Toshiyuki Mizui

Down‐regulation of drebrin A expression suppresses synaptic targeting of NMDA receptors in developing hippocampal neurones

Drebrin is a major F‐actin‐binding protein in the brain. We have recently demonstrated that drebrin A (neurone‐specific isoform) clusters at synapses and governs targeting of the post‐synaptic density 95 protein to synapses during development. To determine the role of drebrin A on excitatory synapse formation, we analysed whether the suppression of drebrin A expression affects filopodia‐spine morphology and synaptic targeting of NMDA receptors in cultured hippocampal neurones. Suppression of developmentally programmed up‐regulation of drebrin A by antisense treatment significantly decreased the density and width of filopodia‐spines. Immunocytochemistry showed that the antisense treatment did not attenuate synaptic clustering of NMDA receptors under conditions that permitted spontaneous activities but inhibited the accelerated targeting of NMDA receptors into synapses by its antagonist d‐(–)‐2‐amino‐5‐phosphonopentanoic acid. These results indicate that drebrin A up‐regulation plays a pivotal role in spine morphogenesis and activity‐dependent synaptic targeting of NMDA receptors.

Drebrin E is involved in the regulation of axonal growth through actin–myosin interactions

Drebrin is a well‐known side‐binding protein of F‐actin in the brain. Immunohistochemical data suggest that the peripheral parts of growing axons are enriched in the drebrin E isoform and mature axons are not. It has also been observed that drebrin E is concentrated in the growth cones of PC12 cells. These data strongly suggest that drebrin E plays a role in axonal growth during development. In this study, we used primary hippocampal neuronal cultures to analyze the role of drebrin E. Immunocytochemistry showed that within axonal growth cones drebrin E specifically localized to the transitional zone, an area in which dense networks of F‐actins and microtubules overlapped. Over‐expression of drebrin E caused drebrin E and F‐actin to accumulate throughout the growth cone and facilitated axonal growth. In contrast, knockdown of drebrin E reduced drebrin E and F‐actin in the growth cone and prevented axonal growth. Furthermore, inhibition of myosin II ATPase masked the promoting effects of drebrin E over‐expression on axonal growth. These results suggest that drebrin E plays a role in axonal growth through actin–myosin interactions in the transitional zone of axonal growth cones.

Myosin II ATPase Activity Mediates the Long-Term Potentiation-Induced Exodus of Stable F-Actin Bound by Drebrin A from Dendritic Spines

The neuronal actin-binding protein drebrin A forms a stable structure with F-actin in dendritic spines. NMDA receptor activation causes an exodus of F-actin bound by drebrin A (DA-actin) from dendritic spines, suggesting a pivotal role for DA-actin exodus in synaptic plasticity. We quantitatively assessed the extent of DA-actin localization to spines using the spine-dendrite ratio of drebrin A in cultured hippocampal neurons, and found that (1) chemical long-term potentiation (LTP) stimulation induces rapid DA-actin exodus and subsequent DA-actin re-entry in dendritic spines, (2) Ca2+ influx through NMDA receptors regulates the exodus and the basal accumulation of DA-actin, and (3) the DA-actin exodus is blocked by myosin II ATPase inhibitor, but is not blocked by myosin light chain kinase (MLCK) or Rho-associated kinase (ROCK) inhibitors. These results indicate that myosin II mediates the interaction between NMDA receptor activation and DA-actin exodus in LTP induction. Furthermore, myosin II seems to be activated by a rapid actin-linked mechanism rather than slow MLC phosphorylation. Thus the myosin-II mediated DA-actin exodus might be an initial event in LTP induction, triggering actin polymerization and spine enlargement.

Spikar, a novel drebrin-binding protein, regulates the formation and stabilization of dendritic spines.

Dendritic spines are small, actin‐rich protrusions on dendrites, the development of which is fundamental for the formation of neural circuits. The actin cytoskeleton is central to dendritic spine morphogenesis. Drebrin is an actin‐binding protein that is thought to initiate spine formation through a unique drebrin‐actin complex at postsynaptic sites. However drebrin overexpression in neurons does not increase the final density of dendritic spines. In this study, we have identified and characterized a novel drebrin‐binding protein, spikar. Spikar is localized in cell nuclei and dendritic spines, and accumulation of spikar in dendritic spines directly correlates with spine density. A reporter gene assay demonstrated that spikar acts as a transcriptional co‐activator for nuclear receptors. We found that dendritic spine, but not nuclear, localization of spikar requires drebrin. RNA‐interference knockdown and overexpression experiments demonstrated that extranuclear spikar regulates dendritic spine density by modulating de novo spine formation and retraction of existing spines. Unlike drebrin, spikar does not affect either the morphology or function of dendritic spines. These findings indicate that drebrin‐mediated postsynaptic accumulation of spikar regulates spine density, but is not involved in regulation of spine morphology.

