Node of Ranvier formation along fibres regenerating through silicone tube implants: a freeze-fracture and thin-section electron microscopic study.

Thin-section and freeze-fracture electron microscopy have been used to examine the morphogenesis of the node of Ranvier in peripheral nerves regenerating through silicone tubes. A major question posed by this study is whether node formation in fibres regenerating across a gap recapitulates that occurring in normal development. Node formation occurs concurrently with myelination and follows a similar spatial gradient of progression from a proximal to distal direction along the regenerated nerve.

The distribution of (Na+ + K+)ATPase is continuous along the axolemma of unensheathed axons from spinal roots of 'dystrophic' mice.

(Na+ + K+)ATPase-like immunoreactivity along the axolemma of sensory and motor neurons and the plasmalemma of Schwann cells from spinal roots of dystrophic mice (129 ReJ Dy/Dy) was determined using polyclonal antibodies specific for guinea pig renal (Na+ + K+)ATPase (GP-17), along with polyclonal (439-2) and monoclonal (9A5) antibodies specific for rat renal (Na+ + K+)ATPase. In normal and dystrophic mice, (Na+ + K+)ATPase-like immunoreactivity was observed along the axolemma at nodes of Ranvier using GP-17 and 439-2, each of which binds to isozymes of (Na+ + K+)ATPase composed of the alpha and alpha + forms of the catalytic subunit. Staining was not seen along the nodal axolemma with 9A5, a preparation that binds to the alpha form of the catalytic subunit.

Changes in synaptic morphology associated with presynaptic and postsynaptic activity: an in vitro study of the electrosensory organ of the thornback ray.

The influence of synaptic activity on synaptic structure was studied by selectively stimulating the presynaptic or postsynaptic membranes of ribbon synapses in an in vitro preparation, and examining the ultrastructure of synapses with conventional electron microscopic methods. Functionally significant changes in synaptic morphology were observed after direct depolarization of the presynaptic membrane or incubation with the neurotransmitter glutamate to depolarize the postsynaptic membrane. After depolarizing the presynaptic membrane for 30 seconds, the depth of the postsynaptic trough was reduced, and other morphological changes correlated with decreased sensitivity and spontaneous activity were evident.

Alterations in the ultrastructure of peripheral nodes of Ranvier associated with repetitive action potential propagation.

We have studied the structure of the node of Ranvier following physiological activation and electrophysiological monitoring. Our results indicate that some structures within the nodal complex undergo microanatomic alterations concomitant with repetitive impulse propagation. The experiments were designed to determine the nature and extent of the morphologic changes and any associated changes in the compound action potential.

Axons regenerated through silicone tube splices. II. Functional morphology.

The recovery of axons regenerated through silicone tube splices was studied with electron microscopic and morphometric methods. Regenerated nerves contained both myelinated and unmyelinated axons of near normal morphology. The number and diameter of axons increased with postoperative time, and size-frequency histograms demonstrated that regeneration occurred in all major fiber groups.

Axons regenerated through silicone tube splices. I. Conduction properties.

Changes in conduction properties of axons regenerating across a 10-mm gap bridged by a silicone cuff were investigated from compound action potential responses. Compound action potentials were detected as early as 6 weeks after surgery, and were small and slowly conducted at maximum velocities of about 3 m/s. With longer regeneration time, the potentials increased in size, velocity, and complexity.

The neuronal endomembrane system. II. The multiple forms of the Golgi apparatus cis element.

The cis element and its associated tubules and vesicles are ideally positioned to play a major role in the sorting of rough endoplasmic reticulum components destined for processing in the Golgi apparatus. Its position is also ideal for playing a major role in the assembly of the saccules which constitute the Golgi apparatus. The present study was undertaken to critically analyze the normal morphology of this Golgi apparatus component.

The neuronal endomembrane system. III. The origins of the axoplasmic reticulum and discrete axonal cisternae at the axon hillock.

The axoplasmic reticulum (AR) and the discrete element (e.g., vesicles, vesiculotubular bodies, multivesicular bodies, etc.

The neuronal endomembrane system. I. Direct links between rough endoplasmic reticulum and the cis element of the Golgi apparatus.

This is the first of three papers describing new components and structural relationships within the neuronal endomembrane system. This system includes: the nuclear envelope, rough endoplasmic reticulum, the Golgi apparatus, lysosomes, axoplasmic reticulum, and discrete cytoplasmic compartments such as vesicles, multivesicular bodies, and so on. Previous high voltage electron microscope studies of osmium-impregnated Golgi apparatus have shown that small varicose tubules often arise from the cis element.

Localization of sodium/potassium adenosine triphosphatase in multiple cell types of the murine nervous system with antibodies raised against the enzyme from kidney.

This report describes the development and characterization of a battery of highly specific antibodies to sodium/potassium (Na+ + K+)-ATPase and their use in localizing this enzyme in nervous tissue. The immunolabeling characteristics of polyclonal antibodies and monoclonal antibodies (Schenk, D. B.

Synaptic morphology and differences in sensitivity.

