Release of mitochondrial Opa1 following oxidative stress in HT22 cells

Cellular mechanisms involved in multiple neurodegenerative diseases converge on mitochondria to induce overproduction of reactive oxygen species, damage to mitochondria, and subsequent cytochrome c release. Little is currently known regarding the contribution mitochondrial dynamics play in cytochrome c release following oxidative stress in neurodegenerative disease. Here we induced oxidative stress in the HT22 cell line with glutamate and investigated key mediators of mitochondrial dynamics to determine the role this process may play in oxidative stress induced neuronal death. We report that glutamate treatment in HT22 cells induces increase in reactive oxygen species (ROS), release of the mitochondrial fusion protein Opa1 into the cytosol, with concomitant release of cytochrome c. Furthermore, following the glutamate treatment alterations in cell signaling coincide with mitochondrial fragmentation which culminates in significant cell death in HT22 cells. Finally, we report that treatment with the antioxidant tocopherol attenuates glutamate induced-ROS increase, release of mitochondrial Opa1 and cytochrome c, and prevents cell death.     

A Golgi fragmentation pathway in neurodegeneration

The Golgi apparatus processes intracellular proteins, but undergoes disassembly and fragmentation during apoptosis in several neurodegenerative disorders such as amyotrophic lateral sclerosis and Alzheimer's disease. It is well known that other cytoplasmic organelles play important roles in cell death pathways. Thus, we hypothesized that Golgi fragmentation might participate in transduction of cell death signals. Here, we found that Golgi fragmentation and dispersal precede neuronal cell death triggered by excitotoxins, oxidative/nitrosative insults, or ER stress. Pharmacological intervention or overexpression of the C-terminal fragment of Grasp65, a Golgi-associated protein, inhibits fragmentation and decreases or delays neuronal cell death. Inhibition of mitochondrial or ER cell death pathways also decreases Golgi fragmentation, indicating crosstalk between organelles and suggesting that the Golgi may be a common downstream-effector of cell death. Taken together, these findings implicate the Golgi as a sensor of stress signals in cell death pathways.     

Modulation of mitochondrial morphology by bioenergetics defects in primary human fibroblasts

Mitochondria are dynamic organelles with continuous fusion and fission, the equilibrium of which results in mitochondrial morphology. Evidence points to there being an intricate relationship between mitochondrial dynamics and oxidative phosphorylation.

We investigated the bioenergetics modulation of mitochondrial morphology in five control cultured primary skin fibroblasts and seven with genetic alterations of oxidative phosphorylation. Under basal conditions, control fibroblasts had essentially filamentous mitochondria. Oxidative phosphorylation inhibition with drugs targeting complex I, III, IV or V induced partial but significant mitochondrial fragmentation, whereas dissipation of mitochondrial membrane potential (DΨm) provoked complete fragmentation, and glycolysis inhibition had no effect. Oxidative phosphorylation defective fibroblasts had essentially normal filamentous mitochondria under basal conditions, although when challenged some of them presented with mild alteration of fission or fusion efficacy. Severely defective cells disclosed complete mitochondrial fragmentation under glycolysis inhibition.

In conclusion, mitochondrial morphology is modulated by DΨm but loosely linked to mitochondrial oxidative phosphorylation. Its alteration by glycolysis inhibition points to a severe oxidative phosphorylation defect.     

Mitochondrial dynamics and neurodegeneration

Mitochondria are key organelles in eukaryotic cells that not only generate adenosine triphosphate but also perform such critical functions as hosting essential biosynthetic pathways, calcium buffering, and apoptotic signaling. In vivo, mitochondria form dynamic networks that undergo frequent morphologic changes through fission and fusion. In neurons, the imbalance of mitochondrial fission/fusion can influence neuronal physiology, such as synaptic transmission and plasticity, and affect neuronal survival. Core components of the mitochondrial fission/fusion machinery have been identified through genetic studies in model organisms. Mutations in some of these genes in humans have been linked to rare neurodegenerative diseases such as Charcot-Marie-Tooth subtype 2A and autosomal dominant optic atrophy. Recent studies also have implicated aberrant mitochondrial fission/fusion in the pathogenesis of more common neurodegenerative diseases such as Parkinson’s disease. These studies establish mitochondrial dynamics as a new paradigm for neurodegenerattve disease research. Compounds that modulate mitochondrial fission/fusion could have therapeutic value in disease intervention.     

