Name: imaging intracellular atp dynamics using fret-based sensors in an organotypic mouse hippocampal slice
Uploaded: 2025-04-28T12:01:15.000+00:00
Duration: 1 min 22 s
Description: Source: Lerchundi, R., et. al. Imaging of Intracellular ATP in Organotypic Tissue Slices of the Mouse Brain using the FRET-based Sensor ATeam1.03YEMK. J. ...

imaging intracellular atp dynamics using fret-based sensors in an organotypic mouse hippocampal slice

Imaging Intracellular ATP Dynamics Using FRET-Based Sensors in an Organotypic Mouse Hippocampal Slice

Prepare experimental ACSF and obtain a pH of 7.4 by bubbling it with 95% oxygen and 5% carbon dioxide through an inserted tubing connected to the carbogen supply for at least 30 minutes. Keep the saline bubbled during the entire experiment. Then, switch on the fluorescent light source of the monochromator.Transfer the organotypic slice culture into the experimental chamber. Place a grid on top of the organotypic slice culture with the frame down, not touching the culture, and the threads up, touching the membrane. Place the chamber on the microscope stage and connect it to the perfusion system.Switch on the peristaltic pump at a flow rate of 1.5 to 2.5 milliliters per minute. Make sure there is no leaking of the perfusion system. Using transmission light, bring the cultured slice into focus and identify the area where experiments shall be performed.Before starting imaging experiments, wait at least 15 minutes to allow slices to adapt to the saline conditions. Then, switch on the camera and the imaging software. Excite the donor fluorescent protein at 435 nanometers. Set the exposure time to between 40 to 90 milliseconds.Then, insert the dichroic mirror and the filters into the beam splitter unit. Split the fluorescence emission at 500 nanometers with an emission image splitter, and employ bandpass filters at 482 plus or minus 16 and 542 plus or minus 13.5 nanometers to further isolate donor and acceptor fluorescence.Select a region of interest apparently devoid of cellular fluorescence for background subtraction. Circle single structures of labeled tissue in the image on the screen to create ROIs. Set the frequency of image acquisition in the overall recording time. For experiments longer than 30 minutes, an acquisition frequency of 0.2 to 0.5 Hertz is recommended to prevent phototoxicity. Subsequently, start the recording.

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All procedures involving animal samples have been reviewed and approved by the appropriate animal ethical review committee.&#160;1. FRET-based ATP Imaging (Figure 1)<ol><li>Before the experiment, prepare E-ACSF and bubble it with 95% O2/5% CO2 for at least 30 min to obtain a pH of 7.4. Switch on the fluorescent light source (Xenon lamp) of the monochromator (Figure 1). Start the perfusion just before taking out the slice from the incubator. NOTE: Keep the saline bubbled with 95% O2 and 5% CO2 during the entire experiment.</li><li>Transfer the slice into an experimental chamber that is constantly perfused with freshly carbogenated E-ACSF using a peristaltic pump (Figure 1). Then, fix the slice with a grid. Place the chamber onto the microscope stage and connect the perfusion system. Gas-proof laboratory tubing is recommended for perfusion. NOTE: Experiments can be performed at room temperature or near physiological temperature, depending on the experimental design. Check the stability and reliability of the perfusion flow to avoid changes of focus induced by movement of the tissue and/or changes in shear stress. Standard perfusion velocities for slice work, used by us and many other laboratories, are 1.5-2.5 mL/min.</li><li>Bring the cultured slice into focus using a transmission light. Identify the area where experiments shall be performed (for example: the CA1 region of the hippocampus). Before starting imaging experiments, wait at least 15 min to allow slices to adapt to the saline conditions. For the configuration of the experimental setup, see&#160;Figure 1.</li><li>Switch on the camera and the imaging software. Then, select the proper filter cube.</li><li>Excite the donor fluorescent protein (eCFP) at 435/17 nm (~435 nm). Set the exposure time between 40 to 90 ms. NOTE: Strong exposure of slices to the fluorescent light may result in phototoxic effects.</li><li>Excitation at 435 nm results in emission at both 475 nm (eCFP; donor) and 527 nm (Venus; acceptor). Split the fluorescence emission at 500 nm with an emission image splitter and employ bandpass filters at 483/32 and 542/27 to further isolate donor and acceptor fluorescence. Strong expression might result in saturation of the detectors. In this case, you might use a neutral density filter to reduce the intensity of excitation.</li><li>Select a region of interest (ROI) apparently devoid of cellular fluorescence for background subtraction. Then, create ROIs delineating cell bodies.</li><li>Set the frequency of image acquisition and the overall recording time. For long (&gt;30 min) experiments, an acquisition frequency of 0.2-0.5 Hz is recommended to prevent phototoxicity.</li><li>Start the recording. It is recommended to record at least 5 min under baseline conditions to ensure the stability of the preparation. NOTE: Adjust the focus of the cell during the recording if needed.</li></ol>

