847 results on '"Svendsen, Clive N."'
Search Results
2. Cell therapy for neurological disorders
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Svendsen, Soshana P. and Svendsen, Clive N.
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- 2024
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3. Surface tension enables induced pluripotent stem cell culture in commercially available hardware during spaceflight
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Mozneb, Maedeh, Arzt, Madelyn, Mesci, Pinar, Martin, Dylan M. N., Pohlman, Stephany, Lawless, George, Doraisingam, Shankini, Al Neyadi, Sultan, Barnawi, Rayyanah, Al Qarni, Ali, Whitson, Peggy A., Shoffner, John, Stoudemire, Jana, Countryman, Stefanie, Svendsen, Clive N., and Sharma, Arun
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- 2024
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4. Disease related changes in ATAC-seq of iPSC-derived motor neuron lines from ALS patients and controls
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Tsitkov, Stanislav, Valentine, Kelsey, Kozareva, Velina, Donde, Aneesh, Frank, Aaron, Lei, Susan, E. Van Eyk, Jennifer, Finkbeiner, Steve, Rothstein, Jeffrey D., Thompson, Leslie M., Sareen, Dhruv, Svendsen, Clive N., and Fraenkel, Ernest
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- 2024
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5. Survival of the fittest glia
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Moser, V. Alexandra and Svendsen, Clive N.
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- 2024
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6. Large-scale differentiation of iPSC-derived motor neurons from ALS and control subjects
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Workman, Michael J, Lim, Ryan G, Wu, Jie, Frank, Aaron, Ornelas, Loren, Panther, Lindsay, Galvez, Erick, Perez, Daniel, Meepe, Imara, Lei, Susan, Valencia, Viviana, Gomez, Emilda, Liu, Chunyan, Moran, Ruby, Pinedo, Louis, Tsitkov, Stanislav, Ho, Ritchie, Kaye, Julia A, Consortium, the Answer ALS, Thompson, Terri, Rothstein, Jeffrey D, Finkbeiner, Steven, Fraenkel, Ernest, Sareen, Dhruv, Thompson, Leslie M, and Svendsen, Clive N
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Biomedical and Clinical Sciences ,Neurosciences ,Brain Disorders ,Clinical Research ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Rare Diseases ,Stem Cell Research - Induced Pluripotent Stem Cell ,Regenerative Medicine ,Genetics ,Neurodegenerative ,Stem Cell Research ,ALS ,Orphan Drug ,Neurological ,Humans ,Amyotrophic Lateral Sclerosis ,Induced Pluripotent Stem Cells ,Motor Neurons ,Cell Differentiation ,Answer ALS Consortium ,iPSC ,motor neurons ,sex differences ,Psychology ,Cognitive Sciences ,Neurology & Neurosurgery ,Biological psychology - Abstract
Using induced pluripotent stem cells (iPSCs) to understand the mechanisms of neurological disease holds great promise; however, there is a lack of well-curated lines from a large array of participants. Answer ALS has generated over 1,000 iPSC lines from control and amyotrophic lateral sclerosis (ALS) patients along with clinical and whole-genome sequencing data. The current report summarizes cell marker and gene expression in motor neuron cultures derived from 92 healthy control and 341 ALS participants using a 32-day differentiation protocol. This is the largest set of iPSCs to be differentiated into motor neurons, and characterization suggests that cell composition and sex are significant sources of variability that need to be carefully controlled for in future studies. These data are reported as a resource for the scientific community that will utilize Answer ALS data for disease modeling using a wider array of omics being made available for these samples.
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- 2023
7. NeuroLINCS Proteomics: Defining human-derived iPSC proteomes and protein signatures of pluripotency
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Matlock, Andrea D, Vaibhav, Vineet, Holewinski, Ronald, Venkatraman, Vidya, Dardov, Victoria, Manalo, Danica-Mae, Shelley, Brandon, Ornelas, Loren, Banuelos, Maria, Mandefro, Berhan, Escalante-Chong, Renan, Li, Jonathan, Finkbeiner, Steve, Fraenkel, Ernest, Rothstein, Jeffrey, Thompson, Leslie, Sareen, Dhruv, Svendsen, Clive N, and Van Eyk, Jennifer E
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Stem Cell Research - Nonembryonic - Human ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Neurosciences ,Rare Diseases ,Stem Cell Research ,Biotechnology ,Human Genome ,Stem Cell Research - Induced Pluripotent Stem Cell ,Neurodegenerative ,Genetics ,Neurological ,Humans ,Induced Pluripotent Stem Cells ,Motor Neurons ,Pluripotent Stem Cells ,Proteome ,Proteomics ,NIH NeuroLINCS Consortium - Abstract
The National Institute of Health (NIH) Library of integrated network-based cellular signatures (LINCS) program is premised on the generation of a publicly available data resource of cell-based biochemical responses or "signatures" to genetic or environmental perturbations. NeuroLINCS uses human inducible pluripotent stem cells (hiPSCs), derived from patients and healthy controls, and differentiated into motor neuron cell cultures. This multi-laboratory effort strives to establish i) robust multi-omic workflows for hiPSC and differentiated neuronal cultures, ii) public annotated data sets and iii) relevant and targetable biological pathways of spinal muscular atrophy (SMA) and amyotrophic lateral sclerosis (ALS). Here, we focus on the proteomics and the quality of the developed workflow of hiPSC lines from 6 individuals, though epigenomics and transcriptomics data are also publicly available. Known and commonly used markers representing 73 proteins were reproducibly quantified with consistent expression levels across all hiPSC lines. Data quality assessments, data levels and metadata of all 6 genetically diverse human iPSCs analysed by DIA-MS are parsable and available as a high-quality resource to the public.
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- 2023
8. Roadmap for C9ORF72 in Frontotemporal Dementia and Amyotrophic Lateral Sclerosis: Report on the C9ORF72 FTD/ALS Summit
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Sattler, Rita, Traynor, Bryan J., Robertson, Janice, Van Den Bosch, Ludo, Barmada, Sami J., Svendsen, Clive N., Disney, Matthew D., Gendron, Tania F., Wong, Philip C., Turner, Martin R., Boxer, Adam, Babu, Suma, Benatar, Michael, Kurnellas, Michael, Rohrer, Jonathan D., Donnelly, Christopher J., Bustos, Lynette M., Van Keuren-Jensen, Kendall, Dacks, Penny A., and Sabbagh, Marwan N.
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- 2023
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9. Reversal of dual epigenetic repression of non-canonical Wnt-5a normalises diabetic corneal epithelial wound healing and stem cells
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Shah, Ruchi, Spektor, Tanya M., Weisenberger, Daniel J., Ding, Hui, Patil, Rameshwar, Amador, Cynthia, Song, Xue-Ying, Chun, Steven T., Inzalaco, Jake, Turjman, Sue, Ghiam, Sean, Jeong-Kim, Jiho, Tolstoff, Sasha, Yampolsky, Sabina V., Sawant, Onkar B., Rabinowitz, Yaron S., Maguen, Ezra, Hamrah, Pedram, Svendsen, Clive N., Saghizadeh, Mehrnoosh, Ljubimova, Julia Y., Kramerov, Andrei A., and Ljubimov, Alexander V.
