Development of mammalian nervous tissue transplanted into the brain and anterior chamber of the eye: problems and prospects

Some theoretical problems arising in connection with nervous tissue grafting in mammals are discussed. The survival of grafts in the brain and anterior eye chamber is provided by a complex of factors, including peculiarities of immunological reaction, blood-brain barrier and certain characteristics of embryonic nervous tissue. Organotypic development of ectopic grafts suggests a significant autonomy of inner genetic programmes in self-organization of brain structures. Development of the graft-host brain nervous connections is, to a great extent, determined by the factors of topographic closeness and the presence of free postsynaptic structures, without prominent specificity of the graft-brain relationships. Complex neurotrophic interactions, mainly provided by the glial cells, are also found between the graft and damaged host brain. A study of electric activity of the grafted neurons has shown a varying degree of dependence of the functional organization of the brain structures on the environmental afferent influences. The grafts can serve as a chronic endogenous source of neurotransmitters and neurohormones, and, possibly, restore interrupted structural connections, thus providing the compensation of some complex brain functions.     

Homotopic transplant of fetal cortex to lesioned motor cortex of adult rats. A comportamental and anatomical study.

Previous investigations have shown that the transplant of fetal nervous tissue in adult, formerly injured, brain induces an improvement of the neurological deficits. The process underlying this finding is not yet known. It has been proposed that this process is favourably supported by the reconstruction of the damaged circuitry, replacing the injured neurons with the transplanted fetal cells. In the present study we have investigated the relation between the improvement of the neurological deficits and the anatomical integration of the transplanted neurons within the host brain. The plan of the investigation included two steps: the first step consisted of inducing neurological deficits by kainic acid lesion of the motor cortex and then studying the changes in the motor learning following a homotopic transplant of fetal cortex in the side of the lesion. The second step consisted of studying the anatomical integration of the transplanted cortex with the thalamus of the host. The results showed that the rats with injury of the motor cortex followed by solid transplant of fetal cortex (E 17) had a significantly greater recovery of the motor learning with respect to non-transplanted rats with a lesioned motor cortex. In the same rats, the connections between the transplanted cerebral cortex and the thalamus of the host has been investigated. WGA-HRP solution was injected in the thalamus and both labeled fiber terminals and labeled cells were searched for in the transplants. The results showed that: 1) the host thalamus projects to the transplanted cortex with a lower density than to the host cortex surrounding the transplant; 2) the thalamic projection to the host cortex is topographically organized, whereas the projection to the transplant is arranged in patches without any topographical organization; 3) the transplant does not send a significant projection to the thalamus of the host. In conclusion, the experimental findings demonstrate that the reconstruction of an injured thalamo-cortical circuitry of adult rats transplanting fetal neurons is not possible. The improvement of the functional deficits by the transplant of fetal tissue may be referred to aspecific factors enhancing the functional activity of the host cortex undamaged by the initial injury. The identification of the nature of the hypothesized factors requires further investigation.     

Brain grafts and Parkinson's disease

In animal models, grafts derived from several different tissues, principally fetal substantia nigra and adrenal medulla from young adults, have been found to be effective in alleviating some of the manifestations of lesions of the substantia nigra. It has been suggested that these grafts function by diffusely secreting dopamine, by exerting trophic effects on the host brain, or by producing a new innervation of the host corpus striatum. Evidence for each of these modes of action is briefly reviewed. Several brain tissue transplantation techniques have been described. Each of these techniques has significant limitations in animal models. The significance of these limitations for human application is described, and possibilities for improving the efficacy of brain tissue transplantation in animal models and for human application are discussed.     

Intra-Retrosplenial Cortical Grafts of Cholinergic Neurons: Functional Incorporation and Restoration of High Affinity Choline Uptake

Fetal septal neurons transplanted into the deafferented retrosplenial cortex (RSC) of rats have been shown to reinnervate the host brain and ameliorate spatial memory deficits. In the present study we examined the effects of implanting cholinergic neurons on high affinity choline uptake (HACU) in the denervated RSC and the correlational relationship between this cholinergic parameter and the level of behavioral recovery. Three groups of animals were used: 1) normal control rats (NC), 2) rats with lesions of the fornix and cingulate pathways (FX), and 3) lesioned rats with fetal septal grafts in the RSC (RSCsep-TPL). We found that intra-RSC septal grafts produced significant increases in HACU, and that recovery of HACU was significantly correlated with the improvements in the performance of spatial reference memory, spatial navigation, and spatial working memory tasks. We have also investigated the ability of the host brain to modulate the activity of the implanted neurons. In particular we evaluated the effect of the animals' performance in a 6-arm radial maze task on high affinity choline uptake (HACU). Animals in each of the NC, FX, and RSCsep-TPL groups were randomly assigned one of the following subgroups: 1) rats that performed the maze task before the determination of HACU (BEH), or 2) rats that did not perform the maze task before the determination of HACU (NON-BEH). Significant increases were observed in the NC and RSCsep-TPL groups, but not in the FX animals, indicating that fetal septal grafts in the RSC can become functionally incorporated with the host neural circuitry, and that the activity of the implanted cholinergic neurons can be modulated by the host brain.     