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<a href='https://app.jove.com/v/60294/imaging-intracellular-atp-organotypic-tissue-slices-mouse-brain-using'>Source: Lerchundi, R., et. al. Imaging of Intracellular ATP in Organotypic Tissue Slices of the Mouse Brain using the FRET-based Sensor ATeam1.03YEMK. J. Vis. Exp. (2019)</a>This video demonstrates the use of FRET(Fluorescence Resonance Energy Transfer)-based sensors to measure intracellular ATP levels in organotypic mouse hippocampal slices, enabling real-time visualization of ATP dynamics in neurons and astrocytes under physiological and experimental conditions.

<figure class='image image-style-align-center' style='display:table;margin-left:auto;margin-right:auto;'><img style='aspect-ratio:1200/560;' src='https://cloudfront.jove.com/files/ftp_upload/23421/23421_Figure_1_editor_23421.jpg' alt='23421_Figure_1.jpg' /></figure>Figure 1: Configuration of the FRET imaging setup. (A) Schematic illustration of the different components and their spatial arrangement required for the FRET imaging setup. The a...

Source: Lerchundi, R., et. al. Imaging of Intracellular ATP in Organotypic Tissue Slices of the Mouse Brain using the FRET-based Sensor ATeam1.03YEMK. J. ...

Secure an organotypic mouse hippocampal slice in an experimental chamber.The slice contains transduced neurons and astrocytes expressing an ATP sensor with donor and acceptor fluorescent proteins.Place the chamber on a fluorescence microscope stage and perfuse it with oxygenated ACSF.Allow the slice to adapt to the buffered conditions.Using transmission light, focus the slice and identify the area of interest.Switch to fluorescence mode and excite the donor fluorescent protein to initiate fluorescence emission.Upon ATP binding, the sensor undergoes conformational changes, enabling fluorescence-based energy transfer from the donor to the acceptor, which emits fluorescence at a longer wavelength.Use a dichroic mirror and bandpass filters to isolate and separate donor and acceptor emissions.Select a region without fluorescence for background subtraction. Then, identify target cells and record their fluorescence over time.Calculate the FRET ratio to monitor intracellular ATP levels in real-time.

11 Görüntüleme. Imaging Intracellular ATP Dynamics Using FRET-Based Sensors in an Organotypic Mouse Hippocampal Slice

Video: Imaging Intracellular ATP Dynamics Using FRET-Based Sensors in an Organotypic Mouse Hippocampal Slice - Deney

Fluorescence Microscopy for ATP Internalization Mediated by Macropinocytosis in Human Tumor Cells and Tumor-xenografted Mice

Adenosine triphosphate (ATP), including extracellular ATP (eATP), has been shown to play significant roles in various aspects of tumorigenesis, such as drug resistance, epithelial-mesenchymal transition (EMT), and metastasis. Intratumoral eATP is 103 to 104 times higher in concentration than in normal tissues. While eATP functions as a messenger to activate purinergic signaling for EMT induction, it is also internalized by cancer cells through upregulated macropinocytosis, a specific type of endocytosis, to perform a wide variety of biological functions. These functions include providing energy to ATP-requiring biochemical reactions, donating phosphate groups during signal transduction, and facilitating or accelerating gene expression as a transcriptional cofactor. ATP is readily available, and its study in cancer and other fields will undoubtedly increase. However, eATP study remains at an early stage, and unresolved questions remain unanswered before the important and versatile activities played by eATP and internalized intracellular ATP can be fully unraveled.
These authors&#39; laboratories&#39; contributions to these early eATP studies include microscopic imaging of non-hydrolysable fluorescent ATP, coupled with high- and low-molecular weight fluorescent dextrans, which serve as macropinocytosis and endocytosis tracers, as well as various endocytosis inhibitors, to monitor and characterize the eATP internalization process. This imaging modality was applied to tumor cell lines and to immunodeficient mice, xenografted with human cancer tumors, to study eATP internalization in vitro and in vivo. This paper describes these in vitro and in vivo protocols, with an emphasis on modifying and finetuning assay conditions so that the macropinocytosis-/endocytosis-mediated eATP internalization assays can be successfully performed in different systems.