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- 2023
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10. Answer ALS, a large-scale resource for sporadic and familial ALS combining clinical and multi-omics data from induced pluripotent cell lines
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Baxi, Emily G, Thompson, Terri, Li, Jonathan, Kaye, Julia A, Lim, Ryan G, Wu, Jie, Ramamoorthy, Divya, Lima, Leandro, Vaibhav, Vineet, Matlock, Andrea, Frank, Aaron, Coyne, Alyssa N, Landin, Barry, Ornelas, Loren, Mosmiller, Elizabeth, Thrower, Sara, Farr, S Michelle, Panther, Lindsey, Gomez, Emilda, Galvez, Erick, Perez, Daniel, Meepe, Imara, Lei, Susan, Mandefro, Berhan, Trost, Hannah, Pinedo, Louis, Banuelos, Maria G, Liu, Chunyan, Moran, Ruby, Garcia, Veronica, Workman, Michael, Ho, Richie, Wyman, Stacia, Roggenbuck, Jennifer, Harms, Matthew B, Stocksdale, Jennifer, Miramontes, Ricardo, Wang, Keona, Venkatraman, Vidya, Holewenski, Ronald, Sundararaman, Niveda, Pandey, Rakhi, Manalo, Danica-Mae, Donde, Aneesh, Huynh, Nhan, Adam, Miriam, Wassie, Brook T, Vertudes, Edward, Amirani, Naufa, Raja, Krishna, Thomas, Reuben, Hayes, Lindsey, Lenail, Alex, Cerezo, Aianna, Luppino, Sarah, Farrar, Alanna, Pothier, Lindsay, Prina, Carolyn, Morgan, Todd, Jamil, Arish, Heintzman, Sarah, Jockel-Balsarotti, Jennifer, Karanja, Elizabeth, Markway, Jesse, McCallum, Molly, Joslin, Ben, Alibazoglu, Deniz, Kolb, Stephen, Ajroud-Driss, Senda, Baloh, Robert, Heitzman, Daragh, Miller, Tim, Glass, Jonathan D, Patel-Murray, Natasha Leanna, Yu, Hong, Sinani, Ervin, Vigneswaran, Prasha, Sherman, Alexander V, Ahmad, Omar, Roy, Promit, Beavers, Jay C, Zeiler, Steven, Krakauer, John W, Agurto, Carla, Cecchi, Guillermo, Bellard, Mary, Raghav, Yogindra, Sachs, Karen, Ehrenberger, Tobias, Bruce, Elizabeth, Cudkowicz, Merit E, Maragakis, Nicholas, Norel, Raquel, Van Eyk, Jennifer E, Finkbeiner, Steven, Berry, James, Sareen, Dhruv, Thompson, Leslie M, Fraenkel, Ernest, and Svendsen, Clive N
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Stem Cell Research ,Rare Diseases ,Stem Cell Research - Induced Pluripotent Stem Cell ,ALS ,Clinical Research ,Neurodegenerative ,Genetics ,Neurosciences ,Human Genome ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Brain Disorders ,Neurological ,Generic health relevance ,Good Health and Well Being ,Amyotrophic Lateral Sclerosis ,Cell Line ,Humans ,Induced Pluripotent Stem Cells ,Motor Neurons ,Psychology ,Cognitive Sciences ,Neurology & Neurosurgery - Abstract
Answer ALS is a biological and clinical resource of patient-derived, induced pluripotent stem (iPS) cell lines, multi-omic data derived from iPS neurons and longitudinal clinical and smartphone data from over 1,000 patients with ALS. This resource provides population-level biological and clinical data that may be employed to identify clinical-molecular-biochemical subtypes of amyotrophic lateral sclerosis (ALS). A unique smartphone-based system was employed to collect deep clinical data, including fine motor activity, speech, breathing and linguistics/cognition. The iPS spinal neurons were blood derived from each patient and these cells underwent multi-omic analytics including whole-genome sequencing, RNA transcriptomics, ATAC-sequencing and proteomics. The intent of these data is for the generation of integrated clinical and biological signatures using bioinformatics, statistics and computational biology to establish patterns that may lead to a better understanding of the underlying mechanisms of disease, including subgroup identification. A web portal for open-source sharing of all data was developed for widespread community-based data analytics.
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- 2022
11. Human iPSC-derived fallopian tube organoids with BRCA1 mutation recapitulate early-stage carcinogenesis.
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Yucer, Nur, Ahdoot, Rodney, Workman, Michael J, Laperle, Alexander H, Recouvreux, Maria S, Kurowski, Kathleen, Naboulsi, Diana J, Liang, Victoria, Qu, Ying, Plummer, Jasmine T, Gayther, Simon A, Orsulic, Sandra, Karlan, Beth Y, and Svendsen, Clive N
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Fallopian Tubes ,Organoids ,Tumor Cells ,Cultured ,Animals ,Humans ,Mice ,Mice ,Nude ,Ovarian Neoplasms ,BRCA1 Protein ,Case-Control Studies ,Xenograft Model Antitumor Assays ,Apoptosis ,Cell Differentiation ,Cell Proliferation ,Germ-Line Mutation ,Female ,Induced Pluripotent Stem Cells ,Carcinogenesis ,carcinogenesis ,disease modeling ,fallopian tube ,induced pluripotent stem cell ,ovarian cancer ,Breast Cancer ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Stem Cell Research ,Prevention ,Clinical Research ,Ovarian Cancer ,Rare Diseases ,Stem Cell Research - Induced Pluripotent Stem Cell ,Cancer ,Aetiology ,2.1 Biological and endogenous factors ,Good Health and Well Being ,Biochemistry and Cell Biology ,Medical Physiology - Abstract
Germline pathogenic mutations in BReast CAncer (BRCA1) genes are thought to drive normal fallopian tube epithelial (FTE) cell transformation to high-grade serous ovarian cancer. No human models capture the sequence of events for disease initiation and progression. Here, we generate induced pluripotent stem cells (iPSCs) from healthy individuals and young ovarian cancer patients with germline pathogenic BRCA1 mutations (BRCA1mut). Following differentiation into FTE organoids, BRCA1mut lines exhibit cellular abnormalities consistent with neoplastic transformation compared to controls. BRCA1mut organoids show an increased production of cancer-specific proteins and survival following transplantation into mice. Organoids from women with the most aggressive ovarian cancer show the greatest pathology, indicating the potential value to predict clinical severity prior to disease onset. These human FTE organoids from BRCA1mut carriers provide a faithful physiological in vitro model of FTE lesion generation and early carcinogenesis. This platform can be used for personalized mechanistic and drug screening studies.
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- 2021
12. GMP-grade human neural progenitors delivered subretinally protect vision in rat model of retinal degeneration and survive in minipigs
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Lu, Bin, Avalos, Pablo, Svendsen, Soshana, Zhang, Changqing, Nocito, Laura, Jones, Melissa K., Pieplow, Cosmo, Saylor, Joshua, Ghiam, Sean, Block, Amanda, Fernandez, Michael, Ljubimov, Alexander V., Small, Kent, Liao, David, Svendsen, Clive N., and Wang, Shaomei
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- 2023
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13. Antiviral drug screen identifies DNA-damage response inhibitor as potent blocker of SARS-CoV-2 replication
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Garcia, Gustavo, Sharma, Arun, Ramaiah, Arunachalam, Sen, Chandani, Purkayastha, Arunima, Kohn, Donald B, Parcells, Mark S, Beck, Sebastian, Kim, Heeyoung, Bakowski, Malina A, Kirkpatrick, Melanie G, Riva, Laura, Wolff, Karen C, Han, Brandon, Yuen, Constance, Ulmert, David, Purbey, Prabhat K, Scumpia, Phillip, Beutler, Nathan, Rogers, Thomas F, Chatterjee, Arnab K, Gabriel, Gülsah, Bartenschlager, Ralf, Gomperts, Brigitte, Svendsen, Clive N, Betz, Ulrich AK, Damoiseaux, Robert D, and Arumugaswami, Vaithilingaraja
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Biological Sciences ,Bioinformatics and Computational Biology ,Coronaviruses ,Coronaviruses Therapeutics and Interventions ,Infectious Diseases ,Biodefense ,Emerging Infectious Diseases ,Lung ,Cancer ,Rare Diseases ,Orphan Drug ,Development of treatments and therapeutic interventions ,5.1 Pharmaceuticals ,Infection ,Good Health and Well Being ,A549 Cells ,Animals ,Antiviral Agents ,COVID-19 ,Chlorocebus aethiops ,DNA Damage ,Drug Evaluation ,Preclinical ,HEK293 Cells ,HeLa Cells ,Humans ,Isoxazoles ,MAP Kinase Signaling System ,Middle East Respiratory Syndrome Coronavirus ,Pyrazines ,SARS-CoV-2 ,Vero Cells ,Virus Replication ,COVID-19 Drug Treatment ,Hela Cells ,ATR kinase ,DNA-damage response pathway ,berzosertib ,high-throughput screen ,mTOR-PI3K-AKT pathway ,nucleoside analogs ,protein kinase inhibitors ,Biochemistry and Cell Biology ,Medical Physiology ,Biological sciences - Abstract
SARS-CoV-2 has currently precipitated the COVID-19 global health crisis. We developed a medium-throughput drug-screening system and identified a small-molecule library of 34 of 430 protein kinase inhibitors that were capable of inhibiting the SARS-CoV-2 cytopathic effect in human epithelial cells. These drug inhibitors are in various stages of clinical trials. We detected key proteins involved in cellular signaling pathways mTOR-PI3K-AKT, ABL-BCR/MAPK, and DNA-damage response that are critical for SARS-CoV-2 infection. A drug-protein interaction-based secondary screen confirmed compounds, such as the ATR kinase inhibitor berzosertib and torin2 with anti-SARS-CoV-2 activity. Berzosertib exhibited potent antiviral activity against SARS-CoV-2 in multiple cell types and blocked replication at the post-entry step. Berzosertib inhibited replication of SARS-CoV-1 and the Middle East respiratory syndrome coronavirus (MERS-CoV) as well. Our study highlights key promising kinase inhibitors to constrain coronavirus replication as a host-directed therapy in the treatment of COVID-19 and beyond as well as provides an important mechanism of host-pathogen interactions.
