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<figure class='table' style='width:1104pt;'><table class='ck-table-resized'><colgroup><col style='width:39.76%;'><col style='width:26.18%;'><col style='width:16.76%;'><col style='width:17.3%;'></colgroup><tbody><tr><td style='height:14.5pt;'>Amplifiers</td><td>Molecular Devices, Sunnyvale, CA, USA</td><td>Axoclamp 2B &amp; Axoclamp 900A</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Audible baseline monitors</td><td>Ampol US LLC, Sarasota, FL, USA</td><td>&#160;BM-A-TM</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Bath Chiller (Isotemp 500LCU)</td><td>ThermoFisher Scientific</td><td>13874647</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Borosilicate glass capillaries (Pinning)</td><td>Warner Instruments</td><td>G150T-6</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Borosilicate glass capillaries (Sharp Electrodes)</td><td>Warner Instruments</td><td>GC100F-10</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>BSA: Bovine Serum Albumin</td><td>Sigma</td><td>A7906</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>CaCl2: Calcium Chloride</td><td>Sigma</td><td>223506</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>DMSO: Dimethyl Sulfoxide</td><td>Sigma</td><td>D8418</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Flow Control Valve</td><td>Warner Instruments</td><td>&#160;FR-50</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Fluorescence system interface, ARC lamp &amp; 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diameter, 7.8&#160;cm)</td><td>Warner Instruments</td><td>PM6 or PH6</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Microscope Stage (Aluminum)</td><td>Siskiyou, Grants Pass, OR, USA</td><td>8090P</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>MTA: 2-Methylthioadenosine diphosphate trisodium salt</td><td>Tocris</td><td>1624</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>NaCl: Sodium Chloride</td><td>Sigma</td><td>S7653</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>NaOH: Sodium Hydroxide</td><td>Sigma</td><td>S8045</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Oscilloscope</td><td>Tektronix, Beaverton, Oregon, USA</td><td>&#160;TDS 2024B</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Phase contrast objectives</td><td>Nikon Instruments Inc</td><td>&#160;(Ph1 DL; 10X &amp; 20X)</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Plexiglas superfusion chamber</td><td>Warner Instruments, Camden, CT, USA</td><td>RC-27</td><td>&#160;</td></tr><tr><td style='height:14.5pt;'>Stereomicroscopes</td><td>Zeiss, NY, USA</td><td>Stemi 2000 &amp; 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analysis of calcium dynamics and membrane potential changes in a mouse arteriolar endothelium

<a href='https://app.jove.com/v/63463/isolation-functional-analysis-arteriolar-endothelium-mouse-brain'>Source: Hakim, M. A. et al., Isolation and Functional Analysis of Arteriolar Endothelium of Mouse Brain Parenchyma.&#160;J. Vis. Exp. (2022).</a>This video demonstrates the functional analysis of an arteriolar endothelial tube isolated from a mouse brain. It outlines the steps for measuring intracellular calcium levels and membrane potential, both at baseline and in response to pharmacological stimulation.

<img src='https://cloudfront.jove.com/files/ftp_upload/23311/23311_Figure1_editor_23311.jpg' alt='23311_Figure1.jpg' />Figure 1: Application of endothelial tube for physiological examination of pathways related to blood flow regulation.&#160;(A) A sharp electrode (purple arrow) is positioned in a cell of an endothelial tube focused in the data acquisition window for photometry. (B) Representative recording of intracellular Ca2+&#160;using Fura-2 photometry in response to MT...

Analysis of Calcium Dynamics and Membrane Potential Changes in a Mouse Arteriolar Endothelium

Source: Hakim, M. A. et al., Isolation and Functional Analysis of Arteriolar Endothelium of Mouse Brain Parenchyma.&#160;J. Vis. Exp. (2022).This video ...

