eoe sub articles

EoE Sub Articles

<figure class='table'><table class='ck-table-resized' style='border-collapse:collapse;font-family:Calibri;font-size:11pt;table-layout:fixed;' cellspacing='0' cellpadding='0' dir='ltr' border='1' data-sheets-root='1' data-sheets-baot='1'><colgroup><col style='width:25%;' width='188'><col style='width:25%;' width='193'><col style='width:25%;' width='145'><col style='width:25%;' width='94'></colgroup><tbody><tr style='height:20px;'><td style='background-color:#ffffff;border:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Glass Microscope Slides</td><td style='background-color:#ffffff;border-bottom:1px solid #000000;border-right:1px solid #000000;border-top:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Fischer Scientific</td><td style='background-color:#ffffff;border-bottom:1px solid #000000;border-right:1px solid #000000;border-top:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>12-549-6</td><td style='border-bottom:1px solid #000000;border-right:1px solid #000000;border-top:1px solid #000000;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='background-color:#ffffff;border-bottom:1px solid #000000;border-left:1px solid #000000;border-right:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Licor Odyssey scanner</td><td style='background-color:#ffffff;border-bottom:1px solid #000000;border-right:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Licor Biotechnology Inc.</td><td style='border-bottom:1px solid #000000;border-right:1px solid #000000;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='border-bottom:1px solid #000000;border-right:1px solid #000000;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='background-color:#ffffff;border-bottom:1px solid #000000;border-left:1px solid #000000;border-right:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Image Studio</td><td style='background-color:#ffffff;border-bottom:1px solid #000000;border-right:1px solid #000000;color:#1a202c;font-family:Roboto;font-size:10pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Licor Biotechnology Inc.</td><td style='border-bottom:1px solid #000000;border-right:1px solid #000000;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='border-bottom:1px solid #000000;border-right:1px solid #000000;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr></tbody></table></figure>

measuring protein expression in the rodent brain using near-infrared fluorescence and high-resolution scanning 

Source:&#160;<a style='text-decoration:none;' href='https://app.jove.com/v/59685/using-near-infrared-fluorescence-and-high-resolution-scanning-to-measure-protein-expression-in-the-rodent-brain'><span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>Kimmelmann-Shultz, B.,&#160;et. al.<span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>&#160;<span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>Using Near-infrared Fluorescence and High-resolution Scanning to Measure Protein Expression in the Rodent Brain.&#160;J. Vis. Exp.<span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>&#160;(2019)</a> &#160;This video demonstrates a near-infrared fluorescence and high-resolution scanning method for measuring protein expression in the rodent brain.

Measuring Protein Expression in the Rodent Brain Using Near-Infrared Fluorescence and High-Resolution Scanning 

Source:&#160;Kimmelmann-Shultz, B.,&#160;et. al.&#160;Using Near-infrared Fluorescence and High-resolution Scanning to Measure Protein Expression in the ...

Take a glass slide containing rat brain tissue sections immunostained for AMPA and NMDA receptors in amygdala neurons.AMPA receptors mediate glutamate-induced sodium influx and fast excitatory synaptic transmission.&#160;In contrast, NMDA receptors mediate glutamate and co-agonist-induced sodium and calcium influx, facilitating slow excitatory synaptic transmission.The receptors are stained with primary antibodies and detected using near-infrared fluorophore-tagged secondary antibodies.Place the slide tissue-side down on the near-infrared scanning interface.Adjust the imaging parameters and begin imaging.Upon laser illumination, the fluorophores on the AMPA and NMDA receptors emit fluorescence.Near-infrared imaging minimizes autofluorescence, enhancing signal clarity.High-resolution scanning further ensures clear differentiation of fluorescence signals, enabling precise visualization of nearby AMPA and NMDA receptors in the amygdala.Using imaging software, calculate the AMPA/NMDA fluorescence intensity ratio in a specific region of interest as a marker of learning and memory.

measuring-protein-expression-rodent-brain-using-near-infrared

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuroimaging

Synaptic & Cellular Imaging

23 Views. Source: Kimmelmann-Shultz, B., et. al. Using Near-infrared Fluorescence and High-resolution Scanning to Measure Protein Expression in the Rodent Brain. J. Vis. Exp. (2019)  This video demonstrates a near-infrared fluorescence and high-resolution scanning method for measuring protein expression in the rodent brain. 

