Neuronal types in the lateral geniculate nucleus of man

Summary Nerve cell types of the lateral geniculate body of man were investigated with the use of a transparent Golgi technique that allows study of not only the cell processes but also the pigment deposits. Three types of neurons have been distinguished:Type-I neurons are medium-to large-sized multipolar nerve cells with radiating dendrites. Dendritic excrescences can often be encountered close to the main branching points. Type-I neurons comprise a variety of forms and have a wide range of dendritic features. Since all intermediate forms can be encountered as well, it appears inadequate to subdivide this neuronal type. One pole of the cell body contains numerous large vacuolated lipofuscin granules, which stain weakly with aldehyde fuchsin.Type-II and type-III neurons are small cells with few, sparsely branching and extended dendrites devoid of spines. In Golgi preparations they cannot be distinguished from each other. Pigment preparations reveal that the majority of these cells contains small and intensely stained lipofuscin granules within their cell bodies (type II), whereas a small number of them remains devoid of any pigment (type III). Intermediate forms do not occur.     

Neuronal types in the striatum of man

Summary Nerve cells of the human striatum were investigated with the use of a newly developed technique that reveals the pattern of pigmentation of individual nerve cells by means of transparent Golgi impregnations of their cell bodies and processes. Five types of neurons are distinguished:Type I is a medium-sized spine-laden neuron with an axon giving off a great number of collateral branches. The vast majority of the cells in the striatum belong to this type. Numerous intensely stained lipofuscin granules are contained in one pole of the cell body and may also extend into adjacent portions of a dendrite.Type II is a medium-sized to large neuron with long intertwining dendrites decorated with spines of uncommon shape. A distinguishing feature of this cell type is the presence of somal spines. This cell type is devoid of pigment or contains only a few tiny lipofuscin granules.Type III is a large multipolar neuron. The cell body generates a few rather extended dendrites that are very sparsely spined. The finely granulated pigment is evenly dispersed within a large portion of the cytoplasm.Type IV is a large aspiny neuron with rounded cell body and richly branching tortuous dendrites. The axon branches frequently in the vicinity of the parent soma. Large pigment granules are concentrated within a circumscribed part of the cell body close to the cell membrane.Type V is a small to medium-sized aspiny neuron. The dendrites break up into a swirling mass of thin branches. More than one axon may be given off from the soma. The axons branch close to the soma into terminal twigs. Cells of this type contain numerous large and well-stained lipofuscin granules.Each of the cell types has a characteristic pattern of pigmentation. The different varieties of nerve cells in the striatum can therefore be distinguished not only in Golgi impregnations but also in pigment-Nissl preparations.     

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.     

Pattern of lipofuscin pigmentation in nitrergic and non-nitrergic,neurofilament immunoreactive myenteric neuron types of human small intestine

Lipofuscin, an autofluorescent age pigment, occurs in enteric neurons. Due to its broad excitation and emission spectra, it overlaps with commonly used fluorophores in immunohistochemistry. We investigated the pattern of lipofuscin pigmentation in neurofilament (NF)-reactive nitrergic and non-nitrergic human myenteric neuron types. Subsequently, we tested two methods for reduction of lipofuscin-like autofluorescence. Myenteric plexus/longitudinal muscle wholemounts of small intestines of five patients undergoing surgery for carcinoma (aged between 18 and 69 years) were double stained for NF and neuronal nitric oxide synthase (nNOS). Lipofuscin pigmentation patterns were semiquantitatively evaluated by using confocal laser scanning microscopy with three different excitation wave lengths (one for undisturbed lipofuscin autofluorescence and two for specific labellings). Two pigmentation patterns could be detected in the five NF-reactive neuron types investigated. In nitrergic/spiny as well as in non-nitrergic/stubby neurons, coarse, intensely autofluorescent pigment granules were prominent. In non-nitrergic type II, III and V neurons, a fine granular, diffusely distributed and less intensely autofluorescent pigment was obvious. After incubation of wholemounts in either CuSO₄ or Sudan black B solutions, unspecific autofluorescence could be substantially reduced whereas specific NF and nNOS fluorescence remained largely unaffected. We conclude that NF immunohistochemistry is useful for morphological representation of subpopulations of human myenteric neurons. The lipofuscin pigmentation in human myenteric neurons reveals at least two different patterns which can be related to distinct neuron types. Incubations of multiply stained whole mounts in both CuSO₄ or Sudan black B are suitable methods for reducing autofluorescence thus facilitating discrimination between specific (immunohistochemical) and non-specific (lipofuscin) fluorescence.     

