Name: Video: Imaging GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy - Concept
Uploaded: 2025-04-28T12:04:02.000+00:00
Duration: 1 min 30 s
Description: 62 Views. Source: Changou, C. A., et. al. Live Images of GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy. J. Vis. Exp. (2017). This video showcases the imaging of insulin-induced GLUT4 translocation in hypothalamic neurons, employing deconvolution microscopy to capture and analyze GFP-GLUT4 trafficking dynamics with high resolution.

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1.Live Image Recording<ol style='list-style-type:decimal;'><li>Preparing Cells for Live Imaging</li></ol>1.&#160;Culture WT and CCR5-/- hypothalamic neuron cells expressing green fluorescence protein labeled glucose transporter 4 (GFP-GLUT4) on the #1.5 (or 0.17mm thickness) glass coverslip which has been pre-coated with poly-D-Lysine in the 6-well plate.2.&#160; Carefully remove the coverslips with neurons using forceps and place it on the glass slides with caution.3.&#160; Remove excess medium/liquid with delicate task wipes. Fold the wipes twice, and carefully place them on top of the coverslip. Gently press down the wipes without moving the coverslip. CAUTION: Do not press the coverslip against the glass slide forcefully. The purpose of this step is to ensure that the coverslip does not move/drift during image acquisition caused by buoyant force.4.&#160; Place coverslips and slides on the deconvolution microscope stage, with the coverslip facing down, and secured properly. This step is to ensure that the slide position remains constant so users can track the same set of target cells later.5.&#160; Observe WT and CCR5-/- hypothalamic neuron cells with a 60x/1.42 NA oil immersion objective lens.6.&#160; Treat the selected cell samples with CCL5 (10 ng/mL) or insulin (10 U/mL) for one min. Add 1.5 &#181;L of diluted insulin on the edge of coverslip.7.&#160; Visualize and record the selected cell samples immediately. Program the video recording software to record for 30 min.2.&#160; Deconvolution microscopy and analysis NOTE: This part of the protocol requires the use of a deconvolution microscope and specialized software for analysis.1.&#160;&#160;Turn on the power of the imaging system, allow microscope stage to initialize properly, and then turn on the LED light source.2.&#160; Add immersion oil (refractive index 1.520 for live samples at 37 &#176;C) on a 60x 1.42 NA objective lens. Place the sample slide on the microscope with the coverslip facing toward the objective lens and secure the slide properly.3.&#160; Use bright-field or fluorescence illumination to identify target cells. Adjust the focus until target cells can be clearly observed. Do not move the objective lens outside of the coverslip area to avoid unnecessary scratch marks.4.&#160; Identify green fluorescence protein conjugated Glucose Transporter 4 (GFP-GLUT4) by the GFP signal. Identify desired target cells for image acquisition. Selected target cell position can be memorized for future reference (see&#160;Figure 1).5.&#160; Set up proper experimental parameters (including pixel number, excitation wavelength, transmission percentage, exposure time, stack thickness, time interval, and total imaging time) on each target cell. For this experiment, the image pixel number was set at 512 x 512 (it can be set at 1,024 x 1,024 for higher resolution) for GFP signals. The exposure time was set between 0.025 to 0.05 s for every 5 min. Minor lateral x, y, and z adjustments can be controlled by the recommended software (see&#160;Materials Table).6.&#160; Set the exposure parameter to approximately 2,000 to 3,000 counts to achieve maximum pixel intensity. To minimize fluorescence photobleaching, reduce the percentage of excitation light transmission as much as possible while keeping exposure time less than 1 s. Repeat these steps for each additional fluorescence channel(s) and each individual area of interest.7.&#160; Set the upper and lower limit of the Z-stack on each target cell. This can be achieved by moving the microscope stage until the top and bottom of the target cell are both slightly out of focus. The users can adjust the resolution of the Z-axis by setting the number of images between the upper and lower limit (which can be done by setting the distance between each image).8.&#160; Stacks of images were deconvolved and later analyzed with the help of the respective software &#8211; Velocity from PerkinElmer in this case.

