@inbook{9756, abstract = {High-resolution visualization and quantification of membrane proteins contribute to the understanding of their functions and the roles they play in physiological and pathological conditions. Sodium dodecyl sulfate-digested freeze-fracture replica labeling (SDS-FRL) is a powerful electron microscopy method to study quantitatively the two-dimensional distribution of transmembrane proteins and their tightly associated proteins. During treatment with SDS, intracellular organelles and proteins not anchored to the replica are dissolved, whereas integral membrane proteins captured and stabilized by carbon/platinum deposition remain on the replica. Their intra- and extracellular domains become exposed on the surface of the replica, facilitating the accessibility of antibodies and, therefore, providing higher labeling efficiency than those obtained with other immunoelectron microscopy techniques. In this chapter, we describe the protocols of SDS-FRL adapted for mammalian brain samples, and optimization of the SDS treatment to increase the labeling efficiency for quantification of Cav2.1, the alpha subunit of P/Q-type voltage-dependent calcium channels utilizing deep learning algorithms.}, author = {Kaufmann, Walter and Kleindienst, David and Harada, Harumi and Shigemoto, Ryuichi}, booktitle = { Receptor and Ion Channel Detection in the Brain}, isbn = {9781071615218}, keywords = {Freeze-fracture replica: Deep learning, Immunogold labeling, Integral membrane protein, Electron microscopy}, pages = {267--283}, publisher = {Humana}, title = {{High-Resolution localization and quantitation of membrane proteins by SDS-digested freeze-fracture replica labeling (SDS-FRL)}}, doi = {10.1007/978-1-0716-1522-5_19}, volume = {169}, year = {2021}, } @article{7391, abstract = {Electron microscopy (EM) is a technology that enables visualization of single proteins at a nanometer resolution. However, current protein analysis by EM mainly relies on immunolabeling with gold-particle-conjugated antibodies, which is compromised by large size of antibody, precluding precise detection of protein location in biological samples. Here, we develop a specific chemical labeling method for EM detection of proteins at single-molecular level. Rational design of α-helical peptide tag and probe structure provided a complementary reaction pair that enabled specific cysteine conjugation of the tag. The developed chemical labeling with gold-nanoparticle-conjugated probe showed significantly higher labeling efficiency and detectability of high-density clusters of tag-fused G protein-coupled receptors in freeze-fracture replicas compared with immunogold labeling. Furthermore, in ultrathin sections, the spatial resolution of the chemical labeling was significantly higher than that of antibody-mediated labeling. These results demonstrate substantial advantages of the chemical labeling approach for single protein visualization by EM.}, author = {Tabata, Shigekazu and Jevtic, Marijo and Kurashige, Nobutaka and Fuchida, Hirokazu and Kido, Munetsugu and Tani, Kazushi and Zenmyo, Naoki and Uchinomiya, Shohei and Harada, Harumi and Itakura, Makoto and Hamachi, Itaru and Shigemoto, Ryuichi and Ojida, Akio}, issn = {2589-0042}, journal = {iScience}, number = {12}, pages = {256--268}, publisher = {Elsevier}, title = {{Electron microscopic detection of single membrane proteins by a specific chemical labeling}}, doi = {10.1016/j.isci.2019.11.025}, volume = {22}, year = {2019}, } @article{736, abstract = {The neurotransmitter receptor subtype, number, density, and distribution relative to the location of transmitter release sites are key determinants of signal transmission. AMPA-type ionotropic glutamate receptors (AMPARs) containing GluA3 and GluA4 subunits are prominently expressed in subsets of neurons capable of firing action potentials at high frequencies, such as auditory relay neurons. The auditory nerve (AN) forms glutamatergic synapses on two types of relay neurons, bushy cells (BCs) and fusiform cells (FCs) of the cochlear nucleus. AN-BC and AN-FC synapses have distinct kinetics; thus, we investigated whether the number, density, and localization of GluA3 and GluA4 subunits in these synapses are differentially organized using quantitative freeze-fracture replica immunogold labeling. We identify a positive correlation between the number of AMPARs and the size of AN-BC and AN-FC synapses. Both types of AN synapses have similar numbers of AMPARs; however, the AN-BC have a higher density of AMPARs than AN-FC synapses, because the AN-BC synapses are smaller. A higher number and density of GluA3 subunits are observed at AN-BC synapses, whereas a higher number and density of GluA4 subunits are observed at AN-FC synapses. The intrasynaptic distribution of immunogold labeling revealed that AMPAR subunits, particularly GluA3, are concentrated at the center of the AN-BC synapses. The central distribution of AMPARs is absent in GluA3-knockout mice, and gold particles are evenly distributed along the postsynaptic density. GluA4 gold labeling was homogenously distributed along both synapse types. Thus, GluA3 and GluA4 subunits are distributed at AN synapses in a target-cell-dependent manner.}, author = {Rubio, María and Matsui, Ko and Fukazawa, Yugo and Kamasawa, Naomi and Harada, Harumi and Itakura, Makoto and Molnár, Elek and Abe, Manabu and Sakimura, Kenji and Shigemoto, Ryuichi}, issn = {18632653}, journal = {Brain Structure and Function}, number = {8}, pages = {3375 -- 3393}, publisher = {Springer}, title = {{The number and distribution of AMPA receptor channels containing fast kinetic GluA3 and GluA4 subunits at auditory nerve synapses depend on the target cells}}, doi = {10.1007/s00429-017-1408-0}, volume = {222}, year = {2017}, } @inbook{1094, abstract = {Immunogold labeling of freeze-fracture replicas has recently been used for high-resolution visualization of protein localization in electron microscopy. This method has higher labeling efficiency than conventional immunogold methods for membrane molecules allowing precise quantitative measurements. However, one of the limitations of freeze-fracture replica immunolabeling is difficulty in keeping structural orientation and identifying labeled profiles in complex tissues like brain. The difficulty is partly due to fragmentation of freeze-fracture replica preparations during labeling procedures and limited morphological clues on the replica surface. To overcome these issues, we introduce here a grid-glued replica method combined with SEM observation. This method allows histological staining before dissolving the tissue and easy handling of replicas during immunogold labeling, and keeps the whole replica surface intact without fragmentation. The procedure described here is also useful for matched double-replica analysis allowing further identification of labeled profiles in corresponding P-face and E-face.}, author = {Harada, Harumi and Shigemoto, Ryuichi}, booktitle = {High-Resolution Imaging of Cellular Proteins}, issn = {1611-3349}, pages = {203 -- 216}, publisher = {Springer}, title = {{Immunogold protein localization on grid-glued freeze-fracture replicas}}, doi = {10.1007/978-1-4939-6352-2_12}, volume = {1474}, year = {2016}, } @article{1546, abstract = {Synaptic efficacy and precision are influenced by the coupling of voltage-gated Ca2+ channels (VGCCs) to vesicles. But because the topography of VGCCs and their proximity to vesicles is unknown, a quantitative understanding of the determinants of vesicular release at nanometer scale is lacking. To investigate this, we combined freeze-fracture replica immunogold labeling of Cav2.1 channels, local [Ca2+] imaging, and patch pipette perfusion of EGTA at the calyx of Held. Between postnatal day 7 and 21, VGCCs formed variable sized clusters and vesicular release became less sensitive to EGTA, whereas fixed Ca2+ buffer properties remained constant. Experimentally constrained reaction-diffusion simulations suggest that Ca2+ sensors for vesicular release are located at the perimeter of VGCC clusters (<30nm) and predict that VGCC number per cluster determines vesicular release probability without altering release time course. This "perimeter release model" provides a unifying framework accounting for developmental changes in both synaptic efficacy and time course.