Dynamin-related protein 1 and mitochondrial fragmentation in neurodegenerative diseases

The purpose of this article is to review the recent developments of abnormal mitochondrial dynamics, mitochondrial fragmentation, and neuronal damage in neurodegenerative diseases, including Alzheimer's, Parkinson's, Huntington's, and amyotrophic lateral sclerosis. The GTPase family of proteins, including fission proteins, dynamin related protein 1 (Drp1), mitochondrial fission 1 (Fis1), and fusion proteins (Mfn1, Mfn2 and Opa1) are essential to maintain mitochondrial fission and fusion balance, and to provide necessary adenosine triphosphate to neurons. Among these, Drp1 is involved in several important aspects of mitochondria, including shape, size, distribution, remodeling, and maintenance of mitochondria in mammalian cells. In addition, recent advancements in molecular, cellular, electron microscopy, and confocal imaging studies revealed that Drp1 is associated with several cellular functions, including mitochondrial and peroxisomal fragmentation, phosphorylation, SUMOylation, ubiquitination, and cell death. In the last two decades, tremendous progress has been made in researching mitochondrial dynamics, in yeast, worms, and mammalian cells; and this research has provided evidence linking Drp1 to neurodegenerative diseases. Researchers in the neurodegenerative disease field are beginning to recognize the possible involvement of Drp1 in causing mitochondrial fragmentation and abnormal mitochondrial dynamics in neurodegenerative diseases. This article summarizes research findings relating Drp1 to mitochondrial fission and fusion, in yeast, worms, and mammals. Based on findings from the Reddy laboratory and others', we propose that mutant proteins of neurodegenerative diseases, including AD, PD, HD, and ALS, interact with Drp1, activate mitochondrial fission machinery, fragment mitochondria excessively, and impair mitochondrial transport and mitochondrial dynamics, ultimately causing mitochondrial dysfunction and neuronal damage.     

Parkin,PINK1 and mitochondrial integrity: emerging concepts of mitochondrial dysfunction in Parkinson’s disease

Mitochondria are dynamic organelles which are essential for many cellular processes, such as ATP production by oxidative phosphorylation, lipid metabolism, assembly of iron sulfur clusters, regulation of calcium homeostasis, and cell death pathways. The dynamic changes in mitochondrial morphology, connectivity, and subcellular distribution are critically dependent on a highly regulated fusion and fission machinery. Mitochondrial function, dynamics, and quality control are vital for the maintenance of neuronal integrity. Indeed, there is mounting evidence that mitochondrial dysfunction plays a central role in several neurodegenerative diseases. In particular, the identification of genes linked to rare familial variants of Parkinson’s disease has fueled research on mitochondrial aspects of the disease etiopathogenesis. Studies on the function of parkin and PINK1, which are associated with autosomal recessive parkinsonism, provided compelling evidence that these proteins can functionally interact to maintain mitochondrial integrity and to promote clearance of damaged and dysfunctional mitochondria. In this review we will summarize current knowledge about the impact of parkin and PINK1 on mitochondria.     

Mitochondrial division inhibitor 1 disrupts oligodendrocyte Ca2+ homeostasis and mitochondrial function

Mitochondrial fission mediated by cytosolic dynamin related protein 1 (Drp1) is essential for mitochondrial quality control but may contribute to apoptosis as well. Blockade of Drp1 with mitochondrial division inhibitor 1 (mdivi-1) provides neuroprotection in several models of neurodegeneration and cerebral ischemia and has emerged as a promising therapeutic drug. In oligodendrocytes, overactivation of AMPA-type ionotropic glutamate receptors (AMPARs) induces intracellular Ca²⁺ overload and excitotoxic death that contributes to demyelinating diseases. Mitochondria are key to Ca²⁺ homeostasis, however it is unclear how it is disrupted during oligodendroglial excitotoxicity. In the current study, we have analyzed mitochondrial dynamics during AMPAR activation and the effects of mdivi-1 on excitotoxicity in optic nerve-derived oligodendrocytes. Sublethal AMPAR activation triggered Drp1-dependent mitochondrial fission, whereas toxic AMPAR activation produced Drp1-independent mitochondrial swelling. Accordingly, mdivi-1 efficiently inhibited Drp1-mediated mitochondrial fission and did not prevent oligodendrocyte excitotoxicity. Unexpectedly, mdivi-1 also induced mitochondrial depolarization, ER Ca²⁺ depletion and modulation of AMPA-induced Ca²⁺ signaling. These off-target effects of mdivi-1 sensitized oligodendrocytes to excitotoxicity and ER stress and eventually produced oxidative stress and apoptosis. Interestingly, in cultured astrocytes mdivi-1 induced nondetrimental mitochondrial depolarization and oxidative stress that did not cause toxicity or sensitization to apoptotic stimuli. In summary, our results provide evidence of Drp1-mediated mitochondrial fission during activation of ionotropic glutamate receptors in oligodendrocytes, and uncover a deleterious and Drp1-independent effect of mdivi-1 on mitochondrial and ER function in these cells. These off-target effects of mdivi-1 limit its therapeutic potential and should be taken into account in clinical studies.     

