Cytoplasmic syncytial interneuronal connection in molluscs

The absolute criteria developed by the authors have been presented; they allow revealing cytoplasmic syncytial connections between processes of nerve cells in vivo and in vitro at the light microscopy level by using classical methods and time lapse videoshooting in the phase contrast. With aid of electron microscopy, metastable membrane contacts and their perforations, cytoplasmic syncytial interneuronal pores, and fusion of nerve processes are demonstrated. In the culture of isolated molluscan neurons, the process of formation of syncytial connections between processes of the same neuron or of different neurons is reproduced. Processes of one neuron, which have syncytial connection with another neuron, are shown to remain viable after death of its neuronal soma. The cytoplasmic varicosities formed on processes of one neuron are able to overcome the place of syncytial contact with processes of another neuron and to move to the body of the latter. A hypothesis is put forward that the cytoplasmic syncytial connection between nerve processes is formed under the conditions of the absence of their glial sheaths.     

“Tight” junctions in the sheath of normal and regenerating motor nerves of the crayfish,Orconectes virilis

Summary Tight or occluding intercellular junctions occur between adjacent glial processes in normal and regenerating crayfish motor nerve sheaths. Although infrequent, these junctions possess the ridge and groove configuration characteristic of freeze-cleaved occluding junctions. When present, nerve sheath tight junctions consist of a single, or at most a few, parallel intramembrane ridges situated on the EF membrane face of the glial plasma membrane. Consequently, such contacts are rarely recognized in thin sections of plasticembedded nerve sheaths. Crayfish nerve sheath tight junctions are of the fascia occludens type and, therefore, do not impede solute flow across the nerve sheath. Fasciae occludentes of regenerating nerve sheaths occur in close proximity to discoid plaque-like aggregates of particles assumed to represent maculae adhaerentes. This relationship, which was not observed in normal nerve sheaths, suggests a functional association between the two types of junctions, perhaps developmental transformation of one junction type into the other. Although ridges and grooves of tight junctions occur next to crossfractured trans-glial channels, no functional significance is proposed for this relationship. This study is the first report of tight intercellular junctions in crustacean glial nerve sheaths.Supported by the National Research Council of Canada     

THE ELECTRON MICROSCOPIC LOCALIZATION OF CHOLINESTERASE ACTIVITY IN THE CENTRAL NERVOUS SYSTEM OF AN INSECT, PERIPLANET A AMERICANAL.

The distribution of esterase activity in the last abdominal ganglion, the connectives and the cereal nerves of the cockroach Periplaneta americana has been investigated cytochemically. Activity of an unspecific eserine-insensitive esterase (or esterases) has been found in glial elements in these regions of the nerve cord. In addition, sites of cholinesterase (eserine-sensitive) activity have been found in association with (a) the glial sheaths of the axons in the cereal nerves and connectives, (b) the glial folds encapsulating the neuron perikarya in the ganglion, and (c) in localized areas along the membranes of axon branches within the neuropile, often flanked by focal clusters of synaptic vesicles. These results are discussed with particular reference to the previously reported insensitivity of the insect nerve cord to applied acetylcholine, and to the probable existence of a cholinergic synaptic mechanism in the central nervous system of this insect.     

