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1. General considerations<ol><li>Use&#160;Drosophila&#160;stocks expressing a permanently rhabdomerally located translocating proteins for analyses regarding protein trafficking (e.g., transient receptor potential-like (TRPL) ion channel:: enhanced green fluorescent protein (eGFP), Arrestin 2 (Arr2)::eGFP).</li><li>Predetermine light exposure conditions of selected flies for the experimental approach.<ol style='list-style-type:decimal;'><li>For dark adaptation, keep the flies in dark boxes for the desired period at 25 &#176;C. For illumination up to 16 h in translocation experiments (e.g., TRPL::eGFP expressing flies), keep flies under a fluorescent tube at room temperature.</li><li>For illuminating flies with colored light, use different colored transparent plastic boxes along with the fluorescent tube.</li></ol></li></ol>2. Water immersion microscopy<ol><li>Fly preparation<ol style='list-style-type:decimal;'><li>Prepare the working space with the needed equipment and reagents, as shown in&#160;Figure 1. Transfer flies with predetermined age and illumination conditions into a pre-cooled 15 mL centrifuge tube and anesthetize by incubating them on ice for 15 to 30 min. NOTE: Carry along 1-day old, dark-adapted flies as reference. Generally, dark-adapted flies should be transferred to an icebox with a lid in the dark. Light-adapted flies can be transferred to the ice in room light.</li><li>Transfer one ice-anesthetized fly headfirst into a 200 &#181;L pipette tip and push the fly toward the tip carefully with compressed air.</li><li>Cut off the pipette tip just in front of the head using a scalpel. Using tweezers, carefully push the fly a few millimeters away from the tip. Cut off the pipette tip again and push the fly back toward the tip with compressed air so that only the head of the fly protrudes from the pipette tip.</li><li>Adhere a piece of plasticine onto an object slide and press the pipette tip into it so that either the left or the right eye of the fly faces upward (Figure 2A). Right before image acquisition, use a laboratory pipette to adhere a large drop of chilled water to the underside of a water immersion objective (Figure 2B). Immediately proceed to image acquisition for best results. NOTE: Significant delay in image acquisition results in reawakening and movements of the fly which may lead to blurry images. &#160;</li></ol></li><li>Image acquisition<ol style='list-style-type:decimal;'><li>Carefully place the object slide with the prepared fly onto the microscope stage and select a water immersion objective.</li><li>Lower the water immersion objective manually until the fly's eye touches the drop (Figure 3A, B).</li><li>Switch on the microscope UV lamp and select the appropriate filter set. Use the eyepieces to position the fly under the objective and focus the microscope on the surface of the eye.</li><li>Switch the light path toward the microscope camera and generate a live image in the corresponding software. Readjust the focus for the camera and evaluate the orientation of the eye, considering that the eye has to face the microscope objective radially, as illustrated in more detail in&#160;Figure 3C-E.</li><li>Use the appropriate LUT (look up table) within the imaging software to detect oversaturation (indicated as red pixels).</li><li>In the case of non-pigmented flies, adjust the exposure time such that the brightest pixels are just below the saturation limit for every image.</li><li>Record an image and save it as a raw file to archive all corresponding metadata of the recording. Export the image in a .tif format for the following quantification. NOTE: Illuminate the flies for 5 minutes with red light (e.g., 630 nm) immediately after image acquisition, if they are intended to be used for further experiments. Red light deactivates the phototransduction cascade that has been activated excessively by intense short-waved light during image acquisition. &#160;</li></ol></li><li>Data analysis and quantification of relative eGFP fluorescence in the rhabdomeres of water immersion micrographs<ol style='list-style-type:decimal;'><li>Download, install, and execute the software ImageJ/Fiji.</li><li>Adjust the ImageJ settings by clicking on&#160;Analyze &gt; Set Measurements...&#160;and check only the box for&#160;Mean Gray Value. Import a .tif image by clicking on&#160;File &gt; Open...&#160;or by dragging and dropping. Choose a representative region of the image that is in focus and enlarge it to 200%-300% by repeatedly pressing&#160;Ctrl&#160;and&#160;+&#160;together.</li><li>Select the&#160;Oval&#160;tool and, while pressing the&#160;Shift&#160;key, generate a circular selection in the image that is significantly smaller than one fluorescent rhabdomere. Before releasing the mouse button, look for the exact size displayed below the toolbar in the ImageJ main window. Use the same size of circular selection for all analyses. NOTE: The exact size of the circular selection in pixels or microns depends on the specific setup. Use a circle approximately 1/3 or 1/4 of the rhabdomeral diameter of 1-day old, dark-adapted control flies.</li><li>Move the circular selection either by mouse-clicking into it and dragging or by pressing the Arrow Keys on the keyboard.</li><li>To measure the fluorescence intensities within the circular selection, move the circle to the first rhabdomere (r1) and click on&#160;Analyze &gt; Measure&#160;or use the shortcut&#160;Ctrl&#160;+&#160;M. A&#160;Result&#160;window listing the measured gray value will pop up.</li><li>Continue with measurements of r2-r6 as repeated measurements and a measurement of the background signal (b). In the case of non-pigmented flies, make additional measurements of the corresponding cell body areas (c1-c6) (Figure 4).</li><li>Repeat steps 2.3.5 and 2.3.6 for two more ommatidia, resulting in three technical replicates. Mark the analyzed ommatidia by using the Pencil tool and save this image for documentation.</li><li>Select and copy the measured gray values from the Result window and paste them into spreadsheet software for further calculations. Sort the values of fluorescence intensity according to their origin into the categories rhabdomere (r), cell body (c), and background (b). Calculate the mean intensity from each category (Ir, Ic, Ib).</li><li>Calculate the relative amount of eGFP present in the rhabdomere.</li><li>Continue with the next image in step 2.3.3. It is recommended to use images from at least five individuals of each experimental group as biological replicates to get a reliable measurement.</li></ol></li></ol>

