eoe sub articles

EoE Sub Articles

1. Growth Inhibition High-Throughput Screening (HTS)
NOTE: The growth inhibitory activity of anticancer agents against patient-derived tumor organoids (PDOs) is evaluated by measuring the intracellular ATP content, as shown in Figure 1. This step is performed using a commercially available cell viability assay kit (see Table of Materials).
<ol>
	<li>On day 0, culture the PDOs (e.g., RLUN007) in flasks until adequate numbers of cell clusters are available for the assay. One day before seeding, transfer the PDO suspension from a 75 cm2 flask to a 15 mL tube and centrifuge at 200 x g for 2 min to measure the PDO pellet volume. Then, resuspend the PDO pellet in 15 mL of fresh medium and transfer it back to a 75 cm2 flask. Culture the cells at 37 &#176;C in 5% CO2. 
	NOTE: The required PDO pellet volume depends on each PDO&#39;s dilution rate and the number of 384-well plates used for the assay. For RLUN007, a 200 &#181;L of cell pellet volume is necessary for seeding into ten 384-well plates.</li>
	<li>On day 1 (24 h after changing the medium), mince the PDOs using cell fragmentation and dispersion equipment (see Table of Materials) with a filter holder containing a 70 &#181;m mesh filter. Then, dilute 15 mL of the PDO suspension by 10x. Seed 40 &#181;L of the PDO suspension into 384-well ultra-low attachment spheroid (round-bottom) microplates (see Table of Materials) using a cell suspension dispenser (see Table of Materials). 
	NOTE: For mincing cell clusters, it is recommended to use the commercially available cell fragmentation and dispersion equipment (see Table of Materials).</li>
	<li>At 24 h after seeding (day 2), treat the PDOs with 0.04 &#181;L of test agent solutions at final concentration ranges of 20 &#181;M to 1.0 nM (10 serial dilutions) using a liquid handler (see Table of Materials).</li>
	<li>On day 8 (144 h after test substance treatment), add intracellular ATP measuring reagent to the test wells. Mix the plates using a mixer and incubate for 10 min at 25 &#176;C. Measure the intracellular ATP content as luminescence using a plate reader (see Table of Materials).</li>
	<li>To calculate the cell viability, divide the quantity of ATP in the test wells by that in the control wells containing the vehicle, with the background subtracted. To calculate the growth rate over 6 days, divide the quantity of ATP in the vehicle control wells by that in the vehicle control wells 24 h after seeding.</li>
	<li>Calculate the 50% inhibitory concentration (IC50) and area under the curve (AUC) values from the dose-response curves using biological data analysis software (see Table of Materials). The Z factor is a dimensionless parameter that ranges from 1 (infinite separation) to &#60;0, defined as Z = 1 - (3&#963;c+ + 3&#963;c-) / |&#181;c+ - &#181;c-|, where &#963;c+, &#963;c-, &#181;c+, and &#181;c- are the standard deviations (&#963;) and averages (&#181;) of the high (c+) and low (c&#8722;) controls, respectively.</li>
</ol>

<table><tbody><tr><td>384-well Ultra-Low Attachment Spheroid Microplate</td><td>Corning</td><td>4516</td><td>Plates for HTS</td></tr><tr><td>Cancer Cell Expansion Media plus</td><td>Fujifilm Wako Pure Chemical</td><td>032-25745</td><td>Medium for F-PDO</td></tr><tr><td>CellPet FT</td><td>JTEC</td><td>-</td><td>Cell fragmentation and dispersion equipment</td></tr><tr><td>CellTiter-Glo 3D Cell Viability Assay</td><td>Promega</td><td>G9683</td><td>Cell viability luminescent assay, intracellular ATP measuring reagent</td></tr><tr><td>Echo 555</td><td>Labcyte</td><td>-</td><td>Liquid handler</td></tr><tr><td>EnSpire</td><td>PerkinElmer</td><td>-</td><td>Plate reader</td></tr><tr><td>Morphit software, version 6.0</td><td>The Edge Software Consultancy</td><td></td><td>Biological data analysis software</td></tr><tr><td>Multidrop Combi</td><td>ThermoFisher Scientific</td><td>5840300</td><td>Cell suspension dispenser</td></tr><tr><td>RLUN007</td><td>Fujifilm Wako Pure Chemical or Summit Pharmaceuticals International</td><td></td><td>Lung tumor derived F-PDO</td></tr><tr><td>Ultra-Low Attachment 75 cm&amp;sup2; Flask</td><td>Corning</td><td>3814</td><td>Culture flask for PDO</td></tr></tbody></table>

atp-based luciferase viability assay: a homogenous method to evaluate the growth-inhibitory potential of test agents on tumor organoids

