Younghye Moon

Mitochondrial membrane depolarization and the selective death of dopaminergic neurons by rotenone: protective effect of coenzyme Q10

Chronic exposure to the pesticide rotenone induces a selective degeneration of nigrostriatal dopaminergic neurons and reproduces the features of Parkinsons disease in experimental animals. This action is thought to be relevant to its inhibition of the mitochondrial complex I, but the precise mechanism of this suppression in selective neuronal death is still elusive. Here we investigate the mechanism of dopaminergic neuronal death mediated by rotenone in primary rat mesencephalic neurons. Low concentrations of rotenone (5–10 nm) induce the selective death of dopaminergic neurons without significant toxic effects on other mesencephalic cells. This cell death was coincident with apoptotic events including capsase‐3 activation, DNA fragmentation, and mitochondrial membrane depolarization. Pretreatment with coenzyme Q10, the electron transporter in the mitochondrial respiratory chain, remarkably reduced apoptosis as well as the mitochondrial depolarization induced by rotenone, but other free radical scavengers such as N‐acetylcysteine, glutathione, and vitamin C did not. Furthermore, the selective neurotoxicity of rotenone was mimicked by the mitochondrial protonophore carbonyl cyanide 4‐(trifluoromethoxy) phenylhydrazone (FCCP), a cyanide analog that effectively collapses a mitochondrial membrane potential. These data suggest that mitochondrial depolarization may play a crucial role in rotenone‐induced selective apoptosis in rat primary dopaminergic neurons.

Control of neuronal migration through rostral migratory stream in mice

During the nervous system development, immature neuroblasts have a strong potential to migrate toward their destination. In the adult brain, new neurons are continuously generated in the neurogenic niche located near the ventricle, and the newly generated cells actively migrate toward their destination, olfactory bulb, via highly specialized migratory route called rostral migratory stream (RMS). Neuroblasts in the RMS form chains by their homophilic interactions, and the neuroblasts in chains continually migrate through the tunnels formed by meshwork of astrocytes, glial tube. This review focuses on the development and structure of RMS and the regulation of neuroblast migration in the RMS. Better understanding of RMS migration may be crucial for improving functional replacement therapy by supplying endogenous neuronal cells to the injury sites more efficiently.

Dissociation of progressive dopaminergic neuronal death and behavioral impairments by bax deletion in a mouse model of parkinson's diseases

Parkinsons disease (PD) is a common, late-onset movement disorder with selective degeneration of dopaminergic (DA) neurons in the substantia nigra (SN). Although the neurotoxin 6-hydroxydopamine (6-OHDA) has been used to induce progressive degeneration of DA neurons in various animal models of PD, the precise molecular pathway and the impact of anti-apoptotic treatment on this neurodegeneration are less understood. Following a striatal injection of 6-OHDA, we observed atrophy and progressive death of DA neurons in wild-type mice. These degenerating DA neurons never exhibited signs of apoptosis (i.e., caspase-3 activation and cytoplasmic release of cytochrome C), but rather show nuclear translocation of apoptosis-inducing factor (AIF), a hallmark of regulated necrosis. However, mice with genetic deletion of the proapoptotic gene Bax (Bax-KO) exhibited a complete absence of 6-OHDA-induced DA neuron death and nuclear translocation of AIF, indicating that 6-OHDA-induced DA neuronal death is mediated by Bax-dependent AIF activation. On the other hand, DA neurons that survived in Bax-KO mice exhibited marked neuronal atrophy, without significant improvement of PD-related behavioral deficits. These findings suggest that anti-apoptotic therapy may not be sufficient for PD treatment, and the prevention of Bax-independent neuronal atrophy may be an important therapeutic target.

Induction of ezrin-radixin-moesin molecules after cryogenic traumatic brain injury of the mouse cortex

Traumatic brain injury promotes rapid induction of microglial cells and infiltration of peripheral macrophages to the injury sites. Such inflammatory responses are mediated by the activation and migration of immune cells, which are influenced by the actin cytoskeleton remodeling. In this study, we observed that the phosphorylation and expressions of ezrin–radixin–moesin (ERM) proteins, which are linkers for cell surface with actin cytoskeleton, are induced in the activated microglia/macrophages, whereas ERM molecules are only marginally expressed in quiescent microglia in the normal brain. These results suggest that ERM activation in the injury penumbra is implicated in the inflammatory immune responses after traumatic brain injury.

Expression of connexin29 and 32 in the penumbra region after traumatic brain injury of mice.

Connexins (Cx) are transmembrane proteins forming vertebrate gap junction channels for direct cell–cell communication. We found that the expressions of two Cx family members, Cx29 and Cx32, were progressively increased in the sharp border of injury penumbra regions after cryotraumatic brain injury. Although these two Cxs are expressed exclusively in the oligodendrocytes in the normal cerebral cortex, their expressions were increased in the astrocytes and microglia localized in the injury border. Highly selective induction of Cxs in the injury border suggests that altered Cxs may contribute to the propagations of injury-related and/or regeneration signals after acute brain injury.

Regional difference of reactive astrogliosis following traumatic brain injury revealed by hGFAP-GFP transgenic mice.