<figure class='table'><table class='ck-table-resized'><colgroup><col style='width:25%;'><col style='width:25%;'><col style='width:25%;'><col style='width:25%;'></colgroup><tbody><tr><td style='padding:0px 3px;vertical-align:bottom;'>DeltaVision deconvolution microscope</td><td style='padding:0px 3px;vertical-align:bottom;'>Applied Precision Inc./(GE Healthcare Life Science)</td><td style='padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='border-right:1px solid transparent;padding:0px;vertical-align:bottom;'>equipped with 60x/1.42 NA oil immersion objective lens; used for taking live cell images</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>SoftWorX application software</td><td style='padding:0px 3px;vertical-align:bottom;'>Applied Precision Inc.</td><td style='padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>used to control microscope and camera</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>VoloCITY software</td><td style='padding:0px 3px;vertical-align:bottom;'>PerkinElmer</td><td style='padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>used to analyze the images</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>Insulin</td><td style='padding:0px 3px;vertical-align:bottom;'>Actrapid, Denmark</td><td style='padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>Kimwipes</td><td style='padding:0px 3px;vertical-align:bottom;'>Kimberly-Clark</td><td style='padding:0px 3px;vertical-align:bottom;'>#FL42572A</td><td style='padding:0px 3px;vertical-align:bottom;'>0.17mm thickness</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>12 mm Microscope coverglass</td><td style='padding:0px 3px;vertical-align:bottom;'>Deckglaser</td><td style='padding:0px 3px;vertical-align:bottom;'>#41001112</td><td style='padding:0px 3px;vertical-align:bottom;'>used for immmunstaining study</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>standard straight-tipped forceps</td><td style='padding:0px 3px;vertical-align:bottom;'>Ideal-tek</td><td style='padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>Surgical tool</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>CCL5/RANTES&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>R&amp;D Systems&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>478-MR-025&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>10ng/ml</td></tr><tr><td style='padding:0px 3px;vertical-align:bottom;'>5 ml pipette&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>Corning costar&#160;</td><td style='padding:0px 3px;vertical-align:bottom;'>4487</td><td style='padding:0px 3px;vertical-align:bottom;'>dissociate brain tissue</td></tr></tbody></table></figure>

imaging glut4 protein trafficking in mouse primary hypothalamic neurons using deconvolution microscopy

<a href='https://app-jove-com.bdigitaluss.remotexs.co/v/56409/live-images-glut4-protein-trafficking-mouse-primary-hypothalamic'>Source: Changou, C. A., et. al. Live Images of GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy. J. Vis. Exp. (2017).</a>This video showcases the imaging of insulin-induced GLUT4 translocation in hypothalamic neurons, employing deconvolution microscopy to capture and analyze GFP-GLUT4 trafficking dynamics with high resolution.

<img src='https://cloudfront-jove-com.bdigitaluss.remotexs.co/files/ftp_upload/23415/23415_Figure1_editor_23415.jpg' alt='23415_Figure1.jpg' />Figure 1: The snapshots of GFP-GLUT4 in hypothalamic neurons. (A, C) GFP-GLUT4 protein expressed in Wildtype (WT) hypothalamic neurons and (B) CCR5-/- hypothalamic neurons. Neurons were stimulated with insulin (A, B) or CCL5 (C). The arrows point to the GFP-GLUT4 punctate in the neuritis before (-) and after (+) insu...

Imaging GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy

Source: Changou, C. A., et. al. Live Images of GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy. J. Vis. ...

Begin with wild-type and CCR5-knockout mouse primary hypothalamic neurons cultured on poly-D-lysine-coated coverslips in a multi-well plate.&#160;These neurons express green fluorescent protein-tagged glucose transporter-4 (GFP-GLUT4) in the cytoplasm.Transfer the coverslips onto glass slides and gently wipe off excess medium to ensure stability during image acquisition.Place a slide on the deconvolution microscope stage with the coverslip facing downward.Visualize the neurons under bright-field illumination, then treat them with the chemokine CCL5 and insulin sequentially.Switch to fluorescence illumination to identify GFP-GLUT4-expressing target neurons and adjust the imaging parameters to capture live fluorescent images.In wild-type neurons, insulin and CCL5 bind to the insulin receptor and CCR5, respectively, activating downstream signaling pathways that drive GFP-GLUT4 membrane translocation.In CCR5-knockout neurons, CCL5 fails to bind, resulting in reduced GFP-GLUT4 translocation.Capture the images and apply a deconvolution algorithm to reduce out-of-focus light, enhancing image clarity and resolution.

imaging-glut4-protein-trafficking-mouse-primary-hypothalamic-neurons

Universidad San Sebastian

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuroimaging

Live Imaging & In Vivo Tracking

62 Views. Source: Changou, C. A., et. al. Live Images of GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy. J. Vis. Exp. (2017). This video showcases the imaging of insulin-induced GLUT4 translocation in hypothalamic neurons, employing deconvolution microscopy to capture and analyze GFP-GLUT4 trafficking dynamics with high resolution. 

