Participation of puncta adherentia junctions in the formation of synaptic connections between a dentate fascia graft and the host brain

The fetal dentate fascia of Wistar rats on the 20th day of gestation was heterotopically grafted into the somatosensory neocortex of adult rats. Granule cells of a graft projected their axons (mossy fibers) to the host brain and established synaptic contacts with inappropriate targets. The organization of ectopic mossy fiber synapses was studied by electron microscopy. It was shown that ectopic synapses reproduce the structural determinants of hippocampal giant synapses and induce a subcellular reorganization of postsynaptic neocortex dendrites. Using morphometric analysis, a significant increase was found in the number of discrete puncta adherentia junctions and their total length in ectopic synapses as compared with the control group. The data obtained indicate that puncta adherentia contacts participate in the structural and chemical adaptation of neuronal targets to alien axons growing from transplants.     

Features of the development of homo- and heterotopic allotransplants of rat embryonal neocortex

Mechanisms of regulation of cell division in the developing neocortex are largely unknown. The aim of the present study was to investigate the influence of a microenvironment on the fetal neocortex histogenesis. The fetal neocortex from 15-day old Wistar rat embryo was grafted into the neocortex, crushed sciatic nerve and anterior chamber of eye of adult rats. A comparative study of graft development was carried out on 1, 3, 7, 10, 30 days using histological (Nissl stain, hematoxylin-eosin) and immunohistochemical (monoclonal antibody to proliferating cell nuclear antigen, and to glial fibrillary acidic protein) methods. Grafted neuroepithelial cells proliferated in grafts that developed in the neocortex and the anterior chamber of eye for 7 days, and in the sciatic nerve for 10 days. In all grafts differentiating neuroblasts, young neurons and mature neurons were observed 7, 10 and 30 days later, respectively. In 10 days, transplants in the nerve have a glial capsule, in contrast to other sites of grafting. The capsule consists of ependymocytes with microvilli and cilia 30 days later. These cells are GFAP-positive. Our results indicate epigenetic influence on the development of neuroepithelial precursors. The microenvironment of the peripheral nerve is suggested to promote glyogenesis in developing grafts. Afferent inputs do not influence the proliferative potency of brain cell precursors.     

Transplantation of human embryonal nervous tissue to the spinal cord of mature rats

Pieces of the wall obtained from the anterior cerebral bladder of human embryos at the age of 8-10 weeks can survive in the spinal cord of mature animals. In the transplant, unlike the normal embryonal histogenesis, neuroepithelial cells make groups of rosellas. The differentiation process of cells of the human nervous tissue transplant can be followed in the rat spinal cord without any immune suppression up to the end of the 2d month of development. During the 3d month the transplant neuroblasts perish as a result of the immune reaction.     

Study of effect of serotonin on histogenesis of rat embryonal neocortex at model of ectopic neurotransplantation

A comparative study has been performed of dynamics of development of ectopic transplants of embryonal (E14) neocortex anlages obtained from intact rats and from the rats administered with serotonin inhibitor para-chlorophenylalanine (PCPA) at the 11th day of pregnancy as well as after incubation of such anlages in the serotonin-containing medium. The goal of this work was to elucidate effect of serotonin on division and differentiation of embryonal neocortex cells. Study of degeneration, mitotic activity, and differentiation (by using immunohistochemical detection of nerve cell nuclear protein--NeuN) of transplanted cells has allowed establishing that serotonin promotes survival and differentiation of transplant neuroepithelial cells as well as participates in regulation of their proliferation. It is suggested that serotonin produces stimulation effect on the cell cycle rate of transplantated cells to thereby accelerate neuronal differentiation.     

The development of peptide-containing neurons within neocortical transplants in adult mice

