retinal maps from each optic nerve are brought together within the chiasm to yield a unified, binocularly congruent, map in the optic tract (Brodal, 1969; DukeElder, 1961; Polyak, 1957; Wolff, 1940). The appeal of this classical view is in its simplicity, based on the assumption that the retinofugal pathway should replicate the sensory surface along its course. We now know that each of these four propositions is incorrect, and that the error is not one simply of degree or extent (Guillery, 1982, 1991). Rather, the above description of the visual pathway is fundamentally flawed because it has failed to take into account the constraints under which the pathway develops. We shall first consider the evidence for rejecting the classical view, from recent studies on the organization of the retinofugal pathway in adult animals and on the development of that organization. We shall then describe three transformations in the fiber order which all occur in the chiasmatic region, two of which were only recently recognized, and for which we must account.

Observations from adult organization

The difference in the fiber order in the optic nerve and tract

Specific modulation of dopamine expression in neuronal hybrid cells by primary cells from different brain regions

MN9D is an immortalized dopamine-containing neuronal hybrid cell line. When MN9D cells were coaggregated with primary embryonic cells of optic tectum, a brain region that does not receive a dopaminergic innervation, there was a marked reduction in their dopamine content, tyrosine hydroxylase immunoreactivity, and tyrosine hydroxylase mRNA. Similar reductions in dopamine content were produced by coaggregation with cells from embryonic thalamus, another brain region devoid of dopaminergic innervation. Coaggregation of MN9D cells with dopaminoceptive cells from the corpus striatum or the cortex did not have a demonstrable stimulatory effect on the dopamine content of MN9D cells. The decrease in MN9D dopamine content produced by optic tectum cells was not reversed by addition of corpus striatum cells. Thus, the MN9D hybrid cells are able to respond to an inhibitory factor(s) from cells derived from brain areas that are not targets for dopaminergic neurons. Catecholamine-producing PC12 cells did not respond in a similar manner, suggesting that the response of MN9D cells is a function of their mesencephalic origin. Given the selective response of MN9D cells to different brain cell populations, this hybrid cell line should facilitate investigations of cell-cell interactions in the central nervous system that may be involved in the expression of neurotransmitter phenotype and establishment of specific neuronal connections.

Responses of retinal axons in vivo and in vitro to position-encoding molecules in the embryonic superior colliculus

We show that rat retinal ganglion cell axons exhibit no topographic specificity in growth along the rostral-caudal axis of the embryonic superior colliculus (SC). Position-related, morphological differences are not found between temporal and nasal axon growth cones. However, embryonic retinal axons respond in vitro to a position-dependent molecular property of SC membranes. In vivo, regional specificity in side branching is the earliest indication that axons make topographic distinctions along the rostral-caudal SC axis. Our contrasting in vivo and in vitro results indicate that molecules encoding rostral-caudal position in the SC neither guide nor restrict retinal axon growth, but may promote the development of topographic connections by controlling specificity in the extension or stabilization of branches.

A subpopulation of hippocampal glial cells specific for the zinc-containing mossy fibre zone in man

The projection of the zinc-containing axons of granule cells of the fascia dentata, e.g. the mossy fibres, is restricted to the hilar region and sector CA3 of the hippocampus. Serial sections of human hippocampi were stained for zinc-containing fibres with a non-perfusion Timm method, while adjacent ones were stained with Darrow red and aldehydefuchsin. GFAP, glutamine synthetase immunocytochemistry and a specific silver stain were employed to label other subtypes of astrocytes. The distribution of Timm-stained areas correlates only with the distribution of aldehydefuchsin-positive glial cells, most probably astrocytes. Since glial cells regulate axonal outgrowth in a region-specific manner, it is temptative to speculate that the aldehydefuchsin-positive glial cell is a candidate for a specific neuron-glia interaction which is somehow involved in the control of outgrowth of mossy fibres.

Specificity of interneuronal connections

A fundamental problem of neurobiological research is how specific connections between individual neurons are established and maintained. In this report different levels of neuronal specificity are described. Some neuronal populations display region specificity, but within the target region they establish synapses with a variety of neurons. A characteristic feature of the afferent innervation of hippocampal neurons is that many fibers terminate in a laminated fashion. Such a layer specificity is known for the afferents from the entorhinal cortex and for the mossy fibers. The entorhinal afferents terminate in the outer molecular layer of the fascia dentata and in the stratum lacunosum-moleculare of the hippocampus proper. The mossy fibers display both region specificity and layer specificity: they form numerous synapses in hippocampal region CA3 but never invade CA1; in CA3 they are restricted to stratum lucidum. An extremely high degree of neuronal specificity is observed in the case of the axo-axonic or chandelier cells. The axons of these neurons specifically terminate on the axon initial segments of projection neurons in the neocortex, hippocampus and fascia dentata. Thus, these cells not only display a target cell specificity but a selectivity for a distinct portion of the target cell's membrane. Some of the factors that contribute to these different levels of neuronal specificity are briefly discussed. Positional cues as well as diffusible molecules from the target region may guide the outgrowing growth cone to its target. Molecular interactions between pre- and postsynaptic membranes, the functional load of the synaptic contact, and the selective death of a number of neurons and synapses further determine the specificity of interneuronal connections.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulators of neuronal migration and neurite growth

A multitude of molecules have been identified over the past few years that promote neurite outgrowth in vitro. The concept that these molecules work mainly by providing an adhesive surface for neuronal growth cones has been challenged by evidence from recent experiments. Some of the substrate molecules have diverse actions on cell migration and neurite growth. In addition, there is now evidence that there are molecules that specifically inhibit growth cone locomotion. This has given rise to the hypothesis that growth cones integrate a variety of growth-promoting and inhibitory signals and translate them into directed locomotion.

Specificity of a target cell-derived stop signal for afferent axonal growth

With a novel model culture system in which afferents are co-cultured with purified populations of target neurons, we have demonstrated that a target cell within the central nervous system (CNS), the cerebellar granule neuron, poses a "stop-growing signal" for its appropriate afferents, the mossy fibers. To ask whether this stop signal is afferent specific, we co-cultured granule neurons with another cerebellar afferent system, the climbing fibers from the inferior olivary nuclei, which normally contact Purkinje neurons, and with retinal ganglion cell afferents, which never enter the cerebellum. Granule neurons do not pose a stop signal to either of these afferents. In contrast to pontine mossy afferents that grow well on laminin and showed reduced outgrowth on granule neurons, both olivary and retinal fibers displayed similar growth on laminin alone or on granule neurons. In addition, each afferent showed different degrees of fasciculation and growth cone morphology on laminin. Thus, the growth arrest signal sent by granule neurons is specifically recognized by their appropriate afferents. Moreover, these three types of afferents exhibit varying growth patterns on the same noncellular and cellular substrates, implicating distinct molecular characteristics of growth regulation for different classes of neurons that would contribute to specificity of synapse formation.

Axon guidance by molecular gradients

In the past year, evidence indicating that some developing axons are guided to their targets, at least in part, by gradients of diffusible chemoattractants secreted by their target cells has continued to accumulate. It has also been shown for the first time that axons can orient in response to smooth gradients of immobilized substrate molecules.