Specific neurotrophic interactions between cortical and subcortical visual structures in developing rat: in vivo studies

Disruption of Foxg1 expression by knock-in of cre recombinase: effects on the development of the mouse telencephalon

The cre/loxP system is used routinely to manipulate gene expression in the mouse nervous system. In order to delete genes specifically from the telencephalon, the Foxg1-cre line was created previously by replacing the intron-less Foxg1 coding region with cre, resulting in a Foxg1 heterozygous mouse. As the telencephalon of heterozygous Foxg1 mice was reported to be normal, this genotype often has been used as the control in subsequent analyses. Here we describe substantial disruption of forebrain development of heterozygous mice in the Foxg1-cre line, maintained on the C57BL/6J background. High resolution magnetic resonance microscopy reveals a significant reduction in the volume of the neocortex, hippocampus and striatum. The alteration in the neocortex results, in part, from a decrease in its tangential dimension, although gross patterning of the cortical sheet appears normal. This decrease is observed in three different Foxg1 heterozygous mouse lines, independent of the method of achieving deletion of the Foxg1 gene. Although Foxg1 is not expressed in the diencephalon, three-dimensional magnetic resonance microscopy revealed that thalamic volume in the adult is reduced. In contrast, at postnatal day 4, thalamic volume is normal, suggesting that interactions between cortex and dorsal thalamus postnatally produce the final adult thalamic phenotype. In the Foxg1-cre line maintained on the C57BL/6J background, the radial domain of the cerebral cortex also is disrupted substantially, particularly in supragranular layers. However, neither Foxg1 heterozygous mice of the Foxg1-tet (tetracycline transactivator) line, nor those of the Foxg1-lacZ and Foxg1-cre lines maintained on a mixed background, displayed a reduced cortical thickness. Thus Cre recombinase contributes to the radial phenotype, although only in the context of the congenic C57BL/6J background. These observations highlight an important role for Foxg1 in cortical development, reveal noteworthy complexity in the invocation of specific mechanisms underlying phenotypes expressed following genetic manipulations and stress the importance of including appropriate controls of all genotypes.

Neural Transplantation in Animal Models of Dementia

Neural transplantation provides a powerful novel technique for investigating the neurobiological basis and potential strategies for repair of a variety of neurodegenerative conditions. The present review considers applications of this technique to dementia. After a general introduction (section 1), attempts to replace damaged neural systems by transplantation are considered in the context of distinct animal models of dementia. These include grafting into aged animals (section 2), into animals with neurotransmitter-selective lesions of subcortical nuclei, in particular involving basal forebrain cholinergic systems (section 3), and into animals with non-specific lesions of neocortical and hippocampal systems (section 4). The next section considers the alternative use of grafts as a source of growth/trophic factors to inhibit degeneration and promote regeneration in the aged brain (section 5). Finally, a number of recent studies have employed transplanted tissues to model and study the neurodegenerative processes associated with ageing and Alzheimer's disease taking place within the transplant itself (section 6). It is concluded (section 7) that although neural transplantation does not offer any immediate prospect of therapeutic repair in clinical dementia, the technique does offer a powerful neurobiological tool for studying the neuropathological processes involved in both spontaneous degeneration and specific diseases of ageing. New understandings derived from neural transplantation may be expected to lead to rational development of novel strategies to inhibit the neurodegenerative process and to promote regeneration in the aged brain.

Cortical diffusible factors increase MAP-2 immunoreactive neuronal population in thalamic cultures

Previous experiments have established that grafts of embryonic day (E) 16 frontal cortex placed into the occipital cortex of postnatal day (P) 0-P1 rats selectively attract axons from the ventrolateral and ventromedial (VL/VM) thalamic nuclei (Frappé et al., Exp. Neurol. 169 (2001) 264). The present study was therefore undertaken to identify any possible maturation-promoting activity of the cortex on VL/VM thalamic cells. In a first step, a primary culture of VL/VM thalamic cells taken from P0-P1 rats was developed. Neurons, glial cells and a few immature, nestin immunoreactive cells were identified in the culture. In a second step, VL/VM thalamic cells that had been maintained in vitro for 4-5 days were cultured for 7 additional days in isolation (control condition) or with an E16 or P5 explant of frontal or occipital cortex placed on a microporous membrane. In control conditions, the total cell population and the percentage of MAP-2 immunoreactive neurons were not modified with time. In contrast, the percentage of MAP-2 immunoreactive neurons was increased in E16 cortex co-cultures whereas the total cell population was unchanged and the proliferative activity remained very low. Also, the mean number of neurites per neuron was increased but no effect was found on neuritic length. Similar effects on neuronal maturation were found with E16 frontal or occipital cortex explants, indicating a lack of areal specificity. P5 cortex also produced, but to a lesser extent, an increase in percentage of MAP-2 immunoreactive neurons. Further, P5 cortex had no effect on mean number of neurites per neuron but substantially promoted elongation of neuronal processes. We propose that in addition to their well-established survival promoting effect, diffusible molecules released by embryonic and early postnatal cortex can promote in vitro the maturation of thalamic neurons.