Transplantation of embryonic neocortex into adult host neocortex leads to the survival of many donor cells, with the subsequent differentiation of the cortical neurons within a loosely laminated cellular pattern. We wanted to know whether peptide-containing neurons that are known to exist in normal neocortex would survive in the transplants, and if so, whether they would differentiate into morphological cell types that normally contain these peptides in cortex. By 30 days after transplantation, the implants were well vascularized and the donor neurons appeared healthy in Nissl-stained preparations. AChE-positive axons grew across the interface and innervated the transplant in moderate densities. Immunocytochemical localization of peptides in the transplant revealed that processes containing the four peptides normally present in cortex also develop in the transplants. These were vasoactive intestinal polypeptide, cholecystokinin, pancreatic polypeptide and somatostatin. Other peptides not yet demonstrated in and presumably not present in neocortex, did not develop in the transplants. These included alpha-melanocyte stimulating hormone, arginine-vasopressin, corticotropin releasing factor, beta-endorphin and substance P. The results demonstrate that peptide-immunoreactive neurons survive in neural transplants, where they develop complicated patterns of axonal arborization. The conditions used in these experiments produced no evidence that peptidergic neurons within the transplant grow out of the transplant and into the host brain within six weeks. Similarly, host peptidergic axons were never seen crossing the interface zone and entering the transplant in any significant numbers.     

Phenotypic differentiation of neurons in intraocular transplants

Neurochemical differentiation of neurons in transplants developing in rat anterior eye chamber was studied. Pieces of the somatosensory neocortex area, isolated from 17-day fetuses of Wistar rats, were used for the transplantation. The general cytological analysis and immunochemical identification of GABAergic neurons in neocortical transplants and in the appropriate brain area of the recipient rats (control) were carried out after 6 months. Cytoarchitectonics typical for neocortex was not revealed in the transplants. Furthermore, a 1.4-fold decrease in numerical density of the entire neuron population was found compared to the control. The proportion of GABAergic nerve cells in the transplanted tissue was reduced even more dramatically— by 13.1 times. The dimensions of all types of neurons, especially GABAergic cells, were greater in the transplants in oculo compared to neocortex in situ. The increase in size occurred mostly due to the cytoplasm. Thus, the nuclei of GABA-positive neurons in the transplants were larger by 1.2 times compared to the control and their perikarya were larger by 1.5 times. The obtained results showed that the conditions in the anterior eye chamber the most dramatically affect the differentiation of GABAergic neurons, and cell hypertrophy, probably, is the functional compensation of the decrease in their number. Considering the literature data on the increased excitability and synchronized neuronal activity in the intraocular transplants, it can be assumed that these transplants can be used as a model for studying the cellular mechanisms of nervous tissue epileptization under disinhibition conditions.     

Comparative analysis of the neocortex during the ontogenesis of cetaceae and primates

Comparative ontogenetic investigation of cytoarchitectonics of the cerebral neocortex has been performed in Cetacea and Primates using paraffin frontal and sagittal cerebral sections stained after Nissl. Cerebral hemispheres of dolphins, whales, monkeys and human being have been studied at various periods of prenatal development and in mature individuals. The comparison has been made at similar stages of cytoarchitectonical differentiation of the cortical plate. At two first stages of the prenatal ontogenesis (formation of the cortical plate and its differentiation into layers) there is not any principle differences between the Cetacea and Primates. Peculiarities of the cerebral cortical plate differentiation in the Cetacea (absence of the internal granular layer IV) is determined at the stage of stratification. Similar agranular character of the cerebral cortex differentiation is maintained during the whole subsequent ontogenesis in the Cetacea (heterogenetic type of the neocortex after Brodman). Absence of the layer IV in the cerebral neocortex determines some other principles in the spatial organization of the cortical-subcortical and in the intracortical connections in the Cetacea brain. This is confirmed by modern data of morphological and electrophysiological investigations. Perhaps, a comparatively more simple initial architectonics of the Cetacea brain limited the level of their functional possibilities, the latter is comparable only with anthropoid apes.     

Transplantation of fetal neocortex in rhesus monkey

A feasibility study of neural transplantation in adult rhesus monkey was undertaken. Fresh and preserved neocortex containing multiplying and maturing neurons obtained from 55–70 gestation days were transplanted into the striatum, cerebellum and cerebral cortex of adult monkeys. Tissues were preserved for 4 days either at subzero temperature in the freezer compartment of the ordinary refrigerator in Ringer lactate or incubated in culture medium. While 2 monkeys out of 5 injected with preserved tissue had successful transplants after 4 months, all the 10 monkeys injected with fresh tissue had no transplants. The size of the two surviving transplants was small. The neurons in the transplants were mainly in clusters. Many of the cells were immature and some showed early degenerative changes. Neuronal processes were restricted to the transplants and thus showed lack of morphological integration with the host tissue. Further studies are in progress to define the nature of the embryonic tissue of primate which can grow and survive and also the role of neural grafts in functional recovery following experimental lesions of the brain regions.     

