Susan B. Udin

Permanent disorganization of the regenerating optic tract in the frog

Abstract The organization of the optic tract as it regenerates following optic nerve transection in adult frogs was studied using microelectrode recordings from optic nerve arborizations in the tectum. In normal frogs, a cut extending from the midline partway across the rostromedial margin of the tectum severs optic axons with receptive fields in the temporosuperior quadrant of the visual field. During regeneration, however, a similar cut spares many axons with temporosuperior fields. This result implies that some fibers which normally enter the tectum via the most medial parts of the optic tract regenerate through other parts of the tract. Despite their anomalous routes, many of these fibers eventually terminate at the appropriate locations in the tectum.

Influencing and Interpreting Visual Input: The Role of a Visual Feedback System

Vertebrates are able to visually identify moving objects and orient toward attractive ones or escape if the objects seem threatening. When there is more than one object in the visual field, they can attend to a particular object. The optic tectum (superior colliculus in mammals) (OT/SC) has long

Effects of choline and other nicotinic agonists on the tectum of juvenile and adult Xenopus frogs : A patch-clamp study

We have used anatomical methods and whole-cell patch-clamp recording to assess the distribution of nicotinic receptors in the tectum of Xenopus frogs and to measure effects of nicotinic ligands (carbachol, cytisine and nicotine) on glutamatergic spontaneous miniature excitatory postsynaptic currents. Our results confirm that retinotectal axons account for the majority of nicotinic receptors in the tectum and that nicotinic agonists exert presynaptic effects that increase the rate of transmitter release on to tectal cells. The nicotinic blockers mecamylamine and methyllycaconitine reduced responses to carbachol and cytisine. A small percentage of cells also showed postsynaptic responses. We have assessed whether there are developmental changes in the frequency of occurrence of spontaneous miniature excitatory postsynaptic currents. The first three months post-metamorphosis fall within the critical period for the dramatic plasticity displayed by binocular inputs during development in Xenopus. During this period, visual activity governs the formation of orderly maps relayed from the ipsilateral eye via the cholinergic projection from the nucleus isthmi to the tectum. In this study, we have found that critical-period tecta (two to 12 weeks postmetamorphosis) tend to have higher spontaneous activity than do older tecta (two to 69 weeks postmetamorphosis), and that nicotinic agonists increase that activity in both groups, with the result that the peak rates in response to nicotinic agonists are higher during the critical period than later. We also investigated the possible role of choline as an agonist of nicotinic receptors in the tectum. We have found that choline, as well as carbachol and cytisine, can cause a reversible increase in the rate of miniature excitatory postsynaptic currents. This result may help to explain how the isthmotectal projection, which accounts for the overwhelming majority of cholinergic input to the tectum, can exert effects on retinotectal terminals even though there are no morphologically identifiable synapses between the two populations. We have examined the morphology of cells filled with biocytin during the patch-clamp experiments, and we find that cells with dendrites in the stratum zonale, a layer with particularly dense input from the contralateral nucleus isthmi, have higher spontaneous activity than cells with dendrites that do not extend into that layer. Nicotinic agonists increased the activity recorded in both classes of cells. In addition, four pretectal cells were identified. Nicotinic agonists increased the rate of spontaneous activity recorded in that population. The results indicate that retinotectal transmission in the superior colliculus can be increased presynaptically by activity of the cholinergic projections of the nucleus isthmi. This modulation may be the basis for observations that blocking of cholinergic input disrupts the formation of topographic retinotectal projections. Moreover, the ability of choline to activate these receptors suggests that this metabolite of acetylcholine may permit paracrine activation of presynaptic receptors even though the tectum contains high acetylcholinesterase activity.

Ultrastructure and GABA Immunoreactivity in Layers 8 and 9 of the Optic Tectum of Xenopus laevis