Influence of neural grafting on rat brain with damaged temporal cortex

This study investigated the feasibility and certain aspects of grafting nerve tissue from 15- and 21-day embryo rats into the left temporal rat cortex damaged by a solution (1 µg/1 µliter) of kainic acid (KA). After unilateral damage induced in the temporal cortex by KA, extensive lesions were found in a number of brain structures (the hippocampus, thalamus, etc.) removed from the KA application site; asymmetry between hemispheres was also revealed from the areas of cross-sections of these structures. In the presence of temporal cortex from 21-day embryos grafted into the lesioned area and setting up axonal connections with the host brain, damage to brain structures removed from the lesioned site was either prevented or substantially reduced. Asymmetry between hemispheres as gauged from the area of their cross sections was no longer present in brain with such grafts; moreover, grafts from 15-day embryos transplanted into a cortex lesioned by KA projected out onto the brain surface, growing and compressing the latter. The damaging action of KA on the host brain extended in the presence of these grafts. A viable graft located within the damaged area is thought to inactivate excitatory transmitters accumulating due to KA action, probably fulfilling the function of the damaged cortex in some measure once connections with the host brain have been set up.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 22, No. 5, pp. 586–595, October–September, 1990.     

Fetal alcohol spectrum disorders: an overview with emphasis on changes in brain and behavior

Fetal alcohol spectrum disorders constitute a major public health problem. This article presents an overview of important issues that surround these disorders and emphasizes the structural and neurobehavioral consequences associated with prenatal exposure to alcohol. Diagnostic criteria are discussed, and possible moderating factors for the range of outcomes are mentioned. In addition, the prevalence of fetal alcohol spectrum disorders is described, and estimates of the financial impact of these disorders are given. Heavy prenatal alcohol exposure can severely affect the physical and neurobehavioral development of a child. Autopsy and brain imaging studies indicate reductions and abnormalities in overall brain size and shape, specifically in structures such as the cerebellum, basal ganglia, and corpus callosum. A wide range of neuropsychological deficits have been found in children prenatally exposed to alcohol, including deficits in visuospatial functioning, verbal and nonverbal learning, attention, and executive functioning. These children also exhibit a variety of behavioral problems that can further affect their daily functioning. Children exposed to alcohol prenatally, with and without the physical features of fetal alcohol syndrome, display qualitatively similar deficits. Determining the behavioral phenotypes that result from heavy prenatal alcohol exposure is critical, because the identification of these children is crucial for early interventions. In addition, knowing which brain areas are involved might enable the development of better intervention strategies. However, intervention needs to go beyond the affected individual to prevent future cases. As evidenced by the staggering financial impact these disorders have on society, prevention efforts need to be aimed at high-risk groups, and this issue needs to be made a high priority in terms of public health.     

New insights into saccular development and vascular formation in lung allografts under the renal capsule

The study of distal lung morphogenesis and vascular development would be greatly facilitated by an in vitro or ex vivo experimental model. In this study we show that the growth of mouse embryonic day 12.5 lung rudiments implanted underneath the kidney capsules of syngeneic or immunodeficient hosts follows closely lung development in utero. The epithelium develops extensively with both proximal and distal differentiation to the saccular stage. The vasculature also develops extensively. Large blood vessels accompany large airways and capillaries develop within the saccular walls. Interestingly, vessels in the lung grafts develop from endothelial progenitor cells endogenous to the explants and host vessels do not vascularize the grafts independently. This suggests that embryonic lungs possess mechanisms to prevent the inappropriate ingrowth of surrounding vessels. However, vessels in the lung grafts do connect to host vessels, showing that embryonic lungs have the ability to stimulate host angiogenesis and recruit host vessel connections. These data support the hypothesis that the lung vasculature develops by both vasculogenic and angiogenic processes: a vascular network develops in situ in lung mesenchyme, which is then connected to angiogenic processes from central vessels. The lung renal capsule allograft is thus an excellent model to study the development of the pulmonary vasculature and of late fetal lung development that requires a functional blood supply.     