Source: Higa, A. et al. <a href="https://app.jove.com/v/62668">High-Throughput In Vitro Assay using Patient-Derived Tumor Organoids.</a> J. Vis. Exp. (2021)
In this video, we demonstrate a rapid, single-addition assay to assess cell viability in patient-derived organoids upon treatment with a test agent using intracellular ATP levels as a marker for cellular metabolic activity. The intracellular ATP levels are measured using the luciferase/luciferin reaction, where the emitted light intensity indicates the cellular viability and, in turn, the test agent&#39;s growth-inhibitory potency.

<img alt="Figure 1" src="/files/ftp_upload/21218/21218_Figure1.jpg" /> 
Figure 1: Summary of the protocol used to create a high-throughput assay system using 384-well microplates.

ATP-Based Luciferase Viability Assay: A Homogenous Method to Evaluate the Growth-Inhibitory Potential of Test Agents on Tumor Organoids

Source: Higa, A. et al. High-Throughput In Vitro Assay using Patient-Derived Tumor Organoids. J. Vis. Exp. (2021)
In this video, we demonstrate a rapid, ...

Adenosine triphosphate, ATP, the primary cell energy source, is vital for diverse cellular functions. Under stress, intracellular ATP levels are negatively impacted, making ATP a good marker for metabolically active, viable cells.
To begin, seed tumor cell suspension into a black-walled, clear-bottom microplate for minimal light scattering during light intensity measurement. The microplate consists of a hydrogel coating that prevents cells from adhering to the plate, enabling cell-to-cell interaction and self-assembly into tumor organoids - three-dimensional tissue cultures that mimic tumor microenvironment.
Next, treat with a test compound. The test compound interacts with the organoid cells and, depending on its growth-inhibitory potential, may disrupt the energy-producing metabolic processes, resulting in intracellular ATP depletion.
Post-treatment, add a one-step reagent comprising detergents, ATPase inhibitors, the enzyme luciferase, luciferase-specific substrate, luciferin, and magnesium ions. Incubate for the desired duration.
The detergent solubilizes the cellular membranes, causing cell lysis and ATP extraction into solution, while the ATPase inhibitors inactivate any released endogenous ATPases, stabilizing ATP.
Following its extraction, ATP, in the presence of magnesium ions, facilitates luciferin to bind to luciferase, which oxidizes luciferin into high-energy oxyluciferin that upon relaxation, generates a bioluminescent photon.
Using a luminometer, measure the light intensity produced by the photons, representative of intracellular ATP concentration. Lower amounts of ATP indicate lower cell viability, suggesting higher growth-inhibitory potential of the test compound.

atp-based-luciferase-viability-assay-homogenous-method-to-evaluate

Research

JoVE Encyclopedia of Experiments

Biological Techniques

Assay Techniques

Cell-based assays

193 次观看. 来源:Higa， A. et al.使用患者来源的肿瘤类器官进行高通量体外检测。J. Vis. Exp.（2021 年） 在本视频中，我们演示了一种快速的单次添加测定法，以评估使用细胞内 ATP 水平作为细胞代谢活性标志物的测试剂处理后患者来源的类器官中的细胞活力。使用荧光素酶/荧光素反应测量细胞内 ATP 水平，其中发射的光强度表示细胞活力，进而表示测试剂的生长抑制效力。 

视频: 基于 ATP 的荧光素酶活力测定:一种评估测试剂对肿瘤类器官生长抑制潜力的均相方法 - 概念

A Rapid Filter Insert-based 3D Culture System for Primary Prostate Cell Differentiation

Conditionally reprogrammed cells (CRCs) provide a sustainable method for primary cell culture and the ability to develop extensive &#34;living biobanks&#34; of patient derived cell lines. For many types of epithelial cells, various three dimensional (3D) culture approaches have been described that support an improved differentiated state. While CRCs retain their lineage commitment to the tissue from which they are isolated, they fail to express many of the differentiation markers associated with the tissue of origin when grown under normal two dimensional (2D) culture conditions. To enhance the application of patient-derived CRCs for prostate cancer research, a 3D culture format has been defined that enables a rapid (2 weeks total) luminal cell differentiation in both normal and tumor-derived prostate epithelial cells. Herein, a filter insert-based format is described for the culturing and differentiation of both normal and malignant prostate CRCs. A detailed description of the procedures required for cell collection and processing for immunohistochemical and immunofluorescent staining are provided. Collectively the 3D culture format described, combined with the primary CRC lines, provides an important medium- to high- throughput model system for biospecimen-based prostate research.