This study presents an ultrastructural analysis of layers 8 and 9 in the optic tectum of Xenopus laevis. Retinotectal axons were labelled with horseradish peroxidase and tectal cells were labelled with antibody to GABA. Four distinct axonal and dendritic structures were identified. GABA‐negative axon terminals formed asymmetric synapses and were categorized as type a‐1 (which included retinotectal axons), characterized by medium size synaptic vesicles and pale mitochondria, and type a‐2 (non‐retinotectal) with large vesicles and dense mitochondria. GABA‐negative dendrites (type d) contained dense mitochondria, microtubules in the dendritic shafts, and dendritic spines devoid of microtubules. GABA‐positive structures contained small synaptic vesicles and dense mitochondria. Some dendrites (type D) were not only postsynaptic but were also presynaptic elements, as defined by the presence of vesicles and distinct synaptic clefts with symmetric specializations. GABA‐positive presynaptic structures were mostly located in vesicle‐filled, bulbous extensions of dendritic shafts and usually terminated onto dendritic spines. Some type D dendrites were the middle element in serial synapses, with input from either GABA‐positive or GABA‐negative structures and output to GABA‐negative structures. Retinotectal terminals were identified as one of the synaptic inputs to GABA‐positive processes. Glia were characterized by granular cytoplasm and large mitochondria, often displaying a crystalline matrix structure. These results indicate that GABA‐positive neurons are a prominent component of circuitry in the superficial layers of the tectum of Xenopus and that, as in mammals, they participate in serial synaptic arrangements in which retinotectal axons are the first element. These arrangements are consistent with complex processing of visual input to the tectum and a central role for inhibitory processes in the shaping of tectal responses.

Dual origins of the mammalian accessory olfactory bulb revealed by an evolutionarily conserved migratory stream

The accessory olfactory bulb (AOB) is a critical olfactory structure that has been implicated in mediating social behavior. It receives input from the vomeronasal organ and projects to targets in the amygdaloid complex. Its anterior and posterior components (aAOB and pAOB) display molecular, connectional and functional segregation in processing reproductive and defensive and aggressive behaviors, respectively. We observed a dichotomy in the development of the projection neurons of the aAOB and pAOB in mice. We found that they had distinct sites of origin and that different regulatory molecules were required for their specification and migration. aAOB neurons arose locally in the rostral telencephalon, similar to main olfactory bulb neurons. In contrast, pAOB neurons arose caudally, from the neuroepithelium of the diencephalic-telencephalic boundary, from which they migrated rostrally to reach their destination. This unusual origin and migration is conserved in Xenopus, providing an insight into the origin of a key component of this system in evolution.

The role of visual experience in the formation of binocular projections in frogs

Summary1.Many parts of the visual system contain topographic maps of the visual field. In such structures, the binocular portion of the visual field is generally represented by overlapping, matching projections relayed from the two eyes. One of the developmental factors which helps to bring the maps from the two eyes into register is visual input.2.The role of visual input is especially dramatic in the frog,Xenopus laevis. In tadpoles of this species, the eyes initially face laterally and have essentially no binocular overlap. At metamorphosis, the eyes begin to move rostrodorsally; eventually, their visual fields have a 170° region of binocular overlap. Despite this major change in binocular overlap, the maps from the ipsilateral and contralateral eyes to the optic tectum normally remain in register throughout development.3.This coordination of the two projections is disrupted by visual deprivation. In dark-rearedXenopus, the contralateral projection is nearly normal but the ipsilateral map is highly disorganized.4.The impact of visual input on the ipsilateral map also is shown by the effect of early rotation of one eye. Examination of the tectal lobe contralateral to the rotated eye reveals that both the contralateral and the ipsilateral maps to that tectum are rotated, even though the ipsilateral map originates from the normal eye. Thus, the ipsilateral map has changed orientation to remain in register with the contralateral map. Similarly, the two maps on the other tectal lobe are in register; in this case, both projections are normally oriented even though the ipsilateral map is from the rotated eye.5.The discovery that the ipsilateral eyes map reaches the tectum indirectly, via a relay in the nucleus isthmi, has made it possible to study the anatomical changes underlying visually dependent plasticity. Retrograde and anterograde tracing with horseradish peroxidase have shown that eye rotation causes isthmotectal axons to follow abnormal trajectories. An axons route first goes toward the tectal site where it normally would arborize but then changes direction to reach a new tectal site. Such rearrangements bring the isthmotectal axons into proximity with retinotectal axons which have the same receptive fields.6.Anterograde horseradish peroxidase filling has also been used to study the trajectories and arborizations of developing isthmotectal axons. The results show that the axons enter the tectum before the onset of eye migration but do not begin to branch profusely until eye movement begins to create a zone of binocular space. Throughout the period of greatest eye movement, many isthmotectal arbors are larger and more diffuse than in older animals.7.A proposal, based on the Hebb-synapse model, is offered to explain how interactions of isthmotectal axons with other isthmotectal axons and with retinotectal axons could help to organize the ipsilateral map and bring it into alignment with the contralateral map.