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- 2021
14. Novel nanopolymer RNA therapeutics normalize human diabetic corneal wound healing and epithelial stem cells
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Kramerov, Andrei A, Shah, Ruchi, Ding, Hui, Holler, Eggehard, Turjman, Sue, Rabinowitz, Yaron S, Ghiam, Sean, Maguen, Ezra, Svendsen, Clive N, Saghizadeh, Mehrnoosh, Ljubimova, Julia Y, and Ljubimov, Alexander V
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Biological Sciences ,Chemical Sciences ,Diabetes ,Stem Cell Research - Nonembryonic - Human ,Biotechnology ,Regenerative Medicine ,Genetics ,Stem Cell Research ,Eye Disease and Disorders of Vision ,Development of treatments and therapeutic interventions ,5.2 Cellular and gene therapies ,2.1 Biological and endogenous factors ,Aetiology ,Eye ,Adenoviridae ,Adult ,Aged ,Aged ,80 and over ,Biomarkers ,Cell Survival ,Cells ,Cultured ,Cornea ,Diabetes Mellitus ,Epithelial Cells ,Female ,Humans ,Male ,Middle Aged ,Nanoparticles ,Oligonucleotides ,Antisense ,Polymers ,RNA ,Receptors ,Cell Surface ,Signal Transduction ,Stem Cells ,Wound Healing ,Diabetic cornea ,Gene therapy ,RNA therapeutics ,miRNA ,Nanobioconjugate ,Wound healing ,Limbal stem cells ,Technology ,Nanoscience & Nanotechnology ,Biological sciences ,Chemical sciences - Abstract
Human diabetic corneas develop delayed wound healing, epithelial stem cell dysfunction, recurrent erosions, and keratitis. Adenoviral gene therapy modulating c-Met, cathepsin F and MMP-10 normalized wound healing and epithelial stem cells in organ-cultured diabetic corneas but showed toxicity in stem cell-enriched cultured limbal epithelial cells (LECs). For a safer treatment, we engineered a novel nanobiopolymer (NBC) that carried antisense oligonucleotide (AON) RNA therapeutics suppressing cathepsin F or MMP-10, and miR-409-3p that inhibits c-Met. NBC was internalized by LECs through transferrin receptor (TfR)-mediated endocytosis, inhibited cathepsin F or MMP-10 and upregulated c-Met. Non-toxic NBC modulating c-Met and cathepsin F accelerated wound healing in diabetic LECs and organ-cultured corneas vs. control NBC. NBC treatment normalized levels of stem cell markers (keratins 15 and 17, ABCG2, and ΔNp63), and signaling mediators (p-EGFR, p-Akt and p-p38). Non-toxic nano RNA therapeutics thus present a safe alternative to viral gene therapy for normalizing diabetic corneal cells.
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- 2021
15. Cross-Comparison of Human iPSC Motor Neuron Models of Familial and Sporadic ALS Reveals Early and Convergent Transcriptomic Disease Signatures
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Ho, Ritchie, Workman, Michael J, Mathkar, Pranav, Wu, Kathryn, Kim, Kevin J, O'Rourke, Jacqueline G, Kellogg, Mariko, Montel, Valerie, Banuelos, Maria G, Arogundade, Olubankole Aladesuyi, Diaz-Garcia, Sandra, Oheb, Daniel, Huang, Steven, Khrebtukova, Irina, Watson, Lisa, Ravits, John, Taylor, Kevin, Baloh, Robert H, and Svendsen, Clive N
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Biological Sciences ,Bioinformatics and Computational Biology ,Genetics ,Neurosciences ,Stem Cell Research ,Clinical Research ,Neurodegenerative ,Stem Cell Research - Induced Pluripotent Stem Cell ,Biotechnology ,ALS ,Brain Disorders ,Rare Diseases ,Human Genome ,Stem Cell Research - Nonembryonic - Human ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Aetiology ,2.1 Biological and endogenous factors ,Neurological ,Amyotrophic Lateral Sclerosis ,Animals ,Disease Models ,Animal ,Humans ,Induced Pluripotent Stem Cells ,Mice ,Motor Neurons ,ELAVL3 ,iPSC ,single-cell RNA-seq ,Biochemistry and Cell Biology ,Biochemistry and cell biology - Abstract
Induced pluripotent stem cell (iPSC)-derived neural cultures from amyotrophic lateral sclerosis (ALS) patients can model disease phenotypes. However, heterogeneity arising from genetic and experimental variability limits their utility, impacting reproducibility and the ability to track cellular origins of pathogenesis. Here, we present methodologies using single-cell RNA sequencing (scRNA-seq) analysis to address these limitations. By repeatedly differentiating and applying scRNA-seq to motor neurons (MNs) from healthy, familial ALS, sporadic ALS, and genome-edited iPSC lines across multiple patients, batches, and platforms, we account for genetic and experimental variability toward identifying unified and reproducible ALS signatures. Combining HOX and developmental gene expression with global clustering, we anatomically classified cells into rostrocaudal, progenitor, and postmitotic identities. By relaxing statistical thresholds, we discovered genes in iPSC-MNs that were concordantly dysregulated in postmortem MNs and yielded predictive ALS markers in other human and mouse models. Our approach thus revealed early, convergent, and MN-resolved signatures of ALS.
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- 2021
16. Human iPSC-derived neural progenitor cells secreting GDNF provide protection in rodent models of ALS and retinal degeneration
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Laperle, Alexander H., Moser, V. Alexandra, Avalos, Pablo, Lu, Bin, Wu, Amanda, Fulton, Aaron, Ramirez, Stephany, Garcia, Veronica J., Bell, Shaughn, Ho, Ritchie, Lawless, George, Roxas, Kristina, Shahin, Saba, Shelest, Oksana, Svendsen, Soshana, Wang, Shaomei, and Svendsen, Clive N.
