lucifer-yellow and Nerve-Degeneration

Spinal cord injury (SCI) launches a complex cascade of events that leads to progressive damage and loss of function. Compromise of plasma membrane integrity due to the mechanical impact is an acute event that may contribute to cellular dysfunction. Therefore, the objective of this study was to better understand the extent of acute plasma membrane damage associated with SCI as a function of injury severity and membrane defect size. Fluorescent cell-impermeant dyes were injected into the cerebrospinal fluid of adult male rats prior to contusion injury, and the anatomical location of cell bodies and axons taking up the dye within 10 min following SCI was quantified. Lucifer yellow uptake was assessed as a function of impact force (experimental groups: sham, 100 kdyn, 150 kdyn, and 200 kdyn force). In a separate group of animals, FITC-conjugated dextran molecules of various sizes (3 kDa and 10 kDa with a 1.6-nm and 2.7-nm radius, respectively) were used to approximate the size of membrane defects following moderate injury (150 kdyn force). Quantification revealed that cellular uptake of lucifer yellow was positively correlated with the force of the mechanical impact, indicating that the severity of injury is related to the degree of acute membrane failure. In addition, after moderate injury, cell bodies and axons (located up to 2 mm and 3 mm from the epicenter, respectively) took up significantly more of the 3-kDa and 10-kDa dextran permeability marker compared to sham controls. Permeable neuronal cell bodies exhibited a morphological appearance characterized by pericellular blebbing, suggesting that plasma membrane compromise is associated with pathophysiological cellular alterations. Collectively, these results enhance our understanding of acute SCI and provide targets for developing novel treatment strategies.

Topics: Animals; Axons; Cell Membrane; Cell Membrane Permeability; Dextrans; Disease Models, Animal; Fluorescein-5-isothiocyanate; Isoquinolines; Male; Nerve Degeneration; Neurons; Rats; Rats, Sprague-Dawley; Spinal Cord Injuries; Stress, Mechanical

Neurone damage and eventual loss may underlie the clinical signs of disease in the transmissible spongiform encephalopathies (TSEs). Although neurone death appears to be through apoptosis, the trigger for this form of cell death in the TSEs is not known. Using two different murine scrapie models, hippocampal pyramidal cells were studied through microinjection of fluorescent dye, and synaptic integrity, using p38-immunoreactivity (p38-IR), both visualized using confocal laser scanning microscopy. Intradendritic distensions and dendritic spine loss were found to co-localize to areas of vacuolar and prion protein pathology in the hippocampus of mice infected with ME7 or 87 V scrapie. A significant reduction in p38-IR was found concomitantly in the hippocampus in ME7 scrapie mice. These results indicate that both pre- and post-synaptic sites are altered by scrapie infection; this would disrupt neuronal circuitry and may initiate apoptotic cell death, giving rise to the neurological disturbances manifested in clinical TSE cases.

Topics: Animals; Dendrites; Fluorescent Dyes; Hippocampus; Isoquinolines; Lipofuscin; Mice; Mice, Inbred C57BL; Microscopy, Confocal; Nerve Degeneration; Prions; Pyramidal Cells; Scrapie; Synapses; Synaptophysin

Retinal axons in goldfish regenerate after optic nerve lesion, restore synaptic connections, and become myelinated by oligodendrocytes. The fate of oligodendrocytes during these events is not known and may require generation of new oligodendrocytes or dedifferentiation and redifferentiation of the existing ones. To determine the reaction of oligodendrocytes to optic nerve lesion, we used the terminal transferase technique to detect apoptosis, bromodeoxyuridine incorporation to reveal mitosis, antibodies to identify myelin and oligodendrocytes, and Lucifer yellow injections to reveal cell morphology. Along with the reappearance of the myelin molecules 36K protein, galactocerebroside, and myelin basic protein, myelinating oligodendrocytes (identified by Lucifer yellow injections) reappear 21 days postlesion. Prior to this time, the dye-filled cells had few processes oriented along the regenerating axons. They resembled oligodendrocytes seen both in vitro and in vivo which express the L1-related E587 antigen and synthesize the 36K myelin protein in coculture with axons. No signs of oligodendrocyte apoptosis were detected after lesion and only few of the oligodendrocytes present had recently arisen. 36K/E587 double-labeled oligodendrocytes which were most likely dedifferentiating oligodendrocytes were identified in 8-day postlesion nerves among E587-positive elongate cells whose numbers increased until 14 days postlesion. These findings suggest that oligodendrocytes dedifferentiate-like Schwann cells-from cells which express myelin molecules to elongate cells which express the L1/E587 antigen. They redifferentiate to myelinate axons from roughly 3 weeks onward. These findings suggest an adaptive plasticity of goldfish oligodendrocytes beneficial to the repair of the visual pathway.