We developed a reproducible method to visualize the internalization of nonhydrolyzable fluorescent adenosine triphosphate (ATP), an ATP surrogate, with high cellular resolution. We validated our method using independent in vitro and in vivo assays-human tumor cell lines and immunodeficient mice xenografted with human tumor tissue.

İnsan Tümör Hücrelerinde ve Tümör-ksinografted Farelerde Makropinositoz Aracılı ATP İçselleştirme için Floresan Mikroskopi

Adenosine triphosphate (ATP), including extracellular ATP (eATP), has been shown to play significant roles in various aspects of tumorigenesis, such as ...

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Visualization and Live Imaging of Oligodendrocyte Organelles in Organotypic Brain Slices Using Adeno-associated Virus and Confocal Microscopy

Neurons rely on the electric insulation and trophic support of myelinating oligodendrocytes. Despite the importance of oligodendrocytes, the advanced tools currently used to study neurons, have only partly been taken on by oligodendrocyte researchers. Cell type-specific staining by viral transduction is a useful approach to study live organelle dynamics. This paper describes a protocol for visualizing oligodendrocyte mitochondria in organotypic brain slices by transduction with adeno-associated virus (AAV) carrying genes for mitochondrial targeted fluorescent proteins under the transcriptional control of the myelin basic protein promoter. It includes the protocol for making organotypic coronal mouse brain slices. A procedure for time-lapse imaging of mitochondria then follows. These methods can be transferred to other organelles and may be particularly useful for studying organelles in the myelin sheath. Finally, we describe a readily available technique for visualization of unstained myelin in living slices by Confocal Reflectance microscopy (CoRe). CoRe requires no extra equipment and can be useful to identify the myelin sheath during live imaging.

Myelinating oligodendrocytes promote rapid action potential propagation and neuronal survival. Described here is a protocol for oligodendrocyte-specific expression of fluorescent proteins in organotypic brain slices with subsequent time-lapse imaging. Further, a simple procedure for visualizing unstained myelin is presented.

Görselleştirme ve Oligodendrocyte organelleri Adeno ilişkili virüs ve Confocal mikroskobu kullanılarak Organotypic beyin dilimleri içinde canlı görüntüleme

Neurons rely on the electric insulation and trophic support of myelinating oligodendrocytes. Despite the importance of oligodendrocytes, the advanced ...

Nörobilim

Two-photon Imaging of Microglial Processes' Attraction Toward ATP or Serotonin in Acute Brain Slices

Microglial cells are resident innate immune cells of the brain that constantly scan their environment with their long processes and, upon disruption of homeostasis, undergo rapid morphological changes. For example, a laser lesion induces in a few minutes an oriented growth of microglial processes, also called &#34;directional motility&#34;, toward the site of injury. A similar effect can be obtained by delivering locally ATP or serotonin (5-hydroxytryptamine [5-HT]). In this article, we describe a protocol to induce a directional growth of microglial processes toward a local application of ATP or 5-HT in acute brain slices of young and adult mice and to image this attraction over time by multiphoton microscopy. A simple method of quantification with free and open-source image analysis software is proposed. A challenge that still characterizes acute brain slices is the limited time, decreasing with age, during which the cells remain in a physiological state. This protocol, thus, highlights some technical improvements (medium, air-liquid interface chamber, imaging chamber with a double perfusion) aimed at optimizing the viability of microglial cells over several hours, especially in slices from adult mice.

Microglia, the resident immune cells of the brain, respond quickly with morphological changes to modifications of their environment. This protocol describes how to use two-photon microscopy to study the attraction of microglial processes toward serotonin or ATP in acute brain slices of mice.

Mikroglial süreçleri cazibe ATP veya Serotonin akut beyin dilimleri içinde doğru iki fotonlu görüntüleme

Microglial cells are resident innate immune cells of the brain that constantly scan their environment with their long processes and, upon disruption of ...

Imaging Intracellular ATP Dynamics Using FRET-Based Sensors in an Organotypic Mouse Hippocampal Slice

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Imaging Intracellular ATP Dynamics Using FRET-Based Sensors in an Organotypic Mouse Hippocampal Slice