<figure class='table' style='width:969pt;'><table class='ck-table-resized'><colgroup><col style='width:46.85%;'><col style='width:16.51%;'><col style='width:17.65%;'><col style='width:18.99%;'></colgroup><tbody><tr><td style='border-top-style:none;height:14.25pt;'>15 mL centrifuge tube</td><td style='border-left-style:none;border-top-style:none;'>Greiner Bio-One</td><td style='border-left-style:none;border-top-style:none;'>188271</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Carbon dioxide anaesthesia fly pad</td><td style='border-left-style:none;border-top-style:none;'>Flystuff</td><td style='border-left-style:none;border-top-style:none;'>59-172</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Cold light lamp (KL 1500 LCD)</td><td style='border-left-style:none;border-top-style:none;'>Zeiss</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Fiji/ImageJ</td><td style='border-left-style:none;border-top-style:none;'>NIH</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:37.5pt;width:454pt;'>Fluorescence microscope with UV lamp, camera, filter set and software (AxioImager.Z1m, Axiocam 530 mono, 38 HE, ZEN2 blue edition)</td><td style='border-left-style:none;border-top-style:none;'>Zeiss</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:41.25pt;width:454pt;'>Fluorescent tube&#160;</td><td style='border-left-style:none;border-top-style:none;'>Osram</td><td style='border-left-style:none;border-top-style:none;'>4050300518039.00</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Laboratory pipette (20-200 &#181;L)</td><td style='border-left-style:none;border-top-style:none;'>Eppendorf</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Object slide</td><td style='border-left-style:none;border-top-style:none;'>Roth</td><td style='border-left-style:none;border-top-style:none;'>656.1</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Pipette tips (200 &#181;L)</td><td style='border-left-style:none;border-top-style:none;'>Labsolute</td><td style='border-left-style:none;border-top-style:none;'>7695844</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Plasticine (Blu-Tack)</td><td style='border-left-style:none;border-top-style:none;'>Bostik</td><td style='border-left-style:none;border-top-style:none;'>30811745</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:14.25pt;'>Stereo microscope (SMZ445)</td><td style='border-left-style:none;border-top-style:none;'>Nikon</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr><tr><td style='border-top-style:none;height:30.0pt;width:454pt;'>Stereo microscope with UV lamp, camera, filer set and software (MZ16F, MC170 HD, GFP3, LAS 4.12)</td><td style='border-left-style:none;border-top-style:none;'>Leica</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td><td style='border-left-style:none;border-top-style:none;'>&#160;</td></tr></tbody></table></figure>