Topics: Animals; Apoptosis; Axons; Cell Differentiation; Goldfish; Isoquinolines; Myelin Proteins; Myelin Sheath; Nerve Degeneration; Nerve Regeneration; Oligodendroglia; Optic Nerve; Retina; Time Factors; Visual Pathways

Using the seafood contaminant domoic acid (an AMPA/kainate receptor agonist), we demonstrate a distinct excitotoxic sequence of events leading to acute neuronal damage in the hippocampal slice as measured by (1) loss of the evoked CA1 field potential, (2) irreversible changes in light transmittance, (3) histopathology, and (4) lucifer yellow injection of single CA1 pyramidal neurons. Change in light transmittance (LT) through the submerged slice indirectly measures altered cell volume, both neuronal and glial. At 37 degrees C, a 1-min superfusion of 10 mu M domoate induced a prolonged reversible increase in LT, primarily in the dendritic regions of CA1 and dentate granule cells (GC), but not in the CA3 region. Spectral analysis (400-800 nm) revealed a wide-band transmittance increase, indicating cell swelling as a major source of the intrinsic signal. The evoked field potential recorded in the CA1 cell body region (PYR) was lost as LT peaked, but completely recovered upon return to the baseline LT level. Increasing domoate exposure to 10 min elicited a different and distinct LT sequence in CA1 and dentate regions. An initial LT increase in dendritic regions evolved in an irreversible decrease in LT. At the same time, LT irreversibly increased in cell body regions (CA1 PYR and GC) and the evoked field potential was irretrievably lost. Also, there was histological damage to cell body and dendritic regions of CA1 and granule cells. Injection of lucifer yellow into single CA1 neurons in slices displaying the irreversible LT sequence revealed extensive dendritic beading, whereas CA1 cells in control slices displayed a smoothly contoured arbor. Consistent with acute neuronal damage, the optical changes generated by domoate did not require extracellular Ca2+, and lowering the temperature protected the slice from irreversible damage to CA1 and GC regions. Although glial changes may also occur, we conclude that imaging light transmittance reveals dynamic and compartmentalized excitotoxic changes in neuronal volume. Beading of the dendritic arbor increases light scatter, thereby decreasing LT and highlighting damaged dendritic regions.

Topics: Animals; Calcium Chloride; Dendrites; Electrophysiology; Fluorescent Dyes; Hippocampus; Image Cytometry; Image Processing, Computer-Assisted; Isoquinolines; Kainic Acid; Male; Membrane Potentials; Microinjections; Nerve Degeneration; Neuromuscular Depolarizing Agents; Neurons; Neurotoxins; Optics and Photonics; Organ Culture Techniques; Rats; Rats, Sprague-Dawley; Receptors, AMPA

A central question in Alzheimer's disease (AD) is the role of amyloid in pathogenesis. Recent discoveries implicating the longer A beta 1-42 form of amyloid in pathogenesis led us to characterize the interaction of A beta with cells to elucidate differences that might account for these observations. We characterized the adsorption, internalization and degradation of radiolabeled A beta in NGF-differentiated PC12 cells under conditions that are not acutely toxic. All A beta peptides examined absorb to the surface of PC12 cells and are internalized; however the adsorption and internalization of A beta 1-42 is significantly greater than that of A beta 1-40 and A beta 1-28. The adsorption of A beta 1-42 is decreased by treatment of the cells with neuraminidase, but not heparitinase. The fate of the internalized A beta 1-42 is also very different than shorter A beta peptides; a fraction of the internalized A beta 1-42 accumulates intracellularly and is resistant to degradation for at least 3 days while A beta 1-40 and shorter peptides are eliminated with a half life of about 1 h. A beta 1-42 does not appear to inhibit lysosomal hydrolases, since A beta 1-28 is degraded at the same rate in the presence or absence of A beta 1-42. The intracellular A beta 1-42 is located in a dense organellar compartment and colocalizes with the lysosomal markers Lucifer Yellow and horseradish peroxidase. These data indicate that there are significant differences in the cell surface adsorption, internalization and catabolism of A beta 1-42 compared to A beta 1-40 and A beta 1-28. These differences may be important for the preferential accumulation of the longer A beta 1-42 isoform and its association with AD pathogenesis.