}, author = {Nakamura, Yukihiro and Harada, Harumi and Kamasawa, Naomi and Matsui, Ko and Rothman, Jason and Shigemoto, Ryuichi and Silver, R Angus and Digregorio, David and Takahashi, Tomoyuki}, journal = {Neuron}, number = {1}, pages = {145 -- 158}, publisher = {Elsevier}, title = {{Nanoscale distribution of presynaptic Ca2+ channels and its impact on vesicular release during development}}, doi = {10.1016/j.neuron.2014.11.019}, volume = {85}, year = {2015}, } @article{1898, abstract = {Fast synaptic transmission is important for rapid information processing. To explore the maximal rate of neuronal signaling and to analyze the presynaptic mechanisms, we focused on the input layer of the cerebellar cortex, where exceptionally high action potential (AP) frequencies have been reported invivo. With paired recordings between presynaptic cerebellar mossy fiber boutons and postsynaptic granule cells, we demonstrate reliable neurotransmission upto ~1 kHz. Presynaptic APs are ultrafast, with ~100μs half-duration. Both Kv1 and Kv3 potassium channels mediate the fast repolarization, rapidly inactivating sodium channels ensure metabolic efficiency, and little AP broadening occurs during bursts of up to 1.5 kHz. Presynaptic Cav2.1 (P/Q-type) calcium channels open efficiently during ultrafast APs. Furthermore, a subset of synaptic vesicles is tightly coupled to Ca2+ channels, and vesicles are rapidly recruited to the release site. These data reveal mechanisms of presynaptic AP generation and transmitter release underlying neuronal kHz signaling.}, author = {Ritzau Jost, Andreas and Delvendahl, Igor and Rings, Annika and Byczkowicz, Niklas and Harada, Harumi and Shigemoto, Ryuichi and Hirrlinger, Johannes and Eilers, Jens and Hallermann, Stefan}, journal = {Neuron}, number = {1}, pages = {152 -- 163}, publisher = {Elsevier}, title = {{Ultrafast action potentials mediate kilohertz signaling at a central synapse}}, doi = {10.1016/j.neuron.2014.08.036}, volume = {84}, year = {2014}, } @article{2478, abstract = {Despite the pivotal functions of the NMDA receptor (NMDAR) for neural circuit development and synaptic plasticity, the molecular mechanisms underlying the dynamics of NMDAR trafficking are poorly understood. The cell adhesion molecule neuroligin-1 (NL1) modifies NMDAR-dependent synaptic transmission and synaptic plasticity, but it is unclear whether NL1 controls synaptic accumulation or function of the receptors. Here, we provide evidence that NL1 regulates the abundance of NMDARs at postsynaptic sites. This function relies on extracellular, NL1 isoform-specific sequences that facilitate biochemical interactions between NL1 and the NMDAR GluN1 subunit. Our work uncovers NL1 isoform-specific cisinteractions with ionotropic glutamate receptors as a key mechanism for controlling synaptic properties.}, author = {Budreck, Elaine C and Kwon, Oh-Bin and Jung, Jung-Hoon and Baudouin, Stéphane J and Thommen, Albert and Kim, Hye-Sun and Fukazawa, Yugo and Harumi Harada and Tabuchi, Katsuhiko and Ryuichi Shigemoto and Scheiffele, Peter and Kim, Joung-Hun}, journal = {PNAS}, number = {2}, pages = {725 -- 730}, publisher = {National Academy of Sciences}, title = {{Neuroligin-1 controls synaptic abundance of NMDA-type glutamate receptors through extracellular coupling}}, doi = {10.1073/pnas.1214718110}, volume = {110}, year = {2013}, } @article{2690, abstract = {Establishing the spatiotemporal concentration profile of neurotransmitter following synaptic vesicular release is essential for our understanding of inter-neuronal communication. Such profile is a determinant of synaptic strength, short-term plasticity and inter-synaptic crosstalk. Synaptically