THE FINE STRUCTURAL ORGANIZATION OF NERVE FIBERS, SHEATHS, AND GLIAL CELLS IN THE PRAWN, PALAEMONETES VULGARIS

In view of reports that the nerve fibers of the sea prawn conduct impulses more rapidly than other invertebrate nerves and look like myelinated vertebrate nerves in the light microscope, prawn nerve fibers were studied with the electron microscope. Their sheaths are found to have a consistent and unique structure that is unlike vertebrate myelin in four respects: (1) The sheath is composed of 10 to 50 thin (200- to 1000-A) layers or laminae; each lamina is a cellular process that contains cytoplasm and wraps concentrically around the axon. The laminae do not connect to form a spiral; in fact, no cytoplasmic continuity has been demonstrated among them. (2) Nuclei of sheath cells occur only in the innermost lamina of the sheath; thus, they lie between the sheath and the axon rather than outside the sheath as in vertebrate myelinated fibers. (3) In regions in which the structural integrity of the sheath is most prominent, radially oriented stacks of desmosomes are formed between adjacent laminae. (4) An ~200-A extracellular gap occurs around the axon and between the innermost sheath laminae, but it is separated from surrounding extracellular spaces by gap closure between the outer sheath laminae, as the membranes of adjacent laminae adhere to form external compound membranes (ECM's). Sheaths are interrupted periodically to form nodes, analogous to vertebrate nodes of Ranvier, where a new type of glial cell called the "nodal cell" loosely enmeshes the axon and intermittently forms tight junctions (ECM's) with it. This nodal cell, in turn, forms tight junctions with other glial cells which ramify widely within the cord, suggesting the possibility of functional axon-glia interaction.     

Cell adhesion molecules in the central nervous system

Cell-cell adhesion molecules play key roles at the intercellular junctions of a wide variety of cells, including interneuronal synapses and neuron-glia contacts. Functional studies suggest that adhesion molecules are implicated in many aspects of neural network formation, such as axon-guidance, synapse formation, regulation of synaptic structure and astrocyte-synapse contacts. Some basic cell biological aspects of the assembly of junctional complexes of neurons and glial cells resemble those of epithelial cells. However, the neuron specific junctional machineries are required to exert neuronal functions, such as synaptic transmission and plasticity. In this review, we describe the distribution and function of cell adhesion molecules at synapses and at contacts between synapses and astrocytes.Key words: synapses, cell adhesion molecules, cadherin superfamily, immunoglobulin superfamily, nerve tissue proteins, axons     

The Fine Structure of Nerve Cells and Fibers, Neuroglia, and Sheaths of the Ganglion Chain in the Cockroach (Periplaneta americana)

The abdominal nerve cord of Periplaneta americana was studied utilizing light and electron microscopes. In the nerve cells, delicate granules, similar to those probably responsible for cytoplasmic basophilia, are evenly distributed in "dark" cells and clumped in "light" cells. Neuroglial cells are stained metachromatically by cresyl violet. The neuroglial cells have many processes which ramify extensively and are enmeshed to form overlapping layers. These imbricated processes ensheath the nerve cells; the inner layer of the sheath penetrates into the neuron and is responsible for the appearance of the trophospongium of Holmgren. Nerve fibers are embedded within glial cells and surrounded by extensions of the plasma membrane similar to mesaxons. Depending on their size, two or several nerve fibers may share a single glial cell. Nerve fibers near their terminations on other nerve fibers contain particles and numerous, large mitochondria. The ganglion is ensheathed by a thick feltwork of connective tissue and perilemmal cells. The abdominal connective has a thinner connective tissue sheath which is without perilemmal cells. The nerve fibers and sheaths in the connective become thinner as they pass through ganglia.     

Glial cells of the crayfish and their relationships with neurons. An ultrastructural study