Transplants of fetal frontal cortex grafted into the occipital cortex of newborn rats receive a substantial thalamic input from nuclei normally projecting to the frontal cortex

A number of molecular and hodological experiments have provided evidence that there is an early commitment of neocortical neurons to express features unique to a certain cortical area. However, the findings of several transplantation experiments have indicated that late embryonic cortical tissue heterotopically grafted into the neocortex of newborn rats receives a set of thalamic projections appropriate for the host cortical locus within which it develops. To provide further information on the extent to which neocortical neurons are predetermined to develop area-specific systems of connections, in this study we have compared the pattern of thalamic afferents to grafts of embryonic day 16 occipital or frontal neocortex transplanted into the occipital cortex of newborn rats. Two months after grafting, a retrograde neurotracer (cholera toxin, subunit b) was injected into the grafts to precisely assess the number of cells in the visual- and/or motor-related nuclei of the host thalamus projecting to each category of transplants (occipital-to-occipital or frontal-to-occipital). Transplants of embryonic occipital cortex received significant input from several visual-related thalamic nuclei, i.e. the lateral posterior and lateral dorsal nuclei, and no input from motor-related thalamic nuclei. However, only few labeled cells were found in the dorsal lateral geniculate nucleus, which was systematically affected by a severe atrophy, probably in response to the lesion of the occipital cortex performed prior to the transplantation. By comparison, transplants of frontal origin received a substantial input from the ventrolateral and ventromedial thalamic nuclei, which normally project to the frontal cortex, but received a weak input from the lateral posterior and lateral dorsal nuclei. Neocortical neurons grafted heterotopically into the neocortex of newborn hosts are not only able to contact cortical and subcortical targets appropriate for their embryonic site of origin, but are also susceptible to derive thalamic inputs closely related to their embryonic origin.

Specific invasion of occipital-to-frontal neocortical grafts by axons from the lateral posterior thalamic nucleus consecutive to neonatal lesion of the rat occipital cortex

Previous work found that transplants of embryonic (E) day 16 occipital cortex placed into the frontal cortex of newborn hosts failed to receive input from visual-related nuclei of the host thalamus. The present study is aimed at determining the possible causes of the lack of visual-related thalamic input to these transplants. For that purpose, a retrograde neurotracer was injected into transplants of embryonic (E16) occipital origin which were placed into the frontal cortex of newborn rats with either intact or damaged occipital cortex. In rats with intact occipital cortex, occipital-to-frontal transplants were indeed not contacted by axons from the dorsal lateral geniculate (DLG) nucleus and received only sparse to negligible input from, respectively, the lateral posterior (LP) and laterodorsal (LD) thalamic nuclei. Yet, following neonatal lesion of the host occipital cortex, the occipital-to-frontal transplants received a significant input from the LP and to a much lesser degree from the LD but practically none from the DLG. Additional control cases with frontal-to-frontal transplants and prior lesion of the occipital cortex did not receive significant input from any of these thalamic nuclei. Thus, following neonatal deprivation of cortical target cells in their main terminal field, LP and to a lesser extent LD axons have the capacity to recognize and significantly innervate appropriate targets even those at some distance from their normal terminal site. DLG neurons degenerate or are not able to contact and invade available terminal space that is provided at some distance from the occipital cortex.

The effects of central administration of neurotrophins or transplants of fetal tectal tissue on retinal ganglion cell survival following removal of the superior colliculus in neonatal rats

In neonatal rats, intraocular injections of brain-derived neurotrophic factor (BDNF) or neurotrophin 4/5 (NT-4/5) enhance the survival of retinal ganglion cells (RGCs) following superior colliculus (SC) ablation [Q. Cui, A.R. Harvey, At least two mechanisms are involved in the death of retinal ganglion cells following target ablation in neonatal rats, J. Neurosci., 15, 1995, pp. 8143-8155.]. The aim of the present study was to determine if: (i) fetal tectal tissue grafted into the lesion site, or (ii) neurotrophins applied centrally to the injured SC, also decreased lesion-induced RGC death. Nuclei of tectally projecting RGCs were identified by injecting diamidino yellow (DY) into the left SC of 2-day-old (P2) Wistar rats. Injected SCs were lesioned at P4. In some animals, embryonic (E16) tectal tissue was then implanted into the lesion cavity; host rats were perfused 24 h or 20 days later. In short-term (24-h) studies, the number of DY-labelled pyknotic profiles was compared to the number of normal DY-labelled RGCs in retinal wholemounts (right eyes). The proportion of dying RGCs in animals with grafts (10.7%, n = 17) was not significantly different from lesion-only rats (13.2%, n = 26). Nonetheless, the long-term (20-day) study showed that, in most rats, fetal tectal tissue survived in the lesion cavity and in some cases, the grafts received host retinal input. In another group, different doses of BDNF or NT-4/5 were applied to the SC after P4 tectal lesions. Rats were perfused 24 h later and the number of pyknotic vs. normal DY-labelled RGCs was determined. Initial trials in which SC lesions were filled with gelfoam soaked in BDNF or NT-4/5 were unsuccessful; however, RGC death was reduced (p < 0.05, Dunnett's test) in rats that received gelfoam implants as well as focal neurotrophin injections into SC rostral to the lesion. The lowest pyknotic rate in individual animals from the BDNF and NT-4/5 groups was 2.41% and 2.01%, respectively. Overall, the proportion of dying RGCs was 7.0% (n = 8) for BDNF and 7.4% (n = 17) for NT-4/5 treated rats. Normal RGC densities were also significantly higher in these animals. NT-4/5 topically applied to the posterior surface of the eye did not reduce RGC death. The data show that the viability of injured neonatal RGCs is increased by specific retrograde neurotrophin-mediated survival signals which can be activated from the SC.