A simultaneous demonstration of particular enteric neuronal cell types with the NADH:nitro BT-dehydrogenase reaction and of nerve fibres containing enkephalin-like immunoreactivity in the myenteric plexus of the porcine small intestine

The myenteric plexus of the porcine small intestine is studied using a combined method for the simultaneous visualization of enteric intramural neuronal cell bodies and peptidergic nerve fibers. As earlier reported, the histochemical method for demonstration of the NADH-dependent dehydrogenase reaction allows the identification of the three neuron types of Dogiel but, in addition, the afore mentioned staining method creates fair conditions in the tissue for the subsequent indirect immunocytochemical visualization of neuropeptides, as demonstrated in this work by means of the indirect immunofluorescence method for enkephalin-like immunoreactivity. Intense fluorescent varicosities of enkephalin-like nerve fibres were found to ramify around dark-blue stained ganglionic cells of type I, type II and type III in a manner suggestive of innervation.     

Some morphological and histochemical features of the midgut myenteric plexus of the common European frog, Rana esculenta.

The neuron morphology and distribution of four putative transmitters were investigated in the myenteric plexus of frog (Rana esculenta) midgut. The gross morphology was revealed by NADH-diaphorase histochemistry, and the shape of the neurons by silver impregnation. Nerve cells had heterogeneous distribution: they either formed ganglia or placed as solitary neurons in the duodenum, while in the rest of the midgut only solitary neurons were observed. Three morphologically distinct cell types were revealed by silver impregnation: mainly type I and type II neurons cells were seen in the duodenum, while the rest of the intestine contained type II and III cells. Catecholamine fluorescence was revealed in nerve fibres in the duodenum, while few small nerve cells were observed in the small intestinal region. Acetylcholinesterase histochemistry showed strongly reactive nerve cells that were associated with the main fibre bundles in the duodenum. Only longitudinally oriented fibres and occasionally stained neurons were seen in the small intestine. Substance P immunocytochemistry revealed an extensive plexus, which contained a moderate number of stained perikarya in the full length of the midgut. Gamma-aminobutyric acid showed non-uniform distribution in the two parts of the midgut: a stronger and more regular fibre staining was found in the duodenum then in the rest of the intestine. Ultrastructural observations demonstrated that intrinsic neurons received synaptic inputs from the profiles contained agranular vesicles, while "P"-type profiles established close contacts with neurons. Both profile types formed close contacts with the smooth muscle cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

NADH-dehydrogenase reaction in combination with immunoperoxidase (PAP) staining for light microscopic observation on the interneuronal relations of the enteric nervous system of the pig

A novel procedure for a simultaneous demonstration of particular enteric nerve cell types and peptidergic nerve fibres has been developed by combining the histochemical reaction for NADH-dependent dehydrogenase and the unlabelled antibody peroxidase-antiperoxidase (PAP) method described by Sternberger. Whole-mount spreads were successively incubated in a NADH: nitroblue tetrazolium solution, fixed with a picric acid/formaldehyde mixture, dehydrated, cleared and rehydrated before processing for immunocytochemical localization of the neuropeptide by the PAP method. The nerve cells appear heavily stained by deposits of dark blue formazan, whereas the peptide-containing nerves appear bright brown. In the myenteric and submucous plexuses of the porcine small intestine the devised method allows an appropriate identification of Dogiel's type I, type II and type III neurons surrounded by varicose enkephalin-like immunoreactive fibre baskets with button-like twigs to the very surface of the ganglionic cells, suggestive of synaptic connections.     

Identification of lactotropes (PRL cells), somatotropes (GH cells), corticotropes (ACTH cells) and thyrotropes (TSH cells) in the pituitary gland of the musk shrew, Suncus murinus L. (Insectivora), by immunohistochemistry

By means of immunohistochemistry, lactotropes, somatotropes, corticotropes and thyrotropes in the pituitary of the male musk shrew, Suncus murinus L., were identified at the electron-microscopic level. Lactotropes were classified into three types: type I containing large (200-450 nm in diameter) round secretory granules, type II with medium-sized (150-250 nm in diameter) ones and type III with small (50-150 nm in diameter) ones. Somatotropes were also classified into type I somatotropes that contain large (450 nm in diameter) spherical secretory granules and type II somatotropes containing comparatively small (300 nm in diameter) round granules. Both type I and II somatotropes were small and sometimes contained rod-shaped granules. Corticotropes were round or oval cells with round secretory granules in various densities and sizes (150-500 nm in diameter) scattered all over the cytoplasm. Thyrotropes were angular or polyhedral cells containing electron-transparent round secretory granules (200-300 nm in diameter) and large irregularly shaped granules with a maximum diameter of about 1,500 nm. Each type of the cells may be distinguished by its respective ultrastructural characteristics alone without the aid of immunohistochemistry.     

