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2. In Situ Gene Therapy via AAV-CRISPR-Cas9-Mediated Targeted Gene Regulation

Author

Moreno, Ana M, Fu, Xin, Zhu, Jie, Katrekar, Dhruva, Shih, Yu-Ru V, Marlett, John, Cabotaje, Jessica, Tat, Jasmine, Naughton, John, Lisowski, Leszek, Varghese, Shyni, Zhang, Kang, and Mali, Prashant

Subjects
Medical Biotechnology, Biomedical and Clinical Sciences, Regenerative Medicine, Neurosciences, Biotechnology, Gene Therapy, Genetics, Development of treatments and therapeutic interventions, 5.2 Cellular and gene therapies, Animals, CRISPR-Cas Systems, Cell Line, Clustered Regularly Interspaced Short Palindromic Repeats, Dependovirus, Gene Editing, Gene Expression Regulation, Genetic Engineering, Genetic Therapy, Genetic Vectors, HEK293 Cells, Humans, Mice, Mice, Inbred C57BL, Retinal Cone Photoreceptor Cells, Retinal Rod Photoreceptor Cells, Retinitis Pigmentosa, Transcription, Genetic, CRISPR-Cas9, gene therapy, retinitis pigmentosa, Biological Sciences, Technology, Medical and Health Sciences, Clinical sciences, Medical biotechnology
Abstract

Development of efficacious in vivo delivery platforms for CRISPR-Cas9-based epigenome engineering will be critical to enable the ability to target human diseases without permanent modification of the genome. Toward this, we utilized split-Cas9 systems to develop a modular adeno-associated viral (AAV) vector platform for CRISPR-Cas9 delivery to enable the full spectrum of targeted in situ gene regulation functionalities, demonstrating robust transcriptional repression (up to 80%) and activation (up to 6-fold) of target genes in cell culture and mice. We also applied our platform for targeted in vivo gene-repression-mediated gene therapy for retinitis pigmentosa. Specifically, we engineered targeted repression of Nrl, a master regulator of rod photoreceptor determination, and demonstrated Nrl knockdown mediates in situ reprogramming of rod cells into cone-like cells that are resistant to retinitis pigmentosa-specific mutations, with concomitant prevention of secondary cone loss. Furthermore, we benchmarked our results from Nrl knockdown with those from in vivo Nrl knockout via gene editing. Taken together, our AAV-CRISPR-Cas9 platform for in vivo epigenome engineering enables a robust approach to target disease in a genomically scarless and potentially reversible manner.

Published
2018

4. Calcium phosphate-bearing matrices induce osteogenic differentiation of stem cells through adenosine signaling.

Author

Shih, Yu-Ru V, Hwang, YongSung, Phadke, Ameya, Kang, Heemin, Hwang, Nathaniel S, Caro, Eduardo J, Nguyen, Steven, Siu, Michael, Theodorakis, Emmanuel A, Gianneschi, Nathan C, Vecchio, Kenneth S, Chien, Shu, Lee, Oscar K, and Varghese, Shyni

Subjects
Bone and Bones, Cells, Cultured, Stem Cells, Humans, Calcium Phosphates, Phosphates, Receptor, Adenosine A2B, RNA, Small Interfering, Adenosine, Adenosine Triphosphate, Biocompatible Materials, Chromatography, High Pressure Liquid, Regeneration, Signal Transduction, Cell Differentiation, Gene Expression Regulation, Osteogenesis, Homeostasis, Phenotype, Sodium-Phosphate Cotransporter Proteins, Type III, Mesenchymal Stromal Cells, biomimetic material, bone metabolism, mineralized matrix, phosphate signaling, Mesenchymal Stem Cells, Cells, Cultured, Receptor, Adenosine A2B, RNA, Small Interfering, Chromatography, High Pressure Liquid, Sodium-Phosphate Cotransporter Proteins, Type III
Abstract

Synthetic matrices emulating the physicochemical properties of tissue-specific ECMs are being developed at a rapid pace to regulate stem cell fate. Biomaterials containing calcium phosphate (CaP) moieties have been shown to support osteogenic differentiation of stem and progenitor cells and bone tissue formation. By using a mineralized synthetic matrix mimicking a CaP-rich bone microenvironment, we examine a molecular mechanism through which CaP minerals induce osteogenesis of human mesenchymal stem cells with an emphasis on phosphate metabolism. Our studies show that extracellular phosphate uptake through solute carrier family 20 (phosphate transporter), member 1 (SLC20a1) supports osteogenic differentiation of human mesenchymal stem cells via adenosine, an ATP metabolite, which acts as an autocrine/paracrine signaling molecule through A2b adenosine receptor. Perturbation of SLC20a1 abrogates osteogenic differentiation by decreasing intramitochondrial phosphate and ATP synthesis. Collectively, this study offers the demonstration of a previously unknown mechanism for the beneficial role of CaP biomaterials in bone repair and the role of phosphate ions in bone physiology and regeneration. These findings also begin to shed light on the role of ATP metabolism in bone homeostasis, which may be exploited to treat bone metabolic diseases.