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- 2023
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17. G4C2 Repeat RNA Initiates a POM121-Mediated Reduction in Specific Nucleoporins in C9orf72 ALS/FTD
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Coyne, Alyssa N, Zaepfel, Benjamin L, Hayes, Lindsey, Fitchman, Boris, Salzberg, Yuval, Luo, En-Ching, Bowen, Kelly, Trost, Hannah, Aigner, Stefan, Rigo, Frank, Yeo, Gene W, Harel, Amnon, Svendsen, Clive N, Sareen, Dhruv, and Rothstein, Jeffrey D
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Biomedical and Clinical Sciences ,Neurosciences ,Alzheimer's Disease Related Dementias (ADRD) ,Rare Diseases ,Frontotemporal Dementia (FTD) ,ALS ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Genetics ,Neurodegenerative ,Brain Disorders ,Acquired Cognitive Impairment ,Stem Cell Research ,Stem Cell Research - Induced Pluripotent Stem Cell ,Dementia ,Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD) ,Neurological ,Active Transport ,Cell Nucleus ,Amyotrophic Lateral Sclerosis ,C9orf72 Protein ,Cells ,Cultured ,Frontotemporal Dementia ,HEK293 Cells ,Humans ,Induced Pluripotent Stem Cells ,Membrane Glycoproteins ,Neural Stem Cells ,Nuclear Pore ,Nuclear Pore Complex Proteins ,C9orf72 ,FTD ,POM121 ,neurodegeneration ,nuclear pore complex ,Psychology ,Cognitive Sciences ,Neurology & Neurosurgery ,Biological psychology - Abstract
Through mechanisms that remain poorly defined, defects in nucleocytoplasmic transport and accumulations of specific nuclear-pore-complex-associated proteins have been reported in multiple neurodegenerative diseases, including C9orf72 Amyotrophic Lateral Sclerosis and Frontotemporal Dementia (ALS/FTD). Using super-resolution structured illumination microscopy, we have explored the mechanism by which nucleoporins are altered in nuclei isolated from C9orf72 induced pluripotent stem-cell-derived neurons (iPSNs). Of the 23 nucleoporins evaluated, we observed a reduction in a subset of 8, including key components of the nuclear pore complex scaffold and the transmembrane nucleoporin POM121. Reduction in POM121 appears to initiate a decrease in the expression of seven additional nucleoporins, ultimately affecting the localization of Ran GTPase and subsequent cellular toxicity in C9orf72 iPSNs. Collectively, our data suggest that the expression of expanded C9orf72 ALS/FTD repeat RNA alone affects nuclear POM121 expression in the initiation of a pathological cascade affecting nucleoporin levels within neuronal nuclei and ultimately downstream neuronal survival.
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- 2020
18. Human iPSC-Derived Cardiomyocytes Are Susceptible to SARS-CoV-2 Infection
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Sharma, Arun, Garcia, Gustavo, Wang, Yizhou, Plummer, Jasmine T, Morizono, Kouki, Arumugaswami, Vaithilingaraja, and Svendsen, Clive N
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Medical Microbiology ,Biomedical and Clinical Sciences ,Pneumonia & Influenza ,Regenerative Medicine ,Pneumonia ,Vaccine Related ,Heart Disease ,Lung ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Cardiovascular ,Stem Cell Research ,Stem Cell Research - Induced Pluripotent Stem Cell ,Biodefense ,Infectious Diseases ,Emerging Infectious Diseases ,Clinical Research ,Prevention ,2.1 Biological and endogenous factors ,Aetiology ,Infection ,Good Health and Well Being ,COVID-19 ,SARS-CoV-2 ,cardiology ,cardiomyocytes ,cardiovascular biology ,coronavirus ,heart ,induced pluripotent stem cells ,stem cell ,viral myocarditis ,Biomedical and clinical sciences - Abstract
Coronavirus disease 2019 (COVID-19) is a pandemic caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). COVID-19 is defined by respiratory symptoms, but cardiac complications including viral myocarditis are also prevalent. Although ischemic and inflammatory responses caused by COVID-19 can detrimentally affect cardiac function, the direct impact of SARS-CoV-2 infection on human cardiomyocytes is not well understood. Here, we utilize human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) as a model to examine the mechanisms of cardiomyocyte-specific infection by SARS-CoV-2. Microscopy and RNA sequencing demonstrate that SARS-CoV-2 can enter hiPSC-CMs via ACE2. Viral replication and cytopathic effect induce hiPSC-CM apoptosis and cessation of beating after 72 h of infection. SARS-CoV-2 infection activates innate immune response and antiviral clearance gene pathways, while inhibiting metabolic pathways and suppressing ACE2 expression. These studies show that SARS-CoV-2 can infect hiPSC-CMs in vitro, establishing a model for elucidating infection mechanisms and potentially a cardiac-specific antiviral drug screening platform.
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- 2020
19. Transplantation of human neural progenitor cells secreting GDNF into the spinal cord of patients with ALS: a phase 1/2a trial
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Baloh, Robert H., Johnson, J. Patrick, Avalos, Pablo, Allred, Peggy, Svendsen, Soshana, Gowing, Genevieve, Roxas, Kristina, Wu, Amanda, Donahue, Becky, Osborne, Sheryl, Lawless, George, Shelley, Brandon, Wheeler, Koral, Prina, Carolyn, Fine, Dana, Kendra-Romito, Tami, Stokes, Haniah, Manoukian, Vicki, Muthukumaran, Abirami, Garcia, Leslie, Bañuelos, Maria G., Godoy, Marlesa, Bresee, Catherine, Yu, Hong, Drazin, Doniel, Ross, Lindsey, Naruse, Robert, Babu, Harish, Macklin, Eric A., Vo, Ashley, Elsayegh, Ashraf, Tourtellotte, Warren, Maya, Marcel, Burford, Matthew, Diaz, Frank, Patil, Chirag G., Lewis, Richard A., and Svendsen, Clive N.
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- 2022
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20. In Vitro and In Vivo Proteomic Comparison of Human Neural Progenitor Cell‐Induced Photoreceptor Survival
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Jones, Melissa K, Lu, Bin, Chen, Dawn Zhaohui, Spivia, Weston R, Mercado, Augustus T, Ljubimov, Alexander V, Svendsen, Clive N, Eyk, Jennifer E, and Wang, Shaomei
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Biomedical and Clinical Sciences ,Ophthalmology and Optometry ,Aging ,Neurosciences ,Stem Cell Research ,Stem Cell Research - Embryonic - Human ,Neurodegenerative ,Eye Disease and Disorders of Vision ,Biotechnology ,5.1 Pharmaceuticals ,5.2 Cellular and gene therapies ,Development of treatments and therapeutic interventions ,2.1 Biological and endogenous factors ,Aetiology ,Eye ,Cell Survival ,Cells ,Cultured ,Eye Proteins ,Humans ,Neural Stem Cells ,Photoreceptor Cells ,Proteomics ,Retinal Degeneration ,human neural progenitor cells ,neuroprotection ,retinal degeneration ,stem cells ,transplantation ,transplantation ,Biological Sciences ,Information and Computing Sciences ,Medical and Health Sciences ,Biochemistry & Molecular Biology ,Biological sciences ,Biomedical and clinical sciences - Abstract
Retinal degenerative diseases lead to blindness with few treatments. Various cell-based therapies are aimed to slow the progression of vision loss by preserving light-sensing photoreceptor cells. A subretinal injection of human neural progenitor cells (hNPCs) into the Royal College of Surgeons (RCS) rat model of retinal degeneration has aided in photoreceptor survival, though the mechanisms are mainly unknown. Identifying the retinal proteomic changes that occur following hNPC treatment leads to better understanding of neuroprotection. To mimic the retinal environment following hNPC injection, a co-culture system of retinas and hNPCs is developed. Less cell death occurs in RCS retinal tissue co-cultured with hNPCs than in retinas cultured alone, suggesting that hNPCs provide retinal protection in vitro. Comparison of ex vivo and in vivo retinas identifies nuclear factor (erythroid-derived 2)-like 2 (NRF2) mediated oxidative response signaling as an hNPC-induced pathway. This is the first study to compare proteomic changes following treatment with hNPCs in both an ex vivo and in vivo environment, further allowing the use of ex vivo modeling for mechanisms of retinal preservation. Elucidation of the protein changes in the retina following hNPC treatment may lead to the discovery of mechanisms of photoreceptor survival and its therapeutic for clinical applications.
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- 2019
21. Regenerative and restorative medicine for eye disease
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Van Gelder, Russell N., Chiang, Michael F., Dyer, Michael A., Greenwell, Thomas N., Levin, Leonard A., Wong, Rachel O., and Svendsen, Clive N.
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- 2022
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22. Genome-wide Analyses Identify KIF5A as a Novel ALS Gene.