Video: Measuring Protein Expression in the Rodent Brain Using Near-Infrared Fluorescence and High-Resolution Scanning  - Concept

Post-embedding Immunogold Labeling of Synaptic Proteins in Hippocampal Slice Cultures

Immunoelectron microscopy is a powerful tool to study biological molecules at the subcellular level. Antibodies coupled to electron-dense markers such as colloidal gold can reveal the localization and distribution of specific antigens in various tissues1. The two most widely used techniques are pre-embedding and post-embedding techniques. In pre-embedding immunogold-electron microscopy (EM) techniques, the tissue must be permeabilized to allow antibody penetration before it is embedded. These techniques are ideal for preserving structures but poor penetration of the antibody (often only the first few micrometers) is a considerable drawback2. The post-embedding labeling methods can avoid this problem because labeling takes place on sections of fixed tissues where antigens are more easily accessible. Over the years, a number of modifications have improved the post-embedding methods to enhance immunoreactivity and to preserve ultrastructure3-5.
Tissue fixation is a crucial part of EM studies. Fixatives chemically crosslink the macromolecules to lock the tissue structures in place. The choice of fixative affects not only structural preservation but also antigenicity and contrast. Osmium tetroxide (OsO4), formaldehyde, and glutaraldehyde have been the standard fixatives for decades, including for central nervous system (CNS) tissues that are especially prone to structural damage during chemical and physical processing. Unfortunately, OsO4 is highly reactive and has been shown to mask antigens6, resulting in poor and insufficient labeling. Alternative approaches to avoid chemical fixation include freezing the tissues. But these techniques are difficult to perform and require expensive instrumentation. To address some of these problems and to improve CNS tissue labeling, Phend et al. replaced OsO4 with uranyl acetate (UA) and tannic acid (TA), and successfully introduced additional modifications to improve the sensitivity of antigen detection and structural preservation in brain and spinal cord tissues7. We have adopted this osmium-free post-embedding method to rat brain tissue and optimized the immunogold labeling technique to detect and study synaptic proteins.
We present here a method to determine the ultrastructural localization of synaptic proteins in rat hippocampal CA1 pyramidal neurons. We use organotypic hippocampal cultured slices. These slices maintain the trisynaptic circuitry of the hippocampus, and thus are especially useful for studying synaptic plasticity, a mechanism widely thought to underlie learning and memory. Organotypic hippocampal slices from postnatal day 5 and 6 mouse/rat pups can be prepared as described previously8, and are especially useful to acutely knockdown or overexpress exogenous proteins. We have previously used this protocol to characterize neurogranin (Ng), a neuron-specific protein with a critical role in regulating synaptic function8,9 . We have also used it to characterize the ultrastructural localization of calmodulin (CaM) and Ca2+/CaM-dependent protein kinase II (CaMKII)10. As illustrated in the results, this protocol allows good ultrastructural preservation of dendritic spines and efficient labeling of Ng to help characterize its distribution in the spine8. Furthermore, the procedure described here can have wide applicability in studying many other proteins involved in neuronal functions.

The localization and distribution of proteins provide important information for understanding their cellular functions. The superior spatial resolution of electron microscopy (EM) can be used to determine the subcellular localization of a given antigen following immunohistochemistry. For tissues of the central nervous system (CNS), preserving structural integrity while maintaining antigenicity has been especially difficult in EM studies. Here, we adopt a procedure that has been used to preserve structures and antigens in the CNS to study and characterize synaptic proteins in rat hippocampal CA1 pyramidal neurons.

Immunoelectron microscopy is a powerful tool to study biological molecules at the subcellular level. Antibodies coupled to electron-dense markers such as ...

