Optic fiber development between dual transplants of retina and superior colliculus placed in the occipital cortex

Summary Fetal rat retina was excised from donor rats at 15 days of gestation and transplanted to the occipital cortex of neonatal host rats in combination with and adjacent to: 1) the appropriate portion of the superior colliculus to serve as a specific target tissue in an attempt to stimulate an outgrowth of optic fibers from the isolated retinal transplant; 2) a sample of the medial thalamus to provide a alternate tissue not normally recipient to the retinofugal projection, thereby serving as a control to further test for the target specificity of the axonal outgrowth from the retinal transplant. After 5–30 days of development samples of transplant and surrounding host cortex were removed and subjected to light and electron microscopic study.The fetal retina has been shown to develop successfully while located in the occipital cortex but this tissue does not form a significant number of optic fibers nor does it demonstrate the normal quantity of ganglion cells, (Matthews et al. 1981). A dual transplant of fetal retina and medial thalamus demonstrates the major types of neurons and sensory elements in the retina as well as concentrations of large neurons in the thalamus. Examination of these transplants with a silver stain, as well as electron microscopy, revealed a network of axons coursing within the transplanted thalamic neuropil but few axons traversing the interface between the retinal and thalamic transplant. Additionally, no axons coursed out of the retina into the surrounding host cortex.Similar studies of dual transplants of retina and superior colliculus revealed marked concentrations of fibers projecting from the periphery of the retinal tissue, extending deep into the adjacent superior colliculus and merging with the tangle of axons found within this tissue. It should be emphasized, however, that such outgrowths from the retina were clearly restricted to those portions in apposition to the transplanted tectum. No axons were found extending from the opposite surface of the retinal transplant in contact with the host cortex.A quantitative analysis of ganglion cell populations in the transplant demonstrated that these were somewhat reduced in all retinal transplants with the exception of those regions located adjacent to a transplant of superimental enlargement of a peripheral target organ during early stages of development reduces the amount of spontaneous neuronal degeneration resulting from a failure to establish functional connections with the available postsynaptic sites in the target.Our experiments indicate that the use of multiple transplants may provide a useful model system for further exploration of the relationship between developing CNS neurons and tissues within the CNS or the periphery which receive their input.     

The connective tissue and glial framework in the optic nerve head of the normal human eye: light and scanning electron microscopic studies

The arrangement of connective tissue components (i.e., collagen, reticular, and elastic fibers) and glial elements in the optic nerve head of the human eye was investigated by the combined use of light microscopy and scanning electron microscopy (SEM). Light-microscopically, the optic nerve head could be subdivided into four parts from the different arrangements of the connective tissue framework: a surface nerve fiber layer, and prelaminar, laminar, and postlaminar regions. The surface nerve fiber layer only possessed connective tissue elements around blood vessels. In the prelaminar region, collagen fibrils, together with delicate elastic fibers, formed thin interrupted sheaths for accommodating small nerve bundles. Immunohistochemistry for the glial fibrillary acidic protein (GFAP) showed that GFAP-positive cells formed columnar structures (i.e., glial columns), with round cell bodies piled up into layers. These glial columns were located in the fibrous sheaths of collagen fibrils and elastic fibers. In the laminar region, collagen fibrils and elastic fibers ran transversely to the optic nerve axis to form a thick membranous layer - the lamina cribrosa - which had numerous round openings for accommodating optic nerve fiber bundles. GFAP-positive cellular processes also ran transversely in association with collagen and elastin components. The postlaminar region had connective tissues which linked the lamina cribrosa with fibrous sheaths for accommodating nerve bundles in the extraocular optic nerve, where GFAP-positive cells acquired characteristics typical of fibrous astrocytes. These findings indicate that collagen fibrils, as a whole, form a continuous network which serves as a skeletal framework of the optic nerve head for protecting optic nerve fibers from mechanical stress as well as for sustaining blood vessels in the optic nerve. The lamina cribrosa containing elastic fibers are considered to be plastic against the mechanical force affected by elevation of the intraocular pressure. The present study has also indicated that glial cells with an astrocytic character play an important role in constructing the connective tissue framework characteristic of the optic nerve head.     

