Brain tissue transplanted to the anterior chamber of the eye

Summary Knowing the ontogenesis of the central monoamine neurons of the rat it is possible to obtain, by free-hand dissection from embryos and newly born animals, pieces containing dopamine (DA), noradrenaline (NA), and 5-hydroxytryptamine (5-HT) neurons that are small enough to permit homologous transplantation to the anterior chamber of the eye of adult animals. With this technique it was established that all three types of immature monoamine neurons are able to survive in the anterior chamber. Fluorescence histochemical analysis of whole mount preparations of the sympathetically denervated host irides revealed that both the catecholamine- and the 5-HT-neurons are able to partly reinnervate the irides, forming networks of varicose nerve terminals similar to the normally present sympathetic adrenergic ground plexus.Monoamine nerve cell bodies are attached to the irides but the majority of fluorescent nerve cell bodies is located within the transplants. Serial sectioning of these transplants showed rather well organized brain tissue, containing groups of fluorescent and non-fluorescent cell bodies, many areas being innervated by monoamine nerve terminals. When brain tissue was transplanted before the normal appearance of fluorescent neuroblasts (embryos with a crown-rump length less than 8 mm) monoamine neurons developed and matured within the eye.The amount of newly formed nerves of central origin recovered on the irides increased with time between the 2nd and 4th postoperative week and persisted after 2 months. The yield of new fibers was better using transplants from embryos with a crown-rump length between 15 and 30 mm than using transplants from larger embryos and newly born animals.If embryonic brain tissue known to be devoid of monoamine nerve cell bodies but containing monoamine nerve terminals in the adult state (cortex cerebri and cerebelli, spinal cord) was transplanted to sympathetically non-denervated eyes, the sympathetic adrenergic fibers seemed to be able to innervate the transplants.This work was supported by grants from the Swedish Medical Research Council (14×–3185), Karolinska Institutets fonder, and Magnus Bergvalls Stiftelse. We thank Miss Monica Eliasson, Mrs. Ulla Flyger, Mrs. Barbro Norstedt and Miss Ingrid Strömberg for skilful technical assistance. The generous gifts of Nialamide, Pfizer, and Pargyline, Abbott are gratefully acknowledged.     

Brain tissue transplanted to the anterior chamber of the eye: 2. Fluorescence histochemistry of immature catecholamine and 5-hydroxytryptamine neurons innervating the rat vas deferens

Summary Small pieces of the wall of the rat vas deferens were homologously transplanted to the anterior chamber of the eye together with small pieces of embryonic brain stem containing either developing noradrenaline (NA) cells of the locus coeruleus or 5-hydroxytryptamine (5-HT) neurons of the developing raphe system. The eyes of the recipients were sympathetically denervated. The double transplants became rapidly vascularized from the host iris. After 31/2 months the irides, together with their two transplants were analyzed by Falck-Hillarp fluorescence microscopy. Both the NA and the 5-HT neurons had survived and matured in the eye. Fluorescent varicose nerve terminals of the NA and 5-HT type respectively were found in all three potential receptor areas, i.e. within the CNS transplants, in the host irides and in the vas deferens transplants. In the latter, the newly formed monoamine nerve terminals arborized mainly within a well developed smooth muscle layer. The density of such new fibres was higher than or similar to that of the normally present sympathetic plexus in areas of the transplant close to the CNS transplant and lower in areas at a distance from the CNS transplant. It is concluded that immature central NA and 5-HT fibres are able to grow simultaneously into different types of sympathetically denervated smooth muscle tissues to form networks of fibres in the receptor organs resembling the normal sympathetic innervation.Supported by the Swedish Medical Research Council (04X-3185), and by grants from Magnus Bergvalls Stiftelse, Tidningen Expressens Prenatalforskningsfond and Karolinska Institutets fonder. We thank miss Ingrid Strömberg for skilful technical assistance. Nialamide^® was generously donated by Swedish Pfizer AB.     

