Your search keyword '"Willis, Brandon J"' showing total 17 results

1. Impact of essential genes on the success of genome editing experiments generating 3313 new genetically engineered mouse lines

Author

Elrick, Hillary, Peterson, Kevin A., Willis, Brandon J., Lanza, Denise G., Acar, Elif F., Ryder, Edward J., Teboul, Lydia, Kasparek, Petr, Birling, Marie-Christine, Adams, David J., Bradley, Allan, Braun, Robert E., Brown, Steve D., Caulder, Adam, Codner, Gemma F., DeMayo, Francesco J., Dickinson, Mary E., Doe, Brendan, Duddy, Graham, Gertsenstein, Marina, Goodwin, Leslie O., Hérault, Yann, Lintott, Lauri G., Lloyd, K. C. Kent, Lorenzo, Isabel, Mackenzie, Matthew, Mallon, Ann-Marie, McKerlie, Colin, Parkinson, Helen, Ramirez-Solis, Ramiro, Seavitt, John R., Sedlacek, Radislav, Skarnes, William C., Smedley, Damien, Wells, Sara, White, Jacqueline K., Wood, Joshua A., Murray, Stephen A., Heaney, Jason D., and Nutter, Lauryl M. J.

Published

2024

2. Whole genome analysis for 163 gRNAs in Cas9-edited mice reveals minimal off-target activity

Author

Peterson, Kevin A, Khalouei, Sam, Hanafi, Nour, Wood, Joshua A, Lanza, Denise G, Lintott, Lauri G, Willis, Brandon J, Seavitt, John R, Braun, Robert E, Dickinson, Mary E, White, Jacqueline K, Lloyd, KC Kent, Heaney, Jason D, Murray, Stephen A, Ramani, Arun, and Nutter, Lauryl MJ

Subjects

Biological Sciences, Genetics, Human Genome, Biotechnology, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Generic health relevance, Mice, Animals, CRISPR-Cas Systems, Gene Editing, Genome, Mutation, Mutagenesis, Biological sciences, Biomedical and clinical sciences

Abstract

Genome editing with CRISPR-associated (Cas) proteins holds exceptional promise for "correcting" variants causing genetic disease. To realize this promise, off-target genomic changes cannot occur during the editing process. Here, we use whole genome sequencing to compare the genomes of 50 Cas9-edited founder mice to 28 untreated control mice to assess the occurrence of S. pyogenes Cas9-induced off-target mutagenesis. Computational analysis of whole-genome sequencing data detects 26 unique sequence variants at 23 predicted off-target sites for 18/163 guides used. While computationally detected variants are identified in 30% (15/50) of Cas9 gene-edited founder animals, only 38% (10/26) of the variants in 8/15 founders validate by Sanger sequencing. In vitro assays for Cas9 off-target activity identify only two unpredicted off-target sites present in genome sequencing data. In total, only 4.9% (8/163) of guides tested have detectable off-target activity, a rate of 0.2 Cas9 off-target mutations per founder analyzed. In comparison, we observe ~1,100 unique variants in each mouse regardless of genome exposure to Cas9 indicating off-target variants comprise a small fraction of genetic heterogeneity in Cas9-edited mice. These findings will inform future design and use of Cas9-edited animal models as well as provide context for evaluating off-target potential in genetically diverse patient populations.