Retinotectal projection after partial ablation of chick optic vesicles.

We excised the dorsal part of the optic vesicle of chick embryos at stages 13-14 (embryonic day 2). The remainder of the optic vesicle reoganized and developed a small eye. This study was undertaken to determine how locus specificity is kept within the reorganized retina. The projection pattern from the reorganized eyes was examined with HRP and DiI, a fluorescence axon tracer. Whole retinal fibers labeled with HRP were found on the medial half of the contralateral tectum, thus showing the lateral half of the tectum as being devoid of retinal fibers. DiI labeling revealed a detailed projection map, with the dorsoposterior to ventroanterior axis of the reorganized eye being projected as the rostrocaudal axis on the medial half of the tectum. These results suggest that the positional specificity along the anteroposterior axis of the optic vesicle was already determined at the time of excision, and that the ventral part of the optic vesicle reorganized the "whole" retina, keeping its original anteroposterior polarity.     

Changes in NADPH diaphorase expression in the fish visual system during optic nerve regeneration and retinal development

The various functions of nitric oxide (NO) in the nervous system are not fully understood, including its role in neuronal regeneration. The goldfish can regenerate its optic nerve after transection, making it a useful model for studying central nervous regeneration in response to injury. Therefore, we have studied the pattern of NO expression in the retina and optic tectum after optic nerve transection, using NADPH diaphorase histochemistry. NO synthesis was transiently up-regulated in the ganglion cell bodies, peaking during the period when retinal axons reach the tectum, between 20–45 days after optic nerve transection. Enzyme activity in the tectum was transiently down-regulated and then returned to control levels at 60 days after optic nerve transection, during synaptic refinement. To compare NO expression in the developing and regenerating retina, we have looked at NO expression in the developing zebrafish retina. In the developing zebrafish retina the pattern of staining roughly followed the pattern of development with the inner plexiform layer and horizontal cells having the strongest pattern of staining. These results suggest that NO may be involved in the survival of ganglion cells in the regenerating retina, and that it plays a different role in the developing retina. In the tectum, NO may be involved in synaptic refinement.     

Cross-species neural transplants of embryonic septal nuclei to the hippocampal formation of adult rats

Summary In the absence of immunosuppressive treatment, suspensions of cells from the developing septal region of mouse embryos were transplanted successfully into the denervated hippocampal formations of adult rat hosts. The longitudinal recovery of acetylcholinesterase (AChE)-containing fibers in the host was the index of transplant success. In transplant recipients, the fornix-fimbrial interconnection between the septum and hippocampal formation was severed unilaterally, and two 5 l aliquots of cell suspension were injected into the hippocampal formations of host rats. Five sets of controls included one in which animals received no surgical intervention (Normal Controls), and another which was subjected to a sham operation (Sham Controls). The fornix-fimbria pathway was transected unilaterally in Lesion Control animals, while Hippocampal Controls received the same lesion plus two injections of non-cholinergic cells from the hippocampal formations of mouse embryos. Injection Controls were subjected to a fornix-fimbria transection and given two injections of debris and dead cells in saline. The cross-species transplants induced the return of a normal AChE laminar pattern in the recipient rats. The density of the laminar pattern, quantified with laser densitometry, was greatest in transplants that had survived for one week, but only in sections adjacent to the injection sites. Although the density decreased from the first through third weeks of survival, overall density of AChE staining stabilized from the fourth through 17th weeks of survival. Because the success rates of these cross-species transplants were similar to those reported for homogenic tissue, it was concluded that the rat brain is a suitable host for xenogenic transplants of septal. neurons from embryonic mice.     

Course of the accessory optic fascicular fibers in the rat

The courses of fibers in the dorsal and lateral fasciculi of the accessory optic tract were studied in the rat by means of a selective silver impregnation method for degenerating nerve fibers and Mesulam's HRP method. The results indicate that except for a moderate number of fibers entering the dorsal terminal nucleus and the lateral terminal nucleus respectively, all optic fibers constituting the dorsal and lateral fasciculi descend the lateral surface of the brain to terminate in the medial terminal nucleus. No ascending optic nerve fiber to the dorsal or lateral terminal nucleus is included in these fasciculi.     