studying membrane protein trafficking in drosophila photoreceptor cells

<a href='https://app-jove-com.remotexs.ntu.edu.sg/v/63375/studying-membrane-protein-trafficking-drosophila-photoreceptor-cells'>Source: Wagner, K. et al., Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells Using eGFP-Tagged Proteins.&#160;J. Vis. Exp. (2022).</a>This video demonstrates the visualization of membrane protein trafficking in Drosophila photoreceptor cells using eGFP-tagged TRPL proteins. It details the preparation of transgenic flies for imaging, the capture of fluorescence images of photoreceptor cells, and the quantification of TRPL trafficking by measuring relative eGFP fluorescence in the rhabdomeres.

<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2804/3316;' src='https://cloudfront-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/23261/23261_Figure1_editor_23261.jpg' alt='23261_Figure1.jpg' /></figure>Figure 1: Water immersion microscopy workspace.&#160; Materials needed are: (A) 15 mL centrifuge tube, (B) ice flakes, (C) chilled distilled water, (D) stereomicroscope, (E) Petri dish, (F) plasticine, (G) object slide, (H) insect pins or pipette tips and scalpel, (I) fluorescence microscope with (J) software.&#160;&#160;<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:2999/1428;' src='https://cloudfront-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/23261/23261_Figure2_editor_23261.jpg' alt='23261_Figure2.jpg' /></figure>Figure 2: Preparation for non-lethal water drop &#160; microscopy.&#160;Illustration of (A) a cold-anesthetized fly fixed inside a 200&#160;&#181;L pipette tip mounted on plasticine-coated object slide and (B) the application of chilled water drop on the underside of the water immersion objective.<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:3714/2857;' src='https://cloudfront-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/23261/23261_Figure3_editor_23261.jpg' alt='23261_Figure3.jpg' /></figure>Figure 3: Positioning of the fly under the fluorescence microscope for water immersion imaging.&#160;Setup and final orientation for image acquisition using the (A) lethal or (B) non-lethal fly preparation protocols. (C) Illustration of fly orientation for obtaining best results of water immersion microscopy images. The ideal point to focus on the eye is not the exact center with respect to the anterior/posterior and dorsal/ventral axes but is slightly above the eye's equator, as indicated by the red arrow. (D) Example of water immersion image for a perfectly positioned eye. All three symmetry axes of the hexagonal ommatidial tiling appear as straight lines and the maximum amount of ommatidia can be in focus at the same time. (E) Example of water immersion image of an improperly positioned eye. The image contains curved axes and a shallow depth of field. Scale bar: 20 &#181;m.<figure class='image image-style-align-center image_resized' style='display:table;margin-left:auto;margin-right:auto;width:75%;'><img style='aspect-ratio:1937/1252;' src='https://cloudfront-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/23261/23261_Figure4_editor_23261.jpg' alt='23261_Figure4.jpg' /></figure>Figure 4: Quantification of relative rhabdomeral fluorescence for translocation studies.&#160;An illustration regarding quantification of relative eGFP fluorescence in the rhabdomeres by measuring the fluorescence intensity of rhabdomere (r), cell body (c), and background (b) of three different representative ommatidia (white circles) in one water immersion microscopy image; scale bar: 10 &#181;m. A magnified ommatidium is shown on the right; scale bar: 2 &#181;m.&#160;

Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells

Source: Wagner, K. et al., Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells Using eGFP-Tagged Proteins.&#160;J. Vis. Exp. ...