Published

2023

3. A resource of targeted mutant mouse lines for 5,061 genes

Author

Birling, Marie-Christine, Yoshiki, Atsushi, Adams, David J, Ayabe, Shinya, Beaudet, Arthur L, Bottomley, Joanna, Bradley, Allan, Brown, Steve DM, Bürger, Antje, Bushell, Wendy, Chiani, Francesco, Chin, Hsian-Jean Genie, Christou, Skevoulla, Codner, Gemma F, DeMayo, Francesco J, Dickinson, Mary E, Doe, Brendan, Donahue, Leah Rae, Fray, Martin D, Gambadoro, Alessia, Gao, Xiang, Gertsenstein, Marina, Gomez-Segura, Alba, Goodwin, Leslie O, Heaney, Jason D, Hérault, Yann, de Angelis, Martin Hrabe, Jiang, Si-Tse, Justice, Monica J, Kasparek, Petr, King, Ruairidh E, Kühn, Ralf, Lee, Ho, Lee, Young Jae, Liu, Zhiwei, Lloyd, KC Kent, Lorenzo, Isabel, Mallon, Ann-Marie, McKerlie, Colin, Meehan, Terrence F, Fuentes, Violeta Munoz, Newman, Stuart, Nutter, Lauryl MJ, Oh, Goo Taeg, Pavlovic, Guillaume, Ramirez-Solis, Ramiro, Rosen, Barry, Ryder, Edward J, Santos, Luis A, Schick, Joel, Seavitt, John R, Sedlacek, Radislav, Seisenberger, Claudia, Seong, Je Kyung, Skarnes, William C, Sorg, Tania, Steel, Karen P, Tamura, Masaru, Tocchini-Valentini, Glauco P, Wang, Chi-Kuang Leo, Wardle-Jones, Hannah, Wattenhofer-Donzé, Marie, Wells, Sara, Wiles, Michael V, Willis, Brandon J, Wood, Joshua A, Wurst, Wolfgang, Xu, Ying, Teboul, Lydia, and Murray, Stephen A

Subjects

Biological Sciences, Genetics, Infectious Diseases, Biotechnology, 2.1 Biological and endogenous factors, Animals, Gene Deletion, Genetic Association Studies, Genome, Genotype, Information Dissemination, International Cooperation, Internet, Mice, Mice, Knockout, Mouse Embryonic Stem Cells, Mutagenesis, Phenotype, International Mouse Phenotyping Consortium, Medical and Health Sciences, Developmental Biology, Agricultural biotechnology, Bioinformatics and computational biology

Abstract

The International Mouse Phenotyping Consortium reports the generation of new mouse mutant strains for over 5,000 genes, including 2,850 novel null, 2,987 novel conditional- ready, and 4,433 novel reporter alleles.

Published

2021

4. Generation of desminopathy in rats using CRISPR‐Cas9

Author

Langer, Henning T, Mossakowski, Agata A, Willis, Brandon J, Grimsrud, Kristin N, Wood, Joshua A, Lloyd, Kevin CK, Zbinden‐Foncea, Hermann, and Baar, Keith

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Genetics, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Animals, CRISPR-Cas Systems, Desmin, Dystrophin, Male, Mice, Muscular Diseases, Mutation, Rats, Precision medicine, Muscular dystrophy, Injury, Exercise, Force transfer, Physiology, Clinical Sciences, Human Movement and Sports Sciences, Clinical sciences, Allied health and rehabilitation science, Sports science and exercise

Abstract

BackgroundDesminopathy is a clinically heterogeneous muscle disease caused by over 60 different mutations in desmin. The most common mutation with a clinical phenotype in humans is an exchange of arginine to proline at position 350 of desmin leading to p.R350P. We created the first CRISPR-Cas9 engineered rat model for a muscle disease by mirroring the R350P mutation in humans.MethodsUsing CRISPR-Cas9 technology, Des c.1045-1046 (AGG > CCG) was introduced into exon 6 of the rat genome causing p.R349P. The genotype of each animal was confirmed via quantitative PCR. Six male rats with a mutation in desmin (n = 6) between the age of 120-150 days and an equal number of wild type littermates (n = 6) were used for experiments. Maximal plantar flexion force was measured in vivo and combined with the collection of muscle weights, immunoblotting, and histological analysis. In addition to the baseline phenotyping, we performed a synergist ablation study in the same animals.ResultsWe found a difference in the number of central nuclei between desmin mutants (1 ± 0.4%) and wild type littermates (0.2 ± 0.1%; P