Influence of the mesonephros on the development of fetal mouse ovaries following transplantation into adult male and female mice

We previously reported that fetal mouse ovaries frequently develop testicular structure following transplantation into adult male mice. The mechanism involved in gonadal sex reversal of ovarian grafts is not known. In the present study, we examined the influence of the adjacent mesonephros on development of the ovarian grafts. The results show that (1) when fetal ovaries were transplanted with the attached mesonephros, the frequency of ovotestis development was higher in male hosts than in female hosts, (2) the fetal ovaries that had been separated from mesonephros developed testicular structures more frequently than those with the mesonephros, and the incidence of ovotestis development was comparable in male and female hosts, (3) removal of the cranial or caudal half of the mesonephros resulted in a similar frequency of ovotestis development, and (4) when fetal ovaries were separated and reattached to the mesonephros, they developed testicular structures at a frequency similar to that of ovaries left attached to the mesonephros, and the sex of mesonephroi reattached to ovarian grafts did not influence the incidence of ovotestis development. These findings suggest that fetal ovaries can develop testicular structures after transplantation regardless of the sex of host, and that the adjacent mesonephros protects ovarian grafts from masculinizing stimuli more efficiently in female host than male hosts.     

Cryopreservation of embryonic cerebral tissue of rat.

Embryonic cerebral tissues (ECT) either fresh or frozen-stored, were cultured and transplanted into the cerebella of neonatal host rats. Many variables including composition of the freezing medium, freezing and thawing rates, and storage time in liquid nitrogen were studied systematically. The results indicated that the following conditions yielded good results for tissue culture: using 1 M Me2SO as the cryoprotectant, freezing the brain tissues at a rate of 1 degrees C/min until it reached -70 degrees C, storing the frozen samples in liquid nitrogen and thawing them fast in a 37 degrees C water bath. The viability of the frozen-thawed tissues was assessed by their abilities to grow and differentiate in vitro and in vivo after intracerebral grafting. In tissue culture, growth and differentiation were similar to those of the fresh ECT. Cell morphology and staining reactions were normal in supravital methylene blue staining, cresyl violet staining, and acetylcholinesterase staining. Neurons had well-developed Nissl bodies, and cholinergic neurons also differentiated. Autoradiographic studies showed that more than 50% of the neurons had the ability to uptake gamma-aminobutyric acid with high affinity. In brain tissue transplantation, 9 of 12 transplants survived subsequent grafting after cryopreservation. Moreover, the grafts of surviving cryopreserved tissue displayed cytological and cytoarchitectural characteristics identical to those of fresh grafts. All grafts were integrated with the surrounding host neural tissue. This suggested that there may be synaptic connections between the transplants and the host brain tissues. From this and similar studies on the subject by others wer conclude that cryopreservation is a feasible method for storage of embryonic brain tissue to be used later for intracerebral grafting.     

Factors involved in the testicular development from fetal mouse ovaries following transplantation

We have previously shown that fetal mouse ovaries develop testicular structures after transplantation into adult male mice. The mechanisms of gonadal sex reversal is poorly understood. In the present study, we examined how a host environment is involved in the induction of testicular development in ovarian grafts. Fetal ovaries on the twelfth day of gestation were microencapsulated with semipermeable membranes, transplanted beneath the kidney capsules of adult male mice, and fixed for histological examinations between the sixteenth and twenty-second day after transplantation. Fifteen of forty-seven ovarian grafts were found to be completely enclosed in microcapsules, whereas the microcapsule membranes of other grafts were partly broken or had been lost. These differences of microencapsulation conditions made it possible to study the role of host factors in gonadal sex reversal. All ovarian grafts surrounded by microcapsule membranes developed ovarian structures. In contrast, most ovarian grafts which had lost the microcapsules developed testicular structures in addition to ovarian structures. When ovarian grafts were partially enclosed in microcapsule membranes, testicular structures developed only in the area in contract with the host kidney. These results suggest that direct interaction between the ovarian graft and cells or large macromolecules from the host is involved in the development of testicular structures in ovarian grafts.     