Reactive astrocytes greatly influence the wound healing and neuronal regeneration processes following brain injury. However, the origin and fate of reactive astrocytes appear to be different depending on the type, severity and duration of brain injury. Using the cryogenic traumatic brain injury model, here we comprehensively addressed the regional differences of reactive astrocytes in the injured cortex. In the proximal region of injury site, NG2-expressing and cytoplasmic Olig2-labeled cells were densely localized 3 days after the injury. Next to this proximal layer, most of reactive astrocytes did not express NG2 but exhibited radial glia-like shape with elongated processes. Accordingly, they expressed the progenitor or radial glial markers, such as vimentin, brain lipid binding protein (BLBP) and the green fluorescent protein (GFP) under the control of the human GFAP (hGFAP) promoter. However, only few glial fibrillary acidic protein (GFAP) expressing astrocytes were found in this layer. Distal to the injury site, most of astrocytes strongly expressed GFAP with hypertonic morphology. At day 15 after injury, all layers expressing GFAP and other marker expressions disappeared, indicating the termination of reactive astrogliosis. Taken together, our data suggest that reactive astrogliosis occurs in a regionally segregated manner in the early phase of brain injury.

Different expression patterns of Phactr family members in normal and injured mouse brain

Phosphatase and actin regulators (Phactrs) are a novel family of proteins expressed in the brain, and they exhibit both strong modulatory activity of protein phosphatase 1 and actin-binding activity. Phactrs are comprised of four family members (Phactr1-4), but their detailed expression patterns during embryonic and postnatal development are not well understood. We found that these family members exhibit different spatiotemporal mRNA expression patterns. Phactr4 mRNA was found in neural stem cells in the developing and adult brains, whereas Phactr1 and 3 appeared to be expressed in post-mitotic neurons. Following traumatic brain injury which promotes neurogenesis in the neurogenic region and gliogenesis in the injury penumbra, the mRNA expression of phactr2 and 4 was progressively increased in the injury penumbra, and phactr4 mRNA and protein induction was observed in reactive astrocytes. These differential expression patterns of phactrs imply specific functions for each protein during development, and the importance of Phactr4 in the reactive gliosis following brain injury.

Function of Ezrin‐Radixin‐Moesin Proteins in Migration of Subventricular Zone‐Derived Neuroblasts Following Traumatic Brain Injury

Throughout life, newly generated neuroblasts from the subventricular zone migrate toward the olfactory bulb through the rostral migratory stream. Upon brain injury, these migrating neuroblasts change their route and begin to migrate toward injured regions, which is one of the regenerative responses after brain damage. This injury‐induced migration is triggered by stromal cell‐derived factor 1 (SDF1) released from microglia near the damaged site; however, it is still unclear how these cells transduce SDF1 signals and change their direction. In this study, we found that SDF1 promotes the phosphorylation of ezrin‐radixin‐moesin (ERM) proteins, which are key molecules in organizing cell membrane and linking signals from the extracellular environment to the intracellular actin cytoskeleton. Blockade of ERM activation by overexpressing dominant‐negative ERM (DN‐ERM) efficiently perturbed the migration of neuroblasts. Considering that DN‐ERM‐expressing neuroblasts failed to maintain proper migratory cell morphology, it appears that ERM‐dependent regulation of cell shape is required for the efficient migration of neuroblasts. These results suggest that ERM activation is an important step in the directional migration of neuroblasts in response to SDF1‐CXCR4 signaling following brain injury. STEM CELLS 2013;31:1696–1705

Induction of neuronal apoptosis by expression of Hes6 via p53-dependent pathway

Hes6 is a member of hairy/enhancer of split (Hes) family that plays a role in the cell proliferation and differentiation. Recently, we found that Hes6 is involved in the regulation of cell proliferation via p53-dependent pathway. In addition to the proliferating regions, brain regions where early post-mitotic neurons are enriched also exhibited Hes6 and p53 mRNA expression. Because p53 is involved in the post-mitotic neuronal apoptosis, here we investigated whether Hes6 can influence the neuronal survival/death. Overexpression of wild-type Hes6 and its mutants induced the apoptosis of primary cultured cortical neurons. In addition, neuronal apoptosis by Hes6 overexpression was markedly blunted in p53(-/-) or Bax(-/-) cortical neurons, suggesting that these pro-apoptotic effects are mediated by p53- and Bax-dependent pathway. However, transactivation-defective mutants of Hes6 also enhanced neuronal apoptosis, suggesting that apoptogenic activity of Hes6 is not directly related to its role in the transcriptional regulation. We propose that Hes6 may play a significant role in the neuronal cell death and/or pathological neurodegeneration via activation of p53 signaling.

Induction of Per1 expression following an experimentally induced epilepsy in the mouse hippocampus

The Period1 (Per1) is a clock-oscillating gene product that plays an essential role in the generation and modulation of circadian rhythm in the suprachiasmatic nucleus (SCN) of hypothalamus. However, Per1 is also expressed in many other brain regions including cerebral cortex, hippocampus, and amygdala, suggesting that Per1 may be involved in the broader cellular functions in addition to the rhythm regulation. In this study, we found that chemical or electrical seizure-inducing stimulations regulate Per1 expression. Treatments with electric convulsive shock (ECS) or kainic acid (KA) robustly up-regulated the expressions of per1 mRNA and protein in the hippocampal formation and cerebral cortex. In consistent, we found that neuronal depolarization or KA treatment increased per1 mRNA expression in cultured primary cortical neurons. Because it has been demonstrated that Per family molecules contribute to the regulation of stress-induced cell death, we also explored the effect of Per1 overexpression on the survival of cultured neurons. However, neither basal, staurosporine- nor KA-induced neuronal death was affected by forced expression of Per1. Collectively, these results suggest that the Per1 expression is neuronal activity- and epileptogen-dependent, although its functional significance is remained to be explored.