The status and organization of astrocytes, oligodendroglia and microglia in grafts of fetal rat cerebral cortex

Immunohistochemical methods were used to study the status and organization of astrocytes, oligodendroglia and microglia in fetal cerebral cortical tissue grafted on to the dorsal surface of the midbrain in newborn host rats. Grafts were examined 1-6 months posttransplantation. All grafts contained large numbers of hypertrophied, intensely glial fibrillary acidic protein-positive astrocytes. Microglia were also activated, displaying slightly increased levels of OX-42 immunoreactivity. The grafts consisted of lobules of gray matter which were separated by bands of myelinated fibres associated with large numbers of Rip-positive oligodendroglia. These glial cells had a relatively normal morphology. The density of astrocytes and microglia was reduced in these white matter-like regions. In association with chronic changes in glial reactivity, transplants also expressed increased levels of chondroitin sulphate proteoglycans (CS-56 antibody). The observed changes in glial cell phenotype and extracellular matrix in cortical transplants are likely to affect neuronal physiology and connectivity in a number of ways, and highlight the importance of studying both glia and neurons in order to gain a more comprehensive picture of the long-term functional potential of fetal brain grafts.

In situ labeling of apoptotic cell death in the cerebral cortex and thalamus of rats during development

Apoptosis is a form of naturally occurring cell death that plays a fundamental role during development and is characterized by internucleosomal DNA fragmentation. In this study we used specific in situ labeling of DNA breaks (Gavrieli et al. [1992] J. Cell. Biol. 119:493-501) to analyze the distribution of apoptotic cells in rat cerebral cortex and thalamus at different developmental stages from embryonic day 16 to adulthood. Control experiments and electron microscopy confirmed that the reaction product was confined to the nucleus of selected cells. Plotting and counting of labeled nuclei in counterstained paraffin sections showed that apoptosis occurred mainly during the first postnatal week and was absent in embryonic and adult samples. In the cortex, the number of apoptotic cells progressively increased from birth to the first postnatal week, with a peak between postnatal (P) day 5 and P8, and subsequently decreased. At the time of maximal expression of apoptosis, labeled nuclei were present mainly in layer VIb and underlying white matter and at the border between cortical plate and layer I. Only a few apoptotic cells were found scattered in the thalamus, without a particular concentration in selected areas, but with a peak at P5. Differences in the number of apoptotic cells between cortex and thalamus suggest that apoptotic cell death may have a different functional significance in the two brain areas.

Fetal hippocampal transplants attenuate CA3 pyramidal cell death resulting from fluid percussion brain injury in the rat

Transplantation of fetal neural tissue has been demonstrated to prevent neuronal loss in a number of CNS injury models including spinal cord contusion. However, no studies have examined the neuroprotective role of fetal transplants in models of traumatic brain injury. The present study examined the ability of fetal neural grafts to attenuate neuronal loss resulting from lateral fluid percussion (FP) brain injury in the rat. Lateral FP in the rat elicits a focal contusion within the parietal/temporal cortex and induces cell death in a subset of hippocampal CA3 pyramidal neurons. To examine potential neuroprotective effects of fetal neural grafts, either E16 fetal hippocampus, E16 fetal cortex, or sterile lactated Ringers was stereotaxically transplanted directly into contused cortex 2 days after FP brain injury. The effects of fetal transplants upon adjacent injured hippocampal CA3 regions were then assessed at 4 weeks after grafting utilizing quantitative image analysis. Both fetal cortex and hippocampal grafts survived within contused cortex. Fetal hippocampal grafts significantly attenuated CA3 cell death resulting from lateral fluid percussion, while fetal cortical transplants induced a small, but nonsignificant, amelioration of CA3 pyramidal loss. Thus, neuroprotection by fetal grafts appeared to be tissue specific with hippocampal, but not cortical, fetal transplants significantly reducing posttraumatic CA3 loss. In summary, fetal neural transplantation can ameliorate hippocampal cell death following experimental brain injury.

Growth-promoting interactions between the murine neocortex and thalamus in organotypic co-cultures

The aim of this study was to assess whether developing cerebral cortex produces diffusible factors that can affect the growth of thalamic cells and, if so, what the role of these factors might be during the formation of thalamocortical connections. We studied interactions between cultured organotypic explants from mice maintained in defined serum-free medium. First, we cultured explants of embryonic dorsolateral thalamus in isolation from any other tissue; after culture, these explants were viewed intact and then sectioned. We estimated the numbers of healthy and pyknotic cells before and after culture, and the rates of mitosis in the explants during culture (using bromodeoxyuridine). Based on these data, we concluded that the majority of cells in the thalamic explants survived, although significant numbers of pyknotic cells did accumulate. Thalamic explants extended either very few or no neurites when cultured alone. We then cultured explants of embryonic thalamus near to explants from other tissues. A gap was always maintained between the explants, and we measured the length and density of neurite outgrowth from each thalamic explant. Slices of embryonic cortex promoted a small but significant increase in the amount of growth from thalamic explants. Postnatal cortex stimulated much more profuse neurite outgrowth; postnatal cerebellum had less of an effect, and postnatal medulla or liver had none. We showed that there was significantly more outgrowth from thalamic explants cultured in medium that had been preconditioned with cortical slices than from thalamic explants cultured in control medium, confirming that diffusible factors were produced by the cortex. The survival and mitotic rates of thalamic cells were unaffected by co-culture with the cortex. We conclude that the developing cortex releases diffusible factors that stimulate the growth of thalamic neurites and that other regions of the brain may also release the same substance(s). The lack of a specific source of thalamic growth promoting factor(s) argues against a role for these factors in guiding thalamic axons to specific targets; indeed, we were unable to demonstrate any chemotropic guidance of thalamic axons towards cortical explants in collagen gels. Since postnatal cortex has a more potent stimulatory effect than prenatal cortex, it seems possible that, in vivo, the cortical-derived factors act mainly on thalamocortical axons that have located their targets and are in the process of arborizing and refining their connections.