Developmental and functional aspects of grafting of the suprachiasmatic nucleus in the Brattleboro and the arrhythmic rat

The development of suprachiasmatic nuclei (SCN) dissected from fetal rats and grafted in adult rat brains has provided additional insights in the normal ontogeny of the SCN. The SCN survives rather easily and develops to its typical adult cytoarchitectonical arrangement of contiguous clusters of vasopressin (VP)-, vasoactive intestinal polypeptide (VIP)- and somatostatin (SOM)- immunoreactive cells. Neither site of implantation, nor the establishment of efferent or afferent connections of the grafted SCN seems to be essential to allow it to develop normally into this distinguishing cytology. This independent maturation does certainly not contradict with its known endogenous and independent potency of circadian pacemaker function in the brain. If the fetal SCN is grafted in such a way that it could merge with the parenchyma of the brain of a VP-deficient Brattleboro rat, the VP neurons of the SCN often establish efferent connections with the genuine target areas of this nucleus as could be shown immunocytochemically. When the fetal SCN is grafted homotopically in the brain of SCN-lesioned rat (or hamster), the surviving SCN neurons are able to reverse the arrhythmicity of these rats. Free-running circadian rhythm of drinking or motor behaviour in constant darkness are induced within weeks after grafting. A correlation between this restorative effect and the immunocytochemical staining pattern of the SCN in the transplant and/or the afferent and efferent connections between graft and host brain, could, however, not be shown conclusively. Transplants with surviving SCN are also seen when arrhythmicity was still present, which made us conclude that there has to be a neural connection between graft and host rather than a neurohumoral control in order to explain the restorative effect of the SCN graft in SCN-lesioned animals.     

Behavioral and Morphological Studies of Fetal Neural Transplants into SCN-Lesioned Rats

We have studied the effects of fetal neuronal grafts on the temporal pattern of drinking behavior of suprachiasmatic nuclei (SCN)-lesioned adult rats. Additionally, in an independent set of animals, the immunohistochemical staining for vasopressin, vasoactive intestinal polypeptide, and neuropeptide Y and the retinal connections to the hypothalamus were studied. The behavioral experiments indicate that anterior hypothalamic transplants induced reorganization of the temporal pattern of drinking behavior when placed in the third ventricle of adult hosts bearing complete SCN lesions, but not when placed in a cavity in the occipital cortex. Such rhythmicity persists only when the animals were recorded under constant darkness but not under constant light, indicating that the restored rhythmicity was generated endogenously but that the oscillator was extremely sensitive to light. Fetal occipital cortex induced reorganization of the temporal pattern of previously arrhythmic hosts, but it disappeared when the animals were recorded under constant light or constant darkness. It is clear that this rhythmicity was exogenous. In contrast to the cortical transplants, the hypothalamic transplants showed a morphological organization similar to that found in the normal hypothalamus regardless of their placement in the host brain. From these observations it is concluded that development of neocortex is more affected by environmental factors than that of the hypothalamus. Both hypothalamic and cortical transplants induced sprouting of retinal fibers into the anterior hypothalamus and the grafted tissue. It is possible that such fibers could be the neuroanatomical substrate by which rhythmicity is induced by cortical tissue.     

Behavioral and Morphological Studies of Fetal Neural Transplants into SCN-Lesioned Rats

We have studied the effects of fetal neuronal grafts on the temporal pattern of drinking behavior of suprachiasmatic nuclei (SCN)-lesioned adult rats. Additionally, in an independent set of animals, the immunohistochemical staining for vasopressin, vasoactive intestinal polypeptide, and neuropeptide Y and the retinal connections to the hypothalamus were studied. The behavioral experiments indicate that anterior hypothalamic transplants induced reorganization of the temporal pattern of drinking behavior when placed in the third ventricle of adult hosts bearing complete SCN lesions, but not when placed in a cavity in the occipital cortex. Such rhythmicity persists only when the animals were recorded under constant darkness but not under constant light, indicating that the restored rhythmicity was generated endogenously but that the oscillator was extremely sensitive to light. Fetal occipital cortex induced reorganization of the temporal pattern of previously arrhythmic hosts, but it disappeared when the animals were recorded under constant light or constant darkness. It is clear that this rhythmicity was exogenous. In contrast to the cortical transplants, the hypothalamic transplants showed a morphological organization similar to that found in the normal hypothalamus regardless of their placement in the host brain. From these observations it is concluded that development of neocortex is more affected by environmental factors than that of the hypothalamus. Both hypothalamic and cortical transplants induced sprouting of retinal fibers into the anterior hypothalamus and the grafted tissue. It is possible that such fibers could be the neuroanatomical substrate by which rhythmicity is induced by cortical tissue.     