JoVE Journal

Immunohistochemical Visualization of Hippocampal Neuron Activity After Spatial Learning in a Mouse Model of Neurodevelopmental Disorders

Induction of phosphorylated extracellular-regulated kinase (pERK) is a reliable molecular readout of learning-dependent neuronal activation. Here, we describe a pERK immunohistochemistry protocol to study the profile of hippocampal neuron activation following exposure to a spatial learning task in a mouse model characterized by cognitive deficits of neurodevelopmental origin. Specifically, we used pERK immunostaining to study neuronal activation following Morris water maze (MWM, a classical hippocampal-dependent learning task) in Engrailed-2 knockout (En2-/-) mice, a model of autism spectrum disorders (ASD). As compared to wild-type (WT) controls, En2-/- mice showed significant spatial learning deficits in the MWM. After MWM, significant differences in the number of pERK-positive neurons were detected in specific hippocampal subfields of En2-/- mice, as compared to WT animals. Thus, our protocol can robustly detect differences in pERK-positive neurons associated to hippocampal-dependent learning impairment in a mouse model of ASD. More generally, our protocol can be applied to investigate the profile of hippocampal neuron activation in both genetic or pharmacological mouse models characterized by cognitive deficits.

We describe an immunohistochemistry protocol to study the profile of hippocampal neuron activation following exposure to a spatial learning task in a mouse model characterized by cognitive deficits of neurodevelopmental origin. This protocol can be applied to both genetic or pharmacological mouse models characterized by cognitive deficits.

Induction of phosphorylated extracellular-regulated kinase (pERK) is a reliable molecular readout of learning-dependent neuronal activation. Here, we ...

Preparation of Acute Slices from Dorsal Hippocampus for Whole-Cell Recording and Neuronal Reconstruction in the Dentate Gyrus of Adult Mice

Although the general architecture of the hippocampus is similar along its longitudinal axis, recent studies have revealed prominent differences in molecular, anatomical and functional criteria suggesting a division into different sub-circuits along its rostro-caudal extent. Owing to differential connectivity and function the most fundamental distinction is made between the dorsal and the ventral hippocampus, which are preferentially involved in spatial and emotional processing, respectively. Accordingly, in vivo work regarding spatial memory formation has focused on the dorsal hippocampus.
In contrast, electro-physiological in vitro recordings have been preferentially performed on intermediate-ventral hippocampus, largely motivated by factors like slice viability and circuit integrity. To allow for direct correlation of in vivo data on spatial processing with in vitro data we have adapted previous sectioning methods to obtain highly viable transverse brain slices from the dorsal-intermediate hippocampus for long-term recordings of principal cells and interneurons in the dentate gyrus. As spatial behavior is routinely analyzed in adult mice, we have combined this transversal slicing procedure with the use of protective solutions to enhance viability of brain tissue from mature animals. We use this approach for mice of about 3 months of age. The method offers a good alternative to the coronal preparation which is frequently used for in vitro studies on dorsal hippocampus. We compare these two preparations in terms of quality of recordings and preservation of morphological features of recorded neurons.

We present a protocol to prepare acute-slices from the dorsal-intermediate hippocampus of mice. We compare this transversal preparation with coronal slicing in terms of quality of recordings and preservation of morphological features of recorded neurons.

Measuring Protein Expression in the Rodent Brain Using Near-Infrared Fluorescence and High-Resolution Scanning

Transcript

Measuring Protein Expression in the Rodent Brain Using Near-Infrared Fluorescence and High-Resolution Scanning

Post-embedding Immunogold Labeling of Synaptic Proteins in Hippocampal Slice Cultures

Immunohistochemical Visualization of Hippocampal Neuron Activity After Spatial Learning in a Mouse Model of Neurodevelopmental Disorders

Preparation of Acute Slices from Dorsal Hippocampus for Whole-Cell Recording and Neuronal Reconstruction in the Dentate Gyrus of Adult Mice