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All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.
1. Prepare Stem Cells for Editing
<ol>
	<li>Grow and culture human pluripotent stem cells (hPSCs) on a 6-well plate containing 2.4 &#215; 106&#160;cells/plate of mitomycin C-inactivated mouse embryonic fibroblast (MEF) feeders grown on gelatin. Maintain hPSCs in 3 ml of human embryonic stem cell media per well (hESC media) and grow in a 37&#160;&#176;C incubator with 3% O2/5% CO2. 
	NOTE: For the success of this protocol, it is not necessary to maintain hPSCs in a low-oxygen incubator; however it is important to note that hPSCs proliferate faster in a high O2&#160;environment, so times and cell numbers should be adjusted accordingly. It should also be noted that hPSCs maintained in low oxygen have lower rates of spontaneous differentiation.
	<ol>
		<li>To make 500 ml hESC media combine 380 ml DMEM/F12, 75 ml Fetal Bovine Serum (FBS), 25 ml KnockOut Serum Replacement (KSR). Add Glutamine (1 mM final concentration), 5 ml 100x Non-essential Amino Acids, 100 units/ml Penicillin-Streptomycin (P/S), basic Fibroblast Growth Factor (bFGF) (4 ng/ml final concentration), and 2-mercaptoethanol (5.5 &#181;M final concentration).</li>
	</ol>
	</li>
	<li>Change media by removing entire volume of media (3 ml) using a glass pipette and vacuum. Replace with 3 ml warm hESC media using a serological pipette. Repeat media change every day until hPSCs are approximately 50% confluent (Day-1).</li>
	<li>One day before targeting (Day-1), change hESC media, removing the old media and adding warm hESC media supplemented with 10 &#181;M Y-27632.</li>
	<li>Also on Day -1, prepare one to two 6-well or 10 cm plates of drug resistant MEF feeder cells from DR4 mice (2.4 &#215; 106&#160;cells/plate). 
	Note: In general, 6 well plates are advantageous over 10 cm plates, as they accommodate more media. 6 well plates also ensure that different clones from different wells are independent. However, a 10 cm plate will allow easier picking, depending on the microscope available for this process.</li>
</ol>
2. Editing Pluripotent Stem Cells
<ol>
	<li>Prepare transfection solutions by pipetting 5 &#181;g each of ZFN 1 and 2 (Figure 1) into a 1.5 ml tube. Pipette 30 &#181;g of the repair plasmid into this tube as well. Finally, pipette 1x Phosphate Buffered Saline (PBS) into the tube to bring the volume up to 300 &#181;l. 
	NOTE: Prepare plasmids as a midiprep (any kit is suitable) with a minimum concentration of 300 ng/&#181;l in order to keep the total volume of the transfection solution under 300 &#181;l. It is not necessary to perform phenol/chloroform extraction, to linearize the plasmid, or to use an endotoxin free plasmid prep kit.</li>
	<li>Remove media from hPSCs using a glass pipette and vacuum. Pipette 2 ml warm 1x PBS into each well to wash the cells.</li>
	<li>Remove the PBS immediately using a glass pipette and vacuum. Add 0.5 ml 0.25% Trypsin-EDTA solution directly onto cells in each well. Place in the incubator (37 &#176;C/5% CO2/3% O2) for approximately 10 min. or until feeder layer starts to lift off the plate.</li>
	<li>Add 2 ml warm esWash media (470 ml DMEM/F12, 25 ml FBS, 100 units/ml P/S) to each well to stop the trypsin reaction.</li>
	<li>Ensure that feeder cells come off as a sheet. Pipette the contents of each well into a single 50 ml conical tube, combining all wells. Triturate cells using a 10 ml serological pipette. It is not necessary to break up the feeder layer; hPSCs will come off of the feeder layer by gentle trituration. There should be about 15 ml of the cell suspension.</li>
	<li>Add 25 ml of esWash media to the tube to bring the volume up to 40 ml total. Allow large feeder chunks to settle at the bottom of tube for 1-2 min. Remove the supernatant (~38 ml) from the tube using a serological pipette and deposit into a new 50 ml conical tube.</li>
	<li>Spin down for 5 min at 190 x g. Remove the supernatant from the tube using a glass pipette and vacuum. Be sure to not disturb the cell pellet. Resuspend the cells in 500 &#181;l 1x PBS. Combine with plasmid transfection solution prepared earlier. Count the cells at this step. Use 5-10 million cells per electroporation.</li>
	<li>Pipette the entire 800 &#181;l suspension into a 4 mm electroporation cuvette, place on ice for 3-5 min. Electroporate cells using the exponential program on the electroporation system with the following parameters: 250 V, 500 &#181;F, &#8734; resistance, and 4 mm cuvette size. After electroporation, place cuvette back on ice for 3 min. 
	NOTE: Observe the time constant of the electroporation on the electroporation system. The time constant varies with cell number and DNA purity. Successful transfections usually have a time constant between 10-14 msec when using the listed conditions and a gene pulser II. Lower electroporation efficiencies can occur when time constants varies from these values.</li>
	<li>Resuspend electroporated cells in 18 ml warm hESC Media supplemented with 10 &#181;M Y-27632. Plate 3 ml of this single cell suspension into each well of a 6 well plate with DR4 feeder cells. Return to incubator (37 &#176;C/5% CO2/3% O2).</li>
</ol>
3. Selection of Positive Colonies
<ol>
	<li>Day 2, remove all media using a glass pipette and vacuum. Replace with 3 ml of warm hESC media supplemented with 10 &#181;M Y-27632. Day 3, remove all media using a glass pipette and vacuum. Replace with 3 ml of warm hESC media without including Y-27632. Day 4, remove all media using a glass pipette and vacuum. Replace with 3 ml warm hESC media supplemented with antibiotics for selection. Return to incubator (37 &#176;C/5% CO2/3% O2). 
	NOTE: The type of antibiotic used will depend on the resistance cassette included in the repair template. When working with WIBR#3 hPSCs (NIH registry 0079), 0.5 &#181;g/ml puromycin, 70 &#181;g/ml G418 (geneticin), and 35 &#181;g/ml hygromycin have been used successfully. Concentrations for selection should be determined empirically by establishing the minimal concentration of antibiotic needed to kill wild-type cells within approximately one week.</li>
	<li>Days 5-12, change media daily, replacing old media each time with warm hESC media supplemented with antibiotics. 
	NOTE: Expect a large amount of cell death. Individual colonies will become apparent around day 8-10. Regular hESC media without antibiotics can be used after 12-14 days of continuous selection. If cell density is high or cell death is slow, acidification of the media should be avoided and it may be necessary to increase the media volume (up to 4-5 ml) during the first few days of selection.</li>
</ol>