The hippocampus and neuro-transplantation

A review of the author's histological and electron-microscopic studies of differentiation of hippocampal transplants with different levels of the graft/host integration. The grafts developing in the anterior eye chamber were the experimental model of complete isolation from the brain. The effects of various factors (age of the donor fetal tissue, host age and strain, degree of the integration with the recipient brain) on the growth and neural organization of grafts were studied. Analysis of fine structure of intraocular and intracortical grafts, as a rule, showed mature highly differentiated neurons and glia and normal density of typical synaptic contacts. However, morphological features suggesting both hyperactivity of some neurons and continuous growth of some neural processes were observed. The expression of nonsynaptic and transport-metabolic interactions between the cells was increased. The observed ultrastructural deviations can be regarded as a compensatory adaptation of the tissue to the deficit of specific afferent signals. It was shown that in the absence of normal cellular targets, axons of the grafted neurons establish functional synaptic contacts with improper neural elements in the host brain.     

Cryopreservation of fetal rat brain tissue later used for intracerebral transplantation

Intracerebral grafting of immature brain tissue is now widely used as a tool to study neuronal development and regeneration in the brain and spinal cord. This has stimulated the interest in methods for storage of such tissue before transplantation. In this study a method for cryopreservation of immature rat central nervous tissue is presented and discussed in relation to current cryobiological principles. The method was applied to brain tissue from 16- and 17-day-old fetal rats, including the neocortex, habenula, septum and basal forebrain, cerebellum, and retina. After storage in liquid nitrogen from 6 to 52 days the tissue was grafted into the brain of adult rats. The recipients survived for 23 to 673 days before their brains were processed by current neuroanatomical, histological methods. The presence of graft tissues was recorded and their cellular and connective organization was examined, including their exchange of nerve connections with the host brain. The results obtained were comparable with results from other studies where the same tissues were grafted immediately after removal from the donor, and a study of cryopreservation of developing hippocampal tissue. We conclude that cryopreservation is a reliable method for storage of immature neural tissue later to be used for intracerebral grafting.     

Examination of Age‐dependent effects of fetal ethanol exposure on behavior,hippocampal cell counts,and doublecortin immunoreactivity in rats

Ethanol is known as a potent teratogen having adverse effects on brain and behavior. However, some of the behavioral deficits caused by fetal alcohol exposure and well expressed in juveniles ameliorate with maturation may suggest some kind of functional recovery occurring during postnatal development. The aim of this study was to reexamine age‐dependent behavioral impairments in fetal‐alcohol rats and to investigate the changes in neurogenesis and gross morphology of the hippocampus during a protracted postnatal period searching for developmental deficits and/or delays that would correlate with behavioral impairments in juveniles and for potential compensatory processes responsible for their amelioration in adults. Ethanol was delivered to the pregnant dams by intragastric intubation throughout 7–21 gestation days at daily dose of 6 g/kg. Isocaloric intubation and intact control groups were included. Locomotor activity, anxiety, and spatial learning tasks were applied to juvenile and young‐adult rats from all groups. Unbiased stereological estimates of hippocampal volumes, the total number of pyramidal and granular cells, and double cortin expressing neurons were carried out for postnatal days (PDs) PD1, PD10, PD30, and PD60. Alcohol insult during second trimester equivalent caused significant deficits in the spatial learning in juvenile rats; however, its effect on hippocampal morphology was limited to a marginally lower number of granular cells in dentate gyrus (DG) on PD30. Thus, initial behavioral deficits and the following functional recovery in fetal‐alcohol subjects may be due to more subtle plastic changes within the hippocampal formation but also in other structures of the extended hippocampal circuit. Further investigation is required. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 74: 498–513, 2014     

Immunohistochemical study on fetal raphe samples transplanted into the leptomeningeal tissue of 5,6-dihydroxytryptamine-treated adult rats