Published

2020

5. Reproducibility of CRISPR-Cas9 methods for generation of conditional mouse alleles: a multi-center evaluation

Author

Gurumurthy, Channabasavaiah B, O’Brien, Aidan R, Quadros, Rolen M, Adams, John, Alcaide, Pilar, Ayabe, Shinya, Ballard, Johnathan, Batra, Surinder K, Beauchamp, Marie-Claude, Becker, Kathleen A, Bernas, Guillaume, Brough, David, Carrillo-Salinas, Francisco, Chan, Wesley, Chen, Hanying, Dawson, Ruby, DeMambro, Victoria, D’Hont, Jinke, Dibb, Katharine M, Eudy, James D, Gan, Lin, Gao, Jing, Gonzales, Amy, Guntur, Anyonya R, Guo, Huiping, Harms, Donald W, Harrington, Anne, Hentges, Kathryn E, Humphreys, Neil, Imai, Shiho, Ishii, Hideshi, Iwama, Mizuho, Jonasch, Eric, Karolak, Michelle, Keavney, Bernard, Khin, Nay-Chi, Konno, Masamitsu, Kotani, Yuko, Kunihiro, Yayoi, Lakshmanan, Imayavaramban, Larochelle, Catherine, Lawrence, Catherine B, Li, Lin, Lindner, Volkhard, Liu, Xian-De, Lopez-Castejon, Gloria, Loudon, Andrew, Lowe, Jenna, Jerome-Majewska, Loydie A, Matsusaka, Taiji, Miura, Hiromi, Miyasaka, Yoshiki, Morpurgo, Benjamin, Motyl, Katherine, Nabeshima, Yo-ichi, Nakade, Koji, Nakashiba, Toshiaki, Nakashima, Kenichi, Obata, Yuichi, Ogiwara, Sanae, Ouellet, Mariette, Oxburgh, Leif, Piltz, Sandra, Pinz, Ilka, Ponnusamy, Moorthy P, Ray, David, Redder, Ronald J, Rosen, Clifford J, Ross, Nikki, Ruhe, Mark T, Ryzhova, Larisa, Salvador, Ane M, Alam, Sabrina Shameen, Sedlacek, Radislav, Sharma, Karan, Smith, Chad, Staes, Katrien, Starrs, Lora, Sugiyama, Fumihiro, Takahashi, Satoru, Tanaka, Tomohiro, Trafford, Andrew W, Uno, Yoshihiro, Vanhoutte, Leen, Vanrockeghem, Frederique, Willis, Brandon J, Wright, Christian S, Yamauchi, Yuko, Yi, Xin, Yoshimi, Kazuto, Zhang, Xuesong, Zhang, Yu, Ohtsuka, Masato, Das, Satyabrata, Garry, Daniel J, Hochepied, Tino, Thomas, Paul, Parker-Thornburg, Jan, Adamson, Antony D, and Yoshiki, Atsushi

Subjects

Biological Sciences, Genetics, Biotechnology, Alleles, Animals, Blastocyst, CRISPR-Associated Protein 9, CRISPR-Cas Systems, Factor Analysis, Statistical, Female, Male, Methyl-CpG-Binding Protein 2, Mice, Knockout, Microinjections, Regression Analysis, Reproducibility of Results, CRISPR-Cas9, Mouse, Transgenesis, Homology-directed repair, Conditional knockout mouse, Floxed allele, Oligonucleotide, Long single-stranded DNA, Machine learning, Reproducibility, Environmental Sciences, Information and Computing Sciences, Bioinformatics

Abstract

BackgroundCRISPR-Cas9 gene-editing technology has facilitated the generation of knockout mice, providing an alternative to cumbersome and time-consuming traditional embryonic stem cell-based methods. An earlier study reported up to 16% efficiency in generating conditional knockout (cKO or floxed) alleles by microinjection of 2 single guide RNAs (sgRNA) and 2 single-stranded oligonucleotides as donors (referred herein as "two-donor floxing" method).ResultsWe re-evaluate the two-donor method from a consortium of 20 laboratories across the world. The dataset constitutes 56 genetic loci, 17,887 zygotes, and 1718 live-born mice, of which only 15 (0.87%) mice contain cKO alleles. We subject the dataset to statistical analyses and a machine learning algorithm, which reveals that none of the factors analyzed was predictive for the success of this method. We test some of the newer methods that use one-donor DNA on 18 loci for which the two-donor approach failed to produce cKO alleles. We find that the one-donor methods are 10- to 20-fold more efficient than the two-donor approach.ConclusionWe propose that the two-donor method lacks efficiency because it relies on two simultaneous recombination events in cis, an outcome that is dwarfed by pervasive accompanying undesired editing events. The methods that use one-donor DNA are fairly efficient as they rely on only one recombination event, and the probability of correct insertion of the donor cassette without unanticipated mutational events is much higher. Therefore, one-donor methods offer higher efficiencies for the routine generation of cKO animal models.