Secure an arteriolar endothelial tube harvested from a mouse brain in a chamber with a continuous buffer flow.Place the chamber in a recording setup.Introduce a calcium-sensitive fluorescent dye. Incubate to allow cellular uptake of the dye.Wash to remove any non-internalized dye.Insert an electrode into an endothelial cell and record the resting membrane potential.Raise the bath temperature to a physiological temperature to facilitate intracellular calcium binding to the dye.Excite the dye and measure fluorescence to quantify baseline cellular calcium levels.&#160;Introduce a drug that binds to specific G-protein-coupled receptors on the endothelial cells, initiating a signaling cascade.This cascade releases calcium ions from the endoplasmic reticulum into the cytoplasm, enhancing calcium-dye binding and fluorescence.Elevated cytoplasmic calcium levels also activate potassium channels, facilitating potassium ion efflux and decreasing membrane potential.Record the data.Increased fluorescence and decreased membrane potential indicate a functional endothelial tube.

analysis-calcium-dynamics-membrane-potential-changes-mouse-arteriolar

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuropathology

Cerebrovascular Diseases

41 Views. Source: Hakim, M. A. et al., Isolation and Functional Analysis of Arteriolar Endothelium of Mouse Brain Parenchyma. J. Vis. Exp. (2022). This video demonstrates the functional analysis of an arteriolar endothelial tube isolated from a mouse brain. It outlines the steps for measuring intracellular calcium levels and membrane potential, both at baseline and in response to pharmacological stimulation. 

Video: Analysis of Calcium Dynamics and Membrane Potential Changes in a Mouse Arteriolar Endothelium - Concept

Isolation of Human Endothelial Cells from Normal Colon and Colorectal Carcinoma - An Improved Protocol

Primary cells isolated from human carcinomas are valuable tools to identify pathogenic mechanisms contributing to disease development and progression. In particular, endothelial cells (EC) constituting the inner surface of vessels, directly participate in oxygen delivery, nutrient supply, and removal of waste products to and from tumors, and are thereby prominently involved in the constitution of the tumor microenvironment (TME). Tumor endothelial cells (TECs) can be used as cellular biosensors of the intratumoral microenvironment established by communication between tumor and stromal cells. TECs also serve as targets of therapy. Accordingly, in culture these cells allow studies on mechanisms of response or resistance to anti-angiogenic treatment. Recently, it was found that TECs isolated from human colorectal carcinoma (CRC) exhibit memory-like effects based on the specific TME they were derived from. Moreover, these TECs actively contribute to the establishment of a specific TME by the secretion of different factors. For example, TECs in a prognostically favorable Th1-TME secrete the anti-angiogenic tumor-suppressive factor secreted protein, acidic and rich in cysteine-like 1 (SPARCL1). SPARCL1 regulates vessel homeostasis and inhibits tumor cell proliferation and migration. Hence, cultures of pure, viable TECs isolated from human solid tumors are a valuable tool for functional studies on the role of the vascular system in tumorigenesis. Here, a new up-to-date protocol for the isolation of primary EC from the normal colon as well as CRC is described. The technique is based on mechanical and enzymatic tissue digestion, immunolabeling, and fluorescence activated cell sorting (FACS)-sorting of triple-positive cells (CD31, VE-cadherin, CD105). With this protocol, viable TEC or normal endothelial cell (NEC) cultures could be isolated from colon tissues with a success rate of 62.12% when subjected to FACS-sorting (41 pure EC cultures from 66 tissue samples). Accordingly, this protocol provides a robust approach to isolate human EC cultures from normal colon and CRC.

Tumor endothelial cells are important determinants of the tumor microenvironment and the course of the disease. Here, a protocol for the isolation of pure and viable endothelial cells from human colorectal carcinoma and normal colon to be used in drug testing and pathogenesis research is described.

Primary cells isolated from human carcinomas are valuable tools to identify pathogenic mechanisms contributing to disease development and progression. In ...

