Name: Video: Transmission Electron Microscopic Imaging of Synaptic Vesicle Endocytosis in Mouse Hippocampal Neurons - Concept
Uploaded: 2025-04-28T12:00:13.000+00:00
Duration: 1 min 29 s
Description: 35 Views. Source: Villarreal, S., et. al., Measuring Synaptic Vesicle Endocytosis in Cultured Hippocampal Neurons. J. Vis. Exp. (2017) This video demonstrates the analysis of synaptic vesicle endocytosis in cultured hippocampal neurons through horseradish peroxidase labeling and electron microscopy.

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All procedures involving animal samples have been reviewed and approved by the appropriate animal ethical review committee.Electron Microscopy<ol><li>Prepare a high K+ stimulation solution with HRP (horseradish peroxidase) as 31.5 mM NaCl, 2 mM CaCl2, 90 mM KCl, 25 mM HEPES (pH 7.4), 30 mM glucose, 2 mM MgCl2, 0.01 mM CNQX, 0.05 mM AP5, and 5 mg/mL HRP, then adjust to pH 7.4 with 5 M NaOH. 1. Stimulate the hippocampal neuron culture with 1.5 mL high K+ stimulation solution at room temperature (referred to as K+) by addition of 1.5 mL to each well for 90 s. In the resting condition (referred to as R), apply the same concentration of 5 mg/mL HRP for 90 s, but with normal saline solution. For the recovery sample, apply high K+ stimulation solution as with the K+ sample, then rapidly wash and replace with normal saline and incubate for 10 min.</li><li>Fixation and staining &#160;<ol style='list-style-type:lower-latin;'><li>Prepare 0.1 M Na cacodylate buffer using 21.4 g/L Na cacodylate at pH 7.4. Fix cells with 4% glutaraldehyde in 0.1 M Na cacodylate buffer for at least 1 h at room temperature. Wash three times with 0.1 M Na cacodylate buffer for 7 min each. </li><li>Prepare Diaminobenzidine (DAB) solution, comprised of 0.5 mg/mL of DAB with 0.3% H2O2 in ddH2O, and filter with a 0.22 &#181;m filter. Apply 1.5 mL DAB solution for 30 min at 37 &#176;C. Wash three times with 0.1 M Na cacodylate buffer for 7 min each. &#160;CAUTION: DAB is a toxic and suspected carcinogen. Please use gloves and lab coats. NOTE: Labeling with DAB occurs due to its oxidation by H2O2, as catalyzed by HRP. Small increases in the components result in an increased signal in the sample. Increasing the concentration of HRP speeds up the effect of the catalyst. Sufficiently large concentrations of H2O2 allow for debilitating side reactions with HRP, inhibiting the effect of labeling32. In this work, the concentrations of this labeling system were chosen based on currently available research. </li><li>Incubate the neurons with 1.5 mL of 1% OsO4 in 0.1 M Na cacodylate buffer for 1 h at 4 &#176;C as post fixation. Wash three times with 1.5 mL of 0.1 M Na cacodylate buffer for 7 min each. &#160;CAUTION: Due to the toxicity and reactivity of OsO4, keeping the sample on ice in a chemical hood is preferable in many cases to using a fridge for the incubation. </li><li>Prepare 0.1 M sodium acetate buffer with 13.61 g/L sodium acetate and 11.43 mL/L glacial acetic acid at pH 5.0. Wash three times with 1.5 mL 0.1 M acetate buffer at pH 5.0 for 7 min each and incubate with 1.5 mL 1% uranyl acetate in 0.1 M acetate buffer at pH 5.0 for 1 h at 4 &#176;C. Wash three times with 1.5 mL 0.1 M acetate buffer for 7 min each. &#160;</li></ol></li><li>Epoxy embedding &#160;<ol style='list-style-type:lower-alpha;'><li>Dehydrate the neuron culture with single 1.5 mL washes of 50%, 70%, and 90% ethanol, for 7 min in each and then 3 washes of 1.5 mL 100% ethanol for 7 min each in a fume hood. </li><li>Mix 485 mL/L bisphenol-A-(epichlorhydrin) epoxy resin, 160 mL/L dodecenyl succinic anhydride (DDSA), 340 mL/L Methyl-5-Norbornene-2,3-Dicarboxylic Anhydride (NMA), and 15 mL/L 2,4,6-tris(dimethylaminomethyl)phenol (DMP-30) to create the epoxy resin. Mix thoroughly, then store under vacuum to remove air bubbles. NOTE: It is critical to remove air bubbles in the resin, especially those smaller than visible to the naked eye, because they can cause cavities in the resin during sectioning. </li><li>Infiltrate the sample by replacing the ethanol with 50% epoxy resin in ethanol for 30 min at room temperature on a shaker, then 70% epoxy resin in ethanol for 30 min at room temperature on a shaker. </li><li>Switch the epoxy resin solution with 100% epoxy resin and incubate for 10 min at 50 &#176;C. Perform two exchanges of fresh 100% epoxy resin with incubations for 1 h at 50 &#176;C. Add fresh 100% epoxy resin and allow to harden at 50 &#176;C overnight and then at 60 &#176;C for over 36 h to harden. </li></ol></li><li>Remove each sample from the muti-well plate with a jeweler's handsaw. Select regions of interest, dense concentrations of cells, using an inverted light microscope, and then cut 70 to 80 nm blocks for sectioning by microtome. Mount the cut region in the microtome chuck and load the microtome. Position the chuck in the microtome and mount a diamond knife with the edge parallel to the surface of the block. Collect sections of 70 to 80 nm thickness directly onto individual grids. </li><li>Dissolve uranyl acetate into water for a 1% solution by weight, and separately dissolve lead citrate into water for a 3% solution by weight. Counterstain the sections by submersion with 1% aqueous uranyl acetate for 15 min and then 3% aqueous lead citrate for 5 min to improve the contrast of the samples. </li><li>EM imaging<ol style='list-style-type:lower-alpha;'><li>Examine the sections with a transmission electron microscope and record images with a CCD digital camera at a primary magnification of 10,000-20,000X.</li></ol></li></ol>