Take a dark-adapted, anesthetized, transgenic, white-eyed fly.The fly expresses eGFP-tagged TRPL ion channels in the photoreceptors of the eye.In darkness, TRPL localizes to the membranes of the rhabdomeres&#8212; the microvilli of the photoreceptors.&#160;Using compressed air, push the fly headfirst into a pipette tip.Trim the tip and push the fly backward.Trim it again and push the fly forward until only its head protrudes.Immobilize the tip in modeling clay adhered to a slide and place it on a fluorescence microscope stage, with the eye facing the microscope objective radially.&#160;Add a drop of water to the objective, then lower it until it touches the eye.Capture images of the photoreceptors.Measure the fluorescence intensities in the rhabdomeres, cell body, and background.Illuminate the fly with orange light to induce TRPL translocation to the cell body.Repeat the imaging and fluorescence measurements.Compare the images to observe reduced rhabdomeral fluorescence post-illumination, indicating TRPL translocation to the cell body.

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106 Views. Source: Wagner, K. et al., Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells Using eGFP-Tagged Proteins. J. Vis. Exp. (2022). This video demonstrates the visualization of membrane protein trafficking in Drosophila photoreceptor cells using eGFP-tagged TRPL proteins. It details the preparation of transgenic flies for imaging, the capture of fluorescence images of photoreceptor cells, and the quantification of TRPL trafficking by measuring relative eGFP fluorescence in t...

Video: Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells - Concept

Dissection and Immunofluorescent Staining of Mushroom Body and Photoreceptor Neurons in Adult Drosophila melanogaster Brains

Nervous system development involves a sequential series of events that are coordinated by several signaling pathways and regulatory networks. Many of the proteins involved in these pathways are evolutionarily conserved between mammals and other eukaryotes, such as the fruit fly Drosophila melanogaster, suggesting that similar organizing principles exist during the development of these organisms. Importantly, Drosophila has been used extensively to identify cellular and molecular mechanisms regulating processes that are required in mammals including neurogenesis, differentiation, axonal guidance, and synaptogenesis. Flies have also been used successfully to model a variety of human neurodevelopmental diseases. Here we describe a protocol for the step-by-step microdissection, fixation, and immunofluorescent localization of proteins within the adult Drosophila brain. This protocol focuses on two example neuronal populations, mushroom body neurons and retinal photoreceptors, and includes optional steps to trace individual mushroom body neurons using Mosaic Analysis with a Repressible Cell Marker (MARCM) technique. Example data from both wild-type and mutant brains are shown along with a brief description of a scoring criteria for axonal guidance defects. While this protocol highlights two well-established antibodies for investigating the morphology of mushroom body and photoreceptor neurons, other Drosophila brain regions and the localization of proteins within other brain regions can also be investigated using this protocol.

Dissection and Immunofluorescent Staining of Mushroom Body and Photoreceptor Neurons in Adult Drosophila melanogaster Brains

This protocol describes the dissection and immunostaining of adult Drosophila melanogaster brain tissues. Specifically, this protocol highlights the use of Drosophila mushroom body and photoreceptor neurons as example neuronal subsets that can be accurately used to uncover general principles underlying many aspects of neuronal development.

Nervous system development involves a sequential series of events that are coordinated by several signaling pathways and regulatory networks. Many of the ...

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Developmental Biology

Quantitative Cell Biology of Neurodegeneration in Drosophila Through Unbiased Analysis of Fluorescently Tagged Proteins Using ImageJ

