Glutamatergic components of the retrosplenial granular cortex in the rat

The ultrastructural characteristics, distribution and synaptic relationships of identified, glutamate-enriched thalamocortical axon terminals and cell bodies in the retrosplenial granular cortex of adult rats is described and compared with GABA-containing terminals and cell bodies, using postembedding immunogold immunohistochemistry and transmission electron microscopy in animals with injections of cholera toxin- horseradish peroxidase (CT-HRP) into the anterior thalamic nuclei. Anterogradely labelled terminals, identified by semi-crystalline deposits of HRP reaction product, were approximately 1 μm in diameter, contained round, clear synaptic vesicles, and established asymmetric (Gray type I) synaptic contacts with dendritic spines and small dendrites, some containing HRP reaction product, identifying them as dendrites of corticothalamic projection neurons. The highest densities of immunogold particles following glutamate immunostaining were found over such axon terminals and over similar axon terminals devoid of HRP reaction product. In serial sections immunoreacted for GABA, these axon terminals were unlabelled, whereas other axon terminals, establishing symmetric (Gray type II) synapses were heavily labelled. Cell bodies of putative pyramidal neurons, containing retrograde HRP label, were numerous in layers V–VI; some were also present in layers I–III. Most were overlain by high densities of gold particles in glutamate but not in GABA immunoreacted sections. These findings provide evidence that the terminals of projection neurons make synaptic contact with dendrites and dendritic spines in the ipsilateral retrosplenial granular cortex and that their targets include the dendrites of presumptive glutamatergic corticothalamic projection neurons.     

Structure of anterior dorsal ventricular ridge in snakes.

Anterior dorsal ventricular ridge (ADVR) is a major subcortical, telencephalic nucleus in snakes. Its structure was studied in Nissl, Golgi, and electron microscopic preparations in several species of snakes. Neurons in ADVR form a homogeneous population. They have large nuclei, scattered cisternae of rough endoplasmic reticulum in their cytoplasm, and bear dendrites from all portions of their somata. The dendrites have a moderate covering of pedunculated spines. Clusters of two to five cells with touching somata can be seen in Nissl, Golgi, and electron microscopic preparations. The area of apposition may contain a series of specialized junctions which resemble gap junctions. Three populations of axons can be identified in rapid Golgi preparations of snake ADVR. Type 1 axons course from the lateral forebrain bundle and bear small varicosities about 1 mu long. Type 2 axons arise from ADVR neurons and bear large varicosities about 5 mu long. The origin of the very thin type 3 axons is not known; they bear small varicosities about 1 mu long. The majority of axon terminals in ADVR are small (1 mu to 2 mu long), contain round synaptic vesicles, and form asymmetric active zones. This type of axon terminates on dendritic spines and shafts and on somata. A small percentage of terminals are large, 5 mu in length, contain round synaptic vesicles, and form asymmetric active zones. This type of axon terminates only on dendritic spines. A small percentage of terminals are small, contain pleomorphic synaptic vesicles, and form symmetric active zones. This type of axon terminates on dendritic shafts and on somata.     

Synapsoarchitectonics of the septum of the cat brain

In the medial and lateral septal nuclei, 4 types of axonal terminals are distinguished. Type I contains spherical vesicles and forms asymmetric synapses on small and middle stems and spines of the dendrites; type I terminals comprise 63% in the medial nucleus of the total number of axons, and in the lateral one--52%. Type II contains polymorphic vesicles and forms symmetrical synapses on the soma and large dendrites. In the medial nucleus they comprise 6%, and in the lateral one--3%. Type III contains either clear spherical (IIIa), or polymorphic (IIIb) vesicles, as well as 1-2 vesicles with a dense core. They form axodendritic, axospine and axosomatic synapses. In the medial nucleus they comprise 25% and 3%, respectively, in the lateral one--40% and 2%. Type IV contains a great number of vesicles with a dense core. These terminals in both septal nuclei comprise 3% and do not participate in formation of active contacts.     