Video: Imaging GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy - Concept

Studying the Hypothalamic Insulin Signal to Peripheral Glucose Intolerance with a Continuous Drug Infusion System into the Mouse Brain

Insulin regulates systematic metabolism in the hypothalamus and the peripheral insulin response. An inflammatory reaction in peripheral adipose tissues contributes to type 2 diabetes mellitus (T2DM) development and appetite regulation in the hypothalamus. Chemokine CCL5 and C-C chemokine receptor type 5 (CCR5) levels have been suggested to mediate arteriosclerosis and glucose intolerance in type 2 diabetes mellitus (T2DM). In addition, CCL5 plays a neuroendocrine role in the hypothalamus by regulating food intake and body temperature, thus, prompting us to investigate its function in hypothalamic insulin signaling and the regulation of peripheral glucose metabolism.
The micro-osmotic pump brain infusion system is a quick and precise way to manipulate CCL5 function and study its effect in the brain. It also provides a convenient alternative approach to generating a transgenic knockout animal. In this system, CCL5 signaling was blocked by intracerebroventricular (ICV) infusion of its antagonist, MetCCL5, using a micro-osmotic pump. The peripheral glucose metabolism and insulin responsiveness was detected by the Oral Glucose Tolerance Test (OGTT) and Insulin Tolerance Test (ITT). Insulin signaling activity was then analyzed by protein blot from tissue samples derived from the animals.
After 7-14 days of MetCCL5 infusion, the glucose metabolism and insulin responsiveness was impaired in mice, as seen in the results of the OGTT and ITT. The IRS-1 serine302 phosphorylation was increased and the Akt activity was reduced in mice hypothalamic neurons following CCL5 inhibition. Altogether, our data suggest that blocking CCL5 in the mouse brain increases the phosphorylation of IRS-1 S302 and interrupts hypothalamic insulin signaling, leading to a decrease in insulin function in peripheral tissues as well as the impairment of glucose metabolism.

This protocol studies the role of chemokine (C-C motif) ligand 5 (CCL5) in the hypothalamus by delivering an antagonist, MetCCL5, into the mouse brain using a micro-osmotic pump brain infusion system. This transient inhibition of CCL5 activity interrupted hypothalamic insulin signaling, leading to glucose intolerance and peripheral systemic insulin sensitivity.

Insulin regulates systematic metabolism in the hypothalamus and the peripheral insulin response. An inflammatory reaction in peripheral adipose tissues ...

JoVE Journal

Medicine

Measuring Glucose Uptake in Drosophila Models of TDP-43 Proteinopathy

Amyotrophic lateral sclerosis is a neurodegenerative disorder causing progressive muscle weakness and death within 2-5 years following diagnosis. Clinical manifestations include weight loss, dyslipidemia, and hypermetabolism; however, it remains unclear how these relate to motor neuron degeneration. Using a Drosophila model of TDP-43 proteinopathy that recapitulates several features of ALS including cytoplasmic inclusions, locomotor dysfunction, and reduced lifespan, we recently identified broad ranging metabolic deficits. Among these, glycolysis was found to be upregulated and genetic interaction experiments provided evidence for a compensatory neuroprotective mechanism. Indeed, despite upregulation of phosphofructokinase, the rate limiting enzyme in glycolysis, an increase in glycolysis using dietary and genetic manipulations was shown to mitigate locomotor dysfunction and increased lifespan in fly models of TDP-43 proteinopathy. To further investigate the effect on TDP-43 proteinopathy on glycolytic flux in motor neurons, a previously reported genetically encoded, FRET-based sensor, FLII12Pglu-700&#181;&#948;6, was used. This sensor is comprised of a bacterial glucose-sensing domain and cyan and yellow fluorescent proteins as the FRET pair. Upon glucose binding, the sensor undergoes a conformational change allowing FRET to occur. Using FLII12Pglu-700&#181;&#948;6, glucose uptake was found to be significantly increased in motor neurons expressing TDP-43G298S, an ALS causing variant. Here, we show how to measure glucose uptake, ex vivo, in larval ventral nerve cord preparations expressing the glucose sensor FLII12Pglu-700&#181;&#948;6 in the context of TDP-43 proteinopathy. This approach can be used to measure glucose uptake and assess glycolytic flux in different cell types or in the context of various mutations causing ALS and related neurodegenerative disorders.

Measuring Glucose Uptake in Drosophila Models of TDP-43 Proteinopathy

Glucose uptake is increased in Drosophila motor neurons affected by TAR DNA binding protein (TDP-43) proteinopathy, as indicated by a FRET-based, genetically encoded glucose sensor.

Amyotrophic lateral sclerosis is a neurodegenerative disorder causing progressive muscle weakness and death within 2-5 years following diagnosis. Clinical ...

Imaging GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy

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Imaging GLUT4 Protein Trafficking in Mouse Primary Hypothalamic Neurons Using Deconvolution Microscopy

Studying the Hypothalamic Insulin Signal to Peripheral Glucose Intolerance with a Continuous Drug Infusion System into the Mouse Brain

Measuring Glucose Uptake in Drosophila Models of TDP-43 Proteinopathy