X Irradiation Changes Dendritic Spine Morphology and Density through Reduction of Cytoskeletal Proteins in Mature Neurons

Neurons are essential components of neural circuits and provide brain function organization. We previously reported that X irradiation induces apoptosis in immature neurons. To the best of our knowledge, there have been few reports investigating the effects of X irradiation on mature neurons. We analyzed the effects of X irradiation on the morphology, density and cytoskeletal proteins in dendritic spines on mature neurons. We prepared developing hippocampal neurons from 18 days embryo by using Bankers method. Neurons at 21 days in vitro were X irradiated at several doses and were immediately fixed. To evaluate the dendritic spine morphology and density, the neurons were transfected with a reporter plasmid for enhanced green fluorescent protein (GFP). Changes in the dendritic spines as a result of X irradiation were evaluated using electron microscopy. To analyze the cytoskeletal proteins within the dendritic spines, we performed immunocytochemistry to detect filamentous actin (F-actin), drebrin and PSD-95. X irradiation immediately changed the dendritic spine morphology, and the irradiated spines were significantly thinner and longer than the nonirradiated spines. X irradiation decreased the dendritic spine density in a dose-dependent manner. Electron microscopy confirmed these changes of dendritic spines by X irradiation. Immunohistochemical studies showed that X irradiation decreased the accumulation of drebrin and F-actin, but not PSD-95, within the dendritic spines. These results suggest that X irradiation immediately decreases the dendritic spine density and changes the morphology of mature neurons by reducing the abundance of cytoskeletal proteins. The abnormal dendritic spines may be associated with acute adverse effects after X irradiation in a clinical setting, although further investigations are warranted to validate these findings.

Effect of radiation on the development of immature hippocampal neurons in vitro.

Abstract Okamoto, M., Suzuki, Y., Shirai, K., Mizui, T., Yoshida, Y., Noda, S., Al-Jahdari, W. S., Shirao, T. and Nakano, T. Effect of Radiation on the Development of Immature Hippocampal Neurons In Vitro. Little is known about the direct biological effects of radiation on immature neurons, despite its relevance to the mental retardation caused by irradiation of the brains of fetuses and children. In this study, we investigated the effects of radiation using primary cultured hippocampal neuronal cells with exclusion of glial cells, focusing on cell survival and structural development. Primary neurons were prepared from the hippocampi of fetal rats at embryonic day 18 and cultured according to Bankers methods. After incubation for 7 days, cells were irradiated with X rays and incubated continuously for 7 or 14 days. The number of neurons, their rate of apoptosis, and the patterns of expression of synaptic proteins on the neural dendrites were investigated by immunohistochemical methods. The total numbers of neurons were the same regardless of whether they were irradiated. The number of TUNEL-positive neurons, which can be considered as undergoing apoptosis, increased significantly in a dose-dependent fashion at both 7 and 14 days after irradiation. The mean numbers of clusters of synaptic proteins on neural dendrites, which are considered to represent their developmental level, decreased dose-dependently at both 7 and 14 days after irradiation. These results suggest that radiation not only induces apoptosis but also produces structural defects in the surviving neurons that may directly suppress neural development.

Heterotopic graft of infant rat brain as an ischemic model for prolonged whole-brain ischemia.

By using a heterotopic brain graft model, we have made histological and electrophysiological studies of the infant rat brain after prolonged ischemia. An infant rat head which had undergone ischemia for more than 90 min, was grafted onto an adult rat by anastomosing the thoracic vessels to the femoral vessels of the host rat. Histological and histochemical studies carried out 10 days after the operation showed that the development of the hippocampus and cerebellum in the grafted brain appeared to be normal. Interneuron growth in the hippocampus and migration of the granule cells in the cerebellum had occurred to a similar extent as in control rats. Extracellular recordings in the hippocampus showed normal characteristics of the postsynaptic potentials including long-term potentiation. This heterotopic graft model would be useful for studying brain function after long periods of ischemia.