Published
2014

12. List of Contributors

Author

Ahadian, Samad, primary, Akiyaman, Kentaro, additional, Alansari, Sarah, additional, Alikhani, Mani, additional, Alikhani, Mona, additional, Arthur, Agnieszka, additional, Arulkumar, Shylaja, additional, Baiguera, Silvia, additional, Bianco, Alessandra, additional, Bissada, Nabil F., additional, Bleicher, Françoise, additional, Bliley, Jacqueline M., additional, Bosshardt, Dieter D., additional, Botero, Tatiana M., additional, Braga, Raquel, additional, Briggs, Kristen K., additional, Brooks, Patricia J., additional, Cannon, Kevin, additional, Carrouel, Florence, additional, Chavez, Miquella G., additional, Cheng, Ming-Te, additional, Christ, George J., additional, Cook, Colin A., additional, Cooper, Paul R., additional, Cox, Timothy C., additional, Cunningham, Michael L., additional, Dashe, Jesse, additional, Davidovitch, Ze’ev, additional, Davies, Lindsay C., additional, Del Gaudio, Costantino, additional, Diekwisch, Thomas G.H., additional, Diogenes, Anibal, additional, Duncan, Randall L., additional, Edwards, Paul C., additional, El-Bialy, Tarek, additional, Enlow, Donald H., additional, Farach-Carson, Mary C., additional, Farges, Jean-Christophe, additional, Feinberg, Stephen E., additional, Felfy, Hady, additional, Freeman, Phillip N., additional, Freilich, Martin, additional, Fujie, Toshinori, additional, Gao, Changyou, additional, Giannobile, William V., additional, Gong, Siew-Ging, additional, Grayson, Warren L., additional, Greene, Robert M., additional, Gronthos, Stan, additional, Gruber, Reinhard, additional, Häkkinen, Lari, additional, Hanna, Craig, additional, Hargreaves, Kenneth M., additional, Satoshi, Emilio Hara, additional, Harrington, Daniel A., additional, Hashmi, Basma, additional, Heino, Jyrki, additional, Hing, Anne V., additional, Holmes, Christina, additional, Honda, Masaki J., additional, Horst, Jeremy A., additional, Hu, Michael S., additional, Hughes, Francis J., additional, Hung, Ben P., additional, Huri, Pinar Yilgor, additional, Ingber, Donald E., additional, Isokawa, Keitaro, additional, Izumi, Kenji, additional, James, Eric N., additional, Jia, Xinqiao, additional, Jin, Yan, additional, Emily Joo, E., additional, Juuri, Emma, additional, Kagami, Hideaki, additional, Kaji, Hirokazu, additional, Kang, Mo K., additional, Kashi, A., additional, Kato, Hiroko, additional, Kaur, Jasvir, additional, Keller, Letitia V., additional, Kemp, Paul D., additional, Khademhosseini, Ali, additional, Khoo, Edmund, additional, Kim, Hae-Won, additional, King, William J., additional, Kirschner, Richard E., additional, Klein, Ophir D., additional, Knowles, Jonathan C., additional, Koivisto, Leeni, additional, Kökten, Tunay, additional, Krebsbach, Paul H., additional, Kuboki, Takuo, additional, Kuchler-Bopp, Sabine, additional, Kucska, Simone, additional, Kuhn, Liisa, additional, Larjava, Hannu, additional, Lee, Eun-Jung, additional, Lee, Joo-Hee, additional, Lee, Oscar K., additional, Lee, Yoo Bin, additional, Lesot, Hervé, additional, Lewis, Mark P., additional, Li, Bei, additional, Li, Luyan, additional, Lim, Jung Yul, additional, Liu, Xing, additional, Liu, Xiaohua, additional, Lo, David D., additional, Longaker, Michael T., additional, Peter Lorenz, H., additional, Lott, David G., additional, Lungová, Vlasta, additional, Ma, Lie, additional, Macchiarini, Paolo, additional, Mammoto, Tadanori, additional, Marei, Mona K., additional, Marolt, Darja, additional, Marra, Kacey G., additional, Martin, Neil R.W., additional, Matalová, Eva, additional, Matsue, Tomokazu, additional, Mehrazarin, Shebli, additional, Mina, Mina, additional, Modo, Michel, additional, Mokry, Jaroslav, additional, Morsczeck, Christian, additional, Moussa, Rania M., additional, Murphy, Neal C., additional, Mushegyan, Vagan, additional, Nagy, Naglaa B., additional, Nair, Lakshmi S., additional, Nayar, Harry, additional, Nör, Jacques E., additional, Obregón, Raquel, additional, Oh, Tae-Ju, additional, Oka, Kyoko, additional, Ostrovidov, Serge, additional, Park, No-Hee, additional, Passineau, Michael J., additional, Passipieri, Juliana A., additional, Pisal, Rishikaysh, additional, Player, Darren, additional, Pradhan-Bhatt, Swati, additional, Parthiban, Selvakumar Prakash, additional, Prochazka, Jan, additional, Prochazkova, Michaela, additional, Qu, Tiejun, additional, Ramalingam, Murugan, additional, Ramón-Azcón, Javier, additional, Rana, Deepti, additional, Ray, Herbert L., additional, Reed, David A., additional, Reinhardt, Dieter P., additional, Richard, Béatrice, additional, Riehl, Brandon D., additional, Rios, Hector F., additional, Peter Rubin, J., additional, Saad, Manal M., additional, Sachar, Ashneet, additional, Sah, Robert L., additional, Saha, Subrata, additional, Saito, Yoko, additional, Sampathkumar, Kaarunya, additional, Sangsuwon, Chinapa, additional, Seo, Byoung Moo, additional, Sharpe, Paul, additional, Shi, Songtao, additional, Shih, Yu-Ru V., additional, Shiku, Hitoshi, additional, Shin, Seung Yun, additional, Sjöqvist, Sebastian, additional, Sloan, Alastair J., additional, Smith, Anthony (Tony) J., additional, Song, In Seok, additional, Stephens, Neil, additional, Stephens, Phil, additional, Svoboda, Kathy K.H., additional, Tabrizian, Maryam, additional, Teixeira, Cristina, additional, Teixeira, Fabricio B., additional, Temple, Joshua P., additional, Thesleff, Irma, additional, Thivichon-Prince, Béatrice, additional, Toriumi, Taku, additional, Treasure, Trevor E., additional, Um, Soyoun, additional, Vishwakarma, Ajaykumar, additional, Wang, Chunfen, additional, Watson, Deborah, additional, Watson, Jeffrey B., additional, Wen, Bo, additional, Witt, Robert L., additional, Wong, Mark E., additional, Yamada, Kenneth M., additional, Yassin, Hala H., additional, Zakheim, Daniel, additional, Zhang, Bing, additional, and Zimmermann, Andrew S., additional