Polysialylated neural cell adhesion molecule and plasticity of ipsilateral connections in Xenopus tectum

The optic tectum of Xenopus offers a readily manipulated system for testing the hypothesis that polysialylation of the neural cell adhesion molecule is associated with axonal plasticity. Axons relaying input to the tectum from the ipsilateral eye employ visual input to establish a topographic map in register with the contralateral map, despite naturally-occurring or surgically-induced repositioning of the eyes. This capacity for activity-dependent refinement or re-organization of the ipsilateral map is normally confined to a period between about one and four months postmetamorphosis but can be restored in adults by local application of N-methyl-D aspartate to the tectum. In addition, dark-rearing prolongs plasticity indefinitely. We have used immunohistochemical staining with antibodies to polysialic acid to determine whether conditions of high plasticity are correlated with high levels of polysialylated neural cell adhesion molecule in the tectum. We find that the staining level is high in tecta from one to three month postmetamorphic frogs but is low both before and after this period. Thus, in normal Xenopus frogs, anti-polysialic acid staining is heavier in the period of high plasticity than in the preceding or following postmetamorphic periods. As a further test of this relationship, we examined brains of adults with experimentally-induced plasticity. Tecta of N-methyl-D-aspartate-treated adults and of dark-reared adults showed higher levels of staining than did the tecta of normally-reared adults. These results also support the hypothesis that the presence of high levels of polysialic acid on neural cell adhesion molecules is causally related to activity-related changes in axonal growth patterns.

Latency and temporal overlap of visually elicited contralateral and ipsilateral firing in Xenopus tectum during and after the critical period

The mechanisms underlying the development of proper topographic registration of binocular maps in the tectum of Xenopus laevis involve correlation of activity patterns of ipsilateral and contralateral inputs. Recent evidence implicates NMDA-type glutamate receptors in this process. In general, NMDA receptors are considered to function optimally when there are multiple, simultaneous excitatory inputs to a dendrite. In the binocular system of the frog, however, the ipsilateral eyes response to a visual stimulus reaches the tectum later than the contralateral eyes response. The reason for this delay is that the ipsilateral pathway to the tectum is indirect, involving a relay in the opposite tectum and nucleus isthmi. In this paper, we evaluate the duration of the delay between arrival of contralateral and ipsilateral input in response to cessation of light and we also gauge the extent of temporal overlap in responses of the two inputs. We find that the average delay is about 10 ms and that this delay is not significantly different during the critical period vs later in development. The temporal overlap is 40-60 ms in duration. We conclude that the intertectal delay does not prevent a substantial period of simultaneous firing of ipsilateral and contralateral inputs in response to sudden changes in illumination. Therefore, the firing patterns of these afferents are compatible with a mechanism of activity-dependent alignment of binocular maps in the tectum.

Expansion and retinotopic order in the goldfish retinotectal map after large retinal lesions

SummaryA peripheral annulus of neural retina and pigment epithelium was removed from the eye of adult goldfish. After survival times from 148 to 560 days, the retinotectal projection from the remaining central fragment was mapped. In most cases, the map was orderly and had expanded to fill the entire contralateral tectum, but when less than 10–15% of the original retina remained intact, the projection failed to fill the entire available tectal space and was abnormally disordered.

Compressed retinotectal projection in hamsters: fewer ganglion cells project to tectum after neonatal tectal lesions.

SummaryAfter partial ablation of the superior colliculus (tectum) in neonatal hamsters, the whole extent of the visual field comes to be represented in a compressed map on the remaining tectal fragment. However, the total volume of tectal tissue in which retinotectal fibers arborize is less than normal. These observations suggest that the retinal ganglion cells which arborize in this reduced volume might arise throughout the whole extent of the retina but be fewer in number than normal. Alternatively, the ganglion cells which project to the tectum might be normal in number but reduced in terminal arbor size. To distinguish between these possibilities, we have used tectal injections of horseradish peroxidase to label retinal ganglion cells which project to the tectum. The numbers of labelled cells per mm2 of retina were counted in selected regions. In hamsters with small lesions, which left 80–85% of the tectum intact, the density of labelled retinal ganglion cells was normal. However, in hamsters with larger lesions, the density of labelled cells was significantly lower than normal.