Appearance and differentiation of NADPH-D-neurons in ontogeny of the cerebral cortex in rats

The appearance of presumptive NO-ergic nerve cells and their differentiation in the rat neocortex were studied. For this purpose, a comparative analysis of the development and differentiation of NADPH-D-positive neurons in the neocortex transplants taken from the embryos of different ages and transplanted in the occipital cortex of adult rats and in the normally developing cerebral cortex. The nervous tissue was stained histochemically for NADPH-D. The results we obtained suggest that no NADPH-D-containing neurons were found in the transplants from 15-day embryos, while they developed in those from 18-day embryos. Hence, precursors of NO-ergic neurons were still absent in the presumptive neocortex of 15-day embryos and appeared only on day 16-18 of embryogenesis. Expression of NADPH-D begins in them only within four to five days, but the neurons are differentiated during a relatively short period of time. Most NADPH-D-positive neurons reach their structural-functional maturity already by the end of the first week of postnatal development, while their complete maturation takes place by the end of the second week of postnatal development.     

Appearance and Differentiation of NADPH-D-Neurons in Ontogeny of Cerebral Cortex in Rats

The appearance of presumptive NO-ergic nerve cells and their differentiation in the rat neocortex were studied. For this purpose, a comparative analysis of the development and differentiation of NADPH-D-positive neurons in the neocortex transplants taken from the embryos of different ages and transplanted in the occipital cortex of adult rats and in the normally developing cerebral cortex was undertaken. The nervous tissue was stained histochemically for NADPH-D. The results we obtained suggest that no NADPH-D-containing neurons were found in the transplants from 15-day embryos, while they developed in those from 18-day embryos. Hence, precursors of NO-ergic neurons were still absent in the presumptive neocortex of 15-day embryos and appeared only on day 16–18 of embryogenesis. Expression of NADPH-D begins in them only within four to five days, but the neurons are differentiated during a relatively short period of time. Most NADPH-D-positive neurons reach their structural–functional maturity already by the end of the first week of postnatal development, while their complete maturation takes place by the end of the second week of postnatal development.     

Involvement of gap junctions in the development of the neocortex

Gap junctions play an important role during the development of the mammalian brain. In the neocortex, gap junctions are already expressed at very early stages of development and they seem to be involved in many processes like neurogenesis, migration and synapse formation. Gap junctions are found in all cell types including progenitor cells, glial cells and neurons. These direct cell-to-cell connections form clusters consisting of a distinct number of cells of a certain type. These clusters can be considered as communication compartments in which the information transfer is mediated electrically by ionic currents and/or chemically by, e.g., small second messenger molecules. Within the neocortex, four such communication compartments can be identified: (1) gap junction-coupled neuroblasts of the ventricular zone and gap junctions in migrating cells and radial glia, (2) gap junction-coupled glial cells (astrocytes and oligodendrocytes), (3) gap junction-coupled pyramidal cells (only during the first two postnatal weeks) and (4) gap junction-coupled inhibitory interneurons. These compartments can consist of sub-compartments and they may overlap to some degree. The compartments 1 and 3 disappear with ongoing develop, whereas compartments 2 and 4 persist in the mature neocortex. Gap junction-mediated coupling of glial cells seems to be important for stabilization of the extracellular ion homeostasis, uptake of neurotransmitters, migration of neurons and myelination of axons. Electrical synapses between inhibitory interneurons facilitate the synchronization of pyramidal cells. In this way, they contribute to the generation of oscillatory network activity correlated with higher cortical functions. The role of gap junctions present in neuroblasts of the ventricular zone as well as the role of gap junctions found in pyramidal cells during the early postnatal stages is less clear. It is assumed that they might help to form precursors of the functional columns observed in the mature neocortex. Although recent developments of new techniques led to the solution of many problems concerning gap junction-coupling between neurons and glial cells in the neocortex, there are many open questions which need to be answered before we can achieve a comprehensive understanding of the role of gap junctions in the development of the neocortex.     