Published

2019

6. Efficient mouse genome engineering by CRISPR-EZ technology

Author

Modzelewski, Andrew J, Chen, Sean, Willis, Brandon J, Lloyd, KC Kent, Wood, Joshua A, and He, Lin

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Human Genome, Biotechnology, Genetics, Animals, CRISPR-Associated Protein 9, Clustered Regularly Interspaced Short Palindromic Repeats, Electroporation, Gene Editing, Mice, Mice, Inbred C57BL, Mice, Knockout, Microinjections, Zygote, Chemical Sciences, Medical and Health Sciences, Bioinformatics

Abstract

CRISPR/Cas9 technology has transformed mouse genome editing with unprecedented precision, efficiency, and ease; however, the current practice of microinjecting CRISPR reagents into pronuclear-stage embryos remains rate-limiting. We thus developed CRISPR ribonucleoprotein (RNP) electroporation of zygotes (CRISPR-EZ), an electroporation-based technology that outperforms pronuclear and cytoplasmic microinjection in efficiency, simplicity, cost, and throughput. In C57BL/6J and C57BL/6N mouse strains, CRISPR-EZ achieves 100% delivery of Cas9/single-guide RNA (sgRNA) RNPs, facilitating indel mutations (insertions or deletions), exon deletions, point mutations, and small insertions. In a side-by-side comparison in the high-throughput KnockOut Mouse Project (KOMP) pipeline, CRISPR-EZ consistently outperformed microinjection. Here, we provide an optimized protocol covering sgRNA synthesis, embryo collection, RNP electroporation, mouse generation, and genotyping strategies. Using CRISPR-EZ, a graduate-level researcher with basic embryo-manipulation skills can obtain genetically modified mice in 6 weeks. Altogether, CRISPR-EZ is a simple, economic, efficient, and high-throughput technology that is potentially applicable to other mammalian species.

Published

2018

7. Rescue of germline transmission from chimeras by IVF after sperm analysis

Author

Li, Ming-Wen, Willis, Brandon J, Evans, Kristin D, Araiza, Renee S, Lee, Angus Yiu-Fai, and Lloyd, KC Kent

Subjects

Biochemistry and Cell Biology, Biological Sciences, Infertility, Contraception/Reproduction, Genetics, Biotechnology, Reproductive health and childbirth, Animals, Animals, Genetically Modified, Chimera, Embryo, Mammalian, Embryonic Stem Cells, Fertilization in Vitro, Genotype, Germ Cells, Male, Mice, Spermatogenesis, Spermatozoa, Technology, Plant Biology & Botany, Biological sciences

Abstract

Successful production of genetically modified mouse lines is dependent on germline transmission (GLT) of mutant alleles from chimeras. When natural mating fails to achieve GLT due to male infertility, sickness, or other problems, sperm can be harvested from chimeras and used for assisted reproductive technologies such as in vitro fertilization (IVF) to attempt to "rescue" GLT. However, a rational, evidence-based approach to determine if such extraordinary efforts should be attempted on a chimera has not been established. Therefore, in the present study we assessed the production, quality and genotype of epididymal sperm harvested from male chimeras generated by blastocyst or morula microinjection of gene targeted embryonic stem (ES) cell clones containing a LacZ expression cassette and that failed to achieve GLT. Results of this analysis enabled us to determine the cause of GLT failure, correlate coat color chimerism with the proportion of LacZ-positive sperm, and test the likelihood of achieving GLT by IVF. In 415 chimeras, 332 (80%) produced no offspring by natural mating ("infertile"), while 83 (20%) produced only wildtype offspring ("fertile"). Of the 332 infertile chimeras, 209 (63%) failed to produce any sperm whatsoever, 48 (15%) had extremely poor quality sperm, and 75 (23%) had good quality sperm. These results indicate that most chimeras that do not achieve GLT by natural mating are infertile, and the primary cause of infertility is failed spermatogenesis. Genotyping of sperm from 519 chimeras revealed a significant positive linear correlation between coat color chimerism and mean percentage of LacZ-positive sperm (R(2) = 0.95). Finally, IVF using good quality, LacZ-positive sperm from fertile and infertile chimeras "rescued" GLT for 19 out of 56 genes. We conclude that an assessment of coat color chimerism together with sperm quality and genotype can better inform the selection of chimeras for IVF to rescue GLT than coat color chimerism alone.

