Akira Nagaoka scite author profile

Non-technical summary Neurons communicate with each other with synapses using chemical messengers. The major synapses in the cerebral cortex utilize glutamate as a messenger and are made on special submicron structures, called dendritic spines. Dendritic spines are diverse in their size and densely packed in the cortex. Therefore, an optical technique for application of glutamate to single spines (two-photon (TP) uncaging) has been intensively used to clarify their functions in vitro. We have here extended 2P uncaging to living adult brain, and found that spine sizes display tight correlations with their functions, such as rapid glutamate sensing and an increase in cytosolic Ca 2+ concentrations, even in vivo, as they were reported for in vitro preparations. Our data suggest that the structure and motility of dendritic spines play a key role in the adult brain function.Abstract Two-photon (2P) uncaging of caged neurotransmitters can efficiently stimulate individual synapses and is widely used to characterize synaptic functions in brain slice preparations. Here we extended 2P uncaging to neocortical pyramidal neurons in adult mice in vivo where caged glutamate was applied from the pial surface. To validate the methodology, we applied a small fluorescent probe using the same method, and confirmed that its concentrations were approximately homogenous up to 200 μm below the cortical surface, and that the extracellular space of the neocortex was as large as 22%. In fact, in vivo whole-cell recording revealed that 2P glutamate uncaging could elicit transient currents (2pEPSCs) very similar to excitatory postsynaptic currents (EPSCs). A spatial resolution of glutamate uncaging was 0.6-0.8 μm up to the depth of 200 μm, and in vivo 2P uncaging was able to stimulate single identified spines. Automated three-dimensional (3-D) mapping of such 2pEPSCs which covered the surfaces of dendritic branches revealed that functional AMPA receptor expression was stable and proportional to spine volume. Moreover, in vivo 2P Ca 2+ imaging and uncaging suggested that the amplitudes of glutamate-induced Ca 2+ transients were inversely proportional to spine volume. Thus, the key structure-function relationships hold in dendritic spines in adult neocortex in vivo, as in young hippocampal slice preparations. In vivo 2P uncaging will be a powerful tool to investigate properties of synapses in the neocortex.

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Abnormal intrinsic dynamics of dendritic spines in a fragile X syndrome mouse model in vivo

Nagaoka

Takehara

Hayashi‐Takagi

et al. 2016

Sci Rep

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Dendritic spine generation and elimination play an important role in learning and memory, the dynamics of which have been examined within the neocortex in vivo. Spine turnover has also been detected in the absence of specific learning tasks, and is frequently exaggerated in animal models of autistic spectrum disorder (ASD). The present study aimed to examine whether the baseline rate of spine turnover was activity-dependent. This was achieved using a microfluidic brain interface and open-dura surgery, with the goal of abolishing neuronal Ca2+ signaling in the visual cortex of wild-type mice and rodent models of fragile X syndrome (Fmr1 knockout [KO]). In wild-type and Fmr1 KO mice, the majority of baseline turnover was found to be activity-independent. Accordingly, the application of matrix metalloproteinase-9 inhibitors selectively restored the abnormal spine dynamics observed in Fmr1 KO mice, without affecting the intrinsic dynamics of spine turnover in wild-type mice. Such findings indicate that the baseline turnover of dendritic spines is mediated by activity-independent intrinsic dynamics. Furthermore, these results suggest that the targeting of abnormal intrinsic dynamics might pose a novel therapy for ASD.

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Glycogen Synthase Kinase-3β: A Prognostic Marker and a Potential Therapeutic Target in Human Bladder Cancer

Naito

Bilim

Yuuki

et al. 2010

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Purpose: Although recent studies have shown glycogen synthase kinase-3β (GSK-3β), a serine/threonine kinase, as a positive regulator of pancreatic, colon, and kidney cancer cell survival and proliferation, the role of GSK-3 in bladder cancer remains unknown. Our objectives were to determine the subcellular localization of GSK-3β and to evaluate the effect of GSK-3 inhibition in bladder cancer.Experimental Design: We used immunohistochemical staining and nuclear/cytosolic fractionation to determine the expression pattern of GSK-3β in human urothelial carcinomas. To study the effect of GSK-3 inhibition on bladder cancer cell proliferation and survival, we used pharmacologic inhibitors of GSK-3, RNA interference, MTS assay, bromodeoxyuridine incorporation assay, quantitative reverse transcriptase-PCR, and Western blotting.Results: We found aberrant nuclear accumulation of GSK-3β in 62% (43 of 69) and 91% (21 of 23) of noninvasive and invasive human urothelial carcinomas, respectively. GSK-3β nuclear staining was significantly associated with high-grade tumors (P < 0.001), advanced stage of bladder cancer (P < 0.05), metastasis (P < 0.05), and worse cause-specific survival (P < 0.05) in bladder cancer patients. Moreover, we found that pharmacologic inhibition or genetic depletion of GSK-3β resulted in decreased viability of bladder cancer cells.Conclusions: Our results suggest nuclear accumulation of GSK-3β as a novel prognostic marker in bladder cancer, show that GSK-3 contributes to urothelial cancer cell proliferation and survival, and identify GSK-3 as a potential therapeutic target in human bladder cancer.

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Re-expression of miR-199a suppresses renal cancer cell proliferation and survival by targeting GSK-3β

et al. 2012

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Akira Nagaoka

In vivo two‐photon uncaging of glutamate revealing the structure–function relationships of dendritic spines in the neocortex of adult mice

Abnormal intrinsic dynamics of dendritic spines in a fragile X syndrome mouse model in vivo

Glycogen Synthase Kinase-3β: A Prognostic Marker and a Potential Therapeutic Target in Human Bladder Cancer

Re-expression of miR-199a suppresses renal cancer cell proliferation and survival by targeting GSK-3β

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