Summary Pieces of fetal midbrain raphe containing serotonergic and dopaminergic neurons were transplanted into the leptomeningeal tissue (see Fig. 3) of adult host rats that had previously been denervated by treatment with 5,6-dihydroxytryptamine. One, 2 and 5 months after transplantation, the rate of neuronal survival in the grafted tissue and the extent of axonal outgrowth into the host brain were studied by use of serotonin and tyrosine hydroxylase (TH) immunohistochemistry. The survival rate of the grafts in the 1-month group was approximately 70%. Neurons containing either serotonin or catecholamine were demonstrated by means of immunocytochemical procedures in the grafts. Two and 5 months after transplantation, serotonin-immunoreactive nerve fibers were densely distributed throughout the graft tissue, while TH-immunoreactive fiber elements were restricted to an area near the somata of TH-positive neurons. Numerous serotonin-immunoreactive fibers derived from the transplant were found in the leptomeningeal tissue surrounding the graft, on the wall of neighboring blood vessels, and also in the adjacent parenchyma of the host brain. Outgrowing TH-immunoreactive nerve fibers were not observed in the host brain, although such elements occurred in the leptomeningeal tissue and the wall of the larger blood vessels. These results suggest that the serotonergic and catecholaminergic (dopaminergic) neurons located in transplants of the raphe nuclei show different patterns when reinnervating the host tissue.     

Restoration of Orcadian Behavior by Anterior Hypothalamic Grafts Containing the Suprachiasmatic Nucleus: Graft/Host Interconnections

Destruction of the hypothalamic suprachiasmatic nucleus (SCN) disrupts circadian behavior. Transplanting SCN tissue from fetal donors into SCN-lesioned recipients can restore circadian behavior to the arhythmic hosts. In the transplantation model employing fetal hamster donors and SCN-lesioned hamsters as hosts, the period of the restored circadian behavior is hamster-typical. However, when fetal rat anterior hypothalamic tissue containing the SCN is implanted into SCN-lesioned rats, the period of the restored circadian rhythm is only rarely typical of that of the intact rat. The use of an anterior hypothalamic heterograft model provides new approaches to donor specificity of restored circadian behavior and with the aid of species-specific markers, provides a means for assessing connectivity between the graft and the host. Using an antibody that stains rat and mouse neuronal tissue but not hamster neurons, it has been demonstrated that rat and mouse anterior hypothalamic heterografts containing the SCN send numerous processes into the host (hamster) neuropil surrounding the graft, consistent with graft efferents reported in other hypothalamic transplantation models in which graft and host tissue can be differentiated (i.e., Brattleboro rat and hypogonadal mouse). Moreover, SCN neurons within anterior hypothalamic grafts send an appropriately restricted set of efferent projections to the host brain which may participate in the functional recovery of circadian locomotor activity.     

Afferent and efferent connections of the sexually dimorphic medial preoptic nucleus of the male quail revealed by in vitro transport of DiI

The medial preoptic nucleus of the Japanese quail is a testosterone-sensitive structure that is involved in the control of male copulatory behavior. The full understanding of the role played by this nucleus in the control of reproduction requires the identification of its afferent and efferent connections. In order to identify neural circuits involved in the control of the medial preoptic nucleus, we used the lipophilic fluorescent tracer DiI implanted in aldheyde-fixed tissue. Different strategies of brain dissection and different implantation sites were used to establish and confirm afferent and efferent connections of the nucleus. Anterograde projections reached the tuberal hypothalamus, the area ventralis of Tsai, and the substantia grisea centralis. Dense networks of fluorescent fibers were also seen in several hypothalamic nuclei, such as the anterior medialis hypothalami, the paraventricularis magnocellularis, and the ventromedialis hypothalami. A major projection in the dorsal direction was also observed from the medial preoptic nucleus toward the nucleus septalis lateralis and medialis. Afferents to the nucleus were seen from all these regions. Implantation of DiI into the substantia grisea centralis also revealed massive bidirectional connections with a large number of more caudal mesencephalic and pontine structures. The substantia grisea centralis therefore appears to be an important center connecting anterior levels of the brain to brain-stem nuclei that may be involved in the control of male copulatory behavior.     

Regeneration of the visual system in gastropods (Mollusca)

Abstract. The topic of tissue and organ regeneration has been of interest to life scientists ever since the phenomenon was noticed. The reason for this is obvious: if one can learn what drives and controls regeneration, i.e., how lost or damaged structures can be replaced, one not only has a better chance to understand an animal's embryogenesis and evolutionary relationship with other taxa, but one would also be in a better position to treat organ loss or tissue damage in humans. In this context, the possible restitution of individual sensory neurons or nerve projections has been of special interest to us. We identified central visual projections in several gastropod species and found that: (1) projections are very extensive across the brain and (2) they have connections with other systems and organs (including, most likely, non-ocular skin photoreceptors) that may be involved in the integration of signals from different sensors. Investigations of afferent and efferent visual elements at a morphological level should help reveal the neuronal basis of a gastropod's behavioral reactions.