Eph receptor-ligand interactions are necessary for guidance of retinal ganglion cell axons in vitro

Previous results of an in vitro guidance test, the stripe assay, have demonstrated the presence of a repulsive axon guidance activity for temporal retinal axons in the posterior part of the vertebrate optic tectum. Ephrin-A5 and Ephrin-A2 are ligands for the EphA subfamily of Eph receptor tyrosine kinases, which are expressed in overlapping gradients in the posterior part of the tectum. When recombinantly expressed, both proteins have been shown to guide retinal ganglion cell axons in the stripe assay. While these results suggest that Ephrin-A5 and Ephrin-A2 form part of the posterior repulsive guidance activity, they do not elucidate whether they are necessary components. Here we report that soluble forms of the ligands at nanomolar concentrations completely abolish this repulsive activity. Similar results were obtained with the soluble extracellular domain of EphA3, which is a receptor for Ephrin-A2 and Ephrin-A5, but not with the corresponding domain of EphB3, a receptor for the transmembrane class of Eph ligands. These experiments show that the repulsive axon guidance activity seen in the stripe assay is mediated by Ephrin-A ligands.     

Cross-species collapse activity of polarized radial glia on retinal ganglion cell axons

Anxiety sensitivity has been implicated as a risk factor in the development and maintenance of anxiety and fear-related disorders. Indeed, persons who score high on the anxiety sensitivity index (ASI) are generally more responsive to biological challenge procedures such as CO2-inhalation that directly evoke the feared bodily events. One would expect, therefore, that persons high on anxiety sensitivity should be more conditionable and hence more likely to acquire fears, than persons low on anxiety sensitivity when CO2-enriched air is used as an unconditioned stimulus (UCS). Undergraduates (N = 96), scoring high, medium and low on the ASI received 8 repeated 20-s inhalations of either 20 or 13% CO2-enriched air (UCSs) paired with one of three CSs differing in fear-relevance (snake, heart and flowers). Several autonomic and self-report measures were assessed. Contrary to expectation, electrodermal and cardiac conditioned responses failed to discriminate between ASI groups. Yet, SUDS and severity and frequency of DSM-IV panic symptoms varied reliably as a function of anxiety sensitivity. Overall, the findings suggest that anxiety sensitivity is related to subjective fear-related complaints, but not autonomic responding and conditionability. We discuss clinical and theoretical implications for understanding the place fo anxiety sensitivity in fear onset.     

Reduced size of retinal ganglion cell axons and hypomyelination in mice lacking brain-derived neurotrophic factor

While brain-derived neurotrophic factor (BDNF) delays the death of axotomized retinal ganglion cells in rodents, it is unclear if it affects any aspect of the normal development of these cells. Here we examined the optic nerve of bdnf-/- mice. Axonal numbers were normal, but their diameter, as well as the proportion of myelinated axons, was reduced at postnatal day 20 (P20). In contrast, the facial nerve was not hypomyelinated. Expression levels of mRNAs coding for the myelin proteins PLP and MBP were substantially reduced in the hippocampus and cortex at P20, but not in the sciatic nerve. Intraventricular injections of BDNF into the ventricles of wild-type mice at P10 and P12 up-regulated expression of PLP in the hippocampus at P14. These results indicate a role of BDNF, discussed as indirect, in the control of myelination in the central nervous system.     

Pathfinding by retinal ganglion cell axons: transplantation studies in genetically and surgically blind mice

Optic axons show a highly stereotypical intracranial course to attain the visual centers of the brainstem. Here we examine the course followed by axons arising from embryonic retinae implanted in neonatal ocular retardation mutant mice in which there had been no prior innervation of the visual centers. Retinae placed on the ventrolateral brainstem adjacent to the normal site of the optic tract send axons dorsolaterally toward the ipsilateral superior colliculus, which they innervate along with a number of other subcortical visual centers. Somewhat unexpectedly, axons also course ventrally to cross at the level of the suprachiasmatic nucleus or, less frequently, caudal to the mammillary body to follow the route of the optic tract and innervate contralateral visual centers. Retinae implanted along the course of the internal capsule emit axons that follow projection fibers through the striatum to innervate the lateral geniculate nucleus and other optic nuclei. These grafts also appear to project to the lateral part of the ventrobasal nucleus of the thalamus. The results show that prior existence of an optic projection is not necessary for axons derived from ectopic retinae to attain visual nuclei, not only on the side of implantation but also on the contralateral side of the brain. The cues that these growing axons follow appear to be stable temporally. The fact that axons can also follow highly anomalous routes, such as through the internal capsule, to attain target nuclei in the brainstem suggests that the normal optic pathway is not an obligatory route for optic outgrowth.     