The median eminence as a model to study presynaptic regulation of neural peptide release

Presynaptic receptors in peptidergic neurons within the brain should be considered as an important target upon which different neurotransmitters or neuromodulators can act to affect peptide release. Evidence reviewed in this paper indicates that the median eminence (ME) of the hypothalamus is an area where many such interactions at the presynaptic level take place. Release of LHRH, somatostatin and vasopressin is affected by a variety of neurotransmitters or neuromodulators, such as norepinephrine, dopamine, epinephrine, histamine, cholinergic and opioid agonists, and peptides such as angiotensin II. The actions of these agents were prevented by the use of specific receptor blockers, indicating the specificity of the response evoked. Furthermore, with the use of classical pharmacological approaches, the type and affinity of the receptor involved is well defined. Other agents, such as prostaglandins (PGE2) or steroids (estradiol) were found to affect the activity of the peptidergic neuron at the synaptic terminal by stimulating directly peptide release (as seems to be the case for the PGE2/LHRH interaction) or by changing the sensitivity of the terminal to other transmitters, as shown for estradiol. In conclusion, the evidence presented indicates that the ME is an excellent model to study presynaptic regulation of neural peptide release. A set of criteria was defined within the text to establish the physiological significance of the in vitro studies. Several of the substances tested, and particularly norepinephrine and dopamine, seem to meet all the requirements to be considered physiological presynaptic regulators of neural peptide release at the level of the ME.     

On the Feedback Between Theory and Experiment in Elucidating the Molecular Mechanisms Underlying Neurotransmitter Release

This review describes the development of the molecular level Ca²⁺-voltage hypothesis. Theoretical considerations and feedback between theory and experiments played a key role in its development. The theory, backed by experiments, states that at fast synapses, membrane potential by means of presynaptic inhibitory autoreceptors controls initiation and termination of neurotransmitter release. A molecular kinetic scheme which depicts initiation and termination of evoked release is discussed. This scheme is able to account for both spontaneous release and evoked release. The physiological implications of this scheme are enumerated.     

Electron microscopical study of synaptic glomeruli in cerebellum transplanted to the anterior eye chamber

Fetal cerebellar anlage from rat fetuses of 15-16 operational days were grafted into the anterior chamber of the eye of adult female albino rat recipients. Survival time of the transplants--containing both cerebellar cortex and cerebellar nuclei--was 2 to 2 1/2 months. Electron microscopical (EM) studies of the thin, under-developed granular layer of the laminated cerebellar cortex revealed the presence of well differentiated cerebellar glomeruli, surrounded by granule cell perikarya. As in the normal cerebellar cortex, the central profile of the glomerular complex was the large mossy terminal, containing spheroid synaptic vesicles, and forming synaptic contacts with dendrites and dendritic digits of the granule cells. Golgi cell axonal varicosities, containing ovoid or pleomorphic synaptic vesicles were found also on the periphery of the glomeruli. In addition, in several synaptic glomeruli, a third neuronal element was also observed, containing flat, discoidal vesicles and receiving synaptic contacts from mossy and Golgi axons, but being also presynaptic to granule cell dendrites. It is suggested that all mossy terminals in the cerebellar transplant originate from the cerebellar nucleus. Morphological evidence is also provided that the presynaptic dendrite-like processes--never found in normal cerebellar cortex--are also processes of nuclear neurons.     

Pharmacological Evidence for the Modulation of Monoamine Release by Adenosine in the Invertebrate Nervous System

An in vitro preparation from the pedal ganglia of the marine bivalve, Mytilus edulis, was used to examine the modulation of transmitter release by adenosine and its analogs from invertebrate nervous tissue. The ganglia of this organism contain the monoamines dopamine (DA), serotonin (5-HT), and norepinephrine (NE), and the presynaptic release of these substances is known to be calcium-dependent. This organism also contains a DA-sensitive adenylate cyclase system which resembles that seen in mammals. Neural tissue from the pedal ganglia was incubated with labeled monoamines, and release studies were then conducted in superfusion chambers; release of monoamines was evoked by the addition of 50 mM KCl. Addition to the superfusion medium of the adenosine analog, 5'-N-ethylcarboxamidoadenosine (NECA; 10 nM), inhibited the release of 5-HT and DA, and to a lesser extent NE, whereas 100-fold higher concentrations of adenosine itself and the adenosine analog, R-N6-phenylisopropyladenosine, were required to achieve comparable levels of inhibition. The inhibitory effects of NECA on neurotransmitter release were blocked by the adenosine receptor antagonist, theophylline (IC50 = 10-14 microM). The results from this study indicate for the first time the possible role of adenosine as a modulator of neurotransmitter release in the invertebrate nervous system.     

