embedding drosophila brain in a matrix for time-lapse imaging of the circadian clock neurons

Embedding Drosophila Brain in a Matrix for Time-Lapse Imaging of the Circadian Clock Neurons

After transferring the brain into working solution, dispense the brain and medium onto the lid of a sterile petri dish. Then add another 3.5 microliters of SAM with antibiotics, and add 3.5 microliters of warm SAM with fibrinogen.It is important to maintain the SAM medium with fibrinogen at 37 degrees throughout this procedure.Next, mix the solution around the brain by gently pipetting with the same pipette tip and aspirate 2 microliters of the solution to deposit on a coverslip for a glass bottomed dish. Then, add 0.8 microliters of thrombin to the droplet and mix very quickly to initialize the polymerization, which will appear white. Then, use forceps to gently pick the brain and set it onto the polymerizing fibrin matrix.Adding the thrombin after the brain was transferred to the droplet. It's not recommended as it complicates a lot the procedure.Orient the brain as needed and very gently push the brain as close to the coverslip as possible. Then pick a layer of polymerized fibrin and fold it on top of the brain, using small and gentle movements that do not detach the matrix. Continue to fold layers of polymerized fibrin over the brain from different parts of the clot to stabilize the brain. Then deposit 20 microliters of SAM with antibiotics over the embedded brain to halt the thrombin activity. Then lay a piece of PTFE membrane over the medium and stick the edges of the membrane to the greased parts of the dish.

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Source:<a style='text-decoration:none;' href='https://appjove.unicartagenaproxy.elogim.com/v/57015/single-cell-resolution-fluorescence-live-imaging-of-drosophila-circadian-clocks-in-larval-brain-culture'><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;'> Sabado, V.,&#160;et al.,&#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;'>Nagoshi, E. Single-cell Resolution Fluorescence Live Imaging of&#160;Drosophila&#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;'>Circadian Clocks in Larval Brain Culture.&#160;J. Vis. Exp.&#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;'>(2018).</a> &#160;This video demonstrates the procedure to embed the&#160;Drosophila brain in a fibrin matrix, followed by time-lapse fluorescence imaging of circadian clock neurons to analyze rhythmic activity synchronized with light/dark cycles.

Source: Sabado, V.,&#160;et al.,&#160;Nagoshi, E. Single-cell Resolution Fluorescence Live Imaging of&#160;Drosophila&#160;Circadian Clocks in Larval ...

Begin with a Petri dish lid containing the&#160;Drosophila larval brain, pre-exposed to a light/dark cycle. The slice contains fluorescent protein-expressing clock neurons.&#160;Add a nutrient-rich medium with antibiotics to support neuronal survival and a warm fibrinogen solution.&#160;Gently mix the solution to distribute fibrinogen evenly.&#160;Place a small amount of this mixture onto the coverslip of a glass-bottom dish.&#160;Add thrombin to react with fibrinogen to induce the formation of a three-dimensional fibrin matrix.Transfer the brain onto this matrix, positioning it anterior-side down to align clock neurons for imaging.&#160;Fold the matrix over the brain to anchor it and prevent movement.&#160;Add nutrient-rich medium to inactivate thrombin activity.&#160;Seal the dish with a gas-permeable membrane to maintain hydration and neuronal viability.&#160;Perform time-lapse fluorescence imaging at specific intervals.&#160;The fluorescence changes in clock neurons reveal their rhythmic activation and inhibition, synchronized with the light/dark cycle, reflecting circadian rhythms, the daily activity cycle.

11 Views. Embedding Drosophila Brain in a Matrix for Time-Lapse Imaging of the Circadian Clock Neurons

Video: Embedding Drosophila Brain in a Matrix for Time-Lapse Imaging of the Circadian Clock Neurons - Experiment

Live Imaging of Drosophila Larval Neuroblasts

Stem cells divide asymmetrically to generate two progeny cells with unequal fate potential: a self-renewing stem cell and a differentiating cell. Given their relevance to development and disease, understanding the mechanisms that govern asymmetric stem cell division has been a robust area of study. Because they are genetically tractable and undergo successive rounds of cell division about once every hour, the stem cells of the Drosophila central nervous system, or neuroblasts, are indispensable models for the study of stem cell division. About 100 neural stem cells are located near the surface of each of the two larval brain lobes, making this model system particularly useful for live imaging microscopy studies. In this work, we review several approaches widely used to visualize stem cell divisions, and we address the relative advantages and disadvantages of those techniques that employ dissociated versus intact brain tissues. We also detail our simplified protocol used to explant whole brains from third instar larvae for live cell imaging and fixed analysis applications.

Live Imaging of Drosophila Larval Neuroblasts

This protocol details a streamlined method used to conduct live cell imaging in the context of an intact larval brain. Live cell imaging approaches are invaluable for the study of asymmetric neural stem cell divisions as well as other neurogenic and developmental processes, consistently uncovering mechanisms that were previously overlooked.

Stem cells divide asymmetrically to generate two progeny cells with unequal fate potential: a self-renewing stem cell and a differentiating cell. Given ...

JoVE Journal

Applications of Immobilization of Drosophila Tissues with Fibrin Clots for Live Imaging

Drosophila is an important model system to study a vast range of biological questions. Various organs and tissues from different developmental stages of the fly such as imaginal discs, the larval brain or egg chambers of adult females or the adult intestine can be extracted and kept in culture for imaging with time-lapse microscopy, providing valuable insights into cell and developmental biology. Here, we describe in detail our current protocol for the dissection of Drosophila larval brains, and then present our current approach for immobilizing and orienting larval brains and other tissues on a glass coverslip using Fibrin clots. This immobilization method only requires the addition of Fibrinogen and Thrombin to the culture medium. It is suitable for high-resolution time lapse imaging on inverted microscopes of multiple samples in the same culture dish, minimizes the lateral drifting frequently caused by movements of the microscope stage in multi-point visiting microscopy and allows for the addition and removal of reagents during the course of imaging. We also present custom-made macros that we routinely use to correct for drifting and to extract and process specific quantitative information from time-lapse analysis.

Applications of Immobilization of Drosophila Tissues with Fibrin Clots for Live Imaging

This protocol describes applications of sample immobilization using Fibrin clots, limiting drifting, and allowing the addition and washout of reagents during live imaging. Samples are transferred to a drop of Fibrinogen containing culture medium on the surface of a coverslip, after which polymerization is induced by adding thrombin.

Drosophila is an important model system to study a vast range of biological questions. Various organs and tissues from different developmental stages of ...

Developmental Biology

Circadian Entrainment of Drosophila Melanogaster

Nearly universal among organisms, circadian rhythms coordinate biological activity to earth&#39;s orbit around the sun. To identify factors creating this rhythm and to understand the resulting outputs, entrainment of model organisms to defined circadian time-points is required. Here we detail a procedure to entrain many Drosophila to a defined circadian rhythm. Furthermore, we detail post-entrainment steps to prepare samples for immunofluorescence, nucleic acid, or protein extraction-based analysis.

Here, we detail how to synchronize Drosophila to a circadian day. This is the first, and most important step necessary for studying biological rhythms and chronobiology.

Nearly universal among organisms, circadian rhythms coordinate biological activity to earth&#39;s orbit around the sun. To identify factors creating this ...

Embedding Drosophila Brain in a Matrix for Time-Lapse Imaging of the Circadian Clock Neurons

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Embedding Drosophila Brain in a Matrix for Time-Lapse Imaging of the Circadian Clock Neurons