JoVE Journal

Cancer Research

Evaluation of Bioenergetic Function in Cerebral Vascular Endothelial Cells

The integrity of the blood-brain-barrier (BBB) is critical to prevent brain injury. Cerebral vascular endothelial (CVE) cells are one of the cell types that comprise the BBB; these cells have a very high-energy demand, which requires optimal mitochondrial function. In the case of disease or injury, the mitochondrial function in these cells can be altered, resulting in disease or&#160;the opening of the BBB. In this manuscript, we introduce a method to measure mitochondrial function in CVE cells by using whole, intact cells and a bioanalyzer. A mito-stress assay is used to challenge the cells that have been perturbed, either physically or chemically, and evaluate their bioenergetic function. Additionally, this method also provides a useful way to screen new therapeutics that have direct effects on mitochondrial function. We have optimized the cell density necessary to yield oxygen consumption rates that allow for the calculation of a variety of mitochondrial parameters, including ATP production, maximal respiration, and spare capacity. We also show the sensitivity of the assay by demonstrating that the introduction of the&#160;microRNA, miR-34a, leads to a pronounced and detectable decrease in mitochondrial activity. While the data shown in this paper is optimized for the bEnd.3 cell line, we have also optimized the protocol for primary CVE cells, further suggesting the utility in preclinical and clinical models.

Endothelial cell mitochondria are critical to maintain blood-brain-barrier integrity. We introduce a protocol to measure bioenergetic function in cerebral vascular endothelial cells.

The integrity of the blood-brain-barrier (BBB) is critical to prevent brain injury. Cerebral vascular endothelial (CVE) cells are one of the cell types ...

Simultaneous Measurements of Intracellular Calcium and Membrane Potential in Freshly Isolated and Intact Mouse Cerebral Endothelium

Cerebral arteries and their respective microcirculation deliver oxygen and nutrients to the brain via blood flow regulation. Endothelial cells line the lumen of blood vessels and command changes in vascular diameter as needed to meet the metabolic demand of neurons. Primary endothelial-dependent signaling pathways of hyperpolarization of membrane potential (Vm) and nitric oxide typically operate in parallel to mediate vasodilation and thereby increase blood flow. Although integral to coordinating vasodilation over several millimeters of vascular length, components of endothelium-derived hyperpolarization (EDH) have been historically difficult to measure. These components of EDH entail intracellular Ca2+ [Ca2+]i increases and subsequent activation of small- and intermediate conductance Ca2+-activated K+ (SKCa/IKCa) channels.
Here, we present a simplified illustration of the isolation of fresh endothelium from mouse cerebral arteries; simultaneous measurements of endothelial [Ca2+]i and Vm using Fura-2 photometry and intracellular sharp electrodes, respectively; and a continuous superfusion of salt solutions and pharmacological agents under physiological conditions (pH 7.4, 37 &#176;C). Posterior cerebral arteries from the Circle of Willis are removed free of the posterior communicating and the basilar arteries. Enzymatic digestion of cleaned posterior cerebral arterial segments and subsequent trituration facilitates removal of adventitia, perivascular nerves, and smooth muscle cells. Resulting posterior cerebral arterial endothelial &#34;tubes&#34; are then secured under a microscope and examined using a camera, photomultiplier tube, and one to two electrometers while under continuous superfusion. Collectively, this method can simultaneously measure changes in endothelial [Ca2+]i and Vm in discrete cellular locations, in addition to the spreading of EDH through gap junctions up to millimeter distances along the intact endothelium. This method is expected to yield a high-throughput analysis of the cerebral endothelial functions underlying mechanisms of blood flow regulation in the normal and diseased brain.

Demonstrated here are protocols for (1) freshly isolating intact cerebral endothelial "tubes" and (2) simultaneous measurements of endothelial calcium and membrane potential during endothelium-derived hyperpolarization. Further, these methods allow for pharmacological tuning of endothelial cell calcium and electrical signaling as individual or interactive experimental variables.

Cerebral arteries and their respective microcirculation deliver oxygen and nutrients to the brain via blood flow regulation. Endothelial cells line the ...

Analysis of Calcium Dynamics and Membrane Potential Changes in a Mouse Arteriolar Endothelium

Transcript

Analysis of Calcium Dynamics and Membrane Potential Changes in a Mouse Arteriolar Endothelium

Isolation of Human Endothelial Cells from Normal Colon and Colorectal Carcinoma - An Improved Protocol

Evaluation of Bioenergetic Function in Cerebral Vascular Endothelial Cells

Simultaneous Measurements of Intracellular Calcium and Membrane Potential in Freshly Isolated and Intact Mouse Cerebral Endothelium