Published

2015

8. Response to correspondence on “Reproducibility of CRISPR-Cas9 methods for generation of conditional mouse alleles: a multi-center evaluation”

Author

Gurumurthy, Channabasavaiah B., O’Brien, Aidan R., Quadros, Rolen M., Adams, Jr, John, Alcaide, Pilar, Ayabe, Shinya, Ballard, Johnathan, Batra, Surinder K., Beauchamp, Marie-Claude, Becker, Kathleen A., Bernas, Guillaume, Brough, David, Carrillo-Salinas, Francisco, Chan, Wesley, Chen, Hanying, Dawson, Ruby, DeMambro, Victoria, D’Hont, Jinke, Dibb, Katharine, Eudy, James D., Gan, Lin, Gao, Jing, Gonzales, Amy, Guntur, Anyonya, Guo, Huiping, Harms, Donald W., Harrington, Anne, Hentges, Kathryn E., Humphreys, Neil, Imai, Shiho, Ishii, Hideshi, Iwama, Mizuho, Jonasch, Eric, Karolak, Michelle, Keavney, Bernard, Khin, Nay-Chi, Konno, Masamitsu, Kotani, Yuko, Kunihiro, Yayoi, Lakshmanan, Imayavaramban, Larochelle, Catherine, Lawrence, Catherine B., Li, Lin, Lindner, Volkhard, Liu, Xian-De, Lopez-Castejon, Gloria, Loudon, Andrew, Lowe, Jenna, Jerome-Majeweska, Loydie, Matsusaka, Taiji, Miura, Hiromi, Miyasaka, Yoshiki, Morpurgo, Benjamin, Motyl, Katherine, Nabeshima, Yo-ichi, Nakade, Koji, Nakashiba, Toshiaki, Nakashima, Kenichi, Obata, Yuichi, Ogiwara, Sanae, Ouellet, Mariette, Oxburgh, Leif, Piltz, Sandra, Pinz, Ilka, Ponnusamy, Moorthy P., Ray, David, Redder, Ronald J., Rosen, Clifford J., Ross, Nikki, Ruhe, Mark T., Ryzhova, Larisa, Salvador, Ane M., Alam, Sabrina Shameen, Sedlacek, Radislav, Sharma, Karan, Smith, Chad, Staes, Katrien, Starrs, Lora, Sugiyama, Fumihiro, Takahashi, Satoru, Tanaka, Tomohiro, Trafford, Andrew, Uno, Yoshihiro, Vanhoutte, Leen, Vanrockeghem, Frederique, Willis, Brandon J., Wright, Christian S., Yamauchi, Yuko, Yi, Xin, Yoshimi, Kazuto, Zhang, Xuesong, Zhang, Yu, Ohtsuka, Masato, Das, Satyabrata, Garry, Daniel J., Hochepied, Tino, Thomas, Paul, Parker-Thornburg, Jan, Adamson, Antony D., Yoshiki, Atsushi, Schmouth, Jean-Francois, Golovko, Andrei, Thompson, William R., Lloyd, K. C. Kent, Wood, Joshua A., Cowan, Mitra, Mashimo, Tomoji, Mizuno, Seiya, Zhu, Hao, Kasparek, Petr, Liaw, Lucy, Miano, Joseph M., and Burgio, Gaetan

Published

2021

9. Abnormal Mammary Development in 129:STAT1-Null Mice is Stroma-Dependent.

Author

Chen, Jane Q, Mori, Hidetoshi, Cardiff, Robert D, Trott, Josephine F, Hovey, Russell C, Hubbard, Neil E, Engelberg, Jesse A, Tepper, Clifford G, Willis, Brandon J, Khan, Imran H, Ravindran, Resmi K, Chan, Szeman R, Schreiber, Robert D, and Borowsky, Alexander D