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.     

Comparative morphology and biochemistry of pancreatic tissue fragments transplanted into the anterior eye chamber and subcutaneous regions of the rat

The present study was designed to compare the morphological changes occurring in pancreatic tissue fragments transplanted into the anterior eye chamber (AEC) and the subcutaneous (SC) regions of the rat. Pancreatic tissue segments were removed from the tail end of the pancreas of neonatal rats and transplanted into the AEC and SC region of the neck of homologous rats. Five weeks after transplantation, the grafts were removed and processed for light microscopy, immunohistochemistry and radioimmunoassay. In both pancreatic tissue grafts, the acinar cells degenerated completely after transplantation. In contrast to this, insulin-, glucagon-, somatostatin- and pancreatic polypeptide-positive cells and pancreatic ducts survived equally well in both the AEC and SC grafts. The pattern and percentage distribution of insulin-, glucagon-, somatostatin- and PP-producing cells in the AEC and SC grafts was similar to that observed in normal pancreas. However, the percentage distribution of glucagon- and PP-containing cells was significantly (p < 0.03) lower in SC grafts when compared to normal. Radioimmunoassay showed that the AEC and SC pancreatic tissue grafts contained large quantities of insulin and glucagon. However, the insulin content of AEC was slightly but not significantly higher than that of SC grafts. The protein content of pancreatic tissue grafts in these transplantation sites was still significantly (p < 0.05) lower compared to normal. Lymphatic infiltration was also more conspicuous in SC grafts compared to AEC grafts. This infiltration by lymphatic cells was confined only to the endocrine portion of the graft. In conclusion, pancreatic tissue grafts survived in both the AEC and SC regions of rats but the AEC appears to be more conducive to graft survival than the SC region.     

Stereoselective Nicotine-Induced Release of Dopamine from Striatal Synaptosomes: Concentration Dependence and Repetitive Stimulation

Using a sensitive perfusion system we have studied the nicotine-induced release of [3H]dopamine ([( 3H]DA) from striatal synaptosomes. Nicotine-evoked release was concentration dependent with an EC50 of 3.8 microM. The response to 1 microM nicotine was comparable to that to 16 mM K+; 10 microM veratridine evoked a larger response. All three stimuli were Ca2+ dependent but only the response to veratridine was blocked by tetrodotoxin. Repetitive stimulations by 1 microM (-)-nicotine (100 microliters) at 30-min intervals resulted in similar levels of [3H]DA release; higher concentrations of (-)-nicotine resulted in an attenuation of the response particularly following the third stimulation. This may reflect desensitisation or tachyphylaxis of the presynaptic nicotinic receptor. The action of nicotine was markedly stereoselective: a 100-fold higher concentration of (+)-nicotine was necessary to evoke the same level of response as 1 microM (-)-nicotine. It is proposed that these presynaptic nicotinic receptors on striatal terminals are equivalent to high-affinity nicotine binding sites described in mammalian brain.     

Unit activity of the septum and hippocampus transplanted alone or together into the anterior chamber of the rat eye

Unit activity of grafts of the septum and hippocampus, developing for 3–6 months in the anterior chamber of the eye was investigated in acute experiments on curarized orcerveau isolé rats. Whereas neurons in the transplanted septum had spontaneous activity of irregular, regular, or rhythmic bursting type, activity was absent in hippocampal grafts or consisted of very infrequent synchronized population sites. If grafts of the septum and hippocampus developed together and contact was established between them, the same types of activity developed in the hippocampus as in the septum. In many paired grafts spontaneous epileptic phenomena were observed; they were easily provoked also by electrical stimulation of one of the grafts. Superfusion with medium with a high Mg⁺⁺ concentration and low Ca⁺⁺ concentration abolished spontaneous activity in most neurons of hippocampal but not septal grafts, and also suppressed some of the epileptic phenomena, evidence of the leading role of the septum in the organization of spontaneous hippocampal unit activity.Institute of Biological Physics, Academy of Sciences of the USSR, Pushchino-on-Oka. Translated from Neirofiziologiya, Vol. 17, No. 1, pp. 61–69, January–February, 1985.     