成年斑马鱼视神经再生期间顶盖表面纤维层和灰质层的突触形态学研究

目的研究斑马鱼视神经再生过程中神经递质的变化,探讨神经递质和神经再生的关系。方法应用斑马鱼视神经再生模型,通过电镜技术观察顶盖表面纤维和灰质层突触的形态变化。结果视神经损伤后顶盖突触变化过程大致可分4个时期：1．视神经损伤后早期顶盖突触结构的退变;突触密度和突触小泡密度均下降,空型终末密度增大,8d时突触小泡密度降到最低水平;而空型终末密度最高。2．损伤后14d再生纤维大量进入顶盖;这一时期大核小泡和小核小泡密度都大量增加,但进入顶盖的纤维还没有或很少形成突触,14d时突触密度降到最低。3．损伤后2ld的特征是突触大量形成和圆形清亮小泡、扁平清亮小泡密度增加。4．再生晚期突触形态和功能恢复及精确化;100d时突触密度和突触小泡密度都大体恢复正常,但大核小泡密度还很高。结论兴奋性神经递质和抑制性神经递质可能对早期神经再生的启动和突触的形成起重要作用,而肽类和胺类可能对再生轴突的投射和精确化有重要作用;神经递质促进神经再生有先后顺序。     

Progress of topographic regulation of the visual projection in the halved optic tectum of adult goldfish.

1. The patterns of re-established visual projections on to the rostral half-tectum are studied following excision of the caudal tectum at various intervals after section of either the contralateral optic nerve or the ipsilateral optic tract in adult goldfish. 2. The pattern of a newly restored retinotectal projection depends on the duration of the post-operative period given to the halved tectum before it is re-innervated by regenrating optic fibres from the retina. 3. When the duration is such that regenerating optic fibres invade the denervated rostral half-tectum at about 40 days or longer after excision of the caudal tectum, the remaining half-tectum is able to accommodate incoming optic fibres not only from the appropriate temporal hemi-retina but also from the foreign nasal hemiretina in an orderly compressed topographic pattern. 4. If the surgical operations are timed so that the halved tectum receive regenerating optic fibres earlier than 33 days after excision of the caudal tectum, the halved tectum initially accommodates only those optic fibres originating from the temporal half of the retina at this early stage. 5. This normal (uncompressed) pattern of the newly regenerated visual projection, however, eventually changes into an orderly compressed pattern at a later period. Post-operative dark-deprivation of the operated fish has no significant effect on the temporal transition. 6. The temporal transition from an initially normal pattern into an orderly compressed pattern may reflect the time course of progressive and systematic changes involved in topographic regulation of the halved tectum into a whole.     

Specific projections of retina transplanted to rat brain

Summary Retinae were taken from fetal rats and transplanted adjacent to the superior colliculus of neonatal rats. After 1 month survival, the transplants were surgically removed from the hosts, locally damaged or injected with horseradish peroxidase (HRP) to determine the distribution of the transplant efferents in the host brains. Histological examination of the transplants revealed cell and plexiform layers characteristic of normal retinae. Since the retinae were undifferentiated at the time of transplantation, this layering developed within the host. The only obvious differences from normal retina were that the layers were organized in rosettes or folded sheets and lacked well developed photoreceptor outer segments. In animals which had lesions or HRP injections confined to the retinal transplant, proper staining of sections of the host brain revealed transplant projections. These projections were confined to the optic tract and nuclei which are normally retinorecipient such as the superior colliculus and dorsal lateral geniculate nucleus. Projections were found along the border of non-retinorecipient nuclei such as the lateral posterior nucleus, but did not appear to enter these nuclei. It was observed that within the superior colliculus the host retinal input had an effect on the distribution of the transplant projection. In one-eyed hosts the transplant projection was distributed throughout the stratum (s.) zonale, s. griseum superficiale, and s. opticum; whereas in the two-eyed hosts, the transplant projection was confined to the s. zonale and the border between s. griseum superficiale and s. opticum.We suggest that a special affinity exists between the axons of the retinal transplants and host visual structures. Furthermore, factors, such as competition and timing may be important in determining the distribution of the transplant axons within the specific target nuclei. Transplantation appears to be a useful technique for further studies on the mechanisms underlying the development of specific neuronal connections.     