Topics: Adsorption; Amino Acid Sequence; Amyloid beta-Protein Precursor; Animals; Cell Compartmentation; Cell Differentiation; Endosomes; Fluorescent Antibody Technique; Fluorescent Dyes; Isomerism; Isoquinolines; Lysosomes; Microscopy, Confocal; Molecular Sequence Data; Nerve Degeneration; PC12 Cells; Rats

The morphology of the neuroendocrine caudodorsal cells (CDCs), which are involved in the regulation of female reproduction in the pond snail Lymnaea stagnalis, was studied in young (200 to 234 days of age) and old (400 to 500 days) animals. Lucifer Yellow fills of ventral CDCs showed that in young animals ventral CDCs branch ipsilaterally as well as contralaterally in the cerebral commissure. In old animals these branches were reduced at different degrees and in some cases even lacking completely, leaving only an axon crossing the commissure. Immunocytochemical stainings with antibodies against CDC peptides (CDCH-I and alpha CDCP) corroborated the finding that ventral CDCs degenerate. Among the other types of CDCs (dorsal, lateral), degeneration was found as well. The immunocytochemical findings showed that in old animals the axon terminals of the CDCs were strongly stained, indicating that they are packed with secretory vesicles containing peptides. It was also found that these darkly stained, peptide-containing axon terminals protruded into the perineurium. These findings suggest that accumulation of peptides in the terminals of the CDCs of old animals may be due to the impaired release. The relationship between atrophy and degeneration of CDCs and cessation of egg-laying activity in Lymnaea is discussed.

Topics: Aging; Animals; Axons; Female; Immunohistochemistry; Isoquinolines; Lymnaea; Nerve Degeneration; Neurons; Neuropeptides; Reproduction

Vestibular nerve afferents innervating the bullfrog utriculus differ in their response dynamics and sensitivity to natural stimulation. They also supply hair cells that differ markedly in hair bundle morphology. To examine the peripheral innervation patterns of individual utricular afferents more closely, afferent fibers were labeled by the extracellular injection of horseradish peroxidase (HRP) into the vestibular nerve after sectioning the vestibular nerve medial to Scarpa's ganglion to allow the degeneration of sympathetic and efferent fibers. The peripheral arborizations of individual afferents were then correlated with the diameters of their parent axons, the regions of the macula they innervate, and the number and type of hair cells they supply. The utriculus is divided by the striola, a narrow zone of distinctive morphology, into medial and lateral parts. Utricular afferents were classified as striolar or extrastriolar according to the epithelial entrance of their parent axons and the location of their terminal fields. In general, striolar afferents had thicker parent axons, fewer subepithelial bifurcations, larger terminal fields, and more synaptic endings than afferents in extrastriolar regions. Afferents in a juxtastriolar zone, immediately adjacent to the medial striola, had innervation patterns transitional between those in the striola and more peripheral parts of the medial extrastriola. Most afferents innervated only a single macular zone. The terminal fields of striolar afferents, with the notable exception of a few afferents with thin parent axons, were generally confined to one side of the striola. Hair cells in the bullfrog utriculus have previously been classified into four types based on hair bundle morphology (Lewis and Li: Brain Res. 83:35-50, 1975). Afferents in the extrastriolar and juxtastriolar zones largely or exclusively innervated Type B hair cells, the predominant hair cell type in the utricular macula. Striolar afferents supplied a mixture of four hair cell types, but largely contacted Type B and Type C hair cells, particularly on the outer rows of the medial striola. Afferents supplying more central striolar regions innervated fewer Type B and large numbers of Type E and Type F hair cells. Striolar afferents with thin parent axons largely supplied Type E hair cells with bulbed kinocilia in the innermost striolar rows.

Topics: Animals; Axons; Ear, Inner; Fluorescent Dyes; Hair Cells, Auditory, Outer; Horseradish Peroxidase; Isoquinolines; Nerve Degeneration; Nerve Fibers, Myelinated; Neurons, Afferent; Peripheral Nerves; Presynaptic Terminals; Rana catesbeiana; Tolonium Chloride; Vestibular Nerve; Vestibule, Labyrinth

Previous light microscopic immunocytochemical studies with antibodies against transmitter-synthesizing enzymes have suggested that septohippocampal neurons undergo retrograde degeneration following transection of their axons by cutting the fimbria-fornix. However, a fine-structural analysis of the degeneration process in these cells is lacking so far. Here we have identified septohippocampal neurons by retrograde tracing with Fluoro-Gold. Thereafter, the fimbria-fornix was transected bilaterally. Fine-structural changes in prelabeled septohippocampal neurons were then studied after varying survival times up to 10 weeks. Examination under the fluorescence microscope of Vibratome sections through the septal region revealed numerous retrogradely labeled cells after all survival times following axotomy. These neurons were then intracellularly injected with the fluorescent dye Lucifer Yellow in order to stain their dendritic arbor. Many cells were found after each survival time that displayed characteristics of septohippocampal neurons in control rats (see Naumann et al., J Comp Neurol 325:207-218, 1992). In addition, increasing with survival time, there were many shrunken neurons with a reduced dendritic arbor. Representative examples of both normal appearing and shrunken neurons were photoconverted for subsequent electron microscopic analysis. Relatively few signs of neuronal degeneration were found at each survival time analyzed. The majority of cells, including the heavily shrunken ones, displayed fine-structural characteristics of normal neurons. However, a few degenerating neurons and reactive glial cells were present in all survival stages. We conclude that axotomized septohippocampal projection neurons cease the expression of transmitter-synthesizing enzymes and shrink, but many more cells survive for extended periods of time without target-derived neurotrophic factor than was assumed in previous light microscopic studies.