Immunocytochemical and immuno-electron-microscopical study of growth hormone cells in male and female rats of various ages

Summary Growth hormone (GH) secretory cells were identified by immunogold cytochemistry, and were classified on the basis of the size of secretory granules. Type I cells contained large secretory granules (250\2-350 nm in diameter). Type II cells contained the large secretory granules and small secretory granules (100\2-150 nm in diameter). Type III cells contained the small secretory granules. The percentages of each GH cell type changed with aging in male and female rats of the Wistar/Tw strain. Type I cells predominated throughout development; the proportion of type I cell was highest at 6 months of age, and decreased thereafter. The proportion of type II and type III cells decreased from 1 month to 6 months of age, but then increased at 12 and 18 months of age. The pituitary content of GH was highest at 6 months of age, and decreased thereafter. Estrogen and androgen, which are known to affect GH secretion, caused changes in the proportion of each GH cell type. The results suggest that when GH secretion is more active the proportion of type I GH cell increased, and when GH secretion is less active the proportion of type II and type III cells increased. The type III GH cell may therefore be an immature type of GH cell, and the type I cell the mature type of GH cell. Type II cells may be intermediate between type I and III cells.     

A histochemical study of the cells of the ventral cord ganglia of the horseshoe crab,Limulus polyphemus (L.)

Summary The ventral cord ganglia of the horseshoe crab, Limulus polyphemus, contains six distinct cell types: three appear to be ordinary neurons and three exhibit the staining affinities of neurosecretory cells.The presumed neurosecretory cells have been termed neurosecretory cell I (NSC I), NSC II and NSC III. NSC I cells contain a colloid-like inclusion which may occur as a single small vacuole or occupy more than one-half of the cell volume. Colloid inclusions occur with greater frequency toward the periphery, although small cells of similar staining affinity occur in cords extending to the fibrous core. The histochemical tests suggest that the cytoplasm is positive for proteins, but contains no strong acidic groups which may have been derived from S-S or S-H groups. The presence of carbohydrate is also indicated.NSC II cells exhibit distinct secretory cycles. Early in the cycle the cytoplasm becomes phloxinophilic and progresses to a distinct fuchsinophilic stage. Small homogeneous irregular inclusions are found in the axon hillock during the latter stages of the cycle. Histochemical tests suggest the presence of a carbohydrate and strong acidic groups which may have been derived from S-S or S-H groups. There are small cells present which appear to be immature neurosecretory cells.NSC III cells are characterized by a perinuclear ring of cytoplasm which is stained by chrome alum hematoxylin but not by paraldehyde fuchsin. A secretory cycle may also be present in this cell type.The three cell types presumed to be ordinary neurons exhibit no particular staining affinity for the stains or tests used in this study.This study was supported in part by a grant from the Central Fund for Research of the Pennsylvania State University.     

Morphological characteristics of different types of neurons in the ventrooralis anterior,ventrooralis internus,and ventrooralis posterior nuclei in the human thalamus

1. Golgi-Kopsch preparations of the oral ventral nuclei of human thalamus were analyzed in an attempt to classify the neuronal types. 2. Three types of neurons are described for the first time in humans. Type I neurons are large or medium in size and bear dendrites with protrusions, spines, and short hair-like appendages. Some have a radiate dendritic arbor and others have dendrites grouped in tufts. The dendritic trees of these neurons are dense. 3. Type II neurons are medium or small in size with less dense dendritic trees. These cells have somatic as well as dendritic appendages of different forms. 4. Relatively rare is a type of very small neurons, type III, with few and sparsely branching dendrites.     

The lipofuscin in neuroglial cells of the optic nerve of Formosan rock-monkey (Macaca cyclopis)

The ultrastructure of lipofuscin granules in neuroglial cells of the optic nerve of the Formosan Rock-Monkey was investigated by electron microscopy. In the cytoplasm of astroglial cells, numerous irregular lipofuscin granules were characterized by the presence of large lipid droplets, small electron-dense pigment granules, and some lamellar structures. The lipofuscin granules of the oligodendroglial cells were composed largely of dense, coarse pigment granules, multilinear structures, and a few small lipid droplets. The lipofuscin granules in microglial cells were characterized by numerous lipid droplets in various sizes, small electron-dense pigment granules, and prominent lamellar structures. It was reported that the lipofuscin granules are wear-and-tear materials and products from the cells in lower functional activity. However, our observations suggest that the presence of lipofuscin granules in the neuroglial cells of the optic nerve is likely a characteristic product of active phagocytosis.     