Receptive-field properties of adult cat's retinal ganglion cells with regenerated axons

Receptive-field properties of retinal ganglion cells (RGCs) that had regenerated their axons were studied by recording single-unit activity from strands teased from peripheral nerve (PN) grafts apposed to the cut optic nerve in adult cats. Of the 286 visually responsive units recorded from PN grafts in 20 cats, 49.7% were classified, according to their receptive-field properties, as Y-cells, 39.5% as X-cells, 6.6% as W-cells, and 4.2% were unclassified. The predominant representation of Y-cells is consistent with a corresponding morphological study (Watanabe et al. 1993a), which identified alpha-cells as the RGC type with the largest proportion of regenerating axons. Among the X-cells, we only found ON-center types, whereas both ON-center and OFF-center Y-cells were found. As in intact retinas, the receptive-field center sizes of Y-cells and W-cells were larger than those of X-cells at corresponding displacements from the area centralis. Within the 10 degrees surrounding the area centralis, the receptive fields of X-cells with regenerated axons were larger than those in intact retinas, suggesting that some rearrangement of retinal circuitry occurred as a consequence of degeneration and regeneration. Receptive-field center responses of Y-, X-, and W-type units with regenerated axons were similar to those found in intact retinas, but the level of spontaneous activity of Y- and X-type units was, in general, less than that of intact RGCs. Receptive-field surrounds were weak or not detected in more than half of the visually responsive RGCs with regenerated axons.     

Possible involvement of gradients in guidance of receptor cell axons towards their target position on the olfactory bulb

There is increasing evidence for directional guidance of growing axons by molecular gradients in target tissues. Aside from biochemical studies on gradients and their role, the capability of axons to approach their target position from different aspects of a two-dimensional field is itself an indication for guidance by gradients. According to this criterion, such guidance is expected to be involved not only in map-formation in the visual system but also in targeting of receptor cell axons in the olfactory bulb. In this paper, physico-chemical concepts of visual mapping are adapted to olfactory targeting. In both cases there must be sophisticated processing of graded cues in the growing tip of the axon for growth cone navigation. In visual map formation, a target position is determined by influences of cues depending on the position of axonal origin; in olfactory targeting, however, these influences are expected to be based on properties of the receptor-cell-specific molecules (possibly including the receptor molecule itself), as well as by gene regulation affecting the levels of expression. According to this concept, the main role of molecules expressed in a receptor-cell-type specific manner is not matching specific counterparts on the target tissue, but instead quantitative modulation of growth cone steering for sensing the direction towards the target position.     

Formation of functional synapses by regenerating adult rat retinal ganglion cell axons in midbrain target regions in vitro

The ability of adult rat retinal ganglion cell (RGC) axons to reinnervate normal target regions was examined in vitro. In co-culture experiments, adult rat retinal explants were placed adjacent to fetal rat midbrain sections that contained the superior colliculus (SC) which is the main target for RGC axons. Adult rat RGCs regrew axons over more than 500 microns on a polylysine-laminin substrate to reach the co-cultured explants. By using neurofilament immunohistochemistry and the fluorescent dye DiI for anterograde and retrograde tracing, it was shown that (1) adult rat RGCs with a stereotyped morphology survived in explant cultures for more than 4 weeks in the presence of fetal midbrain explants, (2) regenerating RGC axons preferentially terminated within midbrain target regions, and (3) RGCs formed functional synapses. In addition, the maturation of the SC region in midbrain explants was examined histologically and ultrastructurally to demonstrate appropriate target development.     

