Inaccuracies in initial growth and arborization of chick retinotectal axons followed by course corrections and axon remodeling to develop topographic order.

The retinotectal projection is organized in a precise retinotopic manner. We find, though, that during development the growth and arborization of temporal retinal axons within the optic tectum of chick embryos is initially imprecise. Axonal targeting errors occur along the rostral-caudal and medial-lateral tectal axes, and arbors are formed at topographically inappropriate positions. Subsequent course corrections along both tectal axes and large-scale axonal remodeling lead to the retinotopic ordering of terminal arborizations characteristic of the mature projection. The trajectories and branching patterns of temporal retinal axons labeled with Dil or DiO were determined in whole mounts of retina and tectum from chicks ranging in age from embryonic day 9 to posthatching. Within the retina, labeled retinofugal axons travel in a compact bundle but do not maintain strict neighbor relations, as they course to the optic fissure. The axons enter the contralateral tectum at its rostral edge and grow caudally. Many extend well past their appropriate terminal zone within rostral tectum; a proportion of these later reverse their direction of growth. Many axons grow onto the tectum at incorrect positions along the medial-lateral tectal axis. Some correct this error in a directed manner by altering their trajectory or extending collateral branches at right angles. About 80% of the positional changes of this type are made in the direction appropriate to correct axon position, and thus are likely a response to tectal positional cues. After maturation of retinotopic order, about half of the axons that project to a mature terminal zone have made abrupt course corrections along one or both tectal axes, indicating that initially mistargeted axons can establish appropriately positioned arbors and survive. The development of temporal axons within the tectum is characterized by 3 phases: elongation, branch and arbor formation, and remodeling. After considerable rostrocaudal elongation, an axon typically develops numerous side branches and arbors, many at inappropriate locations. Most arbors are formed by side branches that develop as interstitial collaterals; few axons grow directly to their appropriate terminal zone and arborize. Aberrant arbors, and axons and axon segments that fail to form arbors in the appropriate terminal zone, are rapidly eliminated over about a 2 d period. Axon degeneration appears to play a role in this remodeling process.

Elicitation of spreading depression by rose bengal photodynamic action.

Spreading depression refers to a slowly propagating depression of the ordinary electrical activity of the nervous tissue. It can be elicited by different types of physical or chemical non-specific stimuli. Various evidences suggest that transient alterations of cell membranes are involved. For this reason, and considering the action of free radicals on cell membranes, the elicitation of the reaction by dye photoactivation has been investigated. Isolated chick retina superfused in the dark with Ringer solution was able to regularly exhibit spreading depression when submitted to 1 microM rose bengal pulse of 5 min in duration, followed by 2.1 x 10(4) to 4.2 x 10(4) Jm-2 light pulse. The phenomenon was monitored either by visual inspection of the light-scattering milky wave that accompanies the reaction or by recording its characteristic slow voltage variation. The reaction was not triggered if the retina, superfused with the dye, was (a) maintained in the dark; (b) illuminated with red light (3.75 x 10(2) to 2.25 x 10(4) Jm-2), or (c) stimulated by white light but superfused with nitrogen-saturated solutions. It is concluded that, under the present conditions, the elicitation of spreading depression is contingent on the photoactivation of rose bengal in the presence of oxygen.

[Light-optic, electron microscopic and electrophysiological study of centrifugal fibers of the retina in the lamprey Lampetra fluviatilis]. / Svetopticheskoe, élektronno-mikroskopicheskoe i élektrofiziologicheskoe issledovanie tsentrobezhnykh volokon v setchatki minogi Lampetra fluviatilis.

Light and electronmicroscopic studies have been made on retinal structures in the lamprey labeled by horseradish peroxidase injected into the peripheral end of the cut optic nerve or to the midbrain tectum. On total retinal preparations, labeled axons were revealed together with dendrites and ganglionic cell bodies, as well as branching (presumably retinopetal) fibers, fine endings of which come closely to the labeled dendrites of the ganglionic cells. Electron microscopic data indicate that the labeled terminations of afferent fibers from synapses with both labeled and unlabeled dendrites, as well as with unlabeled neuronal bodies. It is concluded that centrifugal fibers in lamprey retina form contacts with the bodies and dendrites of the amacrine cells and dendrites of the ganglionic cells. Results of intracellular registration of responses of various retinal elements to the electrical stimulation of the optic nerve support this conclusion.