Mechanisms of Dopamine-Induced Cell Death in Cultured Rat Forebrain Neurons: Interactions with and Differences from Glutamate-Induced Cell Death

Injury to the brain, whether by ischemia or trauma, results in the uncontrolled release of many neurotransmitters, including glutamate and dopamine. Both of these neurotransmitters are neurotoxic in high concentrations, and the oxidative stress caused by reactive oxygen species generation has been implicated in the mechanism of neurotoxicity. In this study, we used cultured rat forebrain neurons to characterize cell death caused by exposure to dopamine and/or glutamate and to investigate potential acute mechanisms of toxicity. Dopamine exposure (250 μMfor 2 h) reduced cell viability to 34.3 ± 5.5% of untreated control 20 h later and increased the number of neurons with apoptotic morphology. The antioxidantN-acetylcysteine (100 μM) inhibited dopamine-induced toxicity and prevented the covalent binding of dopamine quinones to protein. In contrast, glutamate toxicity lacked the hallmark characteristics of apoptosis. When neurons were exposed successively to sublethal concentrations of dopamine and glutamate, cell viability at 20 h was reduced to 62.3 ± 5.2% of untreated control. Apoptosis was not evident, andN-acetylcysteine blocked the potentiating effect of dopamine on glutamate-induced toxicity. We used single-cell fluorescence assays to measure changes in intraneuronal glutathione, intraneuronal Ca²⁺, mitochondrial membrane potential, and DNA integrity as potential acute inducers of neuronal injury. While changes in these parameters could be demonstrated, none were identified as the sole acute inducer of cell death caused by dopamine. In summary, we have characterized a number of neuronal responses to lethal dopamine injury. Also, we have demonstrated that dopamine and glutamate can interactin vitroto potentiate cell death and that the potentiation appears to be induced by oxidative stress.     

Drp1 levels constitutively regulate mitochondrial dynamics and cell survival in cortical neurons

Mitochondria exist as dynamic networks that are constantly remodeled through the opposing actions of fusion and fission proteins. Changes in the expression of these proteins alter mitochondrial shape and size, and may promote or inhibit the propagation of apoptotic signals. Using mitochondrially targeted EGFP or DsRed2 to identify mitochondria, we observed a short, distinctly tubular mitochondrial morphology in postnatal cortical neurons in culture and in retinal ganglion cells in vivo, whereas longer, highly interconnected mitochondrial networks were detected in cortical astrocytes in vitro and non-neuronal cells in the retina in vivo. Differential expression patterns of fusion and fission proteins, in part, appear to determine these morphological differences as neurons expressed markedly high levels of Drp1 and OPA1 proteins compared to non-neuronal cells. This finding was corroborated using optic tissue samples. Moreover, cortical neurons expressed several splice variants of Drp1 including a neuron-specific isoform which incorporates exon 3. Knockdown or dominant-negative interference of endogenous Drp1 significantly increased mitochondrial length in both neurons and non-neuronal cells, but caused cell death only in cortical neurons. Conversely, depletion of the fusion protein, Mfn2, but not Mfn1, caused extensive mitochondrial fission and cell death. Thus, Drp1 and Mfn2 in normal cortical neurons not only regulate mitochondrial morphology, but are also required for cell survival. The present findings point to unique patterns of Drp1 expression and selective vulnerability to reduced levels of Drp1 expression/activity in neurons, and demonstrate that the regulation of mitochondrial dynamics must be tightly regulated in neurons.     