Published
2015
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15. In Situ Gene Therapy via AAV-CRISPR-Cas9-Mediated Targeted Gene Regulation

Author

Moreno, Ana M., primary, Fu, Xin, additional, Zhu, Jie, additional, Katrekar, Dhruva, additional, Shih, Yu-Ru V., additional, Marlett, John, additional, Cabotaje, Jessica, additional, Tat, Jasmine, additional, Naughton, John, additional, Lisowski, Leszek, additional, Varghese, Shyni, additional, Zhang, Kang, additional, and Mali, Prashant, additional

Published
2020
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30. In SituGene Therapy via AAV-CRISPR-Cas9-Mediated Targeted Gene Regulation

Author

Moreno, Ana M., Fu, Xin, Zhu, Jie, Katrekar, Dhruva, Shih, Yu-Ru V., Marlett, John, Cabotaje, Jessica, Tat, Jasmine, Naughton, John, Lisowski, Leszek, Varghese, Shyni, Zhang, Kang, and Mali, Prashant

Abstract

Development of efficacious in vivodelivery platforms for CRISPR-Cas9-based epigenome engineering will be critical to enable the ability to target human diseases without permanent modification of the genome. Toward this, we utilized split-Cas9 systems to develop a modular adeno-associated viral (AAV) vector platform for CRISPR-Cas9 delivery to enable the full spectrum of targeted in situgene regulation functionalities, demonstrating robust transcriptional repression (up to 80%) and activation (up to 6-fold) of target genes in cell culture and mice. We also applied our platform for targeted in vivogene-repression-mediated gene therapy for retinitis pigmentosa. Specifically, we engineered targeted repression of Nrl, a master regulator of rod photoreceptor determination, and demonstrated Nrlknockdown mediates in situreprogramming of rod cells into cone-like cells that are resistant to retinitis pigmentosa-specific mutations, with concomitant prevention of secondary cone loss. Furthermore, we benchmarked our results from Nrlknockdown with those from in vivo Nrlknockout via gene editing. Taken together, our AAV-CRISPR-Cas9 platform for in vivoepigenome engineering enables a robust approach to target disease in a genomically scarless and potentially reversible manner.

