Cell Death In Central Nervous System Research Articles

Glycyl-l-histidyl-l-lysine prevents copper- and zinc-induced protein aggregation and central nervous system cell death in vitro.

Common features of neurodegenerative diseases are oxidative and inflammatory imbalances as well as the misfolding of proteins. An excess of free metal ions can be pathological and contribute to cell death, but only copper and zinc strongly promote protein aggregation. Herein we demonstrate that the endogenous copper-binding tripeptide glycyl-l-histidyl-l-lysine (GHK) has the ability to bind to and reduce copper redox activity and to prevent copper- and zinc-induced cell death in vitro. In addition, GHK prevents copper- and zinc-induced bovine serum albumin aggregation and reverses aggregation through resolubilizing the protein. We further demonstrate the enhanced toxicity of copper during inflammation and the ability of GHK to attenuate this toxicity. Finally, we investigated the effects of copper on enhancing paraquat toxicity and report a protective effect of GHK. We therefore conclude that GHK has potential as a cytoprotective compound with regard to copper and zinc toxicity, with positive effects on protein solubility and aggregation that warrant further investigation in the treatment of neurodegenerative diseases.

A Sublethal Dose of TNFα Potentiates Kainate-Induced Excitotoxicity in Optic Nerve Oligodendrocytes

Glutamate receptor-induced cell death, known as excitotoxicity in both neurons and oligodendrocytes, has been implicated as a common pathway of cell death in numerous central nervous system (CNS) diseases and trauma. Research in both neuronal and oligodendrocyte excitotoxicity has examined glutamate's receptor-mediated effects on CNS cells, and explored strategies to protect cells exposed to the elevated glutamate levels that occur in CNS trauma and disease. Proinflammatory cytokines are also elevated in the injured CNS, and have also been implicated in CNS cell death. Recently, several laboratories have examined cytokines' effects on neuronal and glial excitotoxicity. Here, we review literature concerning the dynamic susceptibility of both neurons and oligodendrocytes to excitotoxicity, and present new data from our laboratory showing that the susceptibility of oligodendrocytes to excitotoxicity is acutely potentiated by the proinflammatory cytokine TNFalpha.

Metallothionein prevents neurodegeneration and central nervous system cell death after treatment with gliotoxin 6-aminonicotinamide.

Transgenic expression of interleukin-6 (IL-6) in the CNS under the control of the glial fibrillary acidic protein (GFAP) gene promoter (GFAP-IL6 mice) induces significant inflammation and neurodegeneration but also affords neuroprotection against acute traumatic brain injury. This neuroprotection is likely mediated by the IL-6-induced protective factors metallothioneins-I and -II (MT-I+II). Here we evaluate the neuroprotective roles of IL-6 vs. MT-I+II during 6-aminonicotinamide (6-AN)-induced neurotoxicity, by using GFAP-IL6 mice and transgenic mice overexpressing MT-I (TgMT) as well as GFAP-IL6 mice crossed with TgMT mice (GFAP-IL6 x TgMT). 6-AN caused acute damage of brainstem gray matter areas identified by necrosis of astrocytes, followed by inflammatory responses. After 6-AN-induced toxicity, secondary damage was observed, consisting of oxidative stress, neurodegeneration, and apoptotic cell death. We hereby show that the primary injury caused by 6-AN was comparable in wild-type and GFAP-IL6 mice, but MT-I overexpression could significantly protect the brain tissue. As expected, GFAP-IL6 mice showed increased CNS inflammation with more gliosis, macrophages, and lymphocytes, including increased cytokine expression, relative to the other mice. However, GFAP-IL6 mice showed reduced oxidative stress (judged from nitrotyrosine, malondialdehyde, and 8-oxoguanine stainings), neurodegeneration (accumulation of neurofibrillary tangles), and apoptosis (determined from TUNEL and caspase-3). MT-I+II expression was significantly higher in GFAP-IL6 mice than in wild types, which may contribute to the IL-6-induced neuroprotection. In support of this, overexpression of MT-I in GFAP-IL6 x TgMT as well as TgMT mice protected the brainstem tissue significantly from 6-AN-induced toxicity and secondary brain tissue damage. Overall, the results demonstrate that brain MT-I+II proteins are fundamental neuroprotective factors, which in the future may become therapeutic agents.

Distinguishing excitotoxic from apoptotic neurodegeneration in the developing rat brain

Much confusion has arisen recently over the question of whether excitotoxic neuronal degeneration can be considered an apoptotic phenomenon. Here, we addressed this question by using ultrastructural methods and DNA fragmentation analysis to compare a prototypic apoptotic in vivo central nervous system cell death process (physiologic cell death in the developing rat brain) with several central nervous system cell death processes in the in vivo infant rat brain that are generally considered excitotoxic (degeneration of hypothalamic neurons after subcutaneous administration of glutamate and acute neurodegeneration induced by hypoxia/ischemia or by concussive head trauma). We found by ultrastructural analysis that glutamate induces neurodegenerative changes in the hypothalamus that are identical to acute changes induced in the infant rat brain by either hypoxia/ischemia or head trauma, and that these changes are fundamentally different both in type and sequence from those associated with physiologic cell death (apoptosis). In addition, we show by ultrastructural analysis that concussive head trauma induces both excitotoxic and apoptotic neurodegeneration, the excitotoxic degeneration being very acute and localized to the impact site, and the apoptotic degeneration being delayed and occurring in regions distant from the impact site. Thus, in the head trauma model, excitotoxic and apoptotic degeneration can be distinguished not only by ultrastructural criteria but by their temporal and spatial patterns of expression. Whereas ultrastructural analysis provided an unambiguous means of distinguishing between excitotoxic and apoptotic neurodegeneration in each example analysed in this study, DNA fragmentation analysis (TUNEL staining or gel electrophoresis) was of no value because these tests were positive for both processes. J. Comp. Neurol. 408:461–476, 1999. © 1999 Wiley-Liss, Inc.

Distinguishing excitotoxic from apoptotic neurodegeneration in the developing rat brain

Much confusion has arisen recently over the question of whether excitotoxic neuronal degeneration can be considered an apoptotic phenomenon. Here, we addressed this question by using ultrastructural methods and DNA fragmentation analysis to compare a prototypic apoptotic in vivo central nervous system cell death process (physiologic cell death in the developing rat brain) with several central nervous system cell death processes in the in vivo infant rat brain that are generally considered excitotoxic (degeneration of hypothalamic neurons after subcutaneous administration of glutamate and acute neurodegeneration induced by hypoxia/ischemia or by concussive head trauma). We found by ultrastructural analysis that glutamate induces neurodegenerative changes in the hypothalamus that are identical to acute changes induced in the infant rat brain by either hypoxia/ischemia or head trauma, and that these changes are fundamentally different both in type and sequence from those associated with physiologic cell death (apoptosis). In addition, we show by ultrastructural analysis that concussive head trauma induces both excitotoxic and apoptotic neurodegeneration, the excitotoxic degeneration being very acute and localized to the impact site, and the apoptotic degeneration being delayed and occurring in regions distant from the impact site. Thus, in the head trauma model, excitotoxic and apoptotic degeneration can be distinguished not only by ultrastructural criteria but by their temporal and spatial patterns of expression. Whereas ultrastructural analysis provided an unambiguous means of distinguishing between excitotoxic and apoptotic neurodegeneration in each example analysed in this study, DNA fragmentation analysis (TUNEL staining or gel electrophoresis) was of no value because these tests were positive for both processes.