Retinal projection to mammalian telencephalon.

Retinal projections were studied in species from 8 orders of mammals using anterograde tracing techniques. The olfactory tubercle of basal telencephalon receives a projection from the retina in all animals. In all species the course of labelled fibers is similar and the terminal distribution of label along the internal border of the granular cell layer is restricted to the mediocaudal region of the tubercle. These shared characteristics suggest that this pathway is a typical mammalian feature, possibly providing for convergence of visual and chemosensory information in telencephalon.

Very large neurons of the inner retina of humans and other mammals.

Large ganglion cells, called parasol cells, are known to occur in the Golgi-stained, human retina. This report describes a population of much larger cells that is not stained by Golgi technique. These cells may be located in the human ganglion cell layer using Nomarski differential interference contrast optics and unstained, flatmounted tissue. These cells are regularly distributed in young and old adults in a Gaussian fashion along the radii that extend from the perimacula toward the far periphery. The author did not find the cells in the central retina. The most frequent (J-type) cells have soma diameters between 26 and 40 microns. Rare (S-type) cells measure up to 55 microns in diameter. Many cells have processes that appear to be axons or dendrites. These cell types may be especially sensitive to damage early in diseases of the inner retina.

Cell sorting out: the self-assembly of tissues in vitro.

The question posed by the science of analytical histology is how the properties and interactions of the components of the tissues determine their organization in the organs. The relevant components of the tissues are the cells and the extracellular matrix. The ability of cohering populations of cells to self-assemble structured tissues by cell sorting out offers an important opportunity for the experimental study of the mechanisms by which the cells and extracellular matrix interact to determine structure. The investigator can manipulate the initial organization and the cellular composition of the system and, in favorable situations, the composition of the extracellular matrix and the activities of candidate adhesive molecules. It can reasonably be expected that the recent progress in the characterization of the molecular species involved in cell-cell and cell-extracellular matrix interaction will allow the analysis of the molecular basis of tissue organization, with study of the self-assembly of tissue structure during sorting out playing an important role in this analysis. The importance of the differential adhesion hypothesis is its success in describing the rules by which macroscopic tissue structure is governed by the adhesive interactions of cell with cell and cell with extracellular matrix. The DAH describes how the physical forces of cell-cell and cell-matrix adhesion determine structure. Elucidation of the particular adhesive molecules involved in these interactions (e.g., the CAMs, junctional proteins, and matrix adhesion molecules) will yield an explanation at the biochemical level. A complete understanding of structure requires both levels of explanation.

Neurofibrillar long-range amacrine cells in mammalian retinae.

A distinct population of wide-field, unistratified amacrine cells are shown to be selectively stained by using neurofibrillar methods in rabbit and cat retinae. Their cell bodies may be located in the inner nuclear, inner plexiform or ganglion cell layers and they branch predominantly in stratum 2 of the inner plexiform layer. Characteristically, each cell has two or more long-range distal processes which extend for 2-3 mm beyond a more symmetrical, proximal dendritic field of 0.6-0.8 mm diameter. Although the neurofibrillar long-range amacrines account for less than 1 amacrine in 500, they achieve effective coverage of the retina by both the proximal and distal dendrites.

Efferent neurotransmission of circadian rhythms in Limulus lateral eye. II. Intracellular recordings in vitro.