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Nicolas, Aude, Kenna, Kevin P, Renton, Alan E, Ticozzi, Nicola, Faghri, Faraz, Chia, Ruth, Dominov, Janice A, Kenna, Brendan J, Nalls, Mike A, Keagle, Pamela, Rivera, Alberto M, van Rheenen, Wouter, Murphy, Natalie A, van Vugt, Joke JFA, Geiger, Joshua T, Van der Spek, Rick A, Pliner, Hannah A, Shankaracharya, Smith, Bradley N, Marangi, Giuseppe, Topp, Simon D, Abramzon, Yevgeniya, Gkazi, Athina Soragia, Eicher, John D, Kenna, Aoife, ITALSGEN Consortium, Mora, Gabriele, Calvo, Andrea, Mazzini, Letizia, Riva, Nilo, Mandrioli, Jessica, Caponnetto, Claudia, Battistini, Stefania, Volanti, Paolo, La Bella, Vincenzo, Conforti, Francesca L, Borghero, Giuseppe, Messina, Sonia, Simone, Isabella L, Trojsi, Francesca, Salvi, Fabrizio, Logullo, Francesco O, D'Alfonso, Sandra, Corrado, Lucia, Capasso, Margherita, Ferrucci, Luigi, Genomic Translation for ALS Care (GTAC) Consortium, Moreno, Cristiane de Araujo Martins, Kamalakaran, Sitharthan, Goldstein, David B, ALS Sequencing Consortium, Gitler, Aaron D, Harris, Tim, Myers, Richard M, NYGC ALS Consortium, Phatnani, Hemali, Musunuri, Rajeeva Lochan, Evani, Uday Shankar, Abhyankar, Avinash, Zody, Michael C, Answer ALS Foundation, Kaye, Julia, Finkbeiner, Steven, Wyman, Stacia K, LeNail, Alex, Lima, Leandro, Fraenkel, Ernest, Svendsen, Clive N, Thompson, Leslie M, Van Eyk, Jennifer E, Berry, James D, Miller, Timothy M, Kolb, Stephen J, Cudkowicz, Merit, Baxi, Emily, Clinical Research in ALS and Related Disorders for Therapeutic Development (CReATe) Consortium, Benatar, Michael, Taylor, J Paul, Rampersaud, Evadnie, Wu, Gang, Wuu, Joanne, SLAGEN Consortium, Lauria, Giuseppe, Verde, Federico, Fogh, Isabella, Tiloca, Cinzia, Comi, Giacomo P, Sorarù, Gianni, Cereda, Cristina, French ALS Consortium, Corcia, Philippe, Laaksovirta, Hannu, Myllykangas, Liisa, Jansson, Lilja, Valori, Miko, Ealing, John, Hamdalla, Hisham, Rollinson, Sara, Pickering-Brown, Stuart, and Orrell, Richard W
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ITALSGEN Consortium ,Genomic Translation for ALS Care (GTAC) Consortium ,ALS Sequencing Consortium ,NYGC ALS Consortium ,Answer ALS Foundation ,Clinical Research in ALS and Related Disorders for Therapeutic Development (CReATe) Consortium ,SLAGEN Consortium ,French ALS Consortium ,Project MinE ALS Sequencing Consortium ,Humans ,Amyotrophic Lateral Sclerosis ,Cohort Studies ,Amino Acid Sequence ,Adult ,Aged ,Aged ,80 and over ,Middle Aged ,Female ,Male ,Genome-Wide Association Study ,Young Adult ,Loss of Function Mutation ,Kinesins ,ALS ,GWAS ,KIF5A ,WES ,WGS ,axonal transport ,cargo ,Brain Disorders ,Genetics ,Human Genome ,Rare Diseases ,Neurosciences ,Neurodegenerative ,Aetiology ,2.1 Biological and endogenous factors ,Neurological ,Psychology ,Cognitive Sciences ,Neurology & Neurosurgery - Abstract
To identify novel genes associated with ALS, we undertook two lines of investigation. We carried out a genome-wide association study comparing 20,806 ALS cases and 59,804 controls. Independently, we performed a rare variant burden analysis comparing 1,138 index familial ALS cases and 19,494 controls. Through both approaches, we identified kinesin family member 5A (KIF5A) as a novel gene associated with ALS. Interestingly, mutations predominantly in the N-terminal motor domain of KIF5A are causative for two neurodegenerative diseases: hereditary spastic paraplegia (SPG10) and Charcot-Marie-Tooth type 2 (CMT2). In contrast, ALS-associated mutations are primarily located at the C-terminal cargo-binding tail domain and patients harboring loss-of-function mutations displayed an extended survival relative to typical ALS cases. Taken together, these results broaden the phenotype spectrum resulting from mutations in KIF5A and strengthen the role of cytoskeletal defects in the pathogenesis of ALS.
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- 2018
23. The Library of Integrated Network-Based Cellular Signatures NIH Program: System-Level Cataloging of Human Cells Response to Perturbations
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Keenan, Alexandra B, Jenkins, Sherry L, Jagodnik, Kathleen M, Koplev, Simon, He, Edward, Torre, Denis, Wang, Zichen, Dohlman, Anders B, Silverstein, Moshe C, Lachmann, Alexander, Kuleshov, Maxim V, Ma'ayan, Avi, Stathias, Vasileios, Terryn, Raymond, Cooper, Daniel, Forlin, Michele, Koleti, Amar, Vidovic, Dusica, Chung, Caty, Schürer, Stephan C, Vasiliauskas, Jouzas, Pilarczyk, Marcin, Shamsaei, Behrouz, Fazel, Mehdi, Ren, Yan, Niu, Wen, Clark, Nicholas A, White, Shana, Mahi, Naim, Zhang, Lixia, Kouril, Michal, Reichard, John F, Sivaganesan, Siva, Medvedovic, Mario, Meller, Jaroslaw, Koch, Rick J, Birtwistle, Marc R, Iyengar, Ravi, Sobie, Eric A, Azeloglu, Evren U, Kaye, Julia, Osterloh, Jeannette, Haston, Kelly, Kalra, Jaslin, Finkbiener, Steve, Li, Jonathan, Milani, Pamela, Adam, Miriam, Escalante-Chong, Renan, Sachs, Karen, Lenail, Alex, Ramamoorthy, Divya, Fraenkel, Ernest, Daigle, Gavin, Hussain, Uzma, Coye, Alyssa, Rothstein, Jeffrey, Sareen, Dhruv, Ornelas, Loren, Banuelos, Maria, Mandefro, Berhan, Ho, Ritchie, Svendsen, Clive N, Lim, Ryan G, Stocksdale, Jennifer, Casale, Malcolm S, Thompson, Terri G, Wu, Jie, Thompson, Leslie M, Dardov, Victoria, Venkatraman, Vidya, Matlock, Andrea, Van Eyk, Jennifer E, Jaffe, Jacob D, Papanastasiou, Malvina, Subramanian, Aravind, Golub, Todd R, Erickson, Sean D, Fallahi-Sichani, Mohammad, Hafner, Marc, Gray, Nathanael S, Lin, Jia-Ren, Mills, Caitlin E, Muhlich, Jeremy L, Niepel, Mario, Shamu, Caroline E, Williams, Elizabeth H, Wrobel, David, Sorger, Peter K, Heiser, Laura M, Gray, Joe W, Korkola, James E, Mills, Gordon B, LaBarge, Mark, Feiler, Heidi S, Dane, Mark A, Bucher, Elmar, Nederlof, Michel, Sudar, Damir, and Gross, Sean
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Bioengineering ,Cancer ,Genetics ,Biotechnology ,2.1 Biological and endogenous factors ,Aetiology ,Generic health relevance ,Good Health and Well Being ,Cataloging ,Computational Biology ,Databases ,Chemical ,Gene Expression Profiling ,Gene Library ,Humans ,Information Storage and Retrieval ,National Health Programs ,National Institutes of Health (U.S.) ,Systems Biology ,Transcriptome ,United States ,BD2K ,L1000 ,MCF10A ,MEMA ,P100 ,data integration ,lincsprogram ,lincsproject ,systems biology ,systems pharmacology ,Biochemistry and Cell Biology - Abstract
The Library of Integrated Network-Based Cellular Signatures (LINCS) is an NIH Common Fund program that catalogs how human cells globally respond to chemical, genetic, and disease perturbations. Resources generated by LINCS include experimental and computational methods, visualization tools, molecular and imaging data, and signatures. By assembling an integrated picture of the range of responses of human cells exposed to many perturbations, the LINCS program aims to better understand human disease and to advance the development of new therapies. Perturbations under study include drugs, genetic perturbations, tissue micro-environments, antibodies, and disease-causing mutations. Responses to perturbations are measured by transcript profiling, mass spectrometry, cell imaging, and biochemical methods, among other assays. The LINCS program focuses on cellular physiology shared among tissues and cell types relevant to an array of diseases, including cancer, heart disease, and neurodegenerative disorders. This Perspective describes LINCS technologies, datasets, tools, and approaches to data accessibility and reusability.