Whisker stimulation metabolically activates thalamus following cortical transplantation but not following cortical ablation

Local cerebral glucose utilization was assessed during whisker stimulation by 2-deoxyglucose autoradiography. Whisker stimulation increased local cerebral glucose utilization in brainstem, thalamus and whisker sensory cortex in normal rats. Whereas whisker stimulation increased glucose metabolism in brainstem, whisker stimulation failed to increase glucose metabolism in thalamus of rats that had whisker sensory cortex ablated 5 h to five weeks previously. The failure of whisker stimulation to activate thalamus after cortical ablations was probably not due to decreased cortical input to thalamus because whisker stimulation activated thalamus after large cortical tetrodotoxin injections. Failure of whisker stimulation to activate thalamus at early times (5 h and one day) after cortical ablations was not due to thalamic neuronal death, since it takes days to weeks for axotomized thalamic neurons to die. The failure of whisker stimulation to activate thalamus at early times after cortical ablations was likely due to the failure of trigeminal brainstem neurons that project to thalamus to activate axotomized thalamic neurons. This might occur because of synaptic retraction, glial stripping or inhibition of trigeminal brainstem synapses onto thalamic neurons. The thalamic neuronal death that occurs over the days and weeks following cortical ablations was associated with thalamic hypometabolism. This is consistent with the idea that the thalamic neurons die because of the absence of a cortically derived trophic factor, since the excitotoxic thalamic cell death that occurs following cortical kainate injections is associated with thalamic hypermetabolism. The glucose metabolism of parts of the host thalamus was higher and the glucose metabolism in surrounding nuclei lower than the normal side of thalamus in rats that sat quietly and had fetal cortex transplants placed into cavities in whisker sensory cortex five to 16 weeks previously. Whisker stimulation in these subjects activated the contralateral host thalamus and fetal cortical transplants. This was accomplished using a double-label 2-deoxyglucose method to assess brain glucose metabolism in the same rat while it was resting and during whisker stimulation. The high glucose metabolism of parts of host thalamus ipsilateral to the fetal cortical transplants is consistent with prolonged survival of some axotomized thalamic neurons. The finding that whisker stimulation activates portions of host thalamus further suggests that the cortical transplants maintained survival of the host thalamic neurons and that synaptic connections between whisker brainstem and thalamic neurons were functional.

Grafts of fetal central nervous system tissue rescue axotomized Clarke's nucleus neurons in adult and neonatal operates

Many conditions are thought to contribute to neuron death after axotomy, including immaturity of the cell at the time of injury, inability to reestablish or maintain target contact, and dependence on trophic factors produced by targets. Exogenous application of neurotrophic factors and transplants of peripheral nerve and embryonic central nervous system (CNS) tissue temporarily rescue axotomized CNS neurons, but permanent rescue may require transplants that are normal targets of the injured neurons. We examined the requirements for survival of axotomized Clarke's nucleus (CN) neurons. Two months after hemisection of the spinal cord at the T8 segment, there was an ipsilateral 30% loss of neurons at the L1 segment in adult operates and a 40% loss in neonates. Transplants of embryonic spinal cord, cerebellum, and neocortex inserted into the T8 segment at the time of hemisection prevented virtually all of the cell death in both adults and neonates, but transplants of embryonic striatum were ineffective. None of the grafts prevented the somal atrophy of CN neurons caused by axotomy. Retrograde transport of fluoro-gold from the cerebellum demonstrated that 33% of all CN neurons at L1 project to the cerebellum, 50% of these died following a T8 hemisection, but all these projection neurons were rescued by a transplant of embryonic spinal cord. These results suggest that the rescue of axotomized CN neurons is relatively specific for the normal target areas of these neurons, but this specificity is not absolute and may depend on the distribution and synthesis of particular neurotrophic agents.

Anatomical and functional characteristics of fetal neocortex transplanted into the neocortex of newborn or adult rats

In humans, the cerebral cortex can be affected by a variety of diseases (vascular, traumatic, neurodegenerative, etc.) and, therefore, several experimental studies have been undertaken to determine to what extent transplantation of cortical neurons could prove a useful treatment for cerebral cortical damage. The purpose of this review is to give an evaluation of the different attempts of neocortical tissue transplantation which have been undertaken, mostly in rodents, during the last decade. First, we examine the functional effects of neocortical tissue transplantation in various tasks designed to assess different aspects of behavior depending upon the localization and function of the cortical area under investigation. Second, a variety of mechanisms have been proposed by which the graft would improve host behavioral capacities. Two of these are considered in this review: trophic action on the host brain and reconstruction of cortical circuitry. Most behavioral studies in rodents seem to indicate that better synaptic integration and larger functional improvements are achieved when the embryonic neocortical tissue is transplanted into immature host neocortex, i.e. in newborn recipients. Transplantation of embryonic neocortex into an adult damaged cortex seems to provide only partial functional improvement. In adult hosts, the synaptic integration of the transplanted neurons is incomplete since, in most instances, long distance projections are not re-established. It seems, therefore, that transplantation of embryonic cortex into adult hosts would prove a useful therapeutic method only if there is a possibility of neutralizing the growth inhibitory factors of the mature host CNS.