We investigated efferent neurotransmission in the Limulus lateral eye by studying the action of pharmacological agents on responses of photoreceptor cells in vitro. We recorded transmembrane potentials from single cells in slices of retina that were excised during the day and maintained for several days in a culture medium. Potentials recorded in the absence of pharmacological agents resemble those recorded from cells in vivo during the day. Octopamine, a putative efferent neurotransmitter, induced changes in photoreceptor potentials that mimicked in part those generated at night by a circadian clock located in the brain. Specifically, octopamine (100 to 500 microM) decreased the frequency of occurrence of quantum bumps in the dark and increased the amplitude of photoreceptor responses to intermediate and high light intensities. Similar actions were produced by naphazoline (25 to 100 microM, potent agonist of octopamine), forskolin (8 to 400 microM, activator of adenylate cyclase), IBMX (1 mM, inhibitor of phosphodiesterase), and 8-bromo-cAMP (500 microM, analogue of cAMP). 8-bromo-cGMP (500 microM, analogue of cGMP) decreased the rate of spontaneous quantum bumps only. Our results support the hypothesis that (1) octopamine is an efferent neurotransmitter of circadian rhythms in the Limulus eye and that (2) it activates adenylate cyclase to increase levels of the second messenger, cAMP, in photoreceptor cells. Circadian changes in photoreceptor responses to moderate intensities may be a specific action of cAMP, since cGMP has no effect. Circadian changes in the rate of spontaneous quantum bumps may involve a less specific intermediate, since both cAMP and cGMP reduce bump rate. Characteristics of the retinal slice preparation precluded a detailed study of the effects of pharmacological agents on retinal morphology.

A quantitative analysis of glial cell coupling in the retina of the axolotl (Ambystoma mexicanum).

The strength of gap junctional coupling of radial glial cells (Müller cells) in the isolated axolotl retina was assessed by monitoring the spread of dye between cells, and by injecting current into one cell and recording the voltage response in surrounding cells. Dye injected into one Müller cell spread to surrounding Müller cells, and could be detected up to 130 micron away, i.e. over 4 times the mean Müller cell spacing of 30 micron. Injecting 1 nA of current into a Müller cell evoked responses of 7 mV in that cell, 1 mV in next neighbour cells, and 0.2 mV in cells at 60 micron distance. Analysis of these data indicates an electrical space constant for the Müller cell network of 15 micron, and predicts that isolated cells should have a resistance of 11.4 M omega. Müller cells isolated by papain dissociation of the retina were found, by whole-cell patch-clamping, to have a mean resistance of 12.4 M omega. These results on lateral coupling are combined with data showing that over 90% of the Müller cell potassium conductance is in the vitreal endfoot of these cells to provide a fairly complete electrical description of the radial glial cell network in the retina. Gap junctional coupling of Müller cells increases by 60% the 'spatial buffering' that these glial cells can carry out to reduce localized rises in extracellular potassium concentration. The location of the majority of the Müller cell potassium conductance in the cell endfoot ensures that laterally buffered K+ is deposited in the vitreous, rather than depolarizing surrounding retinal neurones.

FMRFamide-like immunoreactive neurons of the nervus terminalis of teleosts innervate both retina and pineal organ.

The tetrapeptide FMRFamide (Phe-Met-Arg-Phe-NH2) was first isolated from molluscan ganglia. Subsequently, it has become clear that vertebrate brains also contain endogenous FMRFamide-like substances. In teleosts, the neurons of the nervus terminalis contain an FMRFamide-like substance, and provide a direct innervation to the retina (Proc. Natl. Acad. Sci. U.S.A., 81 [1984] 940-944). Here we report the presence of FMRFamide-immunoreactive axonal bundles in the pineal organ of Coho salmon and three-spined sticklebacks. The largest numbers of axons were observed proximal to the brain, in the pineal stalk, while the distal part of the pineal organ contained only few axons. No FMRFamide-like-immunoreactive (IR) cell bodies were observed in the pineal organ. In adult fish it was not possible to determine the origin of these axons, due to the large numbers of FMRFamide-like IR axons in the teleost brain. However, by following the development of FMRFamide-like IR neurons in the embryonic and larval stickleback brain, it was possible to conclude that, at least in newly hatched fish, FMRFamide-like IR axons that originate in the nucleus nervus terminalis reach the pineal organ. Thus, it seems there is a direct connection between a specialized part of the chemosensory system and both the retina and the pineal organ in teleost fish.