1. Glial cells of the crayfish abdominal ganglia have been studied by transmission electron microscopy. Special attention is paid to the interrelationships between neurons and glial cells. Covers and hemocyte-related elements have also been considered. 2. Glial cells are identified by a common ultrastructure and close relationships with neurons. Four glial classes are considered, depending on their morphology, the compartment of neurons they ensheathe and neuron-glia interface. 3. Four ultrastructural classes of neurons are proposed. They differ in geometry and ultrastructure, as well as in glial covers (complexity and evaginations into the neuron somata). The morphology and organization of glial covers is specific for the neuron type they ensheathe. Specific glial covers do not differ in glia-glia communicatory structures. 4. The morphological and metabolical compartments of neurons are separated from the extracellular matrix or blood by specific glial systems. A system of two cells is interposed between neuron somata and hemolymph or the extracellular matrix. 5. Glial processes are crossed by membraneous tubular systems, at neuron perikarya and axons. Frequent gap junctions of varying area, density and number of IMP are found in the covers of neuron somata. 6. Neuron-glia interface bears numerous communicatory structures for both ionic and macromolecular exchange. They include junctions and transient modifications of membranes. Some of them suggest active transport mechanisms. 7. Modified endocytotic mechanisms seem to be responsible for the glia-to-neuron transfer of macromolecules as well as for the neuron-to-glia transfer of lamellar bodies. 8. The neuropil is divided into glomeruli (electrical or chemical) by glial processes and the trabeculae of the extracellular dense matrix. Neuron-glia membrane appositions have been found in electrical glomeruli. In chemical glomeruli, dense cored vesicles can release their content at neuron-neuron or neuron-glia intercellular cleft, at non-synaptic loci. 9. Neurons of type II contain peripheral complex Golgi systems, associated to subsurface cisternae and neuron-glia gap junctions, suggesting a cooperation of glial cells in specific macromolecular synthesis.     

Interactions between dissociated rat sympathetic neurons and skeletal muscle cells developing in cell culture. I. Cholinergic transmission

Sympathetic neurons, dissociated from superior cervical ganglia of newborn rats, and skeletal muscle cells were grown together in mass cultures containing many neurons (ca. 1000–3000) and myotubes, and in microcultures containing only one to three neurons and one or a few myotubes. When these neurons grow under the influence of certain nonneuronal cells many of them acquire cholinergic functions; in the absence of this influence they remain adrenergic. In the present study, the influence of the skeletal muscle cells was so effective that under certain conditions more than 75% of the neurons expressed cholinergic function as judged by their ability to form excitatory cholinergic synapses with myotubes (from rat and chick) and with each other. Stimulation of single neurons often gave rise in the myotubes to simple (direct) postsynaptic potentials (ejp's) and/or complex responses comprising a burst of ejp's that evoked one or more spikes; it appeared that these complex responses involved the activation of interneuronal pathways. In microcultures, a single neuron often made cholinergic synapses with itself (“autapse”) and/or with another neuron as well as with one or more myotubes. The nicotinic blocking agents, tubocurare (dTC), α-bungarotoxin (α-BuTx), and hexamethonium (C₆), attenuated or abolished the ejp's at moderate concentrations; the muscarinic blocker, atropine, was effective only at high concentrations. At several neuron-myotube junctions, the acetylcholine (ACh) receptors had dTC sensitivity similar to adult extrajunctional receptors; however, when different junctions were pooled the average dTC sensitivity was intermediate between that of adult end plate and extrajunctional receptors. The junctional C₆ sensitivity was much higher than expected from the action of the drug at the adult mammalian end plate. As in other studies, chemical transmission from neuron to neuron was also nicotinic cholinergic, but the nicotinic receptors on the myotubes were pharmacologically distinct from those on the neurons.     

Monosynaptic pathway responsible for generation of bursting activity in theHelix pomatia RPal neuron

The connection between a visceral ganglia interneuron initiating bursting pacemaker activity in the RPal neuron and the RPal neuron itself was investigated inHelix pomatia. Stimulating the interneuron either initiated or intensified bursting activity in the RPal neuron, depending on initial electrical activity in this cell. Replacing calcium with magnesium ions in the extracellular fluid and adding CdCl₂ to this fluid reversibly inhibited the effect of interneuronal stimulation on the RPal neuron. The latter effect was unaffected by increasing the concentration of extracellular Ca²⁺ 10 to 70 mM. Intracellular injection of both Cs⁺ and TEA into the interneuron produced an increase in the duration of its action potentials and rendered the link connecting the neurons more effective. It is deduced that a monosynaptic chemical connection exists between the interneuron and the RPal neuron for which a peptide compound serves as transmitter.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 1, pp. 20–28, January–February, 1987.     