Subjects

Epithelium, Mammary Glands, Animal, Stromal Cells, Animals, Mice, Knockout, Mice, Breast Neoplasms, Disease Models, Animal, Hormones, Cytokines, Cluster Analysis, Gene Expression Profiling, Female, STAT1 Transcription Factor, Isografts, Mammary Glands, Animal, Knockout, Disease Models, General Science & Technology

Abstract

Female 129:Stat1-null mice (129S6/SvEvTac-Stat1(tm1Rds) homozygous) uniquely develop estrogen-receptor (ER)-positive mammary tumors. Herein we report that the mammary glands (MG) of these mice have altered growth and development with abnormal terminal end buds alongside defective branching morphogenesis and ductal elongation. We also find that the 129:Stat1-null mammary fat pad (MFP) fails to sustain the growth of 129S6/SvEv wild-type and Stat1-null epithelium. These abnormalities are partially reversed by elevated serum progesterone and prolactin whereas transplantation of wild-type bone marrow into 129:Stat1-null mice does not reverse the MG developmental defects. Medium conditioned by 129:Stat1-null epithelium-cleared MFP does not stimulate epithelial proliferation, whereas it is stimulated by medium conditioned by epithelium-cleared MFP from either wild-type or 129:Stat1-null females having elevated progesterone and prolactin. Microarrays and multiplexed cytokine assays reveal that the MG of 129:Stat1-null mice has lower levels of growth factors that have been implicated in normal MG growth and development. Transplanted 129:Stat1-null tumors and their isolated cells also grow slower in 129:Stat1-null MG compared to wild-type recipient MG. These studies demonstrate that growth of normal and neoplastic 129:Stat1-null epithelium is dependent on the hormonal milieu and on factors from the mammary stroma such as cytokines. While the individual or combined effects of these factors remains to be resolved, our data supports the role of STAT1 in maintaining a tumor-suppressive MG microenvironment.

Published

2015

10. Whole genome analysis for 163 guide RNAs in Cas9 edited mice reveals minimal off-target activity

Author

Peterson, Kevin A., primary, Khalouei, Sam, additional, Wood, Joshua A., additional, Lanza, Denise G., additional, Lintott, Lauri G., additional, Willis, Brandon J., additional, Seavitt, John R., additional, Hanafi, Nour, additional, Braun, Robert E., additional, Dickinson, Mary E., additional, White, Jacqueline K., additional, Lloyd, K.C. Kent, additional, Heaney, Jason D., additional, Murray, Stephen A., additional, Ramani, Arun, additional, and Nutter, Lauryl M.J., additional

Published

2021

11. On the potential role of globins in brown adipose tissue: a novel conceptual model and studies in myoglobin knockout mice

Author

Blackburn, Michael L., primary, Wankhade, Umesh D., additional, Ono-Moore, Kikumi D., additional, Chintapalli, Sree V., additional, Fox, Renee, additional, Rutkowsky, Jennifer M., additional, Willis, Brandon J., additional, Tolentino, Todd, additional, Lloyd, K. C. Kent, additional, and Adams, Sean H., additional

Published

2021

12. Metabolic physiology and skeletal muscle phenotypes in male and female myoglobin knockout mice

Author

Ono-Moore, Kikumi D., primary, Olfert, I. Mark, additional, Rutkowsky, Jennifer M., additional, Chintapalli, Sree V., additional, Willis, Brandon J., additional, Blackburn, Michael L., additional, Williams, D. Keith, additional, O’Reilly, Juliana, additional, Tolentino, Todd, additional, Lloyd, K. C. Kent, additional, and Adams, Sean H., additional

Published

2021

13. Assessment of three generations of mice derived by ICSI using freeze-dried sperm

Author

Li, Ming-Wen, Willis, Brandon J., Griffey, Stephen M., Spearow, Jimmy L., and Kent Lloyd, K. C.