The retinal nerve fiber layer, neuroretinal rim area, and visual evoked potentials in MS.

In a prospective study of 57 patients with clinically definite, probable, or possible multiple sclerosis (MS), one-half of whom had a history of optic neuritis, retinal nerve fiber layer (RNFL) defects and the neuroretinal rim (NRR) area were quantitatively determined and compared with the visual evoked potential (VEP). There were abnormal VEP latencies in 63% of all patients (definite and probable = 68%, possible = 50%); local or diffuse RNFL defects in 54%, (definite and probable = 54%, possible = 50%); and an abnormally small NRR area in 30% (definite and probable = 32%, possible = 25%). Abnormalities in one or more of the VEP, RNFL, or NRR area occurred in 86% of all patients (definite and probable = 90%, possible = 75%), thus considerably increasing the yield of optic nerve abnormalities over that of the VEP alone. The predominance and extent of the diffuse RNFL defects, which are axonal abnormalities, suggest a more diffuse optic nerve pathology in MS than can be accounted for by a "plaque" pathology and indicate that extensive axonal loss commonly occurs in the optic nerves of MS.

Loss of entrainment and anatomical plasticity after lesions of the hamster retinohypothalamic tract.

The suprachiasmatic nuclei receive photic input information directly through a retinohypothalamic tract (RHT) and indirectly through a projection from the intergeniculate leaflet of the lateral geniculate complex, the geniculohypothalamic tract (GHT). Prior work has established that the RHT is sufficient for entrainment, but has not shown whether it is necessary because it has not been possible to transect that pathway. The present study addresses this problem by employing knife cuts to sever the RHT in male hamsters. Three knife cut procedures were used and one of these succeeded in separating the SCN from the optic chiasm in 8 animals with limited damage to the chiasm and the SCN. The effectiveness of the RHT lesion was confirmed by cholera toxin-HRP histochemistry which demonstrated that the knife cuts eliminate the normal retinal innervation of the SCN while sparing projections to thalamic and tectal visual centers. In a light-dark cycle, the lesioned animals exhibit free-running rhythms indicating that the RHT is necessary for entrainment. A surprising observation is the presence of extensive axonal sprouting of retinal fibers in brains of animals with RHT lesions. The newly-formed axons grow extensively into the SCN, anterior hypothalamus and basal forebrain, but form anomalous axonal plexuses which have no evident function.

Aberrant growth of regenerating retinotectal axons subsequent to optic tract ablation in goldfish.

This study examined the effect of optic tract ablation on retinotectal fiber regeneration in goldfish. Approximately two-thirds of the left optic tract was removed, and, at various times post lesion (10-75 days), the course of regenerating retinotectal fibers was traced using horseradish peroxidase. In all experimental animals, axons were observed regenerating through the visual pathway but at the brachia most of the fibers were channeled through the ventral brachium. We present evidence that fibers in the ventral brachium originated from ganglion cells in all regions of retina and that these fibers grew almost exclusively into ventral half tectum even though some of these fibers would normally synapse in dorsal half tectum. These observations suggest that optic tract ablation does not prevent retinal fiber regeneration but results in aberrant growth through the brachia and significant inhibition of exploratory fiber growth within the tectum.

Distribution of morphologically different retinal axon terminals in the hamster dorsal lateral geniculate nucleus.

Afferent terminal arbors in the hamster LGBd were labelled with horseradish peroxidase (HRP) implanted into the optic tract. Three morphologically distinct terminal types, each with a different regional distribution, were observed. Type R1 terminals are large, ovoid swellings and are predominantly distributed medially within the nucleus. Type R2 terminals are very small, clustered varicosities and are distributed laterally and ventrally. Type R3 terminals are medium in size and their distribution overlaps with that of Type R1 and R2 terminals.

Acute retinal necrosis syndrome presenting with papillitis and arcuate neuroretinitis.