THE DISTRIBUTION OF EXOGENOUS FERRITIN IN TOAD SPINAL GANGLIA AND THE MECHANISM OF ITS UPTAKE BY NEURONS

Toad spinal ganglion cells are individually enclosed in sheaths consisting of one or more attenuated layers of satellite cell cytoplasm surrounded externally by a basement membrane. Narrow (~150 A) extracellular channels separate these layers from one another and from the underlying neuron. In both in vivo and in vitro experiments it was found that molecules of ferritin, a water-soluble protein, are to some extent able to pass across the basement membrane and through these channels to reach the neuronal plasma membrane. Ferritin particles arriving at the neuronal surface are engulfed by the neuron in 0.1 to 0.2 µ "coated" vesicles. The concentration of ferritin in these vesicles is higher than in the perineuronal space. The ferritin incorporated into the neuron is segregated, apparently intact, in multivesicular bodies. It is inferred that the 150A channels in the satellite cell sheath are patent, aqueous spaces through which molecules with a diameter as large as 95 A are able to pass, and that these neurons are capable of taking up whole protein from their immediate environment by the process of pinocytosis.     

Energy utilization and gluconeogenesis in isolated leech segmental ganglia: Quantitative studies on the control and cellular localization of endogenous glycogen

The isolated segmental ganglia of the horse leech Haemopis sanguisuga were used as a model system to study the utilization and control of glycogen stores within nervous tissue. The glycogen in the ganglia was extracted and assayed fluorimentrically and its cellular localization and turnover studied by autoradiography in conjunction with [³H]glucose. We measured the glycogen after various periods of electrical stimulation and after incubation with K⁺, Ca²⁺, ouabain and glucose. The results for each experimental ganglion were compared to a paired control ganglion and the results analysed by paired t-tests. Electrical stimulation caused sequential changes in glycogen levels: a reduction of up to 67% (5–10 min); followed by an increase of up to 124% (between 15–50 min); followed by a reduction of up to 63% (60–90 min). Values were calculated for glucose utilization (e.g. 0.53 μmol glucose/gm wet weight/min after 90 min) and estimates derived for glucose consumption per action potential per neuron (e.g. 0.12 fmol at 90 min). Glucose (1.5–10 mM) increased the amount of glycogen (1.5 mM by 30% at 60 min) and attenuated the effects of electrical stimulation. Ouabain (1 mM) blocked the effect of 5 min electrical stimulation. Nine millimolar K⁺ increased glycogen by 27% after 10 min and decreased glycogen by 34% after 60 min; 3 mM Ca²⁺ had no effect after 10 or 20 min and decreased glycogen by 29% after 60 min. Other concentrations of K⁺ and Ca²⁺ reduced glycogen after 60 min. Autoradiographic analysis demonstrated that the effects of elevated K⁺ were principally within the glial cells. We conclude that (i) the glycogen stores in the glial cells of leech segmental ganglia provide an endogenous energy source which can support sustained neuronal activity, (ii) both electrical stimulation and elevated K⁺ can induce gluconeogenesis within the ganglia, (iii) that electrical activation of neurons produces changes in the glycogen in the glial cells which are controlled in part by changes in K⁺.     

Ultrastructural Characteristics of Interneuronal Connections of the Central Nervous System of Bivalve Molluscs

Ultrastructure and peculiarities of interneuronal contacts are studied in visceral ganglia of two species of bivalve molluscs, Anadara broughtoni and Mactra sulcatoria. Gap, desmosome-like, symmetrical, and classic synaptic junctions between neuronal bodies and their main processes are described. The major part of interneuronal junctions in the ganglia of the molluscs studied are symmetrical. Complex synaptic complexes formed by specialized and non-specialized junctions are observed.     