Topics: Animals; Axons; Female; Hippocampus; Histocytochemistry; Isoquinolines; Nerve Degeneration; Neurons; Rats; Rats, Sprague-Dawley; Septal Nuclei; Tissue Fixation

Using as a neural system the fly retina, which is visually accessible in vivo, we describe a lesion technique that takes advantage of the photodynamic damage produced by extrinsic dyes. Contrary to the photo-inactivation technique described by Miller and Selverston (1979), this technique does not involve intracellular injection, since the dye is applied to the extracellular space of the tissue. This treatment was found to trigger neuronal degeneration and cell permeabilization in fly photoreceptor neurones. We coined the names 'photodegeneration' and 'photopermeabilization' for these two phenomena. While the technique can be used to delete given neurones from the neural circuit after several days' survival time, it was found to produce adequate cytoplasmic labelling for anatomical studies with both light and electron microscopy. Since the area occupied by the degenerating cells is restricted to the light spot imaged onto the nervous tissue, the resolution with this lesion technique can range from single cells to whole neuronal populations. The remarkable precision of the 'photolesions' produced in this way makes this technique a powerful tool for physiological and anatomical investigations on real neural networks, whenever these can be made optically accessible in vivo or in situ.

Topics: Animals; Coloring Agents; Extracellular Space; Female; Fluorescent Dyes; Houseflies; Isoquinolines; Light; Microscopy, Electron; Nerve Degeneration; Neurology; Neurons; Permeability; Photoreceptor Cells; Retina; Rhodamines

Following transection of the optic nerve, ganglion cells in the cat retina undergo retrograde degeneration. However, many small profiles (less than or equal to 10 micron) survive in the ganglion cell layer. Previously considered to be neuroglia, there is now substantial evidence that they are displaced amacrine cells. Their density increases from approximately 1,000 cells/mm2 in peripheral retina to 7,000 cells/mm2 in the central area. Their total number was found to be 850,000, which is five times the number of ganglion cells and also five times the number of astrocytes. Uptake of 3H-muscimol followed by autoradiography labelled 75% of the displaced amacrine cells; hence, the majority seem to be GABAergic. Immunocytochemistry with an antibody directed against choline-acetyl-transferase labelled approximately 10% of the displaced amacrines in the peripheral retina and 17% in the central area. Uptake of serotonin (5-HT) followed by immunocytochemistry was found in 25-30% of displaced amacrines. NADPH diaphorase histochemistry labelled approximately 5% of displaced amacrine cells. The sum of the various percentages make colocalization likely. Intracellular injection of Lucifer Yellow under microscopic control revealed that displaced amacrine cells constitute several morphological types.

Topics: Animals; Autoradiography; Cats; Cell Count; Choline O-Acetyltransferase; Fluorescent Dyes; Immunohistochemistry; Isoquinolines; Muscimol; Nerve Degeneration; Neurons; Retina; Retinal Ganglion Cells; Serotonin

Staining of rat retinal wholemounts with a monoclonal antibody against choline-acetyl-transferase (ChAT) reveals two matching populations of amacrine cells in pigmented and albino rat retinae. One population has cell bodies in the inner nuclear layer (INL). Their dendrites are confined to a narrow stratum in the outer half of the inner plexiform layer (IPL). The other, displaced, population has cell bodies in the ganglion cell layer (GCL) with dendrites stratifying in the middle of the IPL. The density changes with eccentricity, ranging from 1,700 cells/mm2 centrally to 600 cells/mm2 in the periphery. Presumptive cholinergic cells were filled with the fluorescent dye Lucifer yellow. Both subpopulations have the same "starburstlike" morphology as described for rabbit cholinergic amacrine cells (Famiglietti, '83; Tauchi and Masland, '84; Masland et al., '84b). Their dendritic tree sizes change with eccentricity and range from 160 to 300 microns in diameter. Counterstaining of Lucifer yellow-filled cells by ChAT immunohistochemistry did not yield an unequivocal double staining. Nevertheless, indirect evidence of same soma size, same number and form of primary dendrites, same level of stratification, and the good fit into the cholinergic mosaic makes it very likely that the "starburstlike" amacrine cells in the rat use acetylcholine as their transmitter. A comparison with the rabbit cholinergic system strengthens this assumption and reveals a striking similarity between both species.

Topics: Animals; Choline O-Acetyltransferase; Cholinergic Fibers; Dendrites; Immunoenzyme Techniques; Isoquinolines; Nerve Degeneration; Neurons; Optic Nerve; Rats; Retina; Staining and Labeling