Acute retinal necrosis (ARN) syndrome is a diffuse uveitis characterized by a peripheral necrotizing retinitis and retinal vasculitis. The authors document and discuss a case of ARN syndrome that initially presented with remarkable changes in the peripapillary retinal nerve fiber layer that they have termed arcuate neuroretinitis. These changes consisted of a well-defined arcuate band of retinitis paralleling the course of a parafoveal nerve fiber bundle. Evaluation of serial serum antibody titers suggests HSV-2 as a possible causative agent in this unique presentation of ARN syndrome.

Histochemical localization of cytochrome oxidase activity in the visual system of the tree shrew:normal patterns and the effect of retinal impulse blockage.

The tree shrew Tupaia belangeri has three functional pathways (ON-center, OFF-center, and W-like cells) that arise in the retina and proceed through separate LGN laminae to separate cortical targets. To determine whether these pathways have consistent differences in activity, cytochrome oxidase (C.O.) patterns were examined in the retina, LGN, and striate cortex. In six normal tree shrews the outer and inner plexiform layers of the retina were highly reactive for C.O. A pale, vascularized cleft zone separated the a (OFF) and b (ON) inner plexiform sublaminae, which seemed about equally reactive for C.O. In the LGN, laminae 1 and 2 (ON-center cells) and laminae 4 and 5 (mostly OFF-center cells) were highly reactive for C.O. LGN lamina 3 and 6 are part of an W-like afferent pathway. Lamina 3 was distinctly paler than laminae 1, 2, 4, and 5 while lamina 6 was intermediate. In the striate cortex, layer IV was the most reactive layer. Sublayer IVb (predominantly an OFF region) was consistently more reactive than sublayer IVa (predominantly ON). The middle portion, layer IVm, was paler than either IVa or IVb. This paler region includes, but extends above and below, the cell-sparse "cleft" region. Thus, considering all three levels of the retinogeniculostriate pathway, the ON and OFF systems were equally active until they reached the striate cortex, where the OFF system appeared to be more active than the ON. The W-cell laminae in the LGN exhibited the lowest level of activity. The contribution of ganglion cell activity to these patterns was assessed by intravitreal administration of tetrodotoxin (TTX) blockade either monocularly (three animals) or binocularly (two animals). In the TTX-treated retinae, the inner plexiform a and b sublaminae were paler for C.O., although visible, and were still separated by the pale cleft. The ganglion cell layer was very pale in comparison to the normal. In the LGN, monocular TTX blockade reduced the C.O. reactivity in the ON and OFF laminae that received input from the treated eye but had little effect on the W-like cell laminae. The ipsilaterally innervated ON and OFF laminae were more affected than were the contralaterally innervated laminae. Binocular TTX treatment resulted in a decrease of C.O. activity in the binocular segment of the ON and OFF LGN laminae. In the striate cortex, the most marked changes following TTX treatment occurred in layer IV.(ABSTRACT TRUNCATED AT 400 WORDS)

Light microscopic localization of putative glycinergic neurons in the larval tiger salamander retina by immunocytochemical and autoradiographical methods.

Putative glycinergic neurons in the larval tiger salamander retina were localized by a comparative analysis of high affinity 3H-glycine uptake and glycine-like immunoreactivity (Gly-IR) at the light microscopic level. Commonly labeled neurons include at least three types of amacrine cell (Type IAd, Type IAb, Type IIAd; distinguished by soma location and dendritic ramification), cell bodies in the ganglion cell layer (GCL), and rarely observed Type II (inner) bipolar cells. With the increased resolution provided by Gly-IR, we identified a Type IAa amacrine cell, two types of Type IIAd amacrine cells, and Gly-IR interplexiform cells. Gly-IR axons in longitudinal sections of the optic nerve indicate the presence of Gly-IR ganglion cells. The percentage of labeled somas in the inner nuclear layer (INL) compared to all cells in each layer was similar for the two methods: 30-40% in INL 2 (middle layer of somas), 30-40% in INL 3 (inner layer of somas), and about 5% in the GCL. Labeled processes were found throughout the full thickness of the inner plexiform layer (IPL), but with a much denser band in the proximal half (sublamina b). The only major difference between the two methods (3H-glycine uptake vs. Gly-IR) was that Type I (outer) bipolar cells were labeled only by 3H-glycine uptake; these cells were more lightly labeled with silver grains than cell bodies in either INL 2 or INL 3. Postembed labeling of 1 micron Durcupan plastic sections for Gly-IR showed the same pattern, but with much higher resolution, as obtained with 10 micron cryostat sections. This study indicates extensive colocalization of labeling by both probes in INL 2, INL 3, the IPL, and the GCL. We conclude that Gly-IR can serve as a valid and reliable marker for glycine-containing neurons in this retina and suggest that glycine serves as a transmitter for several morphologically distinct types of amacrine cell, an interplexiform cell, and perhaps a small percentage of Type II bipolar cells and ganglion cells.