Temporal changes in beta-tubulin and neurofilament mRNA levels after transection of adult rat retinal ganglion cell axons in the optic nerve

Axons of adult mammalian retinal ganglion cells (RGCs) do not regenerate spontaneously after injury in the optic nerve and show a persistent decrease in the rate of transport of tubulin and neurofilament proteins. To investigate further the expression of cytoskeletal proteins in these axotomized CNS neurons, mRNA levels of beta-tubulin and the 150 kDa neurofilament subunit (NF-M) were measured after interrupting the optic nerve 9 mm from the eye. Northern blots of RNA extracted from whole retinas after optic nerve transection showed that the total level of both of these mRNAs fell after injury. To determine if this decrease was a result of the death of axotomized RGCs or reflected changes in individual neurons, RNA probes were hybridized to radial cryostat sections of normal and axotomized retinas from 1 d to 6 months after injury. Grain counts revealed two trends of tubulin expression in RGCs. An early increase in tubulin mRNAs in the axotomized RGCs was followed by a later decrease. Such an increase in tubulin mRNA levels has been correlated with regenerative growth in other neurons. By 1 week after injury, the beta-tubulin mRNA levels decreased to 70% of the control value. Moreover, the time of this fall coincided with the onset of a marked slowing of cytoskeletal transport that follows injury in the optic nerve. In contrast, NF-M mRNA levels dropped immediately after axotomy, and remained at 80% of the control level. It is suggested that the transient increase in tubulin mRNAs may reflect an early regenerative response whose persistence depends on further growth cone interactions with the substrate.     

Effects of GDNF on retinal ganglion cell survival following axotomy

Recent evidence suggests that approximately 90% of retinal ganglion cells (RGCs) die by the process of apoptosis within 14 days of optic nerve transection. RGCs begin to disappear from the retina between 5 and 7 days postaxotomy when the highest percentage of RGCs show characteristics typical of apoptosis. A single intraocular injection of glial cell-line derived neurotrophic factor (GDNF) given at the time of axotomy resulted in a delay in the initiation of RGC death and increased the densities of surviving RGCs at 7, 10 and 14 days postaxotomy. The mean RGC densities in GDNF treated retinas at 7 (2381 +/- 144), 10 (1561 +/- 117) and 14 (1123 +/- 116) days postaxotomy were significantly higher than that of controls (1835 +/- 82, 835 +/- 272 and 485 +/- 39, respectively). The loss of RGCs was paralleled by increases in TUNEL positive staining in control retinas and a lower percentage of TUNEL positive cells in GDNF treated retinas at 5, 7 and 10 days postaxotomy. These results suggest that GDNF is capable of promoting RGC survival following injury, possibly by interfering with an essential step in apoptosis.     

Age-dependent and cell class-specific modulation of retinal ganglion cell bursting activity by GABA

Competition for postsynaptic targets during development is thought to be driven by differences in temporal patterns of neuronal activity. In the ferret visual system, retinal ganglion cells that are responsive either to the onset (On) or to the offset (Off) of light exhibit similar patterns of spontaneous bursting activity early in development but later develop different bursting rhythms during the period when their axonal arbors segregate to occupy spatially distinct regions in the dorsal lateral geniculate nucleus. Here, we demonstrate that GABAergic transmission plays an important, although not exclusive, role in regulating the bursting patterns of morphologically identified On and Off ganglion cells. During the first and second postnatal weeks, blocking GABAA receptors leads to a decrease in the bursting activity of all ganglion cells, suggesting that GABA potentiates activity at the early ages. Subsequently, during the period of On-Off segregation in the geniculate nucleus, GABA suppresses ganglion cell bursting activity. In particular, On ganglion cells show significantly higher bursting rates when GABAergic transmission is blocked, but the bursting rates of Off ganglion cells are not affected systematically. Thus, developmental differences in the bursting rates of On and Off ganglion cells emerge as GABA becomes inhibitory and as it consistently and more strongly inhibits On compared with Off ganglion cells. Because in many parts of the CNS GABAergic circuits appear early in development, our results also implicate a potentially important and possibly general role for local inhibitory interneurons in creating distinct temporal patterns of presynaptic activity that are specific to each developmental period.     

Changes in the retinal ganglion cell layer and optic nerve of rats exposed neonatally to cocaine

In a study of 452 ex-prisoners in England in 1990, 66 people reported that they were tested for HIV antibodies when last in prison. The circumstances under which many of those who were tested were difficult: 36% found it an unpleasant experience, 17% had not taken the test voluntarily and 55% said they received no counselling. Further information was gathered about the experiences of those who were HIV positive or assumed to be. Most were accommodated in a 'special location', not allowed to associate with other prisoners and denied access to work or recreational facilities. These data highlight the difficulties arising from the policy of Viral Infectivity Restrictions, a set of regulations applied to the management of prisoners with HIV in English prisons. This policy created a distressing situation for those tested for HIV or identified as being HIV positive in prison. For the prison environment, these conditions may create a vicious circle reinforcing inaccurate beliefs and anxieties.     