released glutamate has been suggested to reach a few millimolar in concentration and last for <1 ms. The synaptic cleft is often conceived as a single concentration compartment, whereas a huge gradient likely exists. Modelling studies have attempted to describe this gradient, but two key parameters, the number of glutamate in a vesicle (NGlu) and its diffusion coefficient (DGlu) in the extracellular space, remained unresolved. To determine this profile, the rat calyx of Held synapse at postnatal day 12-16 was studied where diffusion of glutamate occurs two-dimensionally and where quantification of AMPA receptor distribution on individual postsynaptic specialization on medial nucleus of the trapezoid body principal cells is possible using SDS-digested freeze-fracture replica labelling. To assess the performance of these receptors as glutamate sensors, a kinetic model of the receptors was constructed from outside-out patch recordings. From here, we simulated synaptic responses and compared them with the EPSC recordings. Combinations of NGlu and DGlu with an optimum of 7000 and 0.3 μm2 ms-1 reproduced the data, suggesting slow diffusion. Further simulations showed that a single vesicle does not saturate the synaptic receptors, and that glutamate spillover does not affect the conductance amplitude at this synapse. Using the estimated profile, we also evaluated how the number of multiple vesicle releases at individual active zones affects the amplitude of postsynaptic signals.}, author = {Budisantoso, Timotheus and Harumi Harada and Kamasawa, Naomi and Fukazawa, Yugo and Ryuichi Shigemoto and Matsui, Ko}, journal = {Journal of Physiology}, number = {1}, pages = {219 -- 239}, publisher = {Wiley-Blackwell}, title = {{Evaluation of glutamate concentration transient in the synaptic cleft of the rat calyx of Held}}, doi = {10.1113/jphysiol.2012.241398}, volume = {591}, year = {2013}, } @article{2615, abstract = {Taste-mGluR4, cloned from taste tissues, is a truncated variant of brain-expressed mGluR4a (brain-mGluR4), and is known to be a candidate for the receptor involved in the umami taste sense. Although the expression patterns of taste- and brain-mGluR4 mRNAs have been demonstrated, no mention has so far been made of the expression of these two mGluR4 proteins in taste tissues. The present study examined the expression of taste-mGluR4 and brain-mGluR4 proteins in rat taste tissues by using a specific antibody for mGluR4a which shared a C-terminus of both taste- and brain-mGluR4, for immunoblot analysis and immunohistochemistry. Immunoblot analysis showed that both brain-mGluR4 and taste-mGluR4 were expressed in the taste tissues. Taste-mGluR4 was not detected in the cerebellum. The immunoreactive band for brain-mGluR4 protein was much stronger than that for taste-mGluR4 protein. In the cryosections of fungiform, foliate and circumvallate papillae, the antibody against taste-mGluR4 exhibited intense labeling of the taste pores and taste hairs in all the taste buds of gustatory papillae examined; the immunoreaction to the antibody against brain-mGluR4 was more intense at the same sites of the taste buds. The portions of the taste bud cells below the taste pore and surrounding keratinocytes did not show any immunoreactivities. The results of the present study strongly suggest that, in addition to taste-mGluR4, brain-mGluR4 may function even more importantly than the former as a receptor for glutamate, i.e. the umami taste sensation.}, author = {Toyono, Takashi and Seta, Yuji and Sataoka, Shinji and Harada, Harumi and Morotomi, Takahiko and Kawano, Shintaro and Shigemoto, Ryuichi and Toyoshima, Kuniaki}, issn = {0914-9465}, journal = {Archives of Histology and Cytology}, number = {1}, pages = {91 -- 96}, publisher = {Japan Society of Histological Documentation}, title = {{Expression of the metabotropic glutamate receptor, mGluR4a, in the taste hairs of taste buds in rat gustatory papillae}}, doi = {10.1679/aohc.65.91}, volume = {65}, year = {2002}, }