Blood and inflammatory cells of the lungfish Lepidosiren paradoxa

A special interest exists concerning lungfish because they may possess characteristics of the common ancestor of land vertebrates. However, little is known about their blood and inflammatory cells; thus the fine structure, cytochemistry and differential cell counts of coelomic exudate and blood leucocytes were studied in Lepidosiren paradoxa. Blood smear analyses revealed erythrocytes, lymphocytes, monocytes, polymorphonuclear agranulocytes, thrombocytes and three different granulocytes. Blood monocytes and lymphocytes had typical vertebrate morphology. Thrombocytes had large vacuoles filled with a myelin rich structure. The polymorphonuclear agranulocyte had a nucleus morphologically similar to the human neutrophil with no apparent granules. Types I and II granulocytes had eosinophilic granules. Type I granulocytes had round or elongated granules heterogeneous in size, while type II had granules with an electron dense core. Type III granulocyte had many basophilic granules. The order of frequency was: type I granulocyte, followed by lymphocyte, type II granulocyte, monocyte, polymorphonuclear agranulocyte and type III granulocyte. Peroxidase localized mainly at the periphery of the granules from type II granulocytes, while no peroxidase expression was detected in type I granulocytes. Alkaline phosphatase was localized in the granules of type II granulocyte and acid phosphatase cytochemistry also labelled a few vacuoles of polymorphonuclear agranulocyte. About 85% of the coelomic inflammatory exudate cell population was type II granulocyte, 10% polymorphonuclear agranulocyte and 5% macrophages as judged by the nucleus and granule morphology. These results indicate that this lungfish utilises type II granulocytes as its main inflammatory granulocytes and that the polymorphonuclear agranulocyte may also be involved in the inflammatory response. The other two granulocytes appear similar to the mammalian eosinophil and basophil. In summary, this lungfish appears to possess the typical inflammatory granulocytes of teleosts, however, further functional studies are necessary to better understand the polymorphonuclear agranulocyte.     

Small granule-containing cells of the central nervous system of the bivalve mollusk Patinopectin yessoensis (Jay)

In the CNS of the Patinopecten yessoensis (Jay) two types of cells have been revealed. The I type cells are typical unipolar neurons with a developed granular endoplasmic reticulum and Golgi compex, with a nucleus containing small amount of chromatin. They possess elementary peptidergic granules. The II type cells have in their cytoplasm and processes a large amount of electron-opague granules, specific for adrenergic systems. The nucleus is rich in clustered chromatin, the granular endoplasmic reticulum is poorly developed, cytosomes are absent. According to their ultrastructural organization the latter correspond to small granular cells of the mammalian autonomic nervous system.     

Synaptic regulation of paraventricular arginine vasopressin-containing neurons by neuropeptide Y-containing monoaminergic neurons in rats

Summary Synaptic regulation of arginine vasopressin (AVP)-containing neurons by neuropeptide Y (NPY)-containing monoaminergic neurons was demonstrated in the paraventricular nucleus of the rat hypothalamus. NPY and AVP were immunolabeled in the pre- and the post-embedding procedures, respectively, and monoaminergic fibers were marked by incorporating 5-hydroxydopamine (5-OHDA), a false neurotransmitter. The immunoreaction for NPY was expressed by diaminobenzidine (DAB) chromogen, and that for AVP by gold particles. The DAB chromogen was localized on the surface of the membrane structures, such as vesicles or mitochondria, and on the core of large cored vesicles. Gold particles were located on the core of the secretory granules within the AVP cell bodies and processes. The incorporated 5-OHDA was found as dense cores within small or large vesicular structures. From these data, three types of nerve terminals were discernible: NPY-containing monoaminergic, NPY-containing non-aminergic, and monoaminergic fibers. The AVP cell bodies appeared to have synaptic junctions formed by these nerve terminals as well as by the unlabeled nerve terminals which have small clear vesicles and large cored vesicles. These different types of nerve terminals were frequently observed in a closely apposed position on the same AVP cell bodies. The functional relationships of these three types of neuronal terminals are discussed.     

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.     