Study Glial Cell Heterogeneity Influence on Axon Growth Using a New Coculture Method

In the central nervous system of all mammals, severed axons after injury are unable to regenerate to their original targets and functional recovery is very poor ¹. The failure of axon regeneration is a combined result of several factors including the hostile glial cell environment, inhibitory myelin related molecules and decreased intrinsic neuron regenerative capacity ². Astrocytes are the most predominant glial cell type in central nervous system and play important role in axon functions under physiology and pathology conditions ³. Contrast to the homologous oligodendrocytes, astrocytes are a heterogeneous cell population composed by different astrocyte subpopulations with diverse morphologies and gene expression ⁴. The functional significance of this heterogeneity, such as their influences on axon growth, is largely unknown.To study the glial cell, especially the function of astrocyte heterogeneity in neuron behavior, we established a new method by co-culturing high purified dorsal root ganglia neurons with glial cells obtained from the rat cortex. By this technique, we were able to directly compare neuron adhesion and axon growth on different astrocytes subpopulations under the same condition.In this report, we give the detailed protocol of this method for astrocytes isolation and culture, dorsal root ganglia neurons isolation and purification, and the co-culture of DRG neurons with astrocytes. This method could also be extended to other brain regions to study cellular or regional specific interaction between neurons and glial cells.Download video file.^{(56M, mov)}     

INNERVATION OF THE FIBRILLAR FLIGHT MUSCLE OF AN INSECT: TENEBRIO MOLITOR (COLEOPTERA)

The structure of peripheral nerves, and the organization of the myoneural junctions in flight muscle fibers of a beetle is described. The uniaxonal presynaptic nerve branches display the "tunicated" structure reported in the case of other insect nerves and the relationship between the axon and the lemnoblast folds is discussed. The synapsing nerve terminal shows many similarities with that of central and peripheral junctions of other insects and of vertebrates (e.g., the intra-axonal synaptic vesicles) but certain important differences have been noted between this region in Tenebrio flight muscle and in other insect muscles. Firstly, the axon discards the lemnoblast before the junction is established and the axon effects a circumferential synapse with the plasma membrane of the fiber, which alone shows the increased thickness often observed in both pre- and postsynaptic elements. Secondly, in addition to the synaptic vesicles within the axon are present, in the immediately adjacent sarcoplasm, great numbers of larger postsynaptic vesicles which, it is tentatively suggested, may represent the sites of storage of the enzymatic destroyer of the activating substance similarly quantized within the intra-axonal vesicles. The spatial relationship between the peripherally located junctions and the portion of the fiber plasma membrane internalized as circumtracheolar sheaths is considered, and the possible significance of this with respect to impulse conduction is discussed briefly.     

蒙古黄鼠(Citellus dauricus)松果腺的超微结构观察

蒙古黄鼠松果腺主要由低电子密度的松果腺细胞和少量的胶质细胞、含色素细胞、神经突起及血管等组成。松果腺细胞内含有大量的线粒体、溶酶体、微丝、高尔基器、游离核糖体及中等量的光面和粗面内质网。纤毛、中心粒、突触带和致密芯小泡很少。松果腺细胞之间及胶质细胞之间存在电突触。最新被观察到的是大约有5%松果腺细胞内的线粒体产生“融合”现象,形成类似电突触的结构。神经突起可形成轴—轴突触,轴—树突触,并与松果腺细胞形成突触。     

The fine structure of cephalopod blood vessels II. The vessels of the nervous system

Summary Blood vessels of the perioesophageal nerve ganglia (brain) of Octopus vulgaris and the stellate ganglia of Sepia officinalis are described. The vessels have an incomplete endothelium, a complete basement membrane and a complete investment of pericytes. The pericytes are joined by specialised membrane junctions but these are not tight junctions. The main type of neuron/vessel arrangement is one where there is a collagen-filled space between the pericytes and the surrounding glial cells. Axons or neurons are sometimes applied directly to the vessel pericytes and in the neuropil, pericytes contact glial cells that ensheath bundles of axons. Blood spaces between neurons are also present.We would like thank Professor J. Z. Young and Dr. E. G. Gray for encouragement and advice, Mrs. Jane Astafiev for drawing Fig. 11, Mr. S. Waterman for photographic assistance and Miss Cheryl Martin for secretarial and other assistance.     

