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<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='295'><col style='width:25%;' width='205'><col style='width:25%;' width='177'><col style='width:25%;' width='388'></colgroup><tbody><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Diethyl pyrocarbonate (DEPC)</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Sigma Aldrich</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>D5758</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Alexa Fluor 594 Hydrazide</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Invitrogen</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>A10442</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Petri dish (35mm diameter)</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Thermo Fisher Scientific</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>153066</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Ophthalmologic scissors</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Fine Science Tools</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>15000-00</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>#5 Forceps</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Fine Science Tools</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>11252-30</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Glass Micropipette</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Sutter</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>BF120-69-10</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Micropipette Puller</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Sutter</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>P-1000 horizontal pipette puller</td></tr><tr style='height:20px;'><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>1mL syringe</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>Fisher Scientific</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>14-823-2F</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr></tbody></table></figure>

identification of mouse retinal ganglion cell subtypes through fluorescent tracing

Source:&#160;<a style='text-decoration:none;' href='https://appjove.unicartagenaproxy.elogim.com/v/55229/single-cell-rna-seq-of-defined-subsets-of-retinal-ganglion-cells'><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;'>Laboissonniere,&#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;'>. Single-cell RNA-Seq of Defined Subsets of Retinal Ganglion Cells.&#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;'> (2017)</a>. &#160;This video demonstrates a fluorescent tracing technique to identify retinal ganglion cell (RGC) subtypes in a transgenic mouse retina. The process involves securing the isolated retina in a recording chamber, maintaining cell viability with oxygenated perfusion, and targeting fluorescently labeled RGCs using a pipette with a tracer. By analyzing dendritic morphology and stratification, the method enables classification of distinct RGC subtypes.

<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2146/1301;' src='https://cloudfront.jove.com/files/ftp_upload/23519/23519_Figure_1_editor_23519.jpg' alt='23519_Figure_1.jpg' /></figure>Figure 1: Identification of...

Identification of Mouse Retinal Ganglion Cell Subtypes Through Fluorescent Tracing

Source:&#160;Laboissonniere,&#160;et. al. Single-cell RNA-Seq of Defined Subsets of Retinal Ganglion Cells.&#160;J. Vis. Exp. (2017).&#160;This video ...

Place a retinal tissue isolated from a transgenic mouse with fluorescently labeled retinal ganglion cells, or RGCs, in a recording chamber.Visual information is relayed to the RGCs, whose axons transmit it to the brain via the optic nerve.RGC subtypes are distinguished by the branching patterns of their dendrites, which stratify into sublayers within the inner retinal layer.Flatten the retinal tissue and secure it using a tissue anchor.&#160;Transfer the chamber onto a microscope stage and perfuse an oxygenated solution to maintain RGC viability.Using infrared illumination, identify the fluorescent RGCs.Position a pipette containing a fluorescent tracer onto an RGC.&#160;Apply positive pressure to prevent clogging.Switch to negative pressure, drawing the membrane into the pipette to form a seal.&#160;Apply suction to rupture the membrane, establishing a whole-cell configuration that facilitates tracer diffusion into the dendrites.Observe the dendritic morphology and stratification to identify the RGC subtypes.

identification-mouse-retinal-ganglion-cell-subtypes-through

Universidad de Cartagena UDEC

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuroimaging

Synaptic & Cellular Imaging

11 Views. Source: Laboissonniere, et. al. Single-cell RNA-Seq of Defined Subsets of Retinal Ganglion Cells. J. Vis. Exp. (2017).  This video demonstrates a fluorescent tracing technique to identify retinal ganglion cell (RGC) subtypes in a transgenic mouse retina. The process involves securing the isolated retina in a recording chamber, maintaining cell viability with oxygenated perfusion, and targeting fluorescently labeled RGCs using a pipette with a tracer. By analyzing dendritic mo...

Video: Identification of Mouse Retinal Ganglion Cell Subtypes Through Fluorescent Tracing - Concept

Isolation of Primary Murine Retinal Ganglion Cells (RGCs) by Flow Cytometry

Neurodegenerative diseases often have a devastating impact on those affected. Retinal ganglion cell (RGC) loss is implicated in an array of diseases, including diabetic retinopathy and glaucoma, in addition to normal aging. Despite their importance, RGCs have been extremely difficult to study until now due in part to the fact that they comprise only a small percentage of the wide variety of cells in the retina. In addition, current isolation methods use intracellular markers to identify RGCs, which produce non-viable cells. These techniques also involve lengthy isolation protocols, so there is a lack of practical, standardized, and dependable methods to obtain and isolate RGCs. This work describes an efficient, comprehensive, and reliable method to isolate primary RGCs from mice retinae using a protocol based on both positive and negative selection criteria. The presented methods allow for the future study of RGCs, with the goal of better understanding the major decline in visual acuity that results from the loss of functional RGCs in neurodegenerative diseases.