Morphology and immunocytochemistry of two endocrine cell types in the guinea-pig esophageal epithelium

Summary Two types of endocrine cells in the basal layer of the keratinized stratified squamous epithelium in the guinea-pig esophagus were studied with immunohistochemistry by means of a streptavidin-biotin-bridge technique and by the immunofluorescence double-labelling technique. Cell-type I exhibited immunoreactivity to chromogranin A and to nucleosidetriphosphate-adenosinediphosphate(ADP)-phosphotransferase. Ultrastructurally, this cell type was characterized by small cytoplasmic dense-core vesicles in which immunoreactive product was localized. Cell-type II contained large membrane-limited granules, which were moderately electron dense. These granules displayed somatostatin immunoreactivity. Both cell types were located in close vicinity to non-myelinated nerve fibers and small blood vessels. The results provide evidence that, independent from the type of lining epithelium, the gastro-enteropancreatic system in guinea-pig extends to the lower portion of the esophagus.Supported by the German Research Foundation, grant He 919/6-2     

An ultrastructural study on gastric endocrine cells in the stomach gland patch of the koala Phascolarctos cinereus

The endocrine cells in the stomach gland patch of the koala (Phascolarctos cinereus) were studied ultrastructurally. They were classified into 3 types based on the ultrastructural profiles of their endocrine granules and tentatively categorized as type I, II, and III endocrine cells. Type I cells contained round granules that were for the most part larger than those observed in the other 2 cell types. The granules ranged from moderate to relatively high in electron density. Type II cells were angular in shape and characterized by the presence of granules that were polymorphous in profile. Contents of the endocrine granules in type II cells also showed a range of high to moderate electron density. Type III cells were oval or pyramidal in shape. They contained highly polymorphous granules that were round, oval, dumbbell-like or comma in shape and characterized by the presence of a clear space or halo separating the high to low electron-dense core from the limiting membrane of granules. Type III cells were observed most often whereas type I and II cells were a less frequent observation.     

Fine structure of morphologically well-defined type II neurons in the enteric nervous system of the porcine small intestine revealed by immunoreactivity for calcitonin gene-related peptide.

Calcitonin gene-related peptide (CGRP)-containing perikarya and axonal processes were localized by preembedding electron-microscopic immunocytochemistry in the porcine small intestine. Immunoreactive well-defined type II neurons were localized in the plexus myentericus, and plexus submucosus externus and internus. In some cases, they were found in direct contact to the basal lamina surrounding the ganlion, thus being in close apposition to the interstitial space. The perikarya are generally larger than the immunogative nerve cell bodies and have a typical smooth outline. The electron-microscopic features of the labeled nerve processes investigated provide evidence for their axonal nature. These ultrastructural observations confirm previous light-microscopic results which showed that CGRP-containing nerve cells in the porcine small intestine belong to the neuronal population of the type II cells, the processes of which display the ultrastructural features of axons. A large number of reactive varicosities show synaptic specializations on immunonegative nerve cell bodies, suggesting that at least part of the type II neurons have post-synaptic effects on CGRP-negative neurons.     

Cell types within the medial forebrain bundle: a Golgi study of preoptic and hypothalamic neurons in the rat

The morphology of lateral preoptic (POL) and lateral hypothalamic (HLA) neurons was studied in 14- to 200-day-old rats with the chlorate-formaldehyde modification of the Golgi method. Drawings of 91 POL and HLA neurons revealed three distinct neuronal types within the MFB based on somatic size and shape and dendritic morphology. Class I neurons, which accounted for 75-80% of the neurons in the MFB, has fusiform or multipolar somata averaging 21 X 14 micron and 2-5 sparsely branched dendrites with a moderate number of sticklike spines. The extensive dendritic domains of Class I neurons ranged from 700 to 1,500 micron and were usually oriented perpendicular to the longitudinal fibers of the MFB. Both nonoriented and oriented Class I neurons were encountered. Nonoriented Class I neurons had expansive dendritic arbors which reached nearly all regions of the MFB in the coronal plane. Oriented Class I neurons had dendritic domains which were confined to specific regions (e.g., ventral-lateral) of the MFB. Class II neurons, which made up approximately 10% of the MFB neurons, had large multipolar somata averaging 30 X 17 micron and 2-5 stout dendrites which were densely covered with hairlike spines. Class II neurons also exhibited spines on their somata and proximal dendritic trunks and had dendritic domains of 700-1,000 micron. Class III neurons had small somata averaging 15 X 12 micron and restricted dendritic arbors of 500-700 micron in diameter. Class III neurons exhibited both spiny and spine-free dendrites and made up 10% of MFB neurons. Because of the parcellation of chemically coded fiber systems within the MFB, individual POL and HLA neurons may not be homogeneous in the type of afferents they receive from other brain areas.