The relationship of neuromuscular synapse elimination to synaptic degeneration and pathology: Insights from WldS and other mutant mice

Neuromuscular synapse elimination, Wallerian degeneration and peripheral neuropathies are not normally considered as related phenomena. However, recent studies of mutant and transgenic mice, particularly the Wld ^S mutant—in which orthograde degeneration is delayed following axotomy—suggest that re-evaluation of possible links between natural, traumatic and pathogenic regression of synapses may be warranted. During developmental synapse elimination from polyneuronally innervated junctions, some motor nerve terminals progressively and asynchronously vacate motor endplates. A form of asynchronous synapse withdrawal, strongly resembling synapse elimination, also occurs from mononeuronally-innervated motor endplates following axotomy in young adult Wld ^S mutant mice. A similar pattern is observed in skeletal muscles of several neuropathic mutants, including mouse models of dying-back neuropathies, motor neuron disease and—remarkably—models of neurodegenerative diseases such as Huntington's and Alzheimer's diseases. Taken together with recent analysis of synaptic remodelling at neuromuscular junctions in Drosophila, a strong candidate for a common regulatory mechanism in these diverse conditions is one based on protein ubiquitination/deubiquitination. Axotomised neuromuscular junctions in Wld ^S mutant mice offer favourable experimental opportunities for examining developmental mechanisms of synaptic regression, that may also benefit our understanding of how degeneration in the synaptic compartment of a neuron is initiated, and its role in progressive, whole-cell neuronal degeneration.     

Ultrastructure of electrical synapses between nociceptive and anterior pagoda neurons in the CNS of the leech (Whitmania pigra)

We have used electron microscopy to measure quantitatively the morphology of electrical synapses in a circuit that has been proposed to account for the positional discrimination of the leech. Injection of a presynaptic nociceptive sensory neuron and the postsynaptic anterior pagoda neuron with HRP showed gap junctions in the neuropil. After double labeling, La³⁺-treated ganglia revealed labeled gap junctions from 2.0 to 3.5 nm wide. Between the labeled axon terminals, there were innexons with diameters of 8 to 10 nm. The innexon's central pore diameter was 2 nm, and the mean of the center-to-center distance between two innexons was 30 nm. Except for the gap junction areas of nociceptive sensory neuron axon terminals, the other ultrastructural parameters measured by freeze fracture were similar to those of samples labeled with HRP and filled with La³⁺. These data suggested that the gap width, innexon diameter, and its central pore do not on their own account for the mechanism of positional discrimination, which may depend rather on the differences in distribution and number of gap junctions. Electronic Publication     

A glial K+/Cl− cotransporter modifies temperature‐evoked dynamics in Caenorhabditis elegans sensory neurons

K⁺/Cl^? cotransporters (KCCs) are known to be crucial in the control of neuronal electrochemical Cl^? gradient. However, the role of these proteins in glial cells remains largely unexplored despite a number of studies showing expression of KCC proteins in glial cells of many species. Here, we show that the Caenorhabditis elegans K⁺/Cl^? cotransporter KCC‐3 is expressed in glial‐like cells and regulates the thermosensory behavior through modifying temperature‐evoked activity of a thermosensory neuron. Mutations in the kcc‐3 gene were isolated from a genetic screen for mutants defective in thermotaxis. KCC‐3 is expressed and functions in the amphid sheath glia that ensheathes the AFD neuron, a major thermosensory neuron known to be required for thermotaxis. A genetic analysis indicated that the regulation of the thermosensory behavior by KCC‐3 is mediated through AFD, and we further show that KCC‐3 in the amphid sheath glia regulates the dynamics of the AFD activity. Our results show a novel mechanism by which the glial KCC‐3 protein non‐cell autonomously modifies the stimulus‐evoked activity of a sensory neuron and highlights the functional importance of glial KCC proteins in modulating the dynamics of a neural circuitry to control an animal behavior.