<figure class='table' style='width:651pt;'><table class='ck-table-resized'><colgroup><col style='width:15.21%;'><col style='width:17.05%;'><col style='width:22.43%;'><col style='width:45.31%;'></colgroup><tbody><tr><td style='border-top-style:none;height:14.5pt;width:99pt;'>Neurobasal medium</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Thermo Fisher</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>21103-049</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Growth medium for neuron, Warm up to 37&#176;C before use</td></tr><tr><td style='border-top-style:none;height:14.5pt;width:99pt;'>B27</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Thermo Fisher</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>17504-044</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Gradient for neuronal differentiation</td></tr><tr><td style='border-top-style:none;height:14.5pt;width:99pt;'>Glutamax</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Thermo Fisher</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>35050-061</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Gradient for neuronal culture</td></tr><tr><td style='border-top-style:none;height:29.0pt;width:99pt;'>Trypsin XI from bovine pancrease</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Sigma</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>T1005</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Neuronal culture-digest hippocampal tissues</td></tr><tr><td style='border-top-style:none;height:43.5pt;width:99pt;'>Deoxyribonuclease I from bovine pancreas</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Sigma</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>D5025</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Neuronal culture-inhibits viscous cell suspension</td></tr><tr><td style='border-top-style:none;height:43.5pt;width:99pt;'>Poly-l-lysine</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Sigma</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>P4832</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, substrate for neuronal growth, apply on multiwell plate for 1 h at room temperature then wash with sterilized water 3 times</td></tr><tr><td style='border-top-style:none;height:58.0pt;width:99pt;'>Horseradish peroxidase(HRP)</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Sigma</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>P6782</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, labeling of endocytosed synaptic vesicles by catalyzing DAB in presence hydrogen peroxide, final concentration is 5 mg/mL in normal saline, make fresh before use</td></tr><tr><td style='border-top-style:none;height:29.0pt;width:99pt;'>Sodium cacodylate</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Electron Microscopy Sciences</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>12300</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, buffer for fixatives and washing, final concentration is 0.1 N</td></tr><tr><td style='border-top-style:none;height:43.5pt;width:99pt;'>3,3&#8242;-Diaminobenzidine(DAB)</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Sigma</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>D8001</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, labeling of endocytosed synaptic vesicles, substrate for HRP, final concentration is 0.5 mg/mL in DDW and filtered, make fresh before use</td></tr><tr><td style='border-top-style:none;height:43.5pt;width:99pt;'>Hydrogen peroxide solution</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Sigma</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>H1009</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, labeling of endocytosed synaptic vesicles by inducing HRP-DAB reaction, final concentration is 0.3% in DDW, make fresh before use</td></tr><tr><td style='border-top-style:none;height:43.5pt;width:99pt;'>Glutaraldehyde</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Electron Microscopy Sciences</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>16365</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, fixatives, final concentration is 4% in Na-cacodylate buffer, make fresh before use, shake well before to use</td></tr><tr><td style='border-top-style:none;height:29.0pt;width:99pt;'>TEM</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>JEOL</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>200CX</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, imaging of endocytosed vesicles and ultrastructural changes</td></tr><tr><td style='border-top-style:none;height:14.5pt;width:99pt;'>CCD digital camera</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>AMT</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>XR-100</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, capturing images</td></tr><tr><td style='border-top-style:none;height:14.5pt;width:99pt;'>Lead citrate</td><td style='border-left-style:none;border-top-style:none;width:111pt;'>Leica microsystems</td><td style='border-left-style:none;border-top-style:none;width:146pt;'>16707235</td><td style='border-left-style:none;border-top-style:none;width:295pt;'>Electron microscopy, grid staining</td></tr></tbody></table></figure>

