Ayumu Tashiro

NMDA-receptor-mediated, cell-specific integration of new neurons in adult dentate gyrus.

New neurons are continuously integrated into existing neural circuits in adult dentate gyrus of the mammalian brain. Accumulating evidence indicates that these new neurons are involved in learning and memory. A substantial fraction of newly born neurons die before they mature and the survival of new neurons is regulated in an experience-dependent manner, raising the possibility that the selective survival or death of new neurons has a direct role in a process of learning and memory—such as information storage—through the information-specific construction of new circuits. However, a critical assumption of this hypothesis is that the survival or death decision of new neurons is information-specific. Because neurons receive their information primarily through their input synaptic activity, we investigated whether the survival of new neurons is regulated by input activity in a cell-specific manner. Here we developed a retrovirus-mediated, single-cell gene knockout technique in mice and showed that the survival of new neurons is competitively regulated by their own NMDA-type glutamate receptor during a short, critical period soon after neuronal birth. This finding indicates that the survival of new neurons and the resulting formation of new circuits are regulated in an input-dependent, cell-specific manner. Therefore, the circuits formed by new neurons may represent information associated with input activity within a short time window in the critical period. This information-specific addition of new circuits through selective survival or death of new neurons may be a unique attribute of new neurons that enables them to play a critical role in learning and memory.

Experience-Specific Functional Modification of the Dentate Gyrus through Adult Neurogenesis: A Critical Period during an Immature Stage

Neural circuits in the dentate gyrus are continuously modified by adult neurogenesis, whose level is affected by the animals experience. However, it is not known whether this experience-dependent anatomical modification alters the functional properties of the dentate gyrus. Here, using the expression of immediate early gene products, c-fos and Zif268, as indicators of recently activated neurons, we show that previous exposure to an enriched environment increases the total number of new neurons and the number of new neurons responding to reexposure to the same environment. The increase in the density of activated new neurons occurred specifically in response to exposure to the same environment but not to a different experience. Furthermore, we found that these experience-specific modifications are affected exclusively by previous exposure around the second week after neuronal birth but not later than 3 weeks. Thus, the animals experience within a critical period during an immature stage of new neurons determines the survival and population response of the new neurons and may affect later neural representation of the experience in the dentate gyrus. This experience-specific functional modification through adult neurogenesis could be a mechanism by which new neurons exert a long-term influence on the function of the dentate gyrus related to learning and memory.

Development of a novel mouse glioma model using lentiviral vectors.

We report the development of a new method to induce glioblastoma multiforme in adult immunocompetent mice by injecting Cre-loxP–controlled lentiviral vectors expressing oncogenes. Cell type- or region-specific expression of activated forms of the oncoproteins Harvey-Ras and AKT in fewer than 60 glial fibrillary acidic protein–positive cells in the hippocampus, subventricular zone or cortex of mice heterozygous for the gene encoding the tumor suppressor Tp53 were tested. Mice developed glioblastoma multiforme when transduced either in the subventricular zone or the hippocampus. However, tumors were rarely detected when the mice were transduced in the cortex. Transplantation of brain tumor cells into naive recipient mouse brain resulted in the formation of glioblastoma multiforme–like tumors, which contained CD133+ cells, formed tumorspheres and could differentiate into neurons and astrocytes. We suggest that the use of Cre-loxP–controlled lentiviral vectors is a novel way to generate a mouse glioblastoma multiforme model in a region- and cell type-specific manner in adult mice.

Retrovirus-mediated single-cell gene knockout technique in adult newborn neurons in vivo

Single-cell genetic manipulation in an intact brain environment is an informative approach to study molecular mechanism of adult neurogenesis. Here, we describe a protocol for retrovirus-mediated single-cell gene knockout in adult new neurons in vivo. A gene of interest is disrupted in adult floxed mice by a vector based on the Moloney murine leukemia retrovirus, expressing Cre recombinase. High-titer retrovirus is prepared by transfecting plasmids into the HEK293T cells and by concentrating the supernatant containing virus. The retrovirus is stereotaxically injected into the dentate gyrus. Cre recombinase is transduced and expressed in a small fraction of adult new neurons in an intact environment, and the gene knockout is highly efficient within the transduced neurons. Virus preparation takes 7 days, but virus injections take less than 1 h per mouse. By changing the survival time of the mice after the injection, one can analyze the effects on new neurons at different ages.