Transient projections from rat occipital cortex are able to respond to a spinal target derived diffusible factor in vitro

Layer V pyramidal neurons in the occipital part of the rat cerebral cortex project to both the cervical spinal cord and the tectum early in postnatal development. The occipito-spinal projection is transient and is subsequently withdrawn, while a permanent connection is maintained with the tectum. The withdrawal of the transient occipital corticospinal axons may be due to their inability to respond to target-derived influences. In the current study we co-cultured explants of the occipital cortex and cervical spinal gray matter or tectum in 3-D collagen gels. Directional growth of the cortical axons towards either the cervical spinal gray or tectal explant was observed. This indicates that the failure of neurons located in the occipital cortex to maintain collaterals within the spinal cord in vivo is not due to their inability to respond to a target-derived factor, but must be regulated by other extrinsic factors.

Dendritic development in the dorsal lateral geniculate nucleus of ferrets in the postnatal absence of retinal input: a Golgi study

In order to determine the ongoing role of retinal fibers in the development of dorsal lateral geniculate nucleus (dLGN) neurons during postnatal development, the development of dLGN neurons in the postnatal absence of retinal input was studied in pigmented ferrets using the Golgi-Hortega technique. The development of four dLGN cell classes, defined on the basis of somatic and dendritic morphology, was described previously in normal ferrets (Sutton and Brunso-Bechtold, 1991, J. Comp. Neurol. 309:71-85). The present results indicate that the morphological development of dLGN neurons is strikingly similar in normal and experimental ferrets. The exuberant dendritic appendages that appear after eye opening in normal ferrets are overproduced and eliminated in the postnatal absence of retinal input; however, the final reduction of these transient appendages is delayed. Because exuberant appendages develop in the absence of retinal input, their production cannot depend upon visual experience. Differences in cell body size between normal and experimental ferrets are apparent only after neurons can be classified at the end of the first postnatal month. Cell body size is markedly reduced for class 1 neurons; class 2 cells also are reduced in size but to a far lesser extent. As there is a general trend for class 1 neurons to have the functional properties of Y-cells, it is likely that the dLGN neurons most affected by the absence of retinal input also are Y-cells.

Target-derived astroglia regulate axonal outgrowth in a region-specific manner

The potential neuroanatomical specificity of astrocyte influence on neurite outgrowth was studied using an in vitro coculture system in which neurons from embryonic rat spinal cord or hippocampus were grown for 4 days in the presence of, but not in direct contact with, astrocytes derived either from the same region (homotopic coculture) or from different regions (heterotopic coculture) of the rat central nervous system. The results showed that axonal outgrowth was greatly enhanced in heterotopic cocultures in which spinal cord or hippocampal neurons were grown with astrocytes derived from their appropriate CNS target regions. This effect was remarkably specific, because the astroglia harvested from spinal or hippocampal target regions were not effective in promoting axon growth of nonafferent neuronal populations. Dendritic outgrowth was similar under all coculture conditions. These data suggest that diffusible signals, produced by astrocytes, can regulate neurite extension in vitro in a neuroanatomically specific manner and that axons are more sensitive than dendrites to the regional astrocyte environment.

Brain macrophages and microglia respond differently to lesions of the developing and adult visual system

Traumatic injury in the brain usually results in rapid degeneration of neuronal elements and a response by peripherally derived macrophages (brain macrophages, BMOs) and resident microglia. One intriguing result of lesions performed in the developing brain as compared to lesions of the mature brain is the faster resolution of the cellular debris and the absence of significant scarring. The purpose of this study was to examine the response of BMOs to induced cell death distant to the lesion site and to investigate possible differences in the responding phagocytic populations (BMOs versus microglia) following lesions in neonates and adults. Ablation of the visual cortex at birth results in very rapid retrograde degeneration and removal of neurons of the dorsal lateral geniculate nucleus (dLGN) within a few days. Lesions to the visual cortex of adult rats also induce neurons within the dLGN to die, but these cells do so over a much more protracted time course. Utilizing differences in morphology and immunocytochemical staining with the monoclonal antibodies ED1 and OX-42 to distinguish between BMOs and microglia, we found that in the developing CNS, BMOs are signalled rapidly and specifically to the location of induced cell death. Microglia are not involved in this response. As might be expected, the temporal response in the adult is much more protracted. In contrast to the developing brain, microglia and not macrophages are the predominant responding cell class after the adult lesion. The data suggest that these are distinct populations of phagocytic cells that respond to brain damage during development and in the adult, which may be critical in modulating the resolution and growth response after injury.

Differential immunochemical markers reveal the normal distribution of brain macrophages and microglia in the developing rat brain

Brain macrophages and microglia play important roles in central nervous system (CNS) development, especially during regressive events in which particular neuronal and glial constituents are eliminated. The purpose of this study is to provide a complete map of brain macrophage and microglia distribution in all regions of the neuraxis from birth to sexual maturity. We have utilized morphology and immunostaining with the specific antibodies OX-42 and ED1 to distinguish between brain macrophages and microglia. Brain macrophages are large, round cells, 10-15 microns in diameter, with few or no cytoplasmic processes; these cells are ED1- and OX-42-immunopositive. Microglia have small cell bodies with numerous, ramified cytoplasmic processes. These cells are OX-42-positive, and ED1-negative. We found a specific pattern of distribution of brain macrophages, targeting specific cortical and subcortical areas transiently, including developing fiber tracts. These cells disappeared completely by the third postnatal week. In contrast, OX-42-positive microglia exhibited a gradual increase in number and were distributed uniformly throughout gray matter and within white matter tracts. These cells remain in the adult CNS, constituting the resident microglia population. We suggest that these two distinct phagocytic cell populations perform unique functions in the developing brain, including remodeling of restricted CNS areas by brain macrophages that is part of a normal morphological process.