Integrating multiple aspects of mitochondrial dynamics in neurons: Age-related differences and dynamic changes in a chronic rotenone model

Changes in dynamic properties of mitochondria are increasingly implicated in neurodegenerative diseases, particularly Parkinson's disease (PD). Static changes in mitochondrial morphology, often under acutely toxic conditions, are commonly utilized as indicators of changes in mitochondrial fission and fusion. However, in neurons, mitochondrial fission and fusion occur in a dynamic system of axonal/dendritic transport, biogenesis and degradation, and thus, likely interact and change over time. We sought to explore this using a chronic neuronal model (nonlethal low-concentration rotenone over several weeks), examining distal neurites, which may give insight into the earliest changes occurring in PD. Using this model, in live primary neurons, we directly quantified mitochondrial fission, fusion, and transport over time and integrated multiple aspects of mitochondrial dynamics, including morphology and growth/mitophagy. We found that rates of mitochondrial fission and fusion change as neurons age. In addition, we found that chronic rotenone exposure initially increased the ratio of fusion to fission, but later, this was reversed. Surprisingly, despite changes in rates of fission and fusion, mitochondrial morphology was minimally affected, demonstrating that morphology can be an inaccurate indicator of fission/fusion changes. In addition, we found evidence of subcellular compartmentalization of compensatory changes, as mitochondrial density increased in distal neurites first, which may be important in PD, where pathology may begin distally. We propose that rotenone-induced early changes such as in mitochondrial fusion are compensatory, accompanied later by detrimental fission. As evidence, in a dopaminergic neuronal model, in which chronic rotenone caused loss of neurites before cell death (like PD pathology), inhibiting fission protected against the neurite loss. This suggests that aberrant mitochondrial dynamics may contribute to the earliest neuropathologic mechanisms in PD. These data also emphasize that mitochondrial fission and fusion do not occur in isolation, and highlight the importance of analysis and integration of multiple mitochondrial dynamic functions in neurons.     

Mitochondria as a therapeutic target for aging and neurodegenerative diseases

Mitochondria are cytoplasmic organelles responsible for life and death. Extensive evidence from animal models, postmortem brain studies of and clinical studies of aging and neurodegenerative diseases suggests that mitochondrial function is defective in aging and neurodegenerative diseases, such as Alzheimer's disease, Parkinson's disease, Huntington's disease, and amyotrophic lateral sclerosis. Several lines of research suggest that mitochondrial abnormalities, including defects in oxidative phosphorylation, increased accumulation of mitochondrial DNA defects, impaired calcium influx, accumulation of mutant proteins in mitochondria, and mitochondrial membrane potential dissipation are important cellular changes in both early and late-onset neurodegenerative diseases. Further, emerging evidence suggests that structural changes in mitochondria, including increased mitochondrial fragmentation and decreased mitochondrial fusion, are critical factors associated with mitochondrial dysfunction and cell death in aging and neurodegenerative diseases. This paper discusses research that elucidates features of mitochondria that are associated with cellular dysfunction in aging and neurodegenerative diseases and discusses mitochondrial structural and functional changes, and abnormal mitochondrial dynamics in neurodegenerative diseases. It also outlines mitochondria-targeted therapeutics in neurodegenerative diseases.     

4-hydroxynonenal increases neuronal susceptibility to oxidative stress

Increased levels of reactive oxygen species occur in neurodegenerative disorders and may promote neuron death. The lipid peroxidation product 4-hydroxynonenal (HNE) is increased in neurons following oxidative stress and promotes neuron death in vitro and in vivo. The present study examined the possibility that HNE can increase neuron vulnerability to oxidative stress. Application of low concentrations of HNE (50-500 nM) increased neuron death induced by beta-amyloid or glutamate when added within 3 hr of injury. In addition, treatment with HNE exacerbated mitochondrial reactive oxygen species formation and loss of mitochondrial membrane potential in response to beta-amyloid and glutamate. The ability to exacerbate oxidative stress, mitochondrial dysfunction, and neuron death appears to be specific to HNE, because application of other lipid peroxidation products had no effect. These data indicate a role for low levels of HNE in promoting reactive oxygen species accumulation and neuron degeneration by altering mitochondrial homeostasis. In addition, the present study indicates a possible mechanism for reactive oxygen species and lipid peroxidation toxicity in neurodegenerative conditions.     