A relation between synaptic morphology and physiology was observed in an in vitro preparation of a sense organ (the ampulla of Lorenzini), in which activity was monitored from the primary afferent neurons before electron microscopic examination of the afferent synapses. The depth of the postsynaptic trough decreased as prefixation sensitivity of the sense organ decreased. This relation and other ultrastructural differences suggest that physiological properties of synapses are influenced by morphological features.

Orthogonal arrays are redistributed in the membranes of astroglia from alumina-induced epileptic foci.

Freeze-fracture techniques were used to examine the distribution of orthogonal arrays in the membranes of astroglia from specimens of cerebral cortex of epileptic and control rats. Astroglial membranes from experimental chronic epileptic cortex displayed normal densities of arrays in pial-glial regions surrounding the alumina granuloma. Astroglial membranes from deep parenchymal regions of epileptic cortex displayed increased numbers of arrays, especially in regions of membrane not normally displaying arrays.

Molecular morphology of the tetrodotoxin-binding sodium channel protein from Electrophorus electricus in solubilized and reconstituted preparations.

The appearance of detergent-solubilized voltage-regulated sodium channel protein was recently characterized by this laboratory. Negative-staining revealed rod-shaped particles measuring 40 X 170 A. Further studies have suggested that the actual configuration of this protein may be quite different from the rod-shaped structures.

The axoplasmic reticulum within myelinated axons is not transported rapidly.

The axoplasmic reticulum in myelinated axons is an extensive system of branched smooth membranous tubules which is found throughout the length of large axons. To investigate its motility and possible role in fast axonal transport, a focal chilling method was used to arrest transport at two sites separated by a 3 mm wide warm region along the saphenous nerve of mice. The experiments ran for 3-4 h since axoplasmic material travelling faster than 25 mm/day would clear from the central warm region.

Immunocytochemical localization of sodium channel distributions in the excitable membranes of Electrophorus electricus.

The tetrodotoxin binding protein, a major component of the Na+ channel, has been purified from the electric organ of the South American eel Electrophorus electricus. Antibodies to this protein were raised in rabbits and their specificity was demonstrated by a highly sensitive radioimmunoassay and by immunoprecipitation procedures. These antibodies were used to examine the distribution of the binding protein in the eel electroplax membranes and along myelinated nerve axons.

Subunit composition of bovine muscle acetylcholine receptor.

Acetylcholine receptors from fetal calf muscle were purified to homogeneity (specific activity up to 7500 nmol/g of protein), in reasonable yields (20-50%), and near-milligram quantity. Purification was by affinity chromatography on Naja naja siamensis toxin coupled to agarose by using methods similar to those for receptors from fish electric organs, but with modifications to account for the low concentration of receptor in muscle and the high probability of proteolysis. Immunochemical methods are described for approximating the extent of proteolysis in receptor preparations.

Electron microscopic visualization of the tetrodotoxin-binding protein from Electrophorus electricus.

Preparations of highly purified tetrodotoxin-binding protein (sodium channel) from the electric organ of the eel Electrophorus electricus were examined in negatively stained preparations. Structures observed in preparations exhibiting the highest tetrodotoxin binding tended to aggregate into ordered clusters with a unique ribbon-like conformation. The individual particles of these aggregates are elongated or rod-shaped, approximately 40 A wide and 170 A long.

Incorporation of acetylcholine receptors into liposomes. Vesicle structure and acetylcholine receptor function.

Functionally intact acetylcholine receptors can be solubilized from electric organ membranes of Torpedo californica and incorporated into liposomes by the cholate dialysis technique. Freezing and thawing of the reconstituted preparation appears to seal a population of initially leaky vesicles and leads to vesicle fusion. Inclusion of supplementary cholesterol at an optimal concentration of 20% (w/w) greatly enhances vesicle fusion during the freeze-thaw cycle.

Evidence that all newly synthesized proteins destined for fast axonal transport pass through the Golgi apparatus.

Effects of the sodium ionophore, monensin, were examined on the passage from neuronal cell body to axon of materials undergoing fast intracellular transport. In vitro exposure of bullfrog dorsal root ganglia to concentrations of drug less than 1.0 micron led to a dose-dependent depression in the amount of fast-transported [3H]leucine- or [3H]glycerol-labeled material appearing in the nerve trunk.

The distribution of orthogonal arrays in the freeze-fractured rat median eminence.

The distribution of orthogonal arrays of particles and their relationships to gap and tight junctions have been studied in the glia of the freeze-fractured rat median eminence (ME). These rectilinear clusters of intramembrane particles are thought to represent trans-membrane channels for ions or metabolites, and were found to be densely packed on the membranous laminations of the pial-glial limitans. Additionally, arrays were found to be present on all of the perivascular glial end-feet examined.

Return of axonal and glial membrane specializations during remyelination after tellurium-induced demyelination.

We have studied remyelination of rat peripheral nerves after tellurium-induced demyelination using thin section and freeze-fracture techniques. In rats fed a 1% tellurium diet, regions of demyelination were readily identified by myelin debris and the presence of large denuded axons. Remyelination occurred despite continued tellurium ingestion.