Axonal regeneration of retinal ganglion cells

We have developed retinal culture system of adult mammals to investigate neural regeneration from adult retinal ganglion cells (RGC). In this culture system, neurites were regenerated from RGCs of adult retinal explants. Investigation of neurotrophic effects on the neural regeneration showed that some interleukins and neurotrophins enhanced neurite regeneration from adult rat RGCs. We also found that the adult human retina had the ability of neural regeneration and that neurotrophins enhanced this ability. A novel neurotrophic factor secreted by adult rat hepatocytes also enhanced neurite regeneration not only in adult mice but also in aged RGCs. This result indicated the novel hepatocyte secreted factor is an activator which enhances neural regeneration of the aged retina. We concluded that even adult aged RGCs had the ability of axonal regeneration after injury and that neurotrophic factors might enhanced these abilities. Therefore neurotrophic factors might have practicable applications in drug treatments for intractable disease of the neural retina and optic nerve. Future progress of neuroscience is expected to rescue the retina from various diseases, and to render possible the transplantation of the retina and optic nerve.     

Regenerating ganglion cell axons in the adult rat establish retinofugal topography and restore visual function

The mechanisms of neuronal network response to axotomy are poorly understood. In one of the favoured models used to study the fate of injured neurons in the adult rat visual system, appreciable numbers of retinal neurons survive optic nerve injury under conditions of microglia-targeted neuroprotection. Rescued neurons can regenerate their axons and become target-dependently stabilised after reconnection with their natural visual centres by means of a peripheral nerve graft, which, in addition to guidance, actively supports axonal growth. The mechanisms that control regenerative axonal growth and resynaptogenesis include coordinated cell-cell interactions between growing neurites and target cells in order to establish a meaningful reconnectivity. Here the function of the regenerating visual circuitry was first studied by monitoring the ability of animals to discriminate spatial patterns, and second by recording visual evoked cortical potentials (VEPs) in the same animals. These functions were correlated with neuroanatomical studies of the retinotopic organisation of regenerating axons. To achieve these goals, adult rats were behaviourally trained in a Y-maze to discriminate between vertical and horizontal stripes. Both optic nerves were transected, and the regenerating axons of one optic nerve were guided into the area of optic tract with a peripheral nerve graft according to the protocols of neuroprotection and simultaneous grafting, in order to enable large numbers of axons to reinnervate the major visual targets in the midbrain and thalamus. Postoperative testing of the animals showed a marked improvement of visual perception and behaviour. The VEPs of the same animals were measurable indicating a restoration of the visual circuitry including the ascending corticopedal connections. Neuroanatomical assessment of the fibre topography within the graft and the area of termination revealed a rough topographic organisation that may account for restoration of the function. These results suggest that interrupted central pathways can be functionally reconnected by providing a neuroprotective environment in combination with peripheral nerve grafts to bypass lesions.     

Delay of ganglion cell death by tetrodotoxin during retinal development in chick embryos

Acid-soluble collagen from rat skin was modified by active oxygen in vitro, and properties of the modified collagen as a substratum for fibroblasts were studied. When collagen was treated with ascorbate-copper ion systems, cross-linking and a little degradation occurred rapidly. The cells attached but spread poorly on the modified collagen gel as compared with on the untreated collagen gel. On the other hand, when collagen was treated with H2O2-copper ion systems, only degradation of collagen molecule occurred rapidly. This treatment did not affect the attachment and spreading of the cells on the collagen gel, but when the incubation was continued for a long time, the cells migrated actively and gathered. Thymidine incorporation by the cells was suppressed on both modified collagen gels as compared with that on untreated collagen gel, and the extent of the suppression on the H2O2-copper-treated collagen was larger than that on the ascorbate-copper-treated collagen. These results indicate that the active oxygen-induced cross-linking and degradation significantly alter properties of collagen as a substratum for fibroblasts.     

Myelinated axons of ganglion cells in the retinae of teleosts

In the retina of the goldfish and the rainbow trout, the axons of ganglion cells belong to the unmyelinated or the myelinated types. The unmyelinated fibers are either arranged in bundles in direct contact with neighboring fibers or they are separated by intervening lamellae of oligodendroglial cytoplasm. The myelin sheaths of the myelinated fibers differ greatly in thickness. Most fibers show 3 to 5 myelin layers; single fiber elements, however, show 10 or even more layers.     