碱性成纤维细胞生长因子对移植的胚胎脊髓组织存活与生长的影响

用胚胎脊髓腹侧组织块植入缺损运动神经元的大鼠脊髓内；同时把带有神经的拇长伸肌移放到脊髓移植物旁，其神经的断端插入移植的部位。应用碱性成纤维细胞生长因子作用脊髓移植物，经ＨＲＰ逆行追踪、乙酰胆碱酯酶和琥珀酸脱氢酶组化染色等方法显示：碱性成纤维细胞生长因子对移植的胚胎脊髓神经元的存活与生长有促进作用。     

Morphological aspects of the vascularization in intraventricular neural transplants from embryo to embryo

Intraventricular transplants of neural tissues were performed in ovo from embryo to embryo. Fragments of the nervous wall of the optic lobe (tectum) from 14-day chick or 12-day quail embryos (donor) were inserted into the ventricle of the right optic lobe of 6-day chick or 5-day quail embryos (host). Chick-to-chick, chick-to-quail and quail-to-chick grafts were carried out. The vascularization changes occurring in the host tectum and in the grafted neural tissues were analysed under light, transmission, and scanning electron microscopes and by morphometric methods. In the host embryo tectum, the neural graft stimulates a statistically significant increment in vessel density and a vessel sprouting into the ventricle of the optic lobe. The vascular sprouts reach the transplanted tissue and establish connections with its native microvasculature. The chick-to-quail and quail-to chick grafts, submitted to immunoreaction with a quailspecific antibody which recognizes an antigen (MB1) present on endothelial cells, indicate that re-establishment of the circulation in the graft depends upon anastomoses between host and donor vasculatures and the rapid new growth of host-derived and donor-native vessels. The presence of macrophage-like cells escorting the new-growing vessels suggests that these cells are involved in the host and donor tissue angiogenesis.     

Subdivisions of the mesencephalon and isthmus in the lizard Gekko gecko as revealed by ChAT immunohistochemistry

The distribution of cholinergic cell bodies and fibers was examined in the mesencephalon and isthmus of Gekko gecko. Distinct groups with prominent labeled cells were observed in the cranial nerve motor nuclei and isthmic nuclei, and weak labeled cell bodies and fibers were observed in the mesencephalic nucleus of the trigeminal nerve and the central nucleus of the torus semicircularis. After discussing the topological relationships within the tectum and isthmus, we unify the nomenclature of the caudal deep mesencephalic nucleus in lizards and the rostral magnocellular nucleus isthmi in turtles that is similar in terms of the preisthmic position, nontopographic connections with the tectum, and the same midbrain origin to the magnocellular preisthmic nucleus in birds, and may be homologous to the superficial cuneiform nucleus in mammals. None of them belong to the cholinergic nucleus isthmi, as the latter has isthmus origin and topographic reciprocal connections with the tectum. We also discuss the origin and intrinsic function of the inner longitudinal tract of the thick ChAT-ir fibers that course through the mesencephalon and diencephalon. We review the subdivisions of the mesencephalon and isthmus of Gekko gecko as revealed by ChAT immunohistochemistry, as well as the limits of the diencephalo–mesencephalic, mesencephalic–isthmo, and isthmo–rhombocephalic by the ChAT-ir cell- and fiber-poor distribution, and discuss the caudal limit of the isthmus. Our research on the subdivisions of the mesencephalon and isthmus in G. gecko as revealed by ChAT immunohistochemistry will serve as the neuroanatomical basis for subsequent relevant studies of Gekko gecko.     

The serotoninergic system of the brain of the lamprey, Lampetra fluviatilis: an evolutionary perspective.