<table><tbody><tr><td>DMEM/F12</td><td>Life Technologies</td><td>11320082</td><td></td></tr><tr><td>Fetal Bovine Serum (HI)</td><td>Life Technologies</td><td>10082-147</td><td></td></tr><tr><td>Knockout Serum</td><td>Life Technologies</td><td>10828-028</td><td></td></tr><tr><td>Fibroblast Growth Factor - basic</td><td>Life Technologies</td><td>PHG0261</td><td></td></tr><tr><td>Pen/Strep</td><td>Life Technologies</td><td>15140-122</td><td></td></tr><tr><td>Glutamine</td><td>Life Technologies</td><td>25030-081</td><td></td></tr><tr><td>MEM NEAA</td><td>Life Technologies</td><td>11140-050</td><td></td></tr><tr><td>2-mercaptoethanol</td><td>Life Technologies</td><td>21985-023</td><td></td></tr><tr><td>Y-27632</td><td>Calbiochem</td><td>688000</td><td></td></tr><tr><td>6-well plates</td><td>Corning</td><td>3506</td><td></td></tr><tr><td>4 mm Electroporation cuvettes</td><td>Bio-rad</td><td>165-2081</td><td></td></tr><tr><td>X-cel gene pulser II</td><td>Bio-rad</td><td>165-2661</td><td></td></tr><tr><td>0.25% Trypsin-EDTA</td><td>Life Technologies</td><td>25200-056</td><td></td></tr><tr><td>10&amp;times; Phosphate buffered saline (PBS) pH7.4</td><td>Life Technologies</td><td>70011-044</td><td></td></tr><tr><td>Puromycin</td><td>Life Technologies</td><td>A11138-02</td><td></td></tr></tbody></table>

zinc finger nuclease-based genome editing: a technique for modifying genome in human pluripotent stem cells by double-stranded homology dependant repair mechanism

Source: Blair, J. D., et al. <a href="https://www.jove.com/v/53583">Establishment of Genome-edited Human Pluripotent Stem Cell Lines: From Targeting to Isolation.</a> J. Vis. Exp. (2016).
This video demonstrates a technique of zinc-finger nuclease-based genome editing in human pluripotent stem cells (hPSCs). As hPSCs can potentially be differentiated into various cell types, this technology is helpful for in vitro pathological and pharmacological studies in a patient-specific manner.