Neuronal and nonneuronal influences on retinal ganglion cell survival, axonal regrowth, and connectivity after axotomy

In contrast to the abortive regrowth that occurs when axons are interrupted in the adult mammalian CNS, exposure of injured CNS axons to the nonneuronal milieu of a peripheral nerve can lead to extensive axonal elongation. With the application of this experimental approach to the retinocollicular pathway in adult rodents, it has been possible to investigate the influences of neuron-glia and other interactions on the capacity of axotomized CNS neurons to survive injury, to elongate the distances necessary to reach specific targets, and to form connections in the CNS in adult rodents. The results of these investigations indicate that the changed glial environment provided by peripheral nerve grafts permits the guided regeneration of RGC axons to their CNS targets. Back in the CNS glial environment, regenerated axons penetrate their targets for short distances and re-form normal appearing synapses that can excite or inhibit postsynaptic neurons. Further studies will require a better understanding of intrinsic neuronal properties and of the interactions of these neurons with other neurons and with the cellular and noncellular components of the extraneural milieu.

Access to gastric tissue promotes the survival of axotomized neurons in the dorsal motor nucleus of the vagus in neonatal rats

Lesioning the vagus nerve in the neck (cervical vagotomy) results in a rapid and virtually complete loss of motoneurons in the dorsal motor nucleus of the vagus in neonatal rats. The present study sought to determine whether access to gastric target tissue will promote the survival of these motoneurons after axotomy. Quantitative analysis demonstrates that subdiaphragmatic vagotomy, which leaves the cut vagal axons in close proximity to their normal gastric targets, results in significantly less motoneuron loss than cervical vagotomy. Furthermore, the loss of motoneurons after cervical vagotomy can be significantly reduced by transplanting embryonic gastric tissue to the neck of vagotomized neonatal host rats, in the vicinity of the cut axons. The survival effect of transplanted gastric tissue appears specific because control transplants of embryonic bladder tissue fail to reduce motoneuron death after cervical vagotomy. Injections of the neural tracers Fluoro-Gold and cholera toxin-horseradish peroxidase into gastric transplants labeled surviving motoneurons in cervically vagotomized rats, whereas tracer injections into bladder transplants or into host cervical tissues did not. These results indicate that neonatal vagal motoneurons are capable of making the adjustments necessary to survive axotomy if they have access to gastric target cells. The apparent dependence of injured neonatal vagal motoneurons on gastric tissue offers a new system in which to examine in vivo the trophic interactions between neurons and their targets.

Axonal projections between fetal spinal cord transplants and the adult rat spinal cord: a neuroanatomical tracing study of local interactions

Three neuroanatomical tracers have been employed to map the axonal projections formed between transplants of fetal spinal cord tissue and the surrounding host spinal cord in adult rats. Solid pieces of embryonic day 14 (E14) rat spinal cord were placed into hemisection aspiration cavities in the lumbar spinal cord. Injections of either (1) a mixture of horseradish peroxidase and wheat germ agglutinin- conjugated horseradish peroxidase, (2) Fluoro-Gold, or (3) Phaseolus vulgaris leucoagglutinin (PHA-L) were made into the transplants or the neighboring segments of the host spinal cord at 6 weeks to 14 months post-transplantation. Injections of anterograde and retrograde tracers into the transplants revealed extensive intrinsic projections that often spanned the length of the grafts. Axons arising from the transplants extended into the host spinal cord as far as 5 mm from the host-graft interface, as best revealed by retrograde labeling with Fluoro-Gold. Consistent with these observations, iontophoretic injections of PHA-L into the transplants also produced labeled axonal profiles at comparable distances in the host spinal cord, and in some instances elaborate terminals fields were observed surrounding host neurons. The majority of these efferent fibers labeled with PHA-L, however, were confined to the immediate vicinity of the host-graft boundary, and no fibers were seen traversing cellular partitions between host and transplant tissues. Host afferents to the transplants were also revealed by these tracing methods. For example, the injection of Fluoro-Gold into the grafts resulted in labeling of host neurons within the spinal cord and nearby dorsal root ganglia. In most cases, retrogradely labeled neurons in spinal gray matter were located within 0.5 mm of the graft site, although some were seen as far as 4-6 mm away. The distance and relative density of ingrowth exhibited by host axons into the grafts, however, appeared modest based upon the results of HRP and Fluoro-Gold retrograde labeling. This was further confirmed with the PHA-L anterograde method. Whereas some host fibers were seen extending into the transplants, the majority of PHA-L containing axons formed terminal-like profiles at or within 0.5 mm of the host-graft interface. The comprehensive view of intrinsic connectivity and host-graft projections obtained in these studies indicates that intraspinal grafts of fetal spinal cord tissue can establish a short-range intersegmental circuitry in the injured, adult spinal cord. These observations are consistent with the view that such grafts may contribute to the formation of a functional relay between separated segments of the spinal cord after injury.(ABSTRACT TRUNCATED AT 400 WORDS)

Is it possible to repair the damaged prefrontal cortex by neural tissue transplantation?

The techniques are now well established for the viable transplantation of cortical and other neural tissues into the neonatal and adult cortex, at least in the laboratory rat. Under appropriate conditions such grafts survive well and can establish reciprocal connections with the host brain. On this basis, neural transplantation has become a powerful technique for the study of mechanisms involved in the development of the central nervous system and its capacity for regeneration after injury. Moreover, a variety of anatomical, electrophysiological and behavioural techniques suggest that grafted neural tissue may sustain functional interactions with the host brain. However, the extent and duration of recovery using present techniques is extremely limited. It remains undetermined whether such experimental observations may ever acquire therapeutic application.