The discrimination of nine different types of synaptic boutons in the fundus striati (nucleus accumbens septi)

An attempt has been made to discriminate additional types of synapses than have been previously described in the nucleus accumbens septi of the cat, which can, according to Brockhaus (1942), justifiably be termed the fundus striati due to the fact that it possesses all of the morphological and some of the neurochemical features of the striatum. This was undertaken in order to correlate at least one type of synapse with each different afferent pathway. Nine distinct types of synapses could be differentiated electron microscopically: Type I: axo-spinous synapses with sparse, small, round vesicles which seemed to be the nigro-striatal endings (35%). Type II: axo-somatic or axo-dendritic en passant synapses containing small, round vesicles (3%). Type III: axo-spinous synapses filled with densely-packed, small, round vesicles displaying strong postsynaptic thickenings which seem to be cortico-striatal (17%). Type IV: large axo-spinous synapses with densely-arranged, small, round vesicles contacting larger spines branching off a pedicle (9%). Type V: axo-somatic or axo-dendritic synapses containing large pleomorphic vesicles, probably axon collaterals (1%). Type VI: axo-somatic or axo-dendritic synapses with elongated small vesicles (20 X 45 nm) (3%). Type VII: large axo-somatic or axo-dendritic synapses filled by densely-packed, small, round vesicles (11%). Type VIII: large axo-somatic or axo-dendritic synapses containing loosely-arranged, small, round vesicles (8%). Type IX: axo-somatic or axo-dendritic synapses containing large, round vesicles in a translucent axoplasm (13%).     

Synaptic connections of substance P-immunoreactive nerve terminals in the substantia nigra of the rat

Summary A monoclonal antibody that recognises the C-terminal part of substance P was used to study immunoreactive structures in the substantia nigra by the unlabeled antibody, peroxidase-antiperoxidase procedure. Immunoreactivity was present in nerve fibres in all parts of the substantia nigra, particularly in the pars reticulata and pars lateralis. Electron microscopically two types of bouton immunoreactive for substance P were found: Type 1 contained large electron-lucent vesicles, occasional large granulated vesicles and formed symmetrical synapses with dendrites. Type 2 boutons contained smaller, round electron-lucent vesicles, many large granular vesicles and formed asymmetrical synapses (having prominent postjunctional dense bodies) with dendrites and perikarya.Immunoreactive fibres with varicosities that had been identified light microscopically were studied in serial sections in the electron microscope. Each identified varicosity contained synaptic vesicles and formed a single synapse. An individual fibre formed boutons of only one kind (type 1 or type 2) and could form multiple synapses with the same neuron. Thus, an identified fibre in the pars compacta had eight varicosities, each of which was in synaptic contacts (type 2) with the dendrites or soma of the same neuron.The results are consistent with the concept that substance P is a synaptic transmitter in the substantia nigra and indicate that neurons in this region may receive a significant input from substance P-containing afferents, and that there are at least two types of such afferent fibres.     

The synaptic relationships between the primary afferent terminals and the cuneo-thalamic relay neurons in the rat cuneate nucleus

In order to establish the synaptic relationship between the primary afferent terminals and the cuneothalamic relay neurons in the cuneate nucleus, the combined retrograde transport of horseradish peroxidase (HRP) and experimental degeneration have been applied in the young adult albino rats. 10 to 30% HRP was injected contralaterally (0.5 microliter) in the ventrobasal thalamic nucleus and multiple dorsal rhizotomies (C5 to T1) in the cervicothoracic dorsal roots were performed on the side ipsilateral to the cuneate nucleus. The results showed that: The cuneo-thalamic relay (CTN) neurons were the major neuronal type of the nucleus. More than 55% of neurons have been labelled. These neurons were 18-30 micron X 15-25 micron in sizes. They distributed in the whole rostrocaudal extent of the nucleus, particularly dense in the middle portion. The cells varied from round, oval, spindle to multipolar in shapes. They were rich in cytoplasmic organelles and had well-developed roughed endoplasmic reticulum. Their nucleus was either centrally or eccentrically located and was rather regular. The HRP-positive granules were randomly distribute in the perikaryon, dendrites and initial segment of the axons; At least three types of the experimental degeneration of the primary afferent terminals (PAT) were observed in the cuneate nucleus two to three days after dorsal rhizotomy, namely, electron-dense, granular and neurofilamentous. These PAT were mostly large and contained round vesicles. They were commonly found within synaptic complex, in which they were presynaptic to dendrites of various sizes, and were themselves postsynaptic to smaller axon terminals containing flattened vesicles. Degenerating PAT forming isolated synapses were less commonly seen; The PAT in the synaptic complex were directly presynaptic to the dendrites originating from the CTN neurons. The dendrites forming PAT-CTN synases were of large and medium-sized. The PAT did not form direct axo-somatic synapses with the somata of CTN or of any other cell types in the cuneate nucleus.     