<img alt="Figure 1" src="/files/ftp_upload/20972/20972_Figure1.jpg" /> 
Figure 1. Schematic of gene edited AAVS1 locus using the AAV-CAGGS-EGFP repair template. Modified from Hockemeyer et al., 2009.

Zinc Finger Nuclease-Based Genome Editing: A Technique for Modifying Genome in Human Pluripotent Stem Cells by Double-Stranded Homology Dependant Repair Mechanism

Source: Blair, J. D., et al. Establishment of Genome-edited Human Pluripotent Stem Cell Lines: From Targeting to Isolation. J. Vis. Exp. (2016).
This ...

The zinc finger nuclease or ZFN contains a zinc-ion stabilized, DNA-binding macro-domain connected to an endonuclease domain via a linker. This structure helps maintain specificity while cutting DNA.
To use ZFNs for genome editing, take a culture of human pluripotent stem cells. Supplement it with a plasmid encoding ZFN. Add a repair plasmid containing the target gene and the antibiotic resistance gene sandwiched between homology arms or HAs. Electroporate the cell-DNA mixture where the electric current facilitates the entry of plasmids inside the cell.
Once inside, the zinc finger motifs of translated ZFN bind to the triplets of complementary base pairs in the host genome, correctly positioning the Fok-1 restriction endonuclease at the target site. ZFNs bind to opposite strands in pairs allowing Fok-1 homodimerization to form an active catalytic center in which Fok-1 generates DNA double-stranded breaks or DSBs, producing a four-nucleotide overhang.
The presence of HAs in repair plasmid guides the homology-dependent repair where the overhanging end inverts and uses the homologous HA sequence as a template. The DNA synthesis continues by adding nucleotides complementary to the target gene.
The resulting gaps are ligated, facilitating gene insertion. Additionally, the promoterless antibiotic resistance gene is expressed from a host promoter upstream of the insertion site. Successfully edited cells grow in the antibiotic selection medium.

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Research

JoVE Encyclopedia of Experiments

Biological Techniques

Genome Editing Techniques

Gene knock-in

1.4K ビュー. 出典:Blair, J. D., et al.ゲノム編集ヒト多能性幹細胞株の確立:ターゲティングから単離まで。J. Vis. Exp.(2016年)。 このビデオでは、ヒト多能性幹細胞(hPSC)におけるジンクフィンガーヌクレアーゼベースのゲノム編集の技術を示しています。hPSCはさまざまな細胞タイプに分化できる可能性があるため、この技術は患者固有の方法でin vitroの病理学的および薬理学的研究に役立ち?...

ビデオ: Zinc Finger Nuclease-Based Genome Editing:二本鎖ホモロジー依存性修復機構によるヒト多能性幹細胞のゲノム改変技術 - 概念

CRISPR/Cas9-mediated Targeted Integration In Vivo Using a Homology-mediated End Joining-based Strategy

As a promising genome editing platform, the CRISPR/Cas9 system has great potential for efficient genetic manipulation, especially for targeted integration of transgenes. However, due to the low efficiency of homologous recombination (HR) and various indel mutations of non-homologous end joining (NHEJ)-based strategies in non-dividing cells, in vivo genome editing remains a great challenge. Here, we describe a homology-mediated end joining (HMEJ)-based CRISPR/Cas9 system for efficient in vivo precise targeted integration. In this system, the targeted genome and the donor vector containing homology arms (~800 bp) flanked by single guide RNA (sgRNA) target sequences are cleaved by CRISPR/Cas9. This HMEJ-based strategy achieves efficient transgene integration in mouse zygotes, as well as in hepatocytes in vivo. Moreover, a HMEJ-based strategy offers an efficient approach for correction of fumarylacetoacetate hydrolase (Fah) mutation in the hepatocytes and rescues Fah-deficiency induced liver failure mice. Taken together, focusing on targeted integration, this HMEJ-based strategy provides a promising tool for a variety of applications, including generation of genetically modified animal models and targeted gene therapies.

CRISPR/Cas9-mediated Targeted Integration In Vivo Using a Homology-mediated End Joining-based Strategy

The clustered regularly interspaced short palindromic repeats/CRISPR associated protein 9 (CRISPR/Cas9) system provides a promising tool for genetic engineering, and opens up the possibility of targeted integration of transgenes. We describe a homology-mediated end joining (HMEJ)-based strategy for efficient DNA targeted integration in vivo and targeted gene therapies using CRISPR/Cas9.