The distribution of serotonin(5HT)-immunoreactive cell bodies, nerve fibers and terminals was investigated by light microscopy in the lamprey Lampetra fluviatilis. Twenty-three distinct groups of 5HT neuronal somata were identified from diencephalic to rhombencephalic levels in the brain. The diencephalon contained a subependymal population of immunoreactive cells in contact with the cerebrospinal fluid (CSF), which could be subdivided into five separate groups situated in the hypothalamus and ventral thalamus; five additional groups of immunoreactive diencephalic neurons, situated in the dorsal thalamus and thalamo-pretectum, which were not in contact with the CSF, were also identified. In the midbrain, in addition to a few labelled neurons in the optic tectum, two structures containing immunoreactive cells were identified in the tegmentum mesencephali. None of these 5HT cells corresponded to the retinopetal neurons which are situated in the same region. A very large number of 5HT neurons were observed in the hindbrain which could be divided into seven groups in the isthmus rhombencephali and a further three in the rhombencephalon proper. Immunoreactive fibers and terminals were widely distributed throughout the neuraxis. In the telencephalon two 5HT fibers assemblies, lateral and medial, could be identified which terminated in both pallial and subpallial structures. The richest serotoninergic innervation in the telencephalon was found in the lateral portion of the primordium hippocampi and the medial part of the corpus striatum. In the diencephalon, the distribution of immunoreactive fibers and terminals was heterogeneous, being most pronounced in the lateral hypothalamic area and in the infundibulum. The densest arborization of fibers in the mesencephalon was found in the stratum fibrosum et cellulare externum of the optic tectum, a major site of retinal projection, and in the nucleus interpeduncularis mesencephali as well as in the oculomotor nuclei. The rhombencephalon is richly endowed with serotoninergic fibers and terminals, many labelled arborizations being found in the nuclei isthmi rhombencephali and around the nucleus motorius nervi trigemini. Comparative analysis of the serotoninergic systems of petromyzontiforms and gnathostomes indicates that the evolution of this system involves a progressive elimination of the rostral immunoreactive cells and an increasing complexity of the caudal population of serotoninergic neurons.     

The neurological mutation staggerer is expressed in embryonic cerebellar transplants matured in the anterior eye chamber of normal mice

Horseradish peroxidase (HRP)-filled neurons and their processes were consistently detected in the ventral portion of the dog hypothalamus after intraocular injection of HRP. The number of HRP-filled neurons decreased in parallel with the extent of the resection of the optic nerve. HRP-filled neurons were never detected in specimens with a complete resection of the optic nerve. These findings strongly indicate that these HRP-filled neurons in the ventral hypothalamus are the source of centrifugal fibers to the retina.     

Regionalisation and acquisition of polarity in the optic tectum.

The optic tectum differentiates from the alar plate of the mesencephalon and receives retinal fibres in a precise retinotopic manner. Here, mechanisms of tectum polarisation and regionalisation are reviewed. Misexpression of Pax2, Pax5 or En can change the fate of the presumptive diencephalon to that of the tectum. Ephrin A2 and A5 are expressed in a gradient in the tectum, caudal high and rostral low, and may play important roles in the formation of a precise retinotectal projection map. Retinal fibres that express receptors for these ligands, and which come from the temporal retina, are repulsed by the ligands and do not invade the caudal tectum. Both En1 and En2 can regulate posterior characteristics in the tectum by inducing ephrin A2 and A5. Transplantation experiments in chick have indicated that the mes/metencephalic boundary works as an organiser for the tectum and the cerebellum. Fgf8 is a candidate signalling molecule in the organiser. Pax2/5, En, and Fgf8 are in a positive feedback loop for their expression such that misexpression of one of these genes in the diencephalon turns on the feedback loop and can result in induction of an optic tectum. Otx2 and Gbx2 appear to repress each other's expression and contribute to defining the posterior border of the tectum. Misexpression of Otx2 in the metencephalon can change the fate of its alar plate to a tectum, and misexpression of Gbx2 in the mesencephalon can cause anterior shifting of the caudal limit of the tectum. The anterior border of the tectum may be determined as a result of repressive interactions between Pax6 and En1/Pax2. Along the dorsoventral axis of the mesencephalon, Shh contributes to ventralize the tissue; that is, Shh can change the fate of the presumptive tectum to that of the tegmentum that is the ventral structure. It is proposed that the brain vesicle that expresses Otx2, Pax2, and En1 may differentiate into the tectum.     