Reorganization of the cortico-spinal tract after unilateral lesions of the neocortex

By means of retrograde transport of horseradish peroxidase the left and right hemisphere connections of neocortex with right spinal cord in normal and 7-14 days after the left sensory-motor neocortex damage have been investigated. In normal brain the quantity of cross corticospinal projections was revealed. After the unilateral lesion of neocortex the atypical retrograde transport of HRP in neocortex of ipsilateral hemisphere has been observed. The role of collateral sprouting mechanisms in posttraumatic reorganization of the corticospinal tract has been discussed.     

Neurons with different neurotransmitters in embryonic neocortical allografts in the rat sciatic nerve

Different subsets of interneurons in the Wistar rat neocortex and in neocortical transplants developing in a damaged nerve were identified by the following immunohistochemical markers: glutamate decarboxylase (GAD 67) for GABAergic nerve cells, NO-synthase (NOS) for NO-ergic neurons, choline acetyltransferase (ChAT) for cholinergic cells, and tyrosine hydroxylase for catecholaminergic structures. Twentyeight days after surgery, individual GAD 67-ir, NO-ir, ChAT-ir, and very rarely TH-ir cells were detected in the graft. It was shown that the number of GAD 67-ir neurons per unit area in the grafts was less than in the rat neocortex P20.     

Meiosis in autologous ectopic transplants of immature testicular tissue grafted to Callithrix jacchus

Grafting of immature testicular tissue provides a tool to examine testicular development and may offer a perspective for preservation of fertility in prepubertal patients. Successful xenografting in mice, resulting in mature spermatids, has been performed in several species but has failed with testicular tissues from the common marmoset, Callithrix jacchus. Previous data indicate that the hormonal milieu provided by the mouse host might cause this failure. We conducted autologous ectopic transplantation of testicular fragments under the back skin in newborn marmoset monkeys. Seventeen months after transplantation, we found viable transplants in 2 out of the 4 grafted animals. In the transplants, tubules developed up to a state intermediate between the pregraft situation and adult controls. Dividing spermatogonia and primary spermatocytes were present. Boule-like positivity and CDC25A negativity indicated that spermatogenesis was arrested at early meiosis. Immunohistochemistry revealed normal maturation of Sertoli cells, Leydig cells, and peritubular cells. Serum testosterone values were not restored to the normal range and bioactive chorionic gonadotropin levels increased to castrate levels. Meiotic arrest could have occurred in the grafts because of lack of sufficient testosterone or because of hyperthermia caused by the ectopic position of the grafts. We conclude that autologous transplants of immature testicular tissues in the marmoset can mature up to meiosis but that normal serum testosterone levels are not restored. Further studies have to be performed to overcome the meiotic arrest to explore the model further and to develop therapeutic options.     

Immunocytochemical localisation of neuronal nitric oxide synthase in developing and transplanted rabbit retinas

 Nitric oxide (NO) acts as a modulator of neuronal transmission in mature neuronal systems, including the retina. Recently, NO has also been suggested to have a trophic function during development. We examined immunocytochemically the distribution of NO-producing cells in developing and transplanted rabbit retinas. An antibody detecting the neuronal isoform of its biosynthetic enzyme, nitric oxide synthase (NOS), was used on normal developing retinas [starting at embryonic day (E) 15] and on rabbit retinal transplants after various survival times (1–139 days after surgery). Weakly stained cell bodies were first observed in the proximal margin of the neuroblastic layer at E 29. Stained processes projecting towards a developing inner plexiform layer were also visible at this time point. Immunoreactive cells were located at later stages in the innermost part of the inner nuclear layer and in the ganglion cell layer, and are likely to correspond mainly to amacrine cells. NOS-labelled cells were also found in retinal transplants. The first NOS-labelled cells appeared, as in normal developing retinas, in ages corresponding to E 29 and were still detected in transplants corresponding to postnatal day 123. NOS-labelled cells were seen in areas between rosettes, where amacrine cells are located. NOS-labelled processes were at times seen to project for long distances, forming very distinct plexuses. NOS-containing amacrine cells thus appear both in the transplants and in developing retinas in the embryonic stages, long before synaptic function involving these cells can be expected, suggesting a role for NO not only in neuromodulation but also in retinal development. Accepted: 22 January 1997     

Embryologic development of rat adrenal medulla in transplants to the anterior chamber of the eye