The morphology of somatostatin-immunoreactive neurons in the lateral nucleus of the rat amygdala

Three types of somatostatin-immunoreactive neurons are described in the lateral nucleus of the rat amygdala. These three types closely correspond to neurons previously reported in Golgi preparations of the lateral nucleus. Class I somatostatin neurons have triangular- or piriform-shaped somata with large primary dendrites and spiny secondary dendrites. Class II somatostatin neurons have small to medium-sized oval perikarya and are fusiform or multipolar in shape. Class III somatostatin neurons have small spheroid somata with small thinner relatively aspinous dendrites. Class I somatostatin neurons give rise to axons which project outside the lateral nucleus whereas class II and III neurons innervate other somatostatin-positive and non-somatostatin neurons within the lateral nucleus. Somatostatin neurons within the lateral nucleus are hypothesized to function as part of a network of somatostatin neurons extending from cortical regions through the amygdala to basal telencephalic and lower brain stem regions.     

Expression of zebrafish glutamate receptor delta2 in neurons with cerebellum-like wiring

Mammalian glutamate receptor (GluR) delta2 is selectively expressed in cerebellar Purkinje cells and plays key roles in cerebellar plasticity, motor learning, and neural wiring. Here, we isolated cDNA encoding the zebrafish ortholog of mammalian GluRdelta2. We found that in adult zebrafish brain, glurdelta2 mRNA was expressed not only in cerebellar Purkinje cells, but also in the crest cells of the medial octavolateral nucleus (MON) and the type I neurons of the optic tectum. Immunohistochemical analysis revealed that zebrafish GluRdelta2 proteins were selectively localized in the apical dendrites of these neurons. Interestingly, the crest cells of the MON and the type I neurons of the optic tectum receive large numbers of parallel fiber inputs at the apical dendrites and sensory inputs at the proximal or basal dendrites. These results suggest that the expression of zebrafish GluRdelta2 is selective for cerebellum-like neural wiring with large numbers of parallel fiber inputs.     

Ultrastructural study of neurotensin immunoreactivity in the superficial laminae of the dorsal horn of the rat

Neurotensin immunoreactivity was identified in cell bodies, dendrites, spines, axons, terminals and varicosities in superficial laminae of rat spinal cord with the electron microscope. Unlabeled terminals synapsed with neurotensin-immunoreactive cell bodies, dendrites and spines. Presynaptic terminals contained round or pleomorphic vesicles and generally made symmetrical contacts with medium-sized neurotensin-containing dendrites in outer lamina II, and asymmetrical or symmetrical contacts with large and small dendrites and spines in inner lamina II. Neurotensin immunoreactive axons were unmyelinated, and their terminals were presynaptic to unlabeled dendrites and spines in laminae I and II. Terminals contained small, round, clear vesciles (31 nm) and occasional large granular vesicles (78 nm). Contacts in outer lamina II were evenly distributed among dendrites of various sizes and spines, whereas the majority of labeled terminals in inner lamina II made contacts onto small dendrites and spines. These findings indicate that neurotensin effects in rat spinal cord are mediated by axodendritic synapses, and that neurotensin cells at the inner and outer borders of lamina II contact dendrites of efferent neurons or other interneurons in the dorsal horn.     