Uncoupling of ATP-depletion and cell death in human dopaminergic neurons

The mitochondrial inhibitor 1-methyl-4-phenylpyridinium (MPP(+)) is the toxicologically relevant metabolite of 1-methyl-4-phenyltetrahydropyridine (MPTP), which causes relatively selective degeneration of dopaminergic neurons in the substantia nigra. Dopaminergic LUHMES cells were used to investigate whether ATP-depletion can be uncoupled from cell death as a downstream event in these fully post-mitotic human neurons. Biochemical assays indicated that in the homogeneously differentiated cell cultures, MPP(+) was taken up by the dopamine transporter (DAT). MPP(+) then triggered oxidative stress and caspase activation, as well as ATP-depletion followed by cell death. Enhanced survival of the neurons in the presence of agents interfering with mitochondrial pathology, such as the fission inhibitor Mdivi-1 or a Bax channel blocker suggested a pivotal role of mitochondria in this model. However, these compounds did not prevent cellular ATP-depletion. To further investigate whether cells could be rescued despite respiratory chain inhibition by MPP(+), we have chosen a diverse set of pharmacological inhibitors well-known to interfere with MPP(+) toxicity. The antioxidant ascorbate, the iron chelator desferoxamine, the stress kinase inhibitor CEP1347, and different caspase inhibitors reduced cell death, but allowed ATP-depletion in protected cells. None of these compounds interfered with MPP(+) accumulation in the cells. These findings suggest that ATP-depletion, as the initial mitochondrial effect of MPP(+), requires further downstream processes to result in neuronal death. These processes may form self-enhancing signaling loops, that aggravate an initial energetic impairment and eventually determine cell fate.     

Evidence for Synergism Between Cell Death Mechanisms in a Cellular Model of Neurodegeneration in Parkinson’s Disease

Delineation of how cell death mechanisms associated with Parkinson's disease (PD) interact and whether they converge would help identify targets for neuroprotective therapies. The purpose of this study was to use a cellular model to address these issues. Catecholaminergic SH-SY5Y neuroblastoma cells were exposed to a range of compounds (dopamine, rotenone, 5,8-dihydroxy-1,4-naphtho-107 quinone [naphthazarin], and Z-Ile-Glu(OBut)-Ala-Leu-al [PSI]) that are neurotoxic when applied to these cells for extended periods of times at specific concentrations. At the concentrations used, these compounds cause cellular stress via mechanisms that mimic those associated with causing neurodegeneration in PD, namely oxidative stress (dopamine), mitochondrial dysfunction (rotenone), lysosomal dysfunction (naphthazarin), and proteasomal dysfunction (PSI). The compounds were applied to the SH-SY5Y cells either alone or in pairs. When applied separately, the compounds produced a significant decrease in cell viability confirming that oxidative stress, mitochondrial, proteosomal, or lysosomal dysfunction can individually result in catecholaminergic cell death. When the compounds were applied in pairs, some of the combinations produced synergistic effects. Analysis of these interactions indicates that proteasomal, lysosomal, and mitochondrial dysfunction is exacerbated by dopamine-induced oxidative stress. Furthermore, inhibition of the proteasome or lysosome or increasing oxidative stress has a synergistic effect on cell viability when combined with mitochondrial dysfunction, suggesting that all cell death mechanisms impair mitochondrial function. Finally, we show that there are reciprocal relationships between oxidative stress, proteasomal dysfunction, and mitochondrial dysfunction, whereas lysosome dysfunction appears to mediate cell death via an independent pathway. Given the highly interactive nature of the various cell death mechanisms linked with PD, we predict that effective neuroprotective strategies should target multiple sites in these pathways, for example oxidative stress and mitochondria.     