The morphological development and plasticity of embryonic and postnatal rat adrenal medullary cells were studied in homologous adrenal grafts to the anterior chamber of the eye. The eyes of recipient rats were adrenergically denervated 10 days prior to grafting by extirpation of the superior cervical ganglion in order to increase levels of NGF and NGF-like activities in the iris. Grafts taken at the 15th day of embryonic development (E15), i.e., at the beginning of immigration of medullary progenitor cells into the adrenal cortical anlagen, contained no cortical or mature medullary cells after 2 weeks in oculo. Numerous sympathoblastic cells, however, were located at the anterior surface of the iris. E 16 and E 17 transplants showed abundant mature cortical tissue after 2 weeks. Small groups of medullary cells with the ultrastructural characteristics of mature pheochromoblasts or young chromaffin cells were interspersed among cortical cells without forming a discrete medulla. Neuronal cells were exclusively found outside the cortical cell mass. Sympathoblasts grew at the surface of the iris, while young sympathetic nerve cells, which were invested by Schwann cells and received synaptic axon terminals, were embedded into the stroma of the iris. Grafting of E 21 adrenals yielded very similar results except that, in a few instances, young chromaffin cells were located outside the cortex and sympathetic nerve cells were seen to be in close contact with cortical cells. In transplants of adult medullary cells typical mature adrenaline and noradrenaline cells were clearly distinguishable after 8 weeks even in the absence of cortical cells. The only indication of phenotypical changes in these cells was the formation by some of them, of neuritic processes which could be visualized in glyoxylic acid-treated whole mounts of irises. These results are compatible with the idea that embryonic adrenal medullary cells have the environmentally controlled potential to develop along the neuronal or endocrine line, but could also be interpreted in terms of a selection of a specific subpopulation with predetermined potentialities by a specific microenvironment. Moreover, these results suggest that increasing differentiation of medullary cells is accompanied by progressive restrictions in their genetic program, which eventually prevent full transdifferentiation of mature chromaffin into neuronal cells.     

Results of transplanting regions of the midbrain of human embryos into the brain of adult rats

A principle possibility for transplantation of the midbrain areas of the human embryos into the brain of mature rats has been demonstrated. For successful xeno-transplantations the midbrain of 7-8-week-old embryos is the most suitable. The intracerebral transplants grow predominantly along the capsule of the white substance fasciculi. Cell differentiation of the intraventricular transplants in comparison with the intramedullary ones takes less time. Manifestation of the glial scar at the borders of the transplant depends on its localization. Perspectives on applying the method of the nervous embryonal tissue transplantation into the brain of mature animals for reconstruction and formation of new centers in order to compensate cerebral defects are discussed.     

Transplantation of embryonal anlagen of the human neocortex into the brain of the rat

A possibility for transplanting anlages of human embryonal neocortex into mature rat brain has been studied. Light- and electron-microscopic investigations demonstrate that the embryonal tissue of the human neocortex implants into the cerebral grey and white substance of mature rats. In the grafts cellular elements proliferate and differentiate, neuropil is formed. These results open certain perspectives for modelling investigations on histogenesis of neural tissues and on studying possibilities for clinical use of grafts of the human embryonal brain.     

Electrophysiological research into afferent connections of embryonic neocortex allotransplants grafted into the association cortex of adult rats

Grafts of the rat fetal neocortex at the 17–18th day of gestation were placed in the cavity made by aspiration in the primary visual or somatosensory cortex of adult rats. Findings from electrophysiological research performed 3–3.5 months after this transplant showed that neurons of this transplant responded to sensory stimulation specific to the cortical regions replaced by the transplant in 50% of animals. This response was evoked by stimulating local receptive fields displaying a topical organization pattern in a proportion of the animals. Neuronal response in the transplant indicated that the usual field of vision previously existing on the replaced portions of visual cortex had been restored. Electrical stimulation applied locally to a number of brain structures showed that the transplants received afferent inputs from the thalamic nucleus normally projecting to the cortical region replaced by the graft, as well as from homotopic sites on the contralateral cortex. Latencies and time course of neuronal response to stimulating these regions of the host brain resemble those observed in the normal. Afferent inputs from the host brain to cortical transplants thus emulate normal cortical input. Possible mechanisms underlying reinnervation of the grafts are discussed.N. I. Vavilov Institute of General Genetics, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 20, No. 4, July–August, 1988, pp. 448–456.