Neurotensin immunoreactivity in the central nucleus of the rat amygdala: an ultrastructural approach

Neurotensin (NT) was demonstrated in the central nucleus of the rat amygdala (CNA) using a modification of the avidin-biotin complex immunohistochemical technique. Electron-dense reaction product (particles were 15-25 nm in diameter) was localized in perikarya, dendrites, axons, and axon terminals. It was found also associated with profiles of rough endoplasmic reticulum, mitochondria, microtubules, and small agranular as well as large granular vesicles. In distal dendrites, the reaction product was associated with microtubules, vesicles, and postsynaptic densities. Axon terminals of three types formed synaptic contracts with NT-immunoreactive neurons in the CNA: one was characterized by numerous round or oval agranular vesicles, the second by numerous pleomorphic vesicles, and the third by agranular vesicles that were loosely distributed and pleomorphic. All three types formed symmetric axosomatic and asymmetric axodendritic contacts. NT-immunoreactive axon terminals containing small round agranular vesicles stood out clearly from the intermingling profiles of immunonegative structures. We found numerous glomeruli, each consisting of a central NT-immunoreactive dendrite surrounded by all three types of axon terminals. We observed that some NT-immunoreactive terminals formed symmetric axoaxonal contacts with each other, providing evidence for the presence of local NT-to-NT circuits, whereas many others synapsed with axon terminals devoid of NT immunoreactivity.     

Synaptology of three peptidergic neuron types in the central nucleus of the rat amygdala

The synaptology of neurotensin (NT)-, somatostatin (SS)- and vasoactive intestinal polypeptide (VIP)-immunoreactive neurons was studied in the central nucleus of the rat amygdala (CNA). Three types of axon terminals formed synaptic contacts with peptide-immunoreactive neurons in the CNA: Type A terminals containing many round or oval vesicles; Type B terminals containing many pleomorphic vesicles; and Type C terminals containing fewer, pleomorphic vesicles. Peptide-immunoreactive terminals were type A. All three types of terminals formed symmetrical axosomatic and asymmetrical axodendritic contacts. However, type B and peptide-immunoreactive terminals frequently formed symmetrical axodendritic synaptic contacts. VIP-immunoreactive terminals also formed asymmetrical axodendritic contacts. SS- and NT-immunoreactive terminals commonly formed symmetrical contacts on SS- and NT-immunoreactive cell bodies, respectively. VIP-immunoreactive axon terminals were postsynaptic to nonreactive terminals. Type B terminals appeared more frequently on VIP neurons than on NT or SS neurons.     

Light, fluorescence and electron microscopic studies of rabbit subclavian glomera.

The subclavian glomera (aortic bodies) of young New Zealand white rabbits were studied with the light, fluorescence, and electron microscopes. Two cell types were identified: type I, granule-containing (chief) cells, and type II, agranular (sustentacular) cells. The type I cells possessed large nuclei, the normal complement of cytoplasmic organelles and numerous electron-opaque cytoplasmic granules. The type II cells were agranular with attenuated cytoplasmic processes which partially or completely ensheathed the type I cells. The glomera were well vascularized. Capillary endothelial cells contained numerous pinocytotic vesicles, but few fenestrae. Two profiles of nerve terminals were observed. One, apposing the type I cells, contained numerous electron-lucent vesicles, several dense-cored vesicles, mitochondria and possessed membrane specializations resembling those usually observed in synaptic zones. The other profile contained abundant mitochondria and a few electron-lucent and dense-cored vesicles. Structural specializations were not observed on the apposed membranes of these terminals or adjacent to type II cells. Fluorescence histochemistry revealed an intense yellow-green fluorescence in the glomera, which indicated the presence of biogenic amines, possibly primary catecholamines or an indolamine. The electron-opaque granules observed in the type I cells were believed to be the storage sites for these amines. The subclavian glomera were found to be morphologically similar to the carotid body which is a known chemoreceptor.     