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- 2018
24. Microglial transcription profiles in mouse and human are driven by APOE4 and sex
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Moser, V. Alexandra, Workman, Michael J., Hurwitz, Samantha J., Lipman, Rachel M., Pike, Christian J., and Svendsen, Clive N.
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- 2021
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25. An integrated multi-omic analysis of iPSC-derived motor neurons from C9ORF72 ALS patients
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Phatnani, Hemali, Kwan, Justin, Sareen, Dhruv, Broach, James R., Simmons, Zachary, Arcila-Londono, Ximena, Lee, Edward B., Van Deerlin, Vivianna M., Shneider, Neil A., Fraenkel, Ernest, Ostrow, Lyle W., Baas, Frank, Zaitlen, Noah, Berry, James D., Malaspina, Andrea, Fratta, Pietro, Cox, Gregory A., Thompson, Leslie M., Finkbeiner, Steve, Dardiotis, Efthimios, Miller, Timothy M., Chandran, Siddharthan, Pal, Suvankar, Hornstein, Eran, MacGowan, Daniel J., Heiman-Patterson, Terry, Hammell, Molly G., Patsopoulos, Nikolaos.A., Butovsky, Oleg, Dubnau, Joshua, Nath, Avindra, Bowser, Robert, Harms, Matt, Poss, Mary, Phillips-Cremins, Jennifer, Crary, John, Atassi, Nazem, Lange, Dale J., Adams, Darius J., Stefanis, Leonidas, Gotkine, Marc, Baloh, Robert H., Babu, Suma, Raj, Towfique, Paganoni, Sabrina, Shalem, Ophir, Smith, Colin, Zhang, Bin, Harris, Brent, Broce, Iris, Drory, Vivian, Ravits, John, McMillan, Corey, Menon, Vilas, Wu, Lani, Altschuler, Steven, Li, Jonathan, Lim, Ryan G., Kaye, Julia A., Dardov, Victoria, Coyne, Alyssa N., Wu, Jie, Milani, Pamela, Cheng, Andrew, Thompson, Terri G., Ornelas, Loren, Frank, Aaron, Adam, Miriam, Banuelos, Maria G., Casale, Malcolm, Cox, Veerle, Escalante-Chong, Renan, Daigle, J. Gavin, Gomez, Emilda, Hayes, Lindsey, Holewenski, Ronald, Lei, Susan, Lenail, Alex, Lima, Leandro, Mandefro, Berhan, Matlock, Andrea, Panther, Lindsay, Patel-Murray, Natasha Leanna, Pham, Jacqueline, Ramamoorthy, Divya, Sachs, Karen, Shelley, Brandon, Stocksdale, Jennifer, Trost, Hannah, Wilhelm, Mark, Venkatraman, Vidya, Wassie, Brook T., Wyman, Stacia, Yang, Stephanie, Van Eyk, Jennifer E., Lloyd, Thomas E., Finkbeiner, Steven, Rothstein, Jeffrey D., and Svendsen, Clive N.
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- 2021
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26. Concise Review: Stem Cells for Corneal Wound Healing
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Saghizadeh, Mehrnoosh, Kramerov, Andrei A, Svendsen, Clive N, and Ljubimov, Alexander V
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Medical Biotechnology ,Biomedical and Clinical Sciences ,Ophthalmology and Optometry ,Regenerative Medicine ,Physical Injury - Accidents and Adverse Effects ,Eye Disease and Disorders of Vision ,Stem Cell Research - Nonembryonic - Human ,Transplantation ,Stem Cell Research ,Stem Cell Research - Nonembryonic - Non-Human ,5.2 Cellular and gene therapies ,Aetiology ,2.1 Biological and endogenous factors ,Development of treatments and therapeutic interventions ,Eye ,Humans ,Stem Cells ,Wound Healing ,Corneal epithelium ,Keratocyte ,Corneal endothelium ,Wound healing ,Gene therapy ,Stem cell ,Pluripotent stem cell ,Cell transplantation ,Biological Sciences ,Technology ,Medical and Health Sciences ,Immunology ,Biological sciences ,Biomedical and clinical sciences - Abstract
Corneal wound healing is a complex process that occurs in response to various injuries and commonly used refractive surgery. It is a significant clinical problem, which may lead to serious complications due to either incomplete (epithelial) or excessive (stromal) healing. Epithelial stem cells clearly play a role in this process, whereas the contribution of stromal and endothelial progenitors is less well studied. The available evidence on stem cell participation in corneal wound healing is reviewed, together with the data on the use of corneal and non-corneal stem cells to facilitate this process in diseased or postsurgical conditions. Important aspects of corneal stem cell generation from alternative cell sources, including pluripotent stem cells, for possible transplantation upon corneal injuries or in disease conditions are also presented. Stem Cells 2017;35:2105-2114.
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- 2017
27. Directed Differentiation of Human Induced Pluripotent Stem Cells into Fallopian Tube Epithelium.
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Yucer, Nur, Holzapfel, Marie, Jenkins Vogel, Tilley, Lenaeus, Lindsay, Ornelas, Loren, Laury, Anna, Sareen, Dhruv, Barrett, Robert, Karlan, Beth Y, and Svendsen, Clive N
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Fallopian Tubes ,Epithelium ,Mucous Membrane ,Cell Line ,Epithelial Cells ,Mesoderm ,Humans ,Cell Differentiation ,Models ,Biological ,Female ,Induced Pluripotent Stem Cells ,Clinical Research ,Regenerative Medicine ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Stem Cell Research ,Stem Cell Research - Induced Pluripotent Stem Cell ,Cancer ,Stem Cell Research - Embryonic - Human ,Models ,Biological ,Biochemistry and Cell Biology ,Other Physical Sciences - Abstract
The fallopian tube epithelium (FTE) has been recognized as a site of origin of high-grade serous ovarian cancer (HGSC). However, the absence of relevant in vitro human models that can recapitulate tissue-specific architecture has hindered our understanding of FTE transformation and initiation of HGSC. Here, induced pluripotent stem cells (iPSCs) were used to establish a novel 3-dimensional (3D) human FTE organoid in vitro model containing the relevant cell types of the human fallopian tube as well as a luminal architecture that closely reflects the organization of fallopian tissues in vivo. Modulation of Wnt and BMP signaling directed iPSC differentiation into Müllerian cells and subsequent use of pro-Müllerian growth factors promoted FTE precursors. The expression and localization of Müllerian markers verified correct cellular differentiation. An innovative 3D growth platform, which enabled the FTE organoid to self-organize into a convoluted luminal structure, permitted matured differentiation to a FTE lineage. This powerful human-derived FTE organoid model can be used to study the earliest stages of HGSC development and to identify novel and specific biomarkers of early fallopian tube epithelial cell transformation.
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- 2017
28. Patients with ALS show highly correlated progression rates in left and right limb muscles
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Rushton, David J, Andres, Patricia L, Allred, Peggy, Baloh, Robert H, and Svendsen, Clive N
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Biomedical and Clinical Sciences ,Neurosciences ,Clinical Sciences ,Neurodegenerative ,Clinical Research ,Rare Diseases ,ALS ,Brain Disorders ,Neurological ,Musculoskeletal ,Adult ,Amyotrophic Lateral Sclerosis ,Disease Progression ,Extremities ,Follow-Up Studies ,Humans ,Models ,Statistical ,Muscle Strength ,Muscle ,Skeletal ,Neurologic Examination ,Cognitive Sciences ,Neurology & Neurosurgery ,Clinical sciences - Abstract
ObjectiveAmyotrophic lateral sclerosis (ALS) progresses at different rates between patients, making clinical trial design difficult and dependent on large cohorts of patients. Currently, there are few data showing whether the left and right limbs progress at the same or different rates. This study addresses rates of decline in specific muscle groups of patients with ALS and assesses whether there is a relationship between left and right muscles in the same patient, regardless of overall progression.MethodsA large cohort of patients was used to assess decline in muscle strength in right and left limbs over time using 2 different methods: The Tufts Quantitative Neuromuscular Exam and Accurate Test of Limb Isometric Strength protocol. Then advanced linear regression statistical methods were applied to assess progression rates in each limb.ResultsThis report shows that linearized progression models can predict general slopes of decline with good accuracy. Critically, the data demonstrate that while overall decline is variable, there is a high degree of correlation between left and right muscle decline in ALS. This implies that irrespective of which muscle starts declining soonest or latest, their rates of decline following onset are more consistent.ConclusionsFirst, this study demonstrates a high degree of power when using unilateral treatment approaches to detect a slowing in disease progression in smaller groups of patients, thus allowing for paired statistical tests. These findings will be useful in transplantation trials that use muscle decline to track disease progression in ALS. Second, these findings discuss methods, such as tactical selection of muscle groups, which can improve the power efficiency of all ALS clinical trials.