Putative neurotransmitters in the retinae of three urodele species (Triturus alpestris, Salamandra salamandra, Pleurodeles waltli).

The immunocytochemical localization of several substances with putative neurotransmitter or modulator properties was investigated in the retinae of three urodele species. Gamma-aminobutyric acid-like immunoreactive labelling appeared in different types of amacrine and horizontal cells. In addition, labelled fibres in the optic nerve were detected. It was not possible to determine whether these fibres were ganglion-cell axons or part of an efferent projection. Endogenous serotonin was found in several populations of amacrine cells including stratified and diffuse types. Glucagon-like immunoreactivity appeared in one bistratified amacrine cell type, and neurotensin-like immunoreactivity was detected in a single monostratified amacrine cell type. Metenkephalin-like-immunoreactive labelling was type. Metenkephalin-like-immunoreactive labelling was rare but found in several sublaminae of the inner plexiform layer. Thus each peptide-like-immunoreactive cell type makes up a distinct and unique population of cells and probably has a special functional role in retinal processing. There are striking similarities in the peptide-like immunoreactive patterns of Triturus alpestris and Necturus maculosus whereas in Ambystomatidae the peptide-like-immunoreactive systems appear to be differently organized. This supports the hypothesis that Salamandridae and Proteidae are more closely related to each other than to the Ambystomatidae.

The effect of altered neuronal activity on the development of layers in the lateral geniculate nucleus.

The main objective of this study was to examine the role of neural activity in the development of cell layers in the dorsal lateral geniculate nucleus (LGN). We studied this relationship in postnatal tree shrews either by completely blocking retinal ganglion cell activity with TTX or by selectively blocking activity to the developing ON-center LGN layers (1 and 2) with 2-amino-4-phosphonobutyric acid (APB), using unilateral and bilateral eye injections. All manipulations were carried out from birth (P0), when no LGN cell layers are evident, to or past the point when layers are recognizable (i.e., 1-2 weeks). Nissl-stained and cytochrome oxidase (CO)-reacted material was examined for all cases. Our results show that in the absence of activity produced by bilateral TTX injections, interlaminar spaces between cell layers do begin to develop. Retinal afferents, which are segregated at birth, remain segregated, and differential CO staining between matched sets of LGN layers is evident. The normal pace of LGN development, however, is slowed significantly: LGN cells are smaller and interlaminar spaces are narrower than are seen in age-matched controls. Unilateral TTX injections produce similar, but more dramatic and asymmetric, effects on LGN cells, perhaps because cells are at a competitive disadvantage relative to their normally innervated counterparts in cortex. Combining unilateral eye enucleation at P0 with subsequent TTX treatment of the other eye clearly demonstrates that axons from the remaining eye are capable of producing their normal complement of LGN layers. The development of the LGN ON-center layers, 1 and 2, and the interlaminar space between them are more affected by TTX treatment than are the other layers. By contrast, APB eye injections do not selectively affect the development of the ON-center layers, but do result in some slowing of overall LGN development. Taken together, these results suggest that activity of retinal afferents is not essential for initiating interlaminar space formation, but is important for the normal pace of maturation of LGN cell layers.