Here, we present a method for the establishment of a rapid in vitro system that supports the three dimensional culturing and subsequent luminal differentiation of primary prostate epithelial cells.

基于插入 - 滤池3D文化系统原发性前列腺细胞分化

Conditionally reprogrammed cells (CRCs) provide a sustainable method for primary cell culture and the ability to develop extensive &#34;living ...

科研

JoVE Journal

癌症研究

Prostate Organoid Cultures as Tools to Translate Genotypes and Mutational Profiles to Pharmacological Responses

Presented here is a protocol to study pharmacodynamics, stem cell potential, and cancer differentiation in prostate epithelial organoids. Prostate organoids are androgen responsive, three-dimensional (3D) cultures grown in a defined medium that resembles the prostatic epithelium. Prostate organoids can be established from wild-type and genetically engineered mouse models, benign human tissue, and advanced prostate cancer. Importantly, patient derived organoids closely resemble tumors in genetics and in vivo tumor biology. Moreover, organoids can be genetically manipulated using CRISPR/Cas9 and shRNA systems. These controlled genetics make the organoid culture attractive as a platform for rapidly testing the effects of genotypes and mutational profiles on pharmacological responses. However, experimental protocols must be specifically adapted to the 3D nature of organoid cultures to obtain reproducible results. Described here are detailed protocols for performing seeding assays to determine organoid formation capacity. Subsequently, this report shows how to perform drug treatments and analyze pharmacological response via viability measurements, protein isolation, and RNA isolation. Finally, the protocol describes how to prepare organoids for xenografting and subsequent in vivo growth assays using subcutaneous grafting. These protocols yield highly reproducible data and are widely applicable to 3D culture systems.

Presented here is a protocol to study pharmacological responses in prostate epithelial organoids. Organoids closely resemble in vivo biology and recapitulate patient genetics, making them attractive model systems. Prostate organoids can be established from wildtype prostates, genetically engineered mouse models, benign human tissue, and advanced prostate cancer.

前列腺有机体培养作为工具，将基因型和突变谱转化为药理反应

Presented here is a protocol to study pharmacodynamics, stem cell potential, and cancer differentiation in prostate epithelial organoids. Prostate ...

Culture, Manipulation, and Orthotopic Transplantation of Mouse Bladder Tumor Organoids

The development of advanced tumor models has long been encouraged because current cancer models have shown limitations such as lack of three-dimensional (3D) tumor architecture and low relevance to human cancer. Researchers have recently developed a 3D in vitro cancer model referred to as tumor organoids that can mimic the characteristics of a native tumor in a culture dish. Here, experimental procedures are described in detail for the establishment of bladder tumor organoids from a carcinogen-induced murine bladder tumor, including culture, passage, and maintenance of the resulting 3D tumor organoids in vitro. In addition, protocols to manipulate the established bladder tumor organoid lines for genetic engineering using lentivirus-mediated transduction are described, including optimized conditions for the efficient introduction of new genetic elements into tumor organoids. Finally, the procedure for orthotopic transplantation of bladder tumor organoids into the wall of the murine bladder for further analysis is laid out. The methods described in this article can facilitate the establishment of an in vitro model for bladder cancer for the development of better therapeutic options.

This protocol provides detailed experimental steps to establish a three-dimensional in vitro culture of bladder tumor organoids derived from carcinogen-induced murine bladder cancer. Culture methods including passaging, genetic engineering, and orthotopic transplantation of tumor organoids are described.

小鼠膀胱肿瘤器官的培养、操作和正交移植

The development of advanced tumor models has long been encouraged because current cancer models have shown limitations such as lack of three-dimensional ...

ATP-Based Luciferase Viability Assay: A Homogenous Method to Evaluate the Growth-Inhibitory Potential of Test Agents on Tumor Organoids

成績單

ATP-Based Luciferase Viability Assay: A Homogenous Method to Evaluate the Growth-Inhibitory Potential of Test Agents on Tumor Organoids