transmission electron microscopic imaging of synaptic vesicle endocytosis in mouse hippocampal neurons 

<a href='https://app.jove.com/v/55862/measuring-synaptic-vesicle-endocytosis-in-cultured-hippocampal-neurons'>Source: Villarreal, S., et. al., Measuring Synaptic Vesicle Endocytosis in Cultured Hippocampal Neurons. J. Vis. Exp. (2017)</a>This video demonstrates the analysis of synaptic vesicle endocytosis in cultured hippocampal neurons through horseradish peroxidase labeling and electron microscopy.

Transmission Electron Microscopic Imaging of Synaptic Vesicle Endocytosis in Mouse Hippocampal Neurons 

Source: Villarreal, S., et. al., Measuring Synaptic Vesicle Endocytosis in Cultured Hippocampal Neurons. J. Vis. Exp. (2017)This video demonstrates the ...

Begin by treating mouse hippocampal neurons with a high-potassium buffer containing horseradish peroxidase or HRP.High potassium depolarizes presynaptic neurons, triggering synaptic vesicle exocytosis. The neurons then retrieve the synaptic vesicle membranes through endocytosis, by incorporating HRP into the newly formed vesicles. Fix the neurons with glutaraldehyde and wash to remove excess glutaraldehyde.Add hydrogen peroxide and a chromogenic substrate, which is oxidized by HRP to form electron-dense precipitates. Wash to remove any unreacted substrate.Treat with osmium tetroxide to enhance membrane contrast, then wash off the excess reagent. Next, add uranyl acetate to enhance organelle contrast.Dehydrate the neurons using increasing ethanol concentrations and embed them in resin.Microscopically identify cell-dense regions and excise them. Then, prepare ultra-thin sections.Transfer a section onto a copper grid and counterstain them with contrast agents.Using transmission electron microscopy, vesicles containing HRP appear as electron-dense structures.

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Synaptic & Cellular Imaging

35 Views. Source: Villarreal, S., et. al., Measuring Synaptic Vesicle Endocytosis in Cultured Hippocampal Neurons. J. Vis. Exp. (2017) This video demonstrates the analysis of synaptic vesicle endocytosis in cultured hippocampal neurons through horseradish peroxidase labeling and electron microscopy. 

Video: Transmission Electron Microscopic Imaging of Synaptic Vesicle Endocytosis in Mouse Hippocampal Neurons  - Concept

Method to Visualize and Analyze Membrane Interacting Proteins by Transmission Electron Microscopy

Monotopic proteins exert their function when attached to a membrane surface, and such interactions depend on the specific lipid composition and on the availability of enough area to perform the function. Nanodiscs are used to provide a membrane surface of controlled size and lipid content. In the absence of bound extrinsic proteins, sodium phosphotungstate-stained nanodiscs appear as stacks of coins when viewed from the side by transmission electron microscopy (TEM). This protocol is therefore designed to intentionally promote stacking; consequently, the prevention of stacking can be interpreted as the binding of the membrane-binding protein to the nanodisc. In a further step, the TEM images of the protein-nanodisc complexes can be processed with standard single-particle methods to yield low-resolution structures as a basis for higher resolution cryoEM work. Furthermore, the nanodiscs provide samples suitable for either TEM or non-denaturing gel electrophoresis. To illustrate the method, Ca2+-induced binding of 5-lipoxygenase on nanodiscs is presented.