Different populations of dorsal lateral geniculate nucleus neurons have concentration-specific requirements for a cortically derived neuron survival factor

A macromolecular fraction of conditioned culture medium (CM) derived from explant cocultures of embryonic rat posterior cortex and caudal thalamus is able to support the survival of neurons in the dorsal lateral geniculate nucleus (dLGN) of newborn rats following ablation of dLGN cortical target areas. In the present study we tested whether the survival-promoting activity of this target-derived neurotrophic agent was concentration dependent and whether different subpopulations of dLGN neurons were equally responsive. With the starting concentration of the CM fraction designated X, increasing concentration results in a progressive falloff in trophic activity so that at 200X overall dLGN survival is similar to that seen in unconditioned medium (UM) controls. In contrast, diluting the fraction produces an increase in activity until maximal survival is achieved at 0.2X. Further dilutions result in a decline in trophic activity until control values are reached at 0.001X. Two populations of neurons within the dLGN, defined by their time of origin, respond in a specific manner to the different concentrations. Neurons generated during the early stages of neurogenesis (E14) have maximal survival (25.8%) at 0.05X, whereas those neurons generated later (E15/16) are maximally supported (30.7% survival) at 10X, a 200-fold difference in concentration. While it is possible that separate neurotrophic and neurotoxic molecules exist for each of these populations of dLGN neurons, the most parsimonious interpretation of the data is that a single cortically derived neurotrophic factor exists whose production is strictly controlled during development to achieve maximal effect on different populations of thalamic neurons that may be functionally distinct.

Marked neurotrophic effects of diffusible substances released from non-target cerebellar cells on thalamic neurons in culture

A primary culture of thalamic cells from 6-day-old postnatal rats was co-cultured for 6 days with neocortical or cerebellar cells (neurons and astrocytes) from the same litter using a Transwell mesh system. The survival of thalamic neurons grown on the lower well, which were affected by substances released from cells grown on the upper wells, was remarkably promoted by both neocortical co-cultures (target for thalamic projection neurons) and cerebellar co-cultures (non-target). When the cells were seeded on mesh at lower density, the neurotrophic effects of neocortical co-cultures on thalamic neurons (204% of control) were significantly greater than those of cerebellar co-cultures (138%). When the cells were seeded on mesh at higher density, the effects of cerebellar co-cultures increased dramatically (517% of control), while the neurotrophic effects of neocortical co-cultures did not change. Morphologically, the survival of multipolar-shaped thalamic neurons was remarkably improved, as compared to the survival of monopolar, bipolar, and tripolar-shaped thalamic neurons. Basic fibroblast growth factor slightly promoted thalamic neuronal survival (136%), whereas nerve growth factor had no effect. These results suggest that neocortical and cerebellar cells release diffusible factor(s) that promote the survival of specific subpopulation of thalamic neurons, and that at least one of the non-target cerebellar cell-derived factor(s) might be more potent than those released from target neocortical cells.

Functional recovery following transplants of embryonic brain tissue in rats with lesions of visual, frontal and motor cortex: problems and prospects for future research

In animals, fetal brain tissue grafts into damaged adult host brain reduce some of the functional deficits caused by brain lesions. Although neurons from transplants survive and develop reciprocal connections with host brain tissue, such connections are generally not enough to replace damaged fibers completely and support behavioral recovery observed. Moreover, grafts never exhibit a normal morphological appearance as compared to adult tissue, but some metabolic activity is occasionally detected within the transplant. Release and/or diffusion of trophic substances from the transplant, in addition to those from the damage host brain, may partially restore neuronal and behavioral functions especially after lesions of the visual cortex. In this case, it can be hypothesized that fetal transplants serve as "living mini-pumps". In addition, there is evidence that the combination of trophic substances (e.g. GM1 ganglioside) and fetal brain transplants may provide a better opportunity for recovery than either treatment given by itself.

Extension of the critical period for developmental plasticity of the corticospinal pathway

The corticospinal tract (CST) of the rat undergoes a prolonged period of postnatal development. Lesions of the presumptive CST pathway at birth are followed by the aberrant rerouting of the developing corticospinal axons around the lesion site through adjacent undamaged CNS tissue. This developmental plasticity becomes severely restricted by 5-6 days of age, so the axons are no longer capable of growth around the site of injury. The aim of the current study was to determine whether altering the environment at the site of injury by filling the lesion with transplanted fetal spinal cord tissue could prolong the critical period for developmental plasticity of the corticospinal pathway. The spinal cord was damaged (overhemisection) at three stages in the development of the corticospinal (CS) pathway: 1) prior to the arrival of CS axons, 2) after the axons elongated through the cord but prior to synaptogenesis, and 3) after both axonal elongation and synaptogenesis were completed. One to 9 months later, anterograde neuronal tracing with horseradish peroxidase was used to assess the growth of the corticospinal pathway with or without a fetal transplant at the site of injury, and the pattern of labeling was compared with that observed in adult nonlesioned control animals. Our results indicate that the presence of a transplant prolongs the critical period for developmental plasticity of the CST. Transplants elicited growth of CST axons throughout the postnatal period examined. CST axons damaged prior to synaptogenesis exhibited more robust growth than those lesioned after synaptogenesis had been completed. These results suggest that both environmental and neuronal factors interact to regulate the response of immature CS neurons to injury.