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- 2017
29. Modeling Psychomotor Retardation using iPSCs from MCT8-Deficient Patients Indicates a Prominent Role for the Blood-Brain Barrier
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Vatine, Gad D, Al-Ahmad, Abraham, Barriga, Bianca K, Svendsen, Soshana, Salim, Ariel, Garcia, Leslie, Garcia, Veronica J, Ho, Ritchie, Yucer, Nur, Qian, Tongcheng, Lim, Ryan G, Wu, Jie, Thompson, Leslie M, Spivia, Weston R, Chen, Zhaohui, Van Eyk, Jennifer, Palecek, Sean P, Refetoff, Samuel, Shusta, Eric V, and Svendsen, Clive N
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Biological Sciences ,Biomedical and Clinical Sciences ,Pediatric ,Stem Cell Research - Nonembryonic - Human ,Stem Cell Research ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Neurodegenerative ,Stem Cell Research - Induced Pluripotent Stem Cell ,Neurosciences ,Aetiology ,1.1 Normal biological development and functioning ,Underpinning research ,2.1 Biological and endogenous factors ,Neurological ,Blood-Brain Barrier ,Cell Line ,Female ,Humans ,Induced Pluripotent Stem Cells ,Male ,Monocarboxylic Acid Transporters ,Neurons ,Psychomotor Disorders ,Symporters ,MCT8 ,T3 ,blood brain barrier ,disease model ,iPSC ,induced pluripotent stem cells ,monocarboxyl transporter 8 ,neuronal maturation ,thyroid ,thyroid hormone ,Medical and Health Sciences ,Developmental Biology ,Biological sciences ,Biomedical and clinical sciences - Abstract
Inactivating mutations in the thyroid hormone (TH) transporter Monocarboxylate transporter 8 (MCT8) cause severe psychomotor retardation in children. Animal models do not reflect the biology of the human disease. Using patient-specific induced pluripotent stem cells (iPSCs), we generated MCT8-deficient neural cells that showed normal TH-dependent neuronal properties and maturation. However, the blood-brain barrier (BBB) controls TH entry into the brain, and reduced TH availability to neural cells could instead underlie the diseased phenotype. To test potential BBB involvement, we generated an iPSC-based BBB model of MCT8 deficiency, and we found that MCT8 was necessary for polarized influx of the active form of TH across the BBB. We also found that a candidate drug did not appreciably cross the mutant BBB. Our results therefore clarify the underlying physiological basis of this disorder, and they suggest that circumventing the diseased BBB to deliver active TH to the brain could be a viable therapeutic strategy.
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- 2017
30. Human Neural Progenitor Transplantation Rescues Behavior and Reduces α-Synuclein in a Transgenic Model of Dementia with Lewy Bodies
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Goldberg, Natalie RS, Marsh, Samuel E, Ochaba, Joseph, Shelley, Brandon C, Davtyan, Hayk, Thompson, Leslie M, Steffan, Joan S, Svendsen, Clive N, and Blurton-Jones, Mathew
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Medical Biotechnology ,Biomedical and Clinical Sciences ,Transplantation ,Dementia ,Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD) ,Stem Cell Research - Nonembryonic - Human ,Regenerative Medicine ,Lewy Body Dementia ,Parkinson's Disease ,Neurosciences ,Neurodegenerative ,Alzheimer's Disease Related Dementias (ADRD) ,Brain Disorders ,Stem Cell Research - Nonembryonic - Non-Human ,Aging ,Stem Cell Research ,Acquired Cognitive Impairment ,Development of treatments and therapeutic interventions ,Aetiology ,5.2 Cellular and gene therapies ,2.1 Biological and endogenous factors ,Neurological ,Animals ,Astrocytes ,Cells ,Cultured ,Humans ,Lewy Body Disease ,Memory ,Mice ,Neural Stem Cells ,Neurogenesis ,Stem Cell Transplantation ,alpha-Synuclein ,Synucleinopathy ,Glial progenitor ,Astrocyte ,Dopamine ,Glutamate ,Pathology ,Biochemistry and Cell Biology ,Clinical Sciences ,Medical biotechnology ,Biomedical engineering - Abstract
Synucleinopathies are a group of neurodegenerative disorders sharing the common feature of misfolding and accumulation of the presynaptic protein α-synuclein (α-syn) into insoluble aggregates. Within this diverse group, Dementia with Lewy Bodies (DLB) is characterized by the aberrant accumulation of α-syn in cortical, hippocampal, and brainstem neurons, resulting in multiple cellular stressors that particularly impair dopamine and glutamate neurotransmission and related motor and cognitive function. Recent studies show that murine neural stem cell (NSC) transplantation can improve cognitive or motor function in transgenic models of Alzheimer's and Huntington's disease, and DLB. However, examination of clinically relevant human NSCs in these models is hindered by the challenges of xenotransplantation and the confounding effects of immunosuppressant drugs on pathology and behavior. To address this challenge, we developed an immune-deficient transgenic model of DLB that lacks T-, B-, and NK-cells, yet exhibits progressive accumulation of human α-syn (h-α-syn)-laden inclusions and cognitive and motor impairments. We demonstrate that clinically relevant human neural progenitor cells (line CNS10-hNPCs) survive, migrate extensively and begin to differentiate preferentially into astrocytes following striatal transplantation into this DLB model. Critically, grafted CNS10-hNPCs rescue both cognitive and motor deficits after 1 and 3 months and, furthermore, restore striatal dopamine and glutamate systems. These behavioral and neurochemical benefits are likely achieved by reducing α-syn oligomers. Collectively, these results using a new model of DLB demonstrate that hNPC transplantation can impact a broad array of disease mechanisms and phenotypes and suggest a cellular therapeutic strategy that should be pursued. Stem Cells Translational Medicine 2017;6:1477-1490.
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- 2017
31. Huntington’s Disease iPSC-Derived Brain Microvascular Endothelial Cells Reveal WNT-Mediated Angiogenic and Blood-Brain Barrier Deficits
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Lim, Ryan G, Quan, Chris, Reyes-Ortiz, Andrea M, Lutz, Sarah E, Kedaigle, Amanda J, Gipson, Theresa A, Wu, Jie, Vatine, Gad D, Stocksdale, Jennifer, Casale, Malcolm S, Svendsen, Clive N, Fraenkel, Ernest, Housman, David E, Agalliu, Dritan, and Thompson, Leslie M
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Biological Sciences ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Neurosciences ,Huntington's Disease ,Rare Diseases ,Stem Cell Research - Nonembryonic - Human ,Stem Cell Research - Induced Pluripotent Stem Cell ,Stem Cell Research ,Orphan Drug ,Brain Disorders ,Neurodegenerative ,2.1 Biological and endogenous factors ,Aetiology ,Neurological ,Blood-Brain Barrier ,Endothelial Cells ,Gene Regulatory Networks ,Humans ,Huntington Disease ,Induced Pluripotent Stem Cells ,Microvessels ,Neovascularization ,Physiologic ,Transcriptome ,Transcytosis ,Wnt Signaling Pathway ,beta Catenin ,BMEC ,Huntington’s disease ,RNA sequencing ,WNT signaling ,angiogenesis ,blood-brain barrier ,brain microvascular endothelial cell ,epigenetics ,induced pluripotent stem cell ,neurodegeneration ,transcriptome ,Biochemistry and Cell Biology ,Medical Physiology ,Biological sciences - Abstract
Brain microvascular endothelial cells (BMECs) are an essential component of the blood-brain barrier (BBB) that shields the brain against toxins and immune cells. While BBB dysfunction exists in neurological disorders, including Huntington's disease (HD), it is not known if BMECs themselves are functionally compromised to promote BBB dysfunction. Further, the underlying mechanisms of BBB dysfunction remain elusive given limitations with mouse models and post-mortem tissue to identify primary deficits. We undertook a transcriptome and functional analysis of human induced pluripotent stem cell (iPSC)-derived BMECs (iBMEC) from HD patients or unaffected controls. We demonstrate that HD iBMECs have intrinsic abnormalities in angiogenesis and barrier properties, as well as in signaling pathways governing these processes. Thus, our findings provide an iPSC-derived BBB model for a neurodegenerative disease and demonstrate autonomous neurovascular deficits that may underlie HD pathology with implications for therapeutics and drug delivery.