With the rising prevalence of neurodegenerative diseases, it is increasingly important to understand the underlying pathophysiology that leads to neuronal dysfunction and loss. Fluorescence-based imaging tools and technologies enable unprecedented analysis of subcellular neurobiological processes, yet there is still a need for unbiased, reproducible, and accessible approaches for extracting quantifiable data from imaging studies. We have developed a simple and adaptable workflow to extract quantitative data from fluorescence-based imaging studies using Drosophila models of neurodegeneration. Specifically, we describe an easy-to-follow, semi-automated approach using Fiji/ImageJ to analyze two cellular processes: first, we quantify protein aggregate content and profile in the Drosophila optic lobe using fluorescent-tagged mutant huntingtin proteins; and second, we assess autophagy-lysosome flux in the Drosophila visual system with ratiometric-based quantification of a tandem fluorescent reporter of autophagy. Importantly, the protocol outlined here includes a semi-automated segmentation step to ensure all fluorescent structures are analyzed to minimize selection bias and to increase resolution of subtle comparisons. This approach can be extended for the analysis of other cell biological structures and processes implicated in neurodegeneration, such as proteinaceous puncta (stress granules and synaptic complexes), as well as membrane-bound compartments (mitochondria and membrane trafficking vesicles). This method provides a standardized, yet adaptable reference point for image analysis and quantification, and could facilitate reliability and reproducibility across the field, and ultimately enhance mechanistic understanding of neurodegeneration.

Quantitative Cell Biology of Neurodegeneration in Drosophila Through Unbiased Analysis of Fluorescently Tagged Proteins Using ImageJ

We have developed a simple and adaptable workflow to extract quantitative data from fluorescence-imaging-based cell biological studies of protein aggregation and autophagic flux in the central nervous system of Drosophila models of neurodegeneration.

With the rising prevalence of neurodegenerative diseases, it is increasingly important to understand the underlying pathophysiology that leads to neuronal ...

Imaging the Intracellular Trafficking of APP with Photoactivatable GFP

Beta-amyloid (A&#946;) is the major constituent of senile plaques found in the brains of Alzheimer&#8217;s disease patients. A&#946; is derived from the sequential cleavage of Amyloid Precursor Protein (APP) by &#946; and &#947;-secretases. Despite the importance of A&#946; to AD pathology, the subcellular localization of these cleavages is not well established. Work in our laboratory and others implicate the endosomal/lysosomal system in APP processing after internalization from the cell surface. However, the intracellular trafficking of APP is relatively understudied.
While cell-surface proteins are amendable to many labeling techniques, there are no simple methods for following the trafficking of membrane proteins from the Golgi. To this end, we created APP constructs that were tagged with photo-activatable GFP (paGFP) at the C-terminus. After synthesis, paGFP has low basal fluorescence, but it can be stimulated with 413 nm light to produce a strong, stable green fluorescence. By using the Golgi marker Galactosyl transferase coupled to Cyan Fluorescent Protein (GalT-CFP) as a target, we are able to accurately photoactivate APP in the trans-Golgi network. Photo-activated APP-paGFP can then be followed as it traffics to downstream compartments identified with fluorescently tagged compartment marker proteins for the early endosome (Rab5), the late endosome (Rab9) and the lysosome (LAMP1). Furthermore, using inhibitors to APP processing including chloroquine or the &#947;-secretase inhibitor L685, 458, we are able to perform pulse-chase experiments to examine the processing of APP in single cells.
We find that a large fraction of APP moves rapidly to the lysosome without appearing at the cell surface, and is then cleared from the lysosome by secretase-like cleavages. This technique demonstrates the utility of paGFP for following the trafficking and processing of intracellular proteins from the Golgi to downstream compartments.

While the transport of cell surface proteins is relatively easily studied, visualizing the trafficking of intracellular proteins is much more difficult. Here, we use constructs incorporating photoactivatable GFP and demonstrate a method to accurately follow the amyloid precursor protein from the Golgi apparatus to down-stream compartments and follow its clearance.

Beta-amyloid (A&#946;) is the major constituent of senile plaques found in the brains of Alzheimer&#8217;s disease patients. A&#946; is derived from the ...

Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells

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Studying Membrane Protein Trafficking in Drosophila Photoreceptor Cells

Dissection and Immunofluorescent Staining of Mushroom Body and Photoreceptor Neurons in Adult Drosophila melanogaster Brains

Quantitative Cell Biology of Neurodegeneration in Drosophila Through Unbiased Analysis of Fluorescently Tagged Proteins Using ImageJ

Imaging the Intracellular Trafficking of APP with Photoactivatable GFP