Fetal brain grafts rescue adult retinal ganglion cells from axotomy-induced cell death

After intraorbital transection of the optic nerve of adult rats, 90% of the retinal ganglion cells die within 30 days. Since fetal brain extracts and cocultured fetal target regions support the survival of retinal ganglion cells in vitro (Nurcombe and Bennett: Exp. Brain Res. 44: 249-258, '81; McCaffery et al.: Exp. Brain Res. 48: 377-386, '82; Armson and Bennett: Neurosci. Lett. 38: 181-186, '83) we investigated whether cell death in the adult retina could be prevented by transplanting fetal (E16) thalamus and tectum to the proximal stump of the optic nerve of adult rats that was completely transected 2-3 mm behind the optic disc. Unoperated eyes contained 119,973 (+/- 939, SEM) retinal ganglion cells, estimated from axon counts of the intact optic nerve. Of these, 11,601 (+/- 1,857) remained in control operated eyes at 30 days postoperation while in the eyes of grafted rats, 35,086 (+/- 2,278) retinal ganglion cells were counted. Thus, 23,485 (= 22% of those normally dying after transection of the optic nerve) ganglion cells were rescued by the fetal grafts from cell death normally following axotomy. These results indicate that fetal target regions of retinal ganglion cells contain and/or produce neurotrophic molecules that promote the survival of adult axotomized retinal ganglion cells.

Fetal cortical transplants reduce the thalamic atrophy induced by frontal cortical lesions in newborn rats

Fetal neocortical tissue was grafted into frontal cortex lesion cavities made in newborn rats. After survival periods extending up to 14 months, volumetric measurements of the total thalamus and of the lateral, medial and anterior thalamic compartments showed an amelioration of the thalamic atrophy that normally is found after cortical lesions. These results correspond to previous findings demonstrating interconnections between fetal cortical transplants and the host thalamus.

Neurotrophic and behavioral effects of occipital cortex transplants in newborn rats

Cell suspensions of embryonic occipital cortex were transplanted into newborn rats with large unilateral visual cortex lesions. When the animals were adults, they were tested on a difficult visual discrimination, and subsequently their brains were analyzed for possible neurotrophic effects of the transplants on nonvisual cortical areas which normally form connections with the occipital cortex. Behaviorally, animals with lesions and transplants learn to discriminate between columns and rows of squares at a rate which is identical to normal rats while animals with lesions and no transplants are impaired. Volume and cell-density measures show that the transplants also rescue neurons in cortical area 8 that would normally degenerate following the cortical lesion. No such neurotrophic effect of the transplants is found in cortical area 24 or area 17 contralateral to the lesion. In rats with lesions and no transplants, there is a significant correlation between the amount of area 8 remaining after the lesion and trials to criterion on the columns-rows discrimination, a relationship that does not exist in transplant animals because of their normal learning curve and the consistent sparing of area 8. Injections of HRP into the visual cortex contralateral to the lesion result in variable numbers of labeled cells within the transplant. However, there is no consistent relationship between the number of transplant cells which project to the opposite hemisphere and learning of the discrimination. It is suggested that the learning deficit following the lesion is largely attentional and that the sparing of cortical area 8 (which in rats may include the analog of the frontal eye fields present in the primate cortex) contributes to the sparing of function.

Diffusible proteins prolong survival of dorsal lateral geniculate neurons following occipital cortex lesions in newborn rats

Removal of the occipital cortex in newborn rats results in the rapid and nearly complete degeneration of the dorsal lateral geniculate nucleus (dLGN) in 5 days. In previous studies we have shown that transplants of embryonic posterior cortex neurons, which are allowed to develop in culture for 5 days prior to transplantation into the site of the lesion, prolong the survival of a particular population of host dLGN neurons for an additional week. In this study we tested the possibility that the transplant cells synthesize diffusible proteins which are responsible for this neurotrophic effect. Culture medium conditioned by explants of embryonic occipital cortex and diencephalon was concentrated by vacuum dialysis or ultrafiltration through membranes with at least a 10-kDa cut-off. This concentrated medium was loaded into polyacrylamide or sodium alginate gels which were then implanted into the cavity of the lesion. Five days after implantation, the alginate-conditioned-medium implants result in a 3-fold increase in dLGN survival compared to unconditioned medium controls, while a two-fold increase in survival of the nucleus is found with the polyacrylamide-conditioned-medium implants. Proteolysis of the conditioned medium eliminates all neurotrophic activity. The results suggest that the death of dLGN neurons following the cortical lesion is due to the loss of diffusible proteinaceous neurotrophic factors--factors that may operate during normal in vivo development of the geniculocortical pathway.

Specific neurotrophic interactions between cortical and subcortical visual structures in developing rat: in vitro studies

We investigated the influence of different subcortical structures on the survival of specific populations of occipital cortex neurons developing in vitro. Explants of embryonic day 14-15 (E14-15) rat cortex were cultured for 5 days with explants of either diencephalon or optic tectum or another occipital cortex explant. Stereological analysis of the explants revealed that after 5 days in vitro (5 DIV) all the cortical explants contained equal proportions of healthy neurons, glia, neuropil, and degenerating profiles, regardless of the culturing conditions. In order to determine if different neuronal populations survived preferentially in the cortical explants as a result of the presence of potential target or afferent structures, we used HRP filling and 3H-thymidine labeling techniques. Specific differences in the morphology of the cells and their time of origin are found in the cortical explants. In the cortical explants cocultured with diencephalon (Cx + D) the cortical cells that survive tend to be round with small cross-sectional areas and have few neurites. These cells are generated late in the culturing period. The surviving cortical neurons in the cortex plus tectum (Cx + T) cultures are larger--many with a pyramidal-shaped soma and several neurites. These cells are generated earlier in vitro. The cortex cultured with other cortex (Cx + Cx) gives values intermediate to the Cx + D and Cx + T cultures. The results of these experiments suggest that there are diffusible trophic factors that arise from subcortical structures that selectively support the survival of neuron populations in the developing neocortex.