Ultrastructure of the capillaries of nerve tissue transplants growing in the anterior chamber of the eye

Blood capillaries have been studied electron microscopically in the areas of grafts (rat embryonal hippocamp and septal cerebral parts transplanted to mature rats) containing mainly nervous, glial or connective tissue cells. Certain differences in the capillary wall structure have been revealed. In areas with a great concentration of nervous cells, the blood capillaries are characterized by a dense arrangement of cellular elements in their walls, a continuous layer of the glial end-feet, this is specific for the CNS capillaries providing the blood--brain barrier. In peripheral area of the grafts, where glial elements predominate, the capillaries have loose arrangement of the mural cellular elements, great endotheliocyte activity, thick connective tissue tunic, lack of a dense glial surrounding. These characteristics make dubious the statement whether these capillaries possess the blood--brain barrier function. In places where connective tissue cells make aggregates, the capillaries do not possess the barrier properties because of perforations and fenestrae in endothelium and interruptions of the basal membrane, absence of pericapillary glial elements. All types of the capillaries demonstrate certain signs of a high functional activity. Formation of the capillary structure depends on the surrounding tissue.     

The activation of phosphatidylinositol turnover is not directly involved in the modulation of neurotransmitter release mediated by presynaptic muscarinic receptors

In the rat cerebral cortex, the comparative effects of various muscarinic agonists on the release of [³H]dopamine ([³H]DA), [³H]acetylcholine ([³H]ACh), and [³H]5-hydroxytryptamine ([³H]5-HT) from superfused nerve endings and on phosphatidylinositol (PI) turnover were studied. Acetylcholine (ACh) was found to be the most potent among the agonists tested on all three release systems examined, and also on the activation of PI turnover. Oxotremorine and bethanechol were very weak agonists when tested as stimulators of PI turnover. However, oxotremorine was very effective as a release modulator, while bethanechol was completely ineffective. Our data suggest that the activation of PI turnover is not directly involved in the modulation of neurotransmitter release mediated by presynaptic muscarinic receptors.     

Evidence for the Action of Endogenous Adenosine in the Rabbit Retina: Modulation of the Light-Evoked Release of Acetylcholine

Much evidence has accumulated supporting the hypothesis that the purine nucleoside adenosine may indeed function as a neuromodulator in the mammalian retina, but to date no reports have directly illustrated a physiological role for this nucleoside. In other regions of the CNS, adenosine agonists decrease transmitter release, whereas antagonists increase release. A similar role for adenosine in the retina is now apparent. The cholinergic amacrine cells of the rabbit retina were labeled with [3H]choline, and the effects of enzymatic adenosine degradation or adenosine antagonists on the light-evoked efflux of acetylcholine were evaluated. When endogenous adenosine was degraded by addition of adenosine deaminase, the light-evoked release of radioactivity derived from [3H]choline was significantly increased compared with control values. A similar response was observed when rabbit eyecups were superfused with a selective adenosine A1 receptor antagonist. The effect elicited by adenosine deaminase could be almost completely reversed by addition of cyclopentyladenosine, a highly selective A1 receptor agonist. These effects were observed in either the presence or the absence of picrotoxin. The results demonstrate a modulation of retinal physiology by adenosine.     

Insulin Binding in Four Regions of the Developing Rat Brain

Specific insulin binding has been demonstrated in partially purified membranes prepared from four regions of the developing rat brain. Insulin binding to brain membranes demonstrated kinetics and hormonal specificity that were quite similar to those reported for traditional insulin target tissues (e.g., liver and adipose tissue), and binding was significantly correlated with receptor concentration. Binding in the olfactory bulbs, cerebrum, cerebellum, and hypothalamus all reached highest values at 15 days of postnatal life, with the olfactory bulbs generally showing the greatest binding at all ages studied. A temporal relationship was found between insulin binding to brain membranes in the postnatal rat and plasma membrane protein synthesis, especially in the cerebellum and olfactory bulbs.