On the structure of the human striate area. Lamina IVcβ

Summary Layer IVc of the human striate area consists mainly of a great number of small spinous local circuit neurons which store numerous characteristic lipofuscin granules. Since the neurons of the neighbouring layers are almost devoid of pigment deposits the boundaries of lamina IVc are easily traceable. Hence, the pigment granules can be used as internal markers to unequivocally identify these small pigmented spinous local circuit neurons of lamina IVc in ultrathin sections. They have a large spherical nucleus surrounded by a narrow cytoplasmic rim poor in organelles, and very scarcely receive axosomatic symmetric synapses.Within layer IVc four types of synaptic boutons can be distinguished. Type-1-boutons are large, contain a few and loosely arranged round vesicles and make asymmetric synaptic contacts with dendrites and dendritic spines. The type-2-boutons which are also large are filled with densely packed round vesicles which accumulate at the presynaptic membrane. The large type-3-boutons are characterized by elongated vesicles and symmetric synaptic contact zones. These boutons generate several fingerlike protrusions. Small profiles which contain elongated vesicles and form symmetric synaptic contacts, are most probably parts of these protrusions. The large amount of small boutons with round vesicles and asymmetric synaptic contact zones are tentatively described as type-4-boutons although it is far from certain that they represent a uniform class. The presumable origins of the different types of boutons are discussed.Supported by the Deutsche Forschungsgemeinschaft (Br. 634/1)Dedicated to Prof. Dr. med. H. Leonhardt in honor of his 60th birthday     

The fine structure of the dorsal column nucleus and the nucleus of bischoff of the python (Python reticulatus)

Three types of neuronal perikaryal profiles were identified in the dorsal column nucleus and the nucleus of Bischoff of the python (Python reticulatus). Type I neuronal profiles are large (diameters 12–20 μm) with a deeply indented uncleus. The cisterns of rough endoplasmic reticulum (rER) are mostly randomly dispersed. Axosomatic synapses are few. Type II neuronal profiles (9–11 μm) have a smooth, round, or slightly oval nucleus. Several small stacks of rER are present. Type III neuronal profiles (8–10 μm) have little cytoplasm. The nuclear margin is irregular but not deeply infolded. The rER usually consists of a single long perinuclear ribosome-studded cistern. Two types of astrocytic profiles have been identified. Both types contain abundant filaments. Type I astrocytes are large cells, and the nucleus is very irregular in shape. Type II astrocytes are smaller and are found among the myelinated axons in the dorsal funiculus. Two classes of axon terminals have been identified. One class contains round synaptic vesicles (R profiles) and the other flattened vesicles (F profiles). Some R profiles are small (SR profiles), others are large (LR profiles). Some R profiles also contain a few large, dense-cored vesicles. The R and F profiles establish axodendritic and axoaxonal synapses, some of which are located in the synaptic glomeruli and others in the extraglomerular neuropil. In most of the axoaxonal synapses, the presynaptic element is an F profile and the post synaptic element an LR profile. Occasionally, LR profiles are presynaptic to F profiles. The findings in the python are compared with those of the dorsal column nuclei of the rat, cat, and monkey.     

Neuronal and synaptic organization of the lateral geniculate nucleus of the tree shrew,Tupaia glis

Summary The ultrastructural study of the lateral geniculate nucleus (LGN) of the tree shrew (Tupaia glis) revealed two types of neurons: (1) a large thalamocortical relay cell (TCR), which may bear cilia, and (2) a small Golgi type-II interneuron (IN) with an invaginated nucleus. The narrow rim of pale cytoplasm of the IN contains fewer lysosomes and fewer Nissl bodies than the cytoplasm of the TCR. The IN perikarya, which in some cases establish somatosomatic contacts, frequently contain flattened or pleomorphic synaptic vesicles. The ratio of TCR to IN is 31.Three types of axon terminals were observed in the LGN. Two of them contain round synaptic vesicles but differ in size. The large RL boutons undergo dark degeneration after enucleation; they are the terminals of retino-geniculate fibers. The smaller RS boutons show dark degeneration after ablation of the visual cortex; they are the terminals of the cortico-geniculate fibers. The third type of bouton (F₁ does not degenerate after either intervention. The boutons of this type are filled with flattened vesicles and are believed to be intrageniculate terminals. F₂-profiles were interpreted as presynaptic dendrites of the IN. The characteristic synaptic glomeruli found in the LGN contain in their center an optic terminal. These optic terminals establish synaptic contacts with dendrites or spine-like dendritic protrusions of TCRs as well as with presynaptic dendrites. Synaptic triads were also seen. The distribution of the individual types of synaptic contacts in layers 3 and 4 was determined. Layer 4 contains only one third of the retino-geniculate synapses and of the synaptic contacts of F₁-terminals.     