CRISPR/Cas9 仲介の対象となる統合生体内で相同性を介した終わり参加ベースの戦略を使用して

As a promising genome editing platform, the CRISPR/Cas9 system has great potential for efficient genetic manipulation, especially for targeted integration ...

JoVE Journal

遺伝学

Rapid and Efficient Generation of Recombinant Human Pluripotent Stem Cells by Recombinase-mediated Cassette Exchange in the AAVS1 Locus

Even with the revolution of gene-targeting technologies led by CRISPR-Cas9, genetic modification of human pluripotent stem cells&#160;(hPSCs)&#160;is still time consuming. Comparative studies that use recombinant lines with transgenes integrated into safe harbor loci could benefit from approaches that use site-specific targeted recombinases, like Cre or FLPe, which are more rapid and less prone to off-target effects. Such methods have been described, although they do not significantly outperform gene targeting in most aspects. Using Zinc-finger nucleases, we previously created a master cell line in the AAVS1 locus of hPSCs&#160;that contains a GFP-Hygromycin-tk expressing cassette, flanked by heterotypic FRT sequences. Here, we describe the procedures to perform FLPe recombinase-mediated cassette exchange (RMCE) using this line. The master cell line is transfected with a RMCE donor vector, which contains a promoterless Puromycin resistance, and with FLPe recombinase. Application of both a positive (Puromycin) and negative (FIAU) selection program leads to the selection of RMCE without random integrations. RMCE generates fully characterized pluripotent polyclonal transgenic lines in 15 d&#160;with 100% efficiency. Despite the recently described limitations of the AAVS1 locus, the ease of the system paves the way for hPSC transgenesis in isogenic settings, is necessary for comparative studies, and enables semi-high-throughput genetic screens for gain/loss of function analysis that would otherwise be highly time consuming.

Rapid and Efficient Generation of Recombinant Human Pluripotent Stem Cells by Recombinase-mediated Cassette Exchange in the AAVS1 Locus

Here we report a rapid and efficient gene editing method based on RMCE in the AAVS1 locus of human Pluripotent Stem Cells (hPSCs) that improves upon previously described systems. Using this technique, isogenic lines can be rapidly and reliably generated for proper comparative studies, facilitating transgenesis-mediated research with hPSCs.

中リコンビナーゼ媒介カセット交換による組換えヒト多能性幹細胞の迅速かつ効率的な生成<em&gt; AAVS1</em&gt;軌跡

Even with the revolution of gene-targeting technologies led by CRISPR-Cas9, genetic modification of human pluripotent stem cells&#160;(hPSCs)&#160;is ...

医学

Direct Protein Delivery to Mammalian Cells Using Cell-permeable Cys2-His2 Zinc-finger Domains

Due to their modularity and ability to be reprogrammed to recognize a wide range of DNA sequences, Cys2-His2 zinc-finger DNA-binding domains have emerged as useful tools for targeted genome engineering. Like many other DNA-binding proteins, zinc-fingers also possess the innate ability to cross cell membranes. We recently demonstrated that this intrinsic cell-permeability could be leveraged for intracellular protein delivery. Genetic fusion of zinc-finger motifs leads to efficient transport of protein and enzyme cargo into a broad range of mammalian cell types. Unlike other protein transduction technologies, delivery via zinc-finger domains does not inhibit enzyme activity and leads to high levels of cytosolic delivery. Here a detailed step-by-step protocol is presented for the implementation of zinc-finger technology for protein delivery into mammalian cells. Key steps for achieving high levels of intracellular zinc-finger-mediated delivery are highlighted and strategies for maximizing the performance of this system are discussed.

Direct Protein Delivery to Mammalian Cells Using Cell-permeable Cys2-His2 Zinc-finger Domains

Zinc-finger domains are intrinsically cell-permeable and capable of mediating protein delivery into a broad range of mammalian cell types. Here, a detailed step-by-step protocol for implementing zinc-finger technology for intracellular protein delivery is presented.

細胞透過性のCysを用いて哺乳動物細胞への直接タンパク質送達<sub&gt; 2</sub&gt; -His<sub&gt; 2</sub&gt;ジンクフィンガードメイン

Due to their modularity and ability to be reprogrammed to recognize a wide range of DNA sequences, Cys2-His2 zinc-finger DNA-binding domains have emerged ...

Zinc Finger Nuclease-Based Genome Editing: A Technique for Modifying Genome in Human Pluripotent Stem Cells by Double-Stranded Homology Dependant Repair Mechanism

記録

Zinc Finger Nuclease-Based Genome Editing: A Technique for Modifying Genome in Human Pluripotent Stem Cells by Double-Stranded Homology Dependant Repair Mechanism