Published

2009

14. Efficient mouse genome engineering by CRISPR-EZ (CRISPR RNP Electroporation of Zygotes) technology

Author

Modzelewski, Andrew J., Chen, Sean, Willis, Brandon J., Lloyd, K C Kent, Wood, Joshua A., and He, Lin

Subjects

Gene Editing, Mice, Inbred C57BL, Mice, Knockout, Mice, Electroporation, Microinjections, Zygote, CRISPR-Associated Protein 9, Animals, Clustered Regularly Interspaced Short Palindromic Repeats, Article

Abstract

CRISPR/Cas9 technology has transformed mouse genome editing with unprecedented precision, efficiency, and ease; however, the current practice of microinjecting CRISPR reagents into pronuclear-stage embryos remains rate-limiting. We thus developed CRISRP-EZ (CRISPR RNP Electroporation of Zygotes), an electroporation-based technology that outperforms pronuclear and cytoplasmic microinjection in efficiency, simplicity, cost, and throughput. In C57BL/6J and C57BL/6N mouse strains, CRISPR-EZ achieves 100% delivery of Cas9/sgRNA ribonucleoproteins (RNPs), facilitating indel mutations (insertions or deletions), exon deletions, point mutations, and small insertions. In a side-by-side comparison in the high-throughput KnockOut Mouse Project (KOMP) pipeline, CRISPR-EZ consistently outperformed microinjection. Here, we provide an optimized protocol covering single guide RNA (sgRNA) synthesis, embryo collection, RNP electroporation, mouse generation, and genotyping strategies. Using CRISPR-EZ, a graduate-level researcher with basic embryo manipulation skills can obtain genetically modified mice in 6 weeks. Altogether, CRISPR-EZ is a simple, economic, efficient, and high-throughput technology that is potentially applicable to other mammalian species.

Published

2018

15. Re-Evaluating One-step Generation of Mice Carrying Conditional Alleles by CRISPR-Cas9-Mediated Genome Editing Technology

Author

Gurumurthy, Channabasavaiah, primary, Quadros, Rolen, additional, Adams, John, additional, Alcaide, Pilar, additional, Ayabe, Shinya, additional, Ballard, Johnathan, additional, Batra, Surinder K., additional, Beauchamp, Marie-Claude, additional, Becker, Kathleen A, additional, Bernas, Guillaume, additional, Brough, David, additional, Carrillo-Salinas, Francisco, additional, Dawson, Ruby, additional, DeMambro, Victoria, additional, D’Hont, Jinke, additional, Dibb, Katharine, additional, Eudy, James D., additional, Gan, Lin, additional, Gao, Jing, additional, Gonzales, Amy, additional, Guntur, Anyonya, additional, Guo, Huiping, additional, Harms, Donald W., additional, Harrington, Anne, additional, Hentges, Kathryn E., additional, Humphreys, Neil, additional, Imai, Shiho, additional, Ishii, Hideshi, additional, Iwama, Mizuho, additional, Jonasch, Eric, additional, Karolak, Michelle, additional, Keavney, Bernard, additional, Khin, Nay-Chi, additional, Konno, Masamitsu, additional, Kotani, Yuko, additional, Kunihiro, Yayoi, additional, Lakshmanan, Imayavaramban, additional, Larochelle, Catherine, additional, Lawrence, Catherine B., additional, Li, Lin, additional, Lindner, Volkhard, additional, Liu, Xian-De, additional, Lopez-Castejon, Gloria, additional, Loudon, Andrew, additional, Lowe, Jenna, additional, Jerome-Majeweska, Loydie, additional, Matsusaka, Taiji, additional, Miura, Hiromi, additional, Miyasaka, Yoshiki, additional, Morpurgo, Benjamin, additional, Motyl, Katherine, additional, Nabeshima, Yo-ichi, additional, Nakade, Koji, additional, Nakashiba, Toshiaki, additional, Nakashima, Kenichi, additional, Obata, Yuichi, additional, Ogiwara, Sanae, additional, Ouellet, Mariette, additional, Oxburgh, Leif, additional, Piltz, Sandra, additional, Pinz, Ilka, additional, Ponnusamy, Moorthy P., additional, Ray, David, additional, Redder, Ronald J., additional, Rosen, Clifford J, additional, Ross, Nikki, additional, Ruhe, Mark T., additional, Ryzhova, Larisa, additional, Salvador, Ane M., additional, Sedlacek, Radislav, additional, Sharma, Karan, additional, Smith, Chad, additional, Staes, Katrien, additional, Starrs, Lora, additional, Sugiyama, Fumihiro, additional, Takahashi, Satoru, additional, Tanaka, Tomohiro, additional, Trafford, Andrew, additional, Uno, Yoshihiro, additional, Vanhoutte, Leen, additional, Vanrockeghem, Frederique, additional, Willis, Brandon J., additional, Wright, Christian S., additional, Yamauchi, Yuko, additional, Yi, Xin, additional, Yoshimi, Kazuto, additional, Zhang, Xuesong, additional, Zhang, Yu, additional, Ohtsuka, Masato, additional, Das, Satyabrata, additional, Garry, Daniel J., additional, Hochepied, Tino, additional, Thomas, Paul, additional, Parker-Thornburg, Jan, additional, Adamson, Antony D, additional, Yoshiki, Atsushi, additional, Schmouth, Jean-Francois, additional, Golovko, Andrei, additional, Thompson, William R., additional, Lloyd, KC. Kent, additional, Wood, Joshua A., additional, Cowan, Mitra, additional, Mashimo, Tomoji, additional, Mizuno, Seiya, additional, Zhu, Hao, additional, Kasparek, Petr, additional, Liaw, Lucy, additional, Miano, Joseph M., additional, and Burgio, Gaetan, additional