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- 2017
32. Developmental alterations in Huntington's disease neural cells and pharmacological rescue in cells and mice
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Lim, Ryan G, Salazar, Lisa L, Wilton, Daniel K, King, Alvin R, Stocksdale, Jennifer T, Sharifabad, Delaram, Lau, Alice L, Stevens, Beth, Reidling, Jack C, Winokur, Sara T, Casale, Malcolm S, Thompson, Leslie M, Pardo, Monica, Gerardo Garcia Diaz-Barriga, A, Straccia, Marco, Sanders, Phil, Alberch, Jordi, Canals, Josep M, Kaye, Julia A, Dunlap, Mariah, Jo, Lisa, May, Hanna, Mount, Elliot, Anderson-Bergman, Cliff, Haston, Kelly, Finkbeiner, Steven, Kedaigle, Amanda J, Gipson, Theresa A, Yildirim, Ferah, Ng, Christopher W, Milani, Pamela, Housman, David E, Fraenkel, Ernest, Allen, Nicholas D, Kemp, Paul J, Atwal, Ranjit Singh, Biagioli, Marta, Gusella, James F, MacDonald, Marcy E, Akimov, Sergey S, Arbez, Nicolas, Stewart, Jacqueline, Ross, Christopher A, Mattis, Virginia B, Tom, Colton M, Ornelas, Loren, Sahabian, Anais, Lenaeus, Lindsay, Mandefro, Berhan, Sareen, Dhruv, and Svendsen, Clive N
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Biomedical and Clinical Sciences ,Neurosciences ,Rare Diseases ,Regenerative Medicine ,Brain Disorders ,Neurodegenerative ,Stem Cell Research - Induced Pluripotent Stem Cell - Human ,Huntington's Disease ,Stem Cell Research - Nonembryonic - Human ,Stem Cell Research ,Stem Cell Research - Induced Pluripotent Stem Cell ,Aetiology ,2.1 Biological and endogenous factors ,Neurological ,Animals ,Basic Helix-Loop-Helix Transcription Factors ,Cells ,Cultured ,Cognitive Dysfunction ,Corpus Striatum ,Epigenomics ,Gene Expression ,Gene Expression Profiling ,Gene Knockdown Techniques ,Histones ,Humans ,Huntingtin Protein ,Huntington Disease ,Induced Pluripotent Stem Cells ,Isoxazoles ,Mice ,Mice ,Transgenic ,Nerve Tissue Proteins ,Neurogenesis ,Neurons ,Peptides ,Signal Transduction ,Thiophenes ,HD iPSC Consortium ,Psychology ,Cognitive Sciences ,Neurology & Neurosurgery ,Biological psychology - Abstract
Neural cultures derived from Huntington's disease (HD) patient-derived induced pluripotent stem cells were used for 'omics' analyses to identify mechanisms underlying neurodegeneration. RNA-seq analysis identified genes in glutamate and GABA signaling, axonal guidance and calcium influx whose expression was decreased in HD cultures. One-third of gene changes were in pathways regulating neuronal development and maturation. When mapped to stages of mouse striatal development, the profiles aligned with earlier embryonic stages of neuronal differentiation. We observed a strong correlation between HD-related histone marks, gene expression and unique peak profiles associated with dysregulated genes, suggesting a coordinated epigenetic program. Treatment with isoxazole-9, which targets key dysregulated pathways, led to amelioration of expanded polyglutamine repeat-associated phenotypes in neural cells and of cognitive impairment and synaptic pathology in HD model R6/2 mice. These data suggest that mutant huntingtin impairs neurodevelopmental pathways that could disrupt synaptic homeostasis and increase vulnerability to the pathologic consequence of expanded polyglutamine repeats over time.
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- 2017
33. Novel nanopolymer RNA therapeutics normalize human diabetic corneal wound healing and epithelial stem cells
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Kramerov, Andrei A., Shah, Ruchi, Ding, Hui, Holler, Eggehard, Turjman, Sue, Rabinowitz, Yaron S., Ghiam, Sean, Maguen, Ezra, Svendsen, Clive N., Saghizadeh, Mehrnoosh, Ljubimova, Julia Y., and Ljubimov, Alexander V.
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- 2021
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34. Immunosuppressive Functions of M2 Macrophages Derived from iPSCs of Patients with ALS and Healthy Controls
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Zhao, Weihua, Beers, David R., Thonhoff, Jason R., Thome, Aaron D., Faridar, Alireza, Wang, Jinghong, Wen, Shixiang, Ornelas, Loren, Sareen, Dhruv, Goodridge, Helen S., Svendsen, Clive N., and Appel, Stanley H.
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- 2020
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35. Multi-lineage heart-chip models drug cardiotoxicity and enhances maturation of human stem cell-derived cardiovascular cells
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Mozneb, Maedeh, primary, Jenkins, Amelia, additional, Sances, Samuel, additional, Pohlman, Stephany, additional, Workman, Michael J., additional, West, Dylan, additional, Ondatje, Briana, additional, El-Ghazawi, Kareem, additional, Woodbury, Amanda, additional, Garcia, Veronica J., additional, Patel, Shachi, additional, Arzt, Madelyn, additional, Dezem, Felipe, additional, Laperle, Alex H., additional, Moser, V. Alexandra, additional, Ho, Ritchie, additional, Yucer, Nur, additional, Plummer, Jasmine, additional, Barrett, Robert J., additional, Svendsen, Clive N., additional, and Sharma, Arun, additional
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- 2024
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36. Author Correction: Regenerative and restorative medicine for eye disease
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Van Gelder, Russell N., Chiang, Michael F., Dyer, Michael A., Greenwell, Thomas N., Levin, Leonard A., Wong, Rachel O., and Svendsen, Clive N.
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- 2022
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37. Getting the upper hand in ALS
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Svendsen, Clive N.
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- 2022
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38. A novel treatment for Parkinson's disease and ALS: Combined cell and gene therapies
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Svendsen, Soshana P., primary and Svendsen, Clive N., additional
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- 2021
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39. Preface
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Smith, Richard A., primary, Svendsen, Clive N., additional, and Kaspar, Brian K., additional
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- 2021
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40. Contributors
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Aboody, Karen, primary, Aladesuyi Arogundade, Olubankole, additional, Appendino, Giovanni, additional, Bao, Weiqi, additional, Baptista, Marco A.S., additional, Beaulieu, Danielle, additional, Bennett, Frank, additional, Brand, Emma, additional, Cleveland, Don, additional, Cohan, Stanley L., additional, Cuerdo, Jonavelle, additional, DeMesa, Jim, additional, Ennist, David L., additional, Guler, Meryem, additional, Hindiyeh, Nada, additional, Hovren, Hanna, additional, Huang, Yiyun Henry, additional, Jia, Hongmei, additional, Jiang, Jie, additional, Kaspar, Brian K., additional, Kaufmann, Petra, additional, Kaye, Randall, additional, Kelly, Jeffery W., additional, Keymer, Mike, additional, Kim, Doo Yeon, additional, Kresa-Reahl, Kiren, additional, Lee, Ikjae, additional, Leitner, Melanie, additional, Linch, Stefanie N., additional, Lucassen