On the fine structure of the small,heavily pigmented non-pyramidal cells in lamina II and upper lamina III of the human isocortex

Summary With the aid of a newly developed technique for the successive examination of both the Golgi and pigment picture of individual neurons (Braak, 1974a) Braak (1974b) demonstrated that within lamina II and upper lamina III of the human isocortex, heavily pigmented non-pyramidal cells are distributed irregularly and sparsely. The lipofuscin pigment granules serve as excellent internal markers to identify these non-pyramidal cells in ultrathin sections. This favourable circumstance facilitates the study of these interneurons in the electron microscope.The heavily pigmented non-pyramidal cells are small, spherical to ovoid with diameters of about 12–15 m. One pole of the cell comprising a large cytoplasmic area gives rise to a few dendrites, while the other pole is occupied by the nucleus and in some cases is in close apposition to another nerve cell body. The nucleus is deeply invaginated by the large cytoplasmic area and occasionally displays nuclear inclusions. Among the usual organelles distributed within the large cytoplasmic area the mitochondria with a moderately electron dense matrix are abundant and the coarse lipofuscin pigment granules are the most striking elements. The latter contain densely packed filamentous or tubular material and a single vacuole. The perikaryon rarely receives more than 3 type I and type II synapses per section per cell, whereas the dendrites receive numerous synapses of both type I and type II. Within the apposition zone to another nerve cell body (which in no case is a heavily pigmented non-pyramidal cell) puncta adhaerentia occur and also contacts in which the cleft of 8 nm is intersected by a dense stratum.Some of the ultrastructural findings are summarized in the schematic drawing of Figure 15.     

Ultrastructure of the corpus luteum of antarctic seals during pregnancy

Summary The fine structure of granulosa lutein cells from three crabeater seals, Lobodon carcinophagus, and two leopard seals, Hydrurga leptonyx, has been studied from early through mid-pregnancy. Analysis of the arrangement and modifications of the cytoplasmic organelles and inclusions has revealed three types of lutein cells throughout the corpus. Type I cell typically possesses a central nucleus and cytoplasm containing very large amounts of smooth and/or fenestrated endoplasmic cisternae which frequently extend from the juxta-nuclear to the periphery of the cell. Type II cell contains a central or eccentric nucleus, moderate amounts of peripheral, smooth and fenestrated cisternae which often form large and concentric membranous whorls, numerous mitochondria and small lipid droplets. Frequently these cells show polarity in the arrangement of the cytoplasmic organelles and inclusions. Type III cell contains predominant large lipid droplets, many mitochondria, and small amounts of smooth and fenestrated cisternae. In light microscopy the type I cell is evenly granular, while the type III cell is highly vacuolated. Type II cells have both granular and vacuolated conditions. Ultrastructural features of type I and II cells suggest that they probably secrete most of the steroids, whereas the primary role of the type III cells appear to be lipid storage.This research was supported by National Science Foundation, Grant No. 1325 from the Office of Antarctic Biology.     

A Golgi study of the isthmic nuclei in the pigeon (Columba Iivia)

Summary The isthmic nuclei of the pigeon were studied with the use of three different Golgi techniques. The nucleus isthmo-opticus (IO) consists of a single cell type in which all dendrites of one neuron take the same direction and ramify at identical distances from the perikaryon to form dense dendritic arborizations. The cell bodies of the IO neurons form two parallel layers. The dendrites of these neurons always extend to the area between the two layers so that the dendritic arborizations of opposite neurons overlap. A model of the cellular organization of the IO was constructed based upon these morphological characteristics. The neurons of the n. isthmi/pars parvocellularis (Ipc) have oval perikarya and long, smooth, infrequently branching dendrites. All neurons except those at the borders of the nucleus show the same dorsoventral orientation in their dendritic arborizations and together with their afferents seem to have a columnar organization. The dendrites of the neurons located at the margin of the nucleus ramify within the Ipc along its border. The n. semilunaris (Slu) consists of neurons with round somata that have on an average three dendrites with small spines. The axons leave the nucleus from the medial side and join the lemniscus lateralis. The neurons of the n. isthmi/pars magnocellularis (Imc) comprise a generalized isodendritic type resembling the cells of the reticular formation. Axons from the tectum penetrate the nucleus, making numerous en-passant contacts with several neurons.