The role of mitochondrial alterations in the combined toxic effects of human immunodeficiency virus Tat protein and methamphetamine on calbindin positive-neurons

The use of methamphetamine (METH) continues to increase the risk of human immunodeficiency virus (HIV) transmission within both homosexual and heterosexual drug abuser groups. Neurological studies indicate that the progression of HIV encephalitis is also enhanced by illicit drug use. Recently, the authors' studies in the postmortem brains of HIV-positive METH users have shown that the combined effects of HIV and METH selectively damage calbindin (CB)-immunoreactive nonpyramidal neurons, which may contribute to the behavioral alterations observed in these patients. To better understand the mechanisms of toxicity associated with exposure to HIV and METH, neuronal survival, phenotypic markers, levels of oxidative stress, and mitochondrial potential were assessed in vitro in the hippocampal neuronal cell line, HT22, and in primary human neurons exposed to the HIV Tat protein and/or METH. Both Tat and METH were toxic to neurons in a time- and dose-dependent fashion. Neurons exposed to a combination of Tat and METH displayed early evidence of neuronal damage at 6 h, characterized by a decrease in CB and microtubule-associated protein 2 (MAP2) immunoreactivity followed by more extensive cell death at 24 h. Loss of CB immunoreactivity associated with the combined exposure to Tat and METH was accompanied by mitochondrial damage with increased levels of oxidative stress. The toxic effects of Tat and METH were inhibited by blocking mitochondrial uptake of intracellular calcium, whereas blocking calcium flux in the endoplasmic reticulum or from the extracellular environment had no effect on Tat and METH toxicity. These studies indicate that in vitro, when combined, the HIV protein Tat and METH damage CB-immunoreactive nonpyramidal neurons by dysregulating the mitochondrial calcium potential. In combination, Tat and METH may increase cell injury and death, thereby enhancing brain metabolic disturbances observed in HIV-positive METH users in clinical populations.     

Possible extrapyramidal system degradation in Parkinson's disease

Extrapyramidal system, a rich network of nerve and glial cells consists of subcortical and cortical grey matter. The system serves as an integrator of unaware, automatic, repeated, spontaneous, complicated and purposeful motor samples. Muscle tone regulation and its distribution is another decisive extrapyramidal function. This review article concerns to some degradation mechanisms in extrapyramidal system, as either the programmed cell death or apoptosis. The physiologic extracellular decreasing signals creating apoptosis (nerve growth factor--fall) are either genetically expressed or there are neuropathophysiologic processes that may activate pathways leading to apoptosis, namely oxidative stress, glutamate toxicity and calcium homeostasis disruption. The level of dopamine transporter expression (mRNA, methyl-phenyl-pyridinium) might determine the vulnerability of the nigral neurons to the Parkinsonian insult. The most common clinical picture of extrapyramidal disorder-Parkinson's disease-consists of an active dopamine cell death-apoptosis, which is partially programmed like as programmed cell death and partially accidentally installed chain of events. Without morphological criteria, biochemical indicators such as laddered DNA fragmentation pattern and/or the requirement for macromolecular synthesis merely suggest but do not provide unequivocal evidence for apoptosis. There are either genetic or acquired conditions creating unbalance of Bax/Bcl-2 families-proapoptotic and prooncogenic factors, respectively. The first Bax gene cooperates with other genes coding the new transmembrane proteins into the mitochondrial megapores determinating transition by means of death receptors. Bcl-2 codes prooncogenic mitoses and tissue proliferation. The neuroprotective hypothesis of the dopamine agonist action is a very attractive working hypothesis and some of its tenets are derived from the oxidative stress hypothesis for neurodegeneration, but this hypothesis is still controversial.     

Possible extrapyramidal system degradation in Parkinson’s disease

fall) are either genetically expressed or there are neuropathophysiologic processes that may activate pathways leading to apoptosis, namely oxidative stress, glutamate toxicity and calcium homeostasis disruption. The level of dopamine transporter expression (mRNA, methyl-phenyl-pyridinium) might determine the vulnerability of the nigral neurons to the Parkinsonian insult. The most common clinical picture of extrapyramidal disorder—Parkinson’s disease—consists of an active dopamine cell death—apoptosis, which is partially programmed like as programmed cell death and partially accidentally installed chain of events. Without morphological criteria, biochemical indicators such as laddered DNA fragmentation pattern and/or the requirement for macromolecular synthesis merely suggest but do not provide unequivocal evidence for apoptosis. There are either genetic or acquired conditions creating unbalance of Bax/Bcl-2 families—proapoptotic and prooncogenic factors, respectively. The first Bax gene cooperates with other genes coding the new transmembrane proteins into the mitochondrial megapores determinating transition by means of death receptors. Bcl-2 codes prooncogenic mitoses and tissue proliferation. The neuroprotective hypothesis of the dopamine agonist action is a very attractive working hypothesis and some of its tenets are derived from the oxidative stress hypothesis for neurodegeneration, but this hypothesis is still controversial.     