Isolation of Primary Murine Retinal Ganglion Cells RGCs by Flow Cytometry

Millions of people suffer from retinal degenerative diseases that result in irreversible blindness. A common element of many of these diseases is the loss of retinal ganglion cells (RGCs). This detailed protocol describes the isolation of primary murine RGCs by positive and negative selection with flow cytometry.

Neurodegenerative diseases often have a devastating impact on those affected. Retinal ganglion cell (RGC) loss is implicated in an array of diseases, ...

JoVE Journal

Bioengineering

Optical Coherence Tomography: Imaging Mouse Retinal Ganglion Cells In Vivo

Structural changes in the retina are common manifestations of ophthalmic diseases. Optical coherence tomography (OCT) enables their identification in vivo&#8212;rapidly, repetitively, and at a high resolution. This protocol describes OCT imaging in the mouse retina as a powerful tool to study optic neuropathies (OPN). The OCT system is an interferometry-based, non-invasive alternative to common post mortem histological assays. It provides a fast and accurate assessment of retinal thickness, allowing the possibility to track changes, such as retinal thinning or thickening. We present the imaging process and analysis with the example of the Opa1delTTAG mouse line. Three types of scans are proposed, with two quantification methods: standard and homemade calipers. The latter is best for use on the peripapillary retina during radial scans; being more precise, is preferable for analyzing thinner structures. All approaches described here are designed for retinal ganglion cells (RGC) but are easily adaptable to other cell populations. In conclusion, OCT is efficient in mouse model phenotyping and has the potential to be used for the reliable evaluation of therapeutic interventions.

Optical Coherence Tomography: Imaging Mouse Retinal Ganglion Cells In Vivo

This manuscript describes a protocol for the in vivo imaging of the mouse retina with high-resolution spectral domain optical coherence tomography (SD-OCT). It focuses on retinal ganglion cells (RGC) in the peripapillary region, with several scanning and quantifying approaches described.

Structural changes in the retina are common manifestations of ophthalmic diseases. Optical coherence tomography (OCT) enables their identification in ...

Studying Bipolar and Horizontal Neuronal Cells in the Murine Split Retina

Split Retina as an Improved Flatmount Preparation for Studying Inner Nuclear Layer Neurons in Vertebrate Retina

Bipolar cells and horizontal cells of the vertebrate retina are the first neurons to process visual information after photons are detected by photoreceptors. They perform fundamental operations such as light adaptation, contrast sensitivity, and spatial and color opponency. A complete understanding of the precise circuitry and biochemical mechanisms that govern their behavior will advance visual neuroscience research and ophthalmological medicine. However, current preparations for examining bipolar and horizontal cells (retinal whole mounts and vertical slices) are limited in their capacity to capture the anatomy and physiology of these cells. In this work, we present a method for removing photoreceptor cell bodies from live, flatmount mouse retinas, providing enhanced access to bipolar and horizontal cells for efficient patch clamping and rapid immunolabeling. Split retinas are prepared by sandwiching an isolated mouse retina between two pieces of nitrocellulose, then gently peeling them apart. The separation splits the retina just above the outer plexiform layer to yield two pieces of nitrocellulose, one containing the photoreceptor cell bodies and another containing the remaining inner retina. Unlike vertical retina slices, the split retina preparation does not sever the dendritic processes of inner retinal neurons, allowing for recordings from bipolar and horizontal cells that integrate the contributions of gap junction-coupled networks and wide-field amacrine cells. This work demonstrates the versatility of this preparation for the study of horizontal and bipolar cells in electrophysiology, immunohistochemistry, and in situ hybridization experiments.

Author Spotlight: Using the Split Retina Technique for Enhanced Access and Accelerated Experiments 

This work presents an alternative flatmount retina preparation in which the removal of photoreceptor cell bodies enables faster antibody diffusion and improved patch pipette access to inner retinal neurons for immunohistochemistry, in situ hybridization, and electrophysiology experiments.

Identification of Mouse Retinal Ganglion Cell Subtypes Through Fluorescent Tracing

Transcript

Identification of Mouse Retinal Ganglion Cell Subtypes Through Fluorescent Tracing

Isolation of Primary Murine Retinal Ganglion Cells (RGCs) by Flow Cytometry

Optical Coherence Tomography: Imaging Mouse Retinal Ganglion Cells In Vivo

Split Retina as an Improved Flatmount Preparation for Studying Inner Nuclear Layer Neurons in Vertebrate Retina