Published

2018

16. Rescue of germline transmission from chimeras by IVF after sperm analysis

Author

Li, Ming-Wen, primary, Willis, Brandon J., additional, Evans, Kristin D., additional, Araiza, Renee S., additional, Lee, Angus Yiu-Fai, additional, and Lloyd, K. C. Kent, additional

Published

2014

17. Assessment of three generations of mice derived by ICSI using freeze-dried sperm.

Author

Ming-Wen Li, Willis, Brandon J., Griffey, Stephen M., Spearow, Jimmy L., and Lloyd, K. C. Kent

Subjects

FERTILIZATION in vitro, SPERMATOZOA, REPRODUCTIVE technology, BLASTOCYST, OVUM, EMBRYOLOGY, MICE

Abstract

Although the derivation of mice by intracytoplasmic sperm injection (ICSI) using freeze-dried sperm has been demonstrated previously, a comprehensive analysis of their viability, health, and fertility has not. The purpose of the present study was to determine the extent to which ICSI using freeze-dried sperm stored at 4 ?C for 1-2 months from mice on either an inbred (C57BL/6J) or hybrid (B6D2F1/J) genetic background results in genomic instability and/or phenotypic abnormality in mice and two generations of their progeny. Fertilization rates (number of 2-cells per injected oocytes) using ICSI of fresh and freezedried sperm were similar within and between mouse strains, although fewer freeze-dried sperm-derived embryos than fresh sperm-derived embryos developed to blastocysts in vitro (C57BL/6J and B6D2F1/J) and live born pups in vivo (B6D2F1/J only). Nevertheless, once born, mice derived by ICSI using freezedried sperm in both mouse strains were healthy and reproductively sound. No major differences in litter size, weaning rate, and sex ratio were noted in the two generations of progeny (F2 and F3) of ICSI-derived offspring using freeze-dried sperm compared with that in the natural mating (control) group. Further, there was no evidence that either ICSI or freeze drying induced genomic instability, as determined by microsatellite analysis of the derived mice and subsequent generations when compared with both parental genotypes, nor were there differences in the number or types of pathological changes in any of the three generations of progeny. We conclude that viable, healthy and genomically stable mice can be derived by ICSI using freeze-dried mouse sperm stored in the refrigerator for at least 2 months. Further, because freeze drying is a simpler and more economical technique compared with embryo and sperm cryopreservation, the results of this study justify additional research to continue to develop and enhance the technique for the preservation, storage, and sharing of genetically altered mice. [ABSTRACT FROM AUTHOR]

Published

2009