Monoaminergic markers in the optic tectum of the domestic chick

The avian optic tectum has become a reliable model system to study the basic mechanisms that underlie the computation of visual stimuli. Many aspects of its cytoarchitecture, chemoarchitecture, connectivity and development are thoroughly characterized. However, knowledge about its monoaminergic innervation is still incomplete. As a prerequisite to understand a possible functional role of the monoaminergic neurotransmitters, the serotonergic, noradrenergic, and dopaminergic innervation of the optic tectum as well as the distribution of serotonin 2A receptors, the dopamine- and cAMP-regulated phosphoprotein DARPP-32 and calbindin D-28K was studied in domestic chicks by immunohistochemical techniques. Serotonergic, noradrenergic, and tyrosine hydroxylase positive axons and axon terminals were present in all layers of the optic tectum. Generally, the highest densities of serotonergic, noradrenergic, and tyrosine hydroxylase positive fibers were found in the superficial tectal layers 1-8, whereas only moderate densities of serotonergic, noradrenergic, and tyrosine hydroxylase positive fibers became obvious in the deep tectal layers 9-15. Serotonergic fibers were particularly abundant in layers 4, 5a and 7 and serotonin 2A receptors in layer 13. Noradrenergic fibers were densest in layers 4 and 5a, whereas tyrosine hydroxylase positive fibers showed a slightly different distribution pattern with additional dense labeling in layer 7. As revealed by double-labeling immunohistochemistry, serotonergic fibers were closely related to the cell bodies of calbindin-positive horizontal cells in layer 5b and tyrosine hydroxylase positive fibers often contacted DARPP-32+ dendritic shafts in layers 9 and 10. These findings indicate that the catecholaminergic innervation of the optic tectum consists of a noradrenergic and a dopaminergic component and that the noradrenergic, serotonergic, and dopaminergic system may be potentially involved in the modulation of retinal input in the superficial layers of the optic tectum as well as in the modulation of tectal output via the deep tectal layers.     

Dopaminergic innervation of striatal grafts placed into different sites of normal striatum: differences in the tyrosine hydroxylase immunoreactive growth pattern

When patients with Parkinson’s disease initially show symptoms, approximately 80–85% of their dopaminergic nerve fibers in the striatum have degenerated. It is thus of importance to develop strategies to try to rescue the remaining dopaminergic neurons and to stimulate them to induce sprouting. In this study the goal was to examine whether the different subgroups of dopaminergic neurons in the ventral mesencephalon projecting to the basal ganglia have different sprouting capacities when stimulated by the trophic effect of a fetal striatal graft. Lateral ganglionic eminence was implanted into the lateral ventricle, the midportion of dorsal striatum, globus pallidus, or ventral striatum. Solid tissue pieces from 13- to 15-mm fetuses were stereotactically implanted into adult female Sprague-Dawley rats. At postgrafting week 4 the animals were perfused and processed for tyrosine hydroxylase (TH) immunohistochemistry. Transplants placed in the lateral ventricle were TH-negative, except for two cases with TH-positive fibers where the ependymal layer was disrupted, thereby allowing direct contact between the graft and the adjacent host striatum. The transplants placed into dorsal striatum were innervated by small patches of dopaminergic nerve fibers. Areas between the TH-positive patchy structures remained TH-negative. In grafts placed into globus pallidus, both patchy structures and a less dense TH-positive nerve fiber network was noted. The TH-positive growth pattern in transplants placed in ventral striatum was also devided into patchy and widespread growth. Grafts placed in globus pallidus and ventral striatum revealed significantly larger areas of TH-positive innervation compared with that measured in grafts placed in dorsal striatum and the lateral ventricle. In conclusion, it is possible to induce sprouting of TH-immunoreactive nerve fibers from all areas examined. The most potent areas to initiate dopaminergic growth were the globus pallidus and ventral striatum, where both a patchy dense and a widespread, less dense growth was induced. Thus, if using a trophic stimulus to induce sprouting from remaining dopaminergic nerve fibers in Parkinson’s disease, the preferential target to induce sprouting would be ventromedial striatum and growth would be guided toward dorsal striatum owing to the enhanced dopaminergic growth properties in the ventromedial areas.     