Requirement for Brn-3b in early differentiation of postmitotic retinal ganglion cell precursors

Postnatal development of the spinal cord serotonergic (5-HT) system and of swimming movements were studied in newborn Sprague-Dawley rats, in which the serotonin level in the central nervous system was lowered in the prenatal period. For this purpose, para-chlorophenylalanine (PCPA) (300 mg/kg) was administered intraperitoneally to pregnant mother rats on day 8 of gestation, followed by a daily injection of PCPA (80 mg/kg) from day 9 of gestation to delivery. The postnatal development of the 5-HT system in the spinal cord of the pups (PCPA-treated pups) born from the PCPA-administered mothers was markedly delayed during the period between PND 1 and PND 10 in comparison to that in the control pups born from healthy mothers. Postnatally, the control pups developed their swimming movements regularly through three distinct phases: forelimb dominant, forelimb and hindlimb well coordinated, hindlimb dominant. In contrast, in the PCPA-treated pups, swimming movements were disorganized during the period in which the development of 5-HT system was delayed. However, between PND 17 and 22 in which the 5-HT system developed to that extent observed in the control pups, the pups eventually developed swimming movements as observed in the control pups. These results suggest that the disorganized developmental process of swimming movements in the PCPA-treated pups is due to the possible failure in the prenatal and postnatal development of the 5-HT system and its target system in the brain stem and the spinal cord.     

Regeneration of retinal axons into the goldfish optic tectum

The growth of regenerating retinal axons into the central portion of the optic tectum of adult goldfish was examined with the light and electron microscopes. Optic tracts were cut and, two days to five months later, the animals were perfused and the tecta prepared for microscopy. Regenerating axons first reached central regions of the tectum seven to ten days postoperatively. Regenerating axons appear in very large numbers and travel in fascicles in the stratum opticum (SO) and in the adjacent neuropil, the stratum fibrosum et griseum superficiale (SFGS). In the SO, the fascicles are bordered by glial cells and degenerating debris. Within the SFGS, however, the fascicles do not seem to be similarly associated with glial cells and degenerating debris. The youngest regenerating axons are very slender processes, containing microtubules but few or no neurofilaments or dense granular material. By 10 to 14 days postoperatively, neurofilaments can be seen and, in addition, large numbers of vesicles with dense cores appear. The vesicles with dense cores increase in numbers until about 28 days postoperatively and then become quite rare. That vesicles with dense cores were seen in regenerating axons in both SO and SFGS during the period of growth into the tectum but were not seen in axon terminals at any time, suggests that they may be concerned with axon elongation. During the period one month to five months postoperatively, the regenerating axons gradually increase in diameter but do not reach preoperative sizes, suggesting that the regenerative changes may still be occurring. Remyelination is delayed and proceeds slowly. Many axons remain unmyelinated for as long as five months postoperatively.     

The receptive field of the primate P retinal ganglion cell, II: Nonlinear dynamics

The ganglion cells of the primate retina include two major anatomical and functional classes: P cells which project to the four parvocellular layers of the lateral geniculate nucleus (LGN), and M cells which project to the two magnocellular layers. The characteristics of the P-cell receptive field are central to understanding early form and color vision processing (Kaplan et al., 1990; Schiller & Logothetis, 1990). In this and in the following paper, P-cell dynamics are systematically analyzed in terms of linear and nonlinear response properties. Stimuli that favor either the center or the surround of the receptive field were produced on a CRT and modulated with a broadband signal composed of multiple m-sequences (Benardete et al., 1992b; Benardete & Victor, 1994). The first-order responses were calculated and analyzed in this paper (part I). The findings are: (1) The first-order responses of the center and surround depend linearly on contrast. (2) The dynamics of the center and surround are well described by a bandpass filter model. The most significant difference between center and surround dynamics is a delay of approximately 8 ms in the surround response. (3) In the LGN, these responses are attenuated and delayed by an additional 1-5 ms. (4) The spatial transfer function of the P cell in response to drifting sine gratings at three temporal frequencies was measured. This independent method confirmed the delay between the (first-order) responses of the center and surround. This delay accounts for the dependence of the spatial transfer function on the frequency of stimulation.