Low accumulation of drebrin at glutamatergic postsynaptic sites on GABAergic neurons

Glutamatergic synapses form onto both glutamatergic and GABAergic neurons. These two types of glutamatergic synapses differ in their electrical responses to high-frequency stimulation and postsynaptic density protein composition. However, it is not known whether they differ in the actin cytoskeleton composition. In the present study, we used hippocampal neuronal cultures prepared from glutamate decarboxylase 67 (GAD67)-GFP knock-in mice and analyzed the differences in the actin cytoskeleton at glutamatergic synapses contacting GABAergic and glutamatergic neurons. Drebrin-binding actin filaments enriched in dendritic spines are known to play a pivotal role in spine formation. Immunocytochemical analyses demonstrated that drebrin accumulated at glutamatergic synapses on GABAergic neurons as well as at those on glutamatergic neurons. However, the density of drebrin clusters along dendrites in GABAergic neurons was significantly lower than those of glutamatergic neurons. Furthermore, the level of drebrin accumulating at glutamatergic synapses was lower on GABAergic neurons than on glutamatergic neurons. In neurons overexpressing drebrin, drebrin cluster density and accumulation levels in GABAergic and glutamatergic neurons were similar, suggesting that the low drebrin levels in the glutamatergic postsynaptic sites on GABAergic neurons may be because GABAergic neurons express low levels of drebrin. On the other hand, pharmacological analysis demonstrated that the postsynaptic localization of drebrin depended on actin cytoskeleton organization in both GABAergic and glutamatergic neurons. Together these results indicated that, although GABAergic and glutamatergic neurons share common regulatory systems affecting drebrin localization, the density of drebrin-positive glutamatergic synapses formed on GABAergic neurons is lower than those on glutamatergic neurons. This is probably due to the low expression of drebrin in GABAergic neurons.

BDNF Binds Its Pro-Peptide with High Affinity and the Common Val66Met Polymorphism Attenuates the Interaction

Most growth factors are initially synthesized as precursors then cleaved into bioactive mature domains and pro-domains, but the biological roles of pro-domains are poorly understood. In the present study, we investigated the pro-domain (or pro-peptide) of brain-derived neurotrophic factor (BDNF), which promotes neuronal survival, differentiation and synaptic plasticity. The BDNF pro-peptide is a post-processing product of the precursor BDNF. Using surface plasmon resonance and biochemical experiments, we first demonstrated that the BDNF pro-peptide binds to mature BDNF with high affinity, but not other neurotrophins. This interaction was more enhanced at acidic pH than at neutral pH, suggesting that the binding is significant in intracellular compartments such as trafficking vesicles rather than the extracellular space. The common Val66Met BDNF polymorphism results in a valine instead of a methionine in the pro-domain, which affects human brain functions and the activity-dependent secretion of BDNF. We investigated the influence of this variation on the interaction between BDNF and the pro-peptide. Interestingly, the Val66Met polymorphism stabilized the heterodimeric complex of BDNF and its pro-peptide. Furthermore, compared with the Val-containing pro-peptide, the complex with the Met-type pro-peptide was more stable at both acidic and neutral pH, suggesting that the Val66Met BDNF polymorphism forms a more stable complex. A computational modeling provided an interpretation to the role of the Val66Met mutation in the interaction of BDNF and its pro-peptide. Lastly, we performed electrophysiological experiments, which indicated that the BDNF pro-peptide, when pre-incubated with BDNF, attenuated the ability of BDNF to inhibit hippocampal long-term depression (LTD), suggesting a possibility that the BDNF pro-peptide may interact directly with BDNF and thereby inhibit its availability. It was previously reported that the BDNF pro-domain exerts a chaperone-like function and assists the folding of the BDNF protein. However, our results suggest a new role for the BDNF pro-domain (or pro-peptide) following proteolytic cleave of precursor BDNF, and provide insight into the Val66Met polymorphism.

Comparison of the radiosensitivities of neurons and glial cells derived from the same rat brain

Non-proliferating cells, such as mature neurons, are generally believed to be more resistant to X-rays than proliferating cells, such as glial and vascular endothelial cells. Therefore, the late adverse effects of radiotherapy on the brain have been attributed to the radiation-induced damage of glial and vascular endothelial cells. However, little is known about the radiosensitivities of neurons and glial cells due to difficulties in culturing these cells, particularly neurons, independently. In the present study, primary dissociated neurons and glial cultures were prepared separately from the hippocampi and cerebrum, respectively, which had been obtained from the same fetal rat on embryonic day 18. X-irradiations of 50 Gy were performed on the cultured neurons and glial cells at 7 and 21 days in vitro (DIV). The cells were fixed at 24 h after irradiation. Terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling was then performed to measure the apoptotic indices (AIs). The AIs of non-irradiated and irradiated neurons at 7 DIV were 23.7±6.7 and 64.9±4.8%, and those at 21 DIV were 52.1±17.4 and 44.6±12.5%, respectively. The AIs of non-irradiated and irradiated glial cells at 7 DIV were 5.8±1.5 and 78.4±3.3% and those at 21 DIV were 9.6±2.6 and 86.3±4.9%, respectively. Glial cells and neurons were radiosensitive at 7 DIV. However, while glial cells were radiosensitive at 21 DIV, neurons were not.