Readjustment of retinotectal projection following reimplantation of a rotated or inverted tectal tissue in adult goldfish.

1. The pattern of visual projection from the retina on to the optic tectum following reimplantation of a piece of the tectal tissue was studied with neurophysiological mapping methods in adult goldfish. 2. When a rectangular piece of the tectum was dissected, lifted free, and then reimplanted to the same tectum after rotation by 180 degrees around the dorsoventral axis, the re-established visual projection later showed a complete reversal of retinotopic order within the reimplanted area with reference to the normal projection on to the intact surrounding area of the same tectum. The localized reversal was observed as early as 65 days, and also as late as 721 days after the 180 degree rotated reimplantation. 3. If a square piece of the tectal tissue was reimplanted after rotation by 90 degrees anticlockwise around the dorsoventral axis, the restored visual projection later showed a corresponding localized 90 degrees rotation within the reimplanted ares. 4. When the entire laminar structure of a dissected tectal tissue was inverted, and the reimplanted upside-down along the same rostrocaudal axis of the tectum, the restored visual projection on to the inverted tectal reimplant was found to be organized in a reverse retinotopic order along only the mediolateral axis within the reimplanted area. The restored visual projection retained a correct retinotopic order along the rostrocaudal axis. The same trends were also observed after regeneration of the optic fibres following section of the contralateral optic nerve. 5. If the inverted tectal tissue was reimplanted along the same mediolateral axis of the tectum, the re-established visual projection showed a localized reversal of retinotopic order along only the rostrocaudal axis within the reimplanted area. Sectioning the contralateral optic nerve made no difference to the result. 6. These results suggest that a piece of adult tectal tissue retains its original topographic polarity regardless of the orientation of reimplantation after either a rotation or an inversion. Furthermore the retention is not a short-lived transitory phenomenon. It persisted as long as the reimplanted tissue survived. 7. Histological examination of the operated tecta revealed that the reimplanted tectal tissues underwent a severe derangement in their laminar structures. It was impossible to identify the main target zone of retinotectal projection (the stratum fibrosum et griseum superficiale) or the central cellular layer (the stratum griseum centrale) in the reimplants. The prominent feature of the deranged tectal tissue was irregular vortices of tangled fibre bundles. Sparse tectal neurones of bipolar and granular types were irregularly scattered in the deranged structure of the reimplant. 8. Thus, the retention of original topographic polarity did not require an integrity of the cytoarchitectonic structure of the reimplanted tectal tissue.     

Restricted fiber growth from substance P-immunoreactive brain neurons grafted to the anterior eye chamber of the rat

Substance P (SP)-immunoreactive cell groups from fetal rat brain were homografted to the anterior eye chamber and left there for 2 months to mature, to elucidate their capacity to form nerve fibers in this ectopic environment. All grafts survived well, were rapidly revascularized from the host iris and proliferated to final sizes 2- to 4-fold the volume at transplantation. In spite of a rich SP fiber innervation of the transplant neuropil, no or almost no SP-positive fibers reached out from the transplant on to the iris. Monoamine histochemical analysis of the same locus coeruleus transplants revealed abundant fluorescent locus-derived nerve fibers of the host irides. Thus, a marked difference in growth behavior between noradrenergic and SP-immunoreactive neurons from the same brainstem region was found.     

Transmitter phenotype is a major determinant in the specificity of synapses formed by cholinergic neurons transplanted to the hippocampus

Embryonic habenular or striatal cholinergic tissues were transplanted to the hippocampal formation of adult rats. The connectivity of these grafts with the host hippocampal formation was analysed using acetylcholinesterase histochemistry and immunocytochemistry with a monoclonal antibody to choline acetyltransferase. Both graft types produced laminar arrangements of acetylcholinesterase-positive fibers in the hippocampal formation that closely resembled the native pattern of cholinergic innervation. In addition, graft-derived choline acetyltransferase-immunoreactive synapses were found in the host hippocampal formation. These synapses were formed on non-immunoreactive dendritic structures and were similar to the types of cholinergic synapses found in the hippocampal formation of normal animals. These data indicate that the cholinergic transmitter phenotype is a major determinant of whether a neuron will form typical cholinergic synapses with hippocampal targets.