Role of Rho GTPases in the morphogenesis and motility of dendritic spines.

Dendritic spines are major sites to receive synapses in the mammalian brain. Spines with abnormal morphologies are found in different brain diseases, suggesting that malformation of dendritic spines could be causally linked to those diseases. Rho GTPase-signaling pathways are implicated in the regulation of spine morphology and also in some forms of mental retardation. Therefore, understanding the dynamic regulation of spine morphology by Rho GTPases may provide insights into the etiology and therapeutic strategy of brain diseases. This chapter describes methods used to examine the molecular mechanisms regulating the morphological features of dendritic spines, including slice cultures, biolistic transfections, and live imaging techniques, and summarizes our findings made using these methods.

Critical maturational period of new neurons in adult dentate gyrus for their involvement in memory formation

Adult dentate gyrus produces new neurons continuously throughout life. Multiple lines of evidence have pointed to the possibility that young neurons during a certain maturational stage mediate an important role in memory processing. In this review, we highlight the existing evidence of a ‘critical period’ for new neurons in their involvement in memory formation, describe the unique properties of young neurons as potential mechanisms underlying the critical period, and discuss the implications of the critical period for the function of adult neurogenesis.

A neuroprotective role for microRNA miR-1000 mediated by limiting glutamate excitotoxicity

Evidence has begun to emerge for microRNAs as regulators of synaptic signaling, specifically acting to control postsynaptic responsiveness during synaptic transmission. In this report, we provide evidence that Drosophila melanogaster miR-1000 acts presynaptically to regulate glutamate release at the synapse by controlling expression of the vesicular glutamate transporter (VGlut). Genetic deletion of miR-1000 led to elevated apoptosis in the brain as a result of glutamatergic excitotoxicity. The seed-similar miR-137 regulated VGluT2 expression in mouse neurons. These conserved miRNAs share a neuroprotective function in the brains of flies and mice. Drosophila miR-1000 showed activity-dependent expression, which might serve as a mechanism to allow neuronal activity to fine-tune the strength of excitatory synaptic transmission.

Novelty-induced phase-locked firing to slow gamma oscillations in the hippocampus : requirement of synaptic plasticity

Temporally precise neuronal firing phase-locked to gamma oscillations is thought to mediate the dynamic interaction of neuronal populations, which is essential for information processing underlying higher-order functions such as learning and memory. However, the cellular mechanisms determining phase locking remain unclear. By devising a virus-mediated approach to perform multi-tetrode recording from genetically manipulated neurons, we demonstrated that synaptic plasticity dependent on the GluR1 subunit of AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazole propionate) receptor mediates two dynamic changes in neuronal firing in the hippocampal CA1 area during novel experiences: the establishment of phase-locked firing to slow gamma oscillations and the rapid formation of the spatial firing pattern of place cells. The results suggest a series of events potentially underlying the acquisition of new spatial information: slow gamma oscillations, originating from the CA3 area, induce the two GluR1-dependent changes of CA1 neuronal firing, which in turn determine information flow in the hippocampal-entorhinal system.

Place cells and long-term potentiation in the hippocampus

Place cells show location-specific firing patterns according to an animals position in an environment and are thought to contribute to the spatial representation required for self-navigation. Decades of study have extensively characterized the properties of place cells and suggested the involvement of long-term potentiation (LTP), a long-lasting synaptic strengthening, in place cell activity. Here, we review the basic characteristics of place cell activity and the findings that support the idea that LTP contributes to the formation, maintenance, and plasticity of place cell activity.

Imaging Newborn Granule Cells in Fixed Sections

This protocol describes the harvesting of brain tissue from mice that have had the retroviral vector CAG-GFP injected into the dentate gyrus. Brain tissue from these mice is dissected, the tissue is fixed, and the sections are prepared. The fixed sections are imaged using fluorescent confocal microscopy, and newborn granule cells containing GFP are visualized and are characterized.