Published
2018
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37. Biomineralized Matrices Dominate Soluble Cues To Direct Osteogenic Differentiation of Human Mesenchymal Stem Cells through Adenosine Signaling.

Author

Heemin Kang, Shih, Yu-Ru V., and Varghese, Shyni

Subjects
*BIOMINERALIZATION, *BONE growth, *CELL differentiation, *MESENCHYMAL stem cells, *ADENOSINES, *CELLULAR signal transduction
Abstract

Stem cell differentiation is determined by a repertoire of signals from its microenvironment, which includes the extracellular matrix (ECM) and soluble cues. The ability of mesenchymal stem cells (MSCs), a common precursor for the skeletal system, to differentiate into osteoblasts and adipocytes in response to their local cues plays an important role in skeletal tissue regeneration and homeostasis. In this study, we investigated whether a bone-specific calcium phosphate (CaP) mineral environment could induce osteogenic differentiation of human MSCs, while inhibiting their adipogenic differentiation, in the presence of adipogenic-inducing medium. We also examined the mechanism through which the mineralized matrix suppresses adipogenesis of hMSCs to promote their osteogenic differentiation. Our results show that hMSCs cultured on mineralized matrices underwent osteogenic differentiation despite being cultured in the presence of adipogenic medium, which indicates the dominance of matrix-based cues of the mineralized matrix in directing osteogenic commitment of stem cells. Furthermore, the mineralized matrix-driven attenuation of adipogenesis was reversed with the inhibition of A2b adenosine receptor (A2bR), implicating a role of adenosine signaling in mineralized environment-mediated inhibition of adipogenesis. Such synthetic matrices with an intrinsic ability to direct differentiation of multipotent adult stem cells toward a targeted phenotype while inhibiting their differentiation into other lineages not only will be a powerful tool in delineating the role of complex microenvironmental cues on stem cell commitment but also will contribute to functional tissue engineering and their translational applications. [ABSTRACT FROM AUTHOR]

Published
2015
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40. Coordinated Changes of Mitochondrial Biogenesis and Antioxidant Enzymes During Osteogenic Differentiation of Human Mesenchymal Stem Cells.

Author

CHIEN-TSUN CHEN, SHIH, YU-RU V., KUO, TOM K., LEE, OSCAR K., and YAU-HUEI WEI

Subjects
CELL differentiation, GLYCOLYSIS, MITOCHONDRIAL DNA, STEM cells, SUPEROXIDE dismutase, ORIGIN of life, ENZYMOLOGY
Abstract

The multidifferentiation ability of mesenchymal stem cells holds great promise for cell therapy. Numerous studies have focused on the establishment of differentiation protocols, whereas little attention has been paid to the metabolic changes during the differentiation process. Mitochondria, the powerhouse of mammalian cells, vary in their number and function in different cell types with different energy demands, but how these variations are associated with cell differentiation remains elusive. In this study, we investigated the changes of mitochondrial biogenesis and bioenergetic function using human mesenchymal stem cells (hMSCs) because of their well-defined differentiation potentials. Upon osteogenic induction, the copy number of mitochondrial DNA, protein subunits of the respiratory enzymes, oxygen consumption rate, and intracellular ATP content were increased, indicating the upregulation of aerobic mitochondrial metabolism. On the other hand, undifferentiated hMSCs showed higher levels of glycolytic enzymes and lactate production rate, suggesting that hMSCs rely more on glycolysis for energy supply in comparison with hMSC-differentiated osteoblasts. In addition, we observed a dramatic decrease of intracellular reactive oxygen species (ROS) as a consequence of upregulation of two antioxidant enzymes, manganesedependent superoxide dismutase and catalase. Finally, we found that exogenous H2O2 and mitochondrial inhibitors could retard the osteogenic differentiation. These findings suggested an energy production transition from glycolysis to oxidative phosphorylation in hMSCs upon osteogenic induction. Meanwhile, antioxidant enzymes were concurrently upregulated to prevent the accumulation of intracellular ROS. Together, our findings suggest that coordinated regulation of mitochondrial biogenesis and antioxidant enzymes occurs synergistically during osteogenic differentiation of hMSCs. [ABSTRACT FROM AUTHOR]

Published
2008
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