Many proteins perform their function when attached to membrane surfaces. The binding of extrinsic proteins on nanodisc membranes can be indirectly imaged by transmission electron microscopy. We show that the characteristic stacking (rouleau) of nanodiscs induced by the negative stain sodium phosphotungstate is prevented by the binding of extrinsic protein.

Monotopic proteins exert their function when attached to a membrane surface, and such interactions depend on the specific lipid composition and on the ...

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Biochemistry

A Simplified Method for Ultra-Low Density, Long-Term Primary Hippocampal Neuron Culture

Culturing primary hippocampal neurons in vitro facilitates mechanistic interrogation of many aspects of neuronal development. Dissociated embryonic hippocampal neurons can often grow successfully on glass coverslips at high density under serum-free conditions, but low density cultures typically require a supply of trophic factors by co-culturing them with a glia feeder layer, preparation of which can be time-consuming and laborious. In addition, the presence of glia may confound interpretation of results and preclude studies on neuron-specific mechanisms. Here, a simplified method is presented for ultra-low density (~2,000 neurons/cm2), long-term (&#62;3 months) primary hippocampal neuron culture that is under serum free conditions and without glia cell support. Low density neurons are grown on poly-D-lysine coated coverslips, and flipped on high density neurons grown in a 24-well plate. Instead of using paraffin dots to create a space between the two neuronal layers, the experimenters can simply etch the plastic bottom of the well, on which the high density neurons reside, to create a microspace conducive to low density neuron growth. The co-culture can be easily maintained for &#62;3 months without significant loss of low density neurons, thus facilitating the morphological and physiological study of these neurons. To illustrate this successful culture condition, data are provided to show profuse synapse formation in low density cells after prolonged culture. This co-culture system also facilitates the survival of sparse individual neurons grown in islands of poly-D-lysine substrates and thus the formation of autaptic connections.

Low density cultures of primary hippocampal neurons usually require glia feeder layer to supply neurotrophic factors and sustain longevity. We describe here a simplified method to culture ultra-low density neurons on glass coverslips in the presence of a high density neuronal feeder layer, which facilitates investigation of specific neuronal-autonomous mechanisms.

Culturing primary hippocampal neurons in vitro facilitates mechanistic interrogation of many aspects of neuronal development. Dissociated embryonic ...

Sample Preparation and Imaging of Exosomes by Transmission Electron Microscopy

Exosomes are nano-sized extracellular vesicles secreted by body fluids and are known to represent the characteristics of cells that secrete them. The contents and morphology of the secreted vesicles reflect cell behavior or physiological status, for example cell growth, migration, cleavage, and death. The exosomes&#39; role may depend highly on size, and the size of exosomes varies from 30 to 300 nm. The most widely used method for exosome imaging is negative staining, while other results are based on Cryo-Transmission Electron Microscopy, Scanning Electron Microscopy, and Atomic Force Microscopy. The typical exosome&#39;s morphology assessed through negative staining is a cup-shape, but further details are not yet clear. An exosome well-characterized through structural study is necessary particular in medical and pharmaceutical fields. Therefore, function-dependent morphology should be verified by electron microscopy techniques such as labeling a specific protein in the detailed structure of exosome. To observe detailed structure, ultrathin sectioned images and negative stained images of exosomes were compared. In this protocol, we suggest transmission electron microscopy for the imaging of exosomes including negative staining, whole mount immuno-staining, block preparation, thin section, and immuno-gold labelling.

This protocol describes the various techniques necessary for transmission electron microscopy including negative staining, ultrathin sectioning for detailed structure, and immuno-gold labelling to determine the positions of specific proteins in exosomes.

Exosomes are nano-sized extracellular vesicles secreted by body fluids and are known to represent the characteristics of cells that secrete them. The ...

Transmission Electron Microscopic Imaging of Synaptic Vesicle Endocytosis in Mouse Hippocampal Neurons

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Transmission Electron Microscopic Imaging of Synaptic Vesicle Endocytosis in Mouse Hippocampal Neurons

Method to Visualize and Analyze Membrane Interacting Proteins by Transmission Electron Microscopy

A Simplified Method for Ultra-Low Density, Long-Term Primary Hippocampal Neuron Culture

Sample Preparation and Imaging of Exosomes by Transmission Electron Microscopy