Dysregulation of mitochondrial fusion and fission: an emerging concept in neurodegeneration

Mitochondrial dysfunction is increasingly being recognized as an important factor contributing to the pathogenesis of neurodegenerative disorders. However, at present, the molecular basis underlying the decline in mitochondrial function is not really understood, but recent experimental evidence has shed some light on the pivotal role of mitochondrial morphology control in this process. In particular, dysregulated mitochondrial fusion and fission events can now be regarded as playing important pathogenic roles in neurodegeneration. In healthy cells, mitochondrial morphology is maintained through a dynamic balance between fusion and fission processes, and this regulated balance seems to be required for maintaining normal mitochondrial and cellular function. Moreover, during programmed cell death, activation of mitochondrial fission occurs, leading to mitochondrial fragmentation (Karbowski et al. in J Cell Biol 164:493–499, 2004). Consequently, inhibition of mitochondrial fission results in a significantly reduced cellular susceptibility toward apoptosis. The clinical relevance of maintaining a finely tuned balance between mitochondrial fusion and fission processes is underscored by the fact that the pathogenesis of certain hereditary neurodegenerative disorders such as autosomal dominant optic atrophy (ADOA) and Charcot-Marie-Tooth neuropathy type 2A (CMT2A) can now be linked to mutations in genes encoding mediators of mitochondrial fusion. In this article, I will summarize important aspects of what is currently known about the molecular machinery regulating mitochondrial fission and fusion in mammalian cells. Special emphasis will be given to the consequences of dysregulated mitochondrial morphology with regard to the pathogenesis of neurodegenerative disorders. A detailed understanding of the mitochondrial fission and fusion machinery will be a prerequisite for the development of therapeutic approaches to inhibit the neuronal cell death underlying certain neurodegenerative disorders.     

Effect of acidosis, oxidative stress, and glutamate toxicity on the survival of mature and immature cultured cerebellar granule cells

The effects of various pathogenic factors on the viability of cultured immature and mature granule cells of rat cerebellum that developed during brain hypoxia and reoxygenation were compared. These factors included acidosis, oxidative stress, and glutamate toxicity. Incubation of both mature (seven-nine daysof culturing) and immature (three-four days of culturing) cerebellar granule cells for 24 hours under the conditions of external acidosis or oxidative stress was shown to induce neuronal death in these cultures. Immature neurons were significantly more sensitive to these factors than mature ones. Immature neurons were also more sensitive to the staurosporine apoptosis inductor. However, glutamate treatment (100 μM) resulted in neuronal death only in the mature cultures. The results demonstrated that immature neurons were more sensitive to damaging factors not connected with glutamate toxicity than the mature neurons.     

Role of c-Fos protein on glutamate toxicity in primary neural hippocampal cells

The hippocampus is extremely sensitive to microenvironmental signals and toxic events, including massive glutamate release. Despite the extensive literature related to the cascade of molecular events triggered in postsynaptic neurons, the distinction between proapoptotic and survival pathways is still being discussed. In this study, we have investigated the role of c-Fos in glutamate-induced toxicity in primary cultures of hippocampal neurons by using antisense oligonucleotide (ASO) technology. Exposure of cells (5 days in vitro; DIV) to glutamate 0.5 mM for 24 hr caused massive nuclear alteration. An increase in the number of caspase-3-positive cells was also observed 24 hr after glutamate treatment. The expression of c-fos and c-jun immediate-early genes was increased 30 min after glutamate exposure. The study of c-Fos and c-Jun protein expression revealed an increase in the number of cells positive for both antibodies. To investigate whether the expression of c-Fos protein after glutamate treatment was related to cell death activation or cell survival pathways, cells were exposed to 5 microM of c-fos ASO at 4 DIV, 24 hr before glutamate treatment. The presence of the ASO in the medium significantly decreased the number of altered nuclei, and this was associated with a significant reduction in the number of c-Fos-positive cells after glutamate treatment. Exposure of cells to the c-fos ASO under the conditions described above decreased caspase-3 immunostaining induced by glutamate. These results suggest that the synthesis of c-Fos protein after glutamate exposure favors cell death pathway activation in which caspase-3 is also involved.