bromochloroacetic-acid and Nerve-Degeneration

In an experimental autoimmune animal model, retinal ganglion cell (RGC) loss was induced through immunization with glaucoma-related antigens. The target of this study was to investigate the pathomechanism behind this decline and the serum antibody reactivity against ocular and neuronal tissues after immunization with glaucoma- and non-glaucoma-associated antigens.. Rats immunized with optic nerve antigen homogenate (ONA) or keratin (KER) were compared to control rats (CO). Intraocular pressure (IOP) was measured, and the fundi were examined regularly. Four weeks afterward, cells were counted in retinal flat mounts. Retina, optic nerve, and brain sections from healthy animals and optic nerve sections from immunized animals were incubated with serum collected at different time points. The occurrence of autoreactive antibodies was examined. Signs of antibody deposits, microglia activation, and demyelination were sought in optic nerves of immunized animals. Brain sections were examined for abnormalities.. No IOP or fundus changes were observed. Animals immunized with ONA showed a significant cell loss compared with the CO group. Elevated autoreactive antibodies against retina, optic nerve, and brain were observed. Animals immunized with KER, despite their immunologic response against KER, demonstrated neither RGC loss, nor increased development of autoreactive antibodies. Optic nerve from animals immunized with ONA demonstrated antibody accumulation, glia activation, and demyelination. No such observations were made in the KER or CO groups. Brain sections were without pathologic findings.. Systemic autoimmunity against ocular and neuronal epitopes, mediated by accordant autoreactive antibodies, is involved in the inflammatory processes that cause RGC degeneration in this experimental animal model.

Topics: Animals; Autoantibodies; Brain; Demyelinating Diseases; Disease Models, Animal; Epitopes; Glaucoma; Immunization; Immunoglobulin G; Intraocular Pressure; Keratins; Male; Microglia; Nerve Degeneration; Nerve Tissue Proteins; Optic Nerve; Rats; Rats, Inbred Lew; Retinal Ganglion Cells

To determine whether apoptotic process is involved in the delayed neuronal death in hippocampal CA1 region following forebrain ischemia in gerbils, time dependent activation of caspase and DNA fragmentation were evaluated by immuno-staining and terminal dUTP nick-end-labeling staining, respectively. After transient forebrain ischemia in gerbils, activation of apoptosis related caspase, including caspase-3, was apparent, and it preceded DNA fragmentation in CA1 region. These observations suggest that apoptotic process is involved in hippocampal delayed neuronal death.

Topics: Animals; Antibodies, Monoclonal; Apoptosis; Caspase 3; Caspases; DNA Fragmentation; Gerbillinae; Hippocampus; Immunohistochemistry; In Situ Nick-End Labeling; Ischemic Attack, Transient; Keratins; Male; Nerve Degeneration; Pyramidal Cells; Time Factors

We evaluated the influence of skin innervation on the epidermis in mice. The rich innervation of skin was demonstrated by immunocytochemistry with protein gene product 9.5, a ubiquitin carboxy hydrolase. Protein gene product-immunoreactive nerve fibers were in the epidermis, subepidermal plexus, dermal nerve trunks, and nerve terminals around sweat glands. Effects of denervation on the plantar surface of the hind foot was assessed by comparing the thickness of the epidermis, which was innervated by the sciatic nerve. Within 48 h after sectioning of the sciatic nerve, protein gene product (+)-nerves in the territory of the sciatic nerve were completely degenerated. There was a significant thinning of the denervated epidermis 72 h post-transection (30.5+/-1.1 vs 41.4+/-2.9 microm, 74+/-4% of the control side). The reduction in epidermal thickness persisted when skin remained denervated (69-75% of the control side). Incorporation of bromodeoxyuridine was reduced 24 h after denervation (71+/-6% of the control side). Reduction in bromodeoxyuridine-incorporation was most pronounced within 48 h after denervation (19+/-6% of the control side). Therefore, the reduction in bromodeoxyuridine-labeling followed a similar temporal course as the thinning of the epidermis (25-50%). Both epidermal thinning and reduced bromodeoxyuridine-labeling were reversed by epidermal reinnervation three months after denervation. Patterns of keratinocyte differentiation and programmed cell death were unaffected by skin denervation. These findings are consistent with the notion that skin innervation exerts influence on the proliferation of keratinocytes and the thickness of the epidermis, and offers a new look at the interaction between nociceptive nerves and their innervated targets.

Topics: Animals; Biomarkers; Cell Division; Denervation; Epidermal Cells; Epidermis; Hindlimb; Immunohistochemistry; In Situ Nick-End Labeling; Keratinocytes; Keratins; Male; Mice; Mice, Inbred ICR; Nerve Degeneration; Nerve Regeneration; Nerve Tissue Proteins; Sciatic Nerve; Skin; Thiolester Hydrolases; Ubiquitin Thiolesterase

Hair cell regeneration is well documented in the inner ear sensory epithelia of lower vertebrates and birds and may occur in the vestibular organs of mammals. By contrast, hair cell loss in the mature mammalian cochlea is considered irreversible. However, recent reports have suggested that an attempt at hair cell regeneration could occur in vivo in aminoglycoside-lesioned cochleas from neonatal rats. After amikacin treatment, atypical cells with apical specialization reminiscent of early differentiating stereocilia are transiently present at the apex of the intoxicated cochleas but fail to differentiate as hair cells in later stages. In the present study, we used electronic microscopy, histochemistry, and confocal microscopy to investigate the cellular rearrangements in the amikacin-lesioned organ of Corti of rat pups. In addition, we used 5-bromo-2'-deoxyuridine immunocytochemistry to determine whether mitotic processes are involved in the formation of the atypical cells. The morphologic and molecular data suggest that atypical cells are not recovering hair cells, but share characteristics of immature hair cells and supporting cells. Proliferative cells were absent from the region occupied by atypical cells, suggesting that the latter did not arise through mitotic processes. Altogether, the present results support the hypothesis that atypical cells arise through direct transformation of some of the supporting cells that reorganize during hair cell degeneration.

Topics: Amikacin; Animals; Anti-Bacterial Agents; Antimetabolites; Bromodeoxyuridine; Cell Size; Epithelial Cells; Hair Cells, Auditory; Keratins; Microscopy, Electron; Microscopy, Electron, Scanning; Nerve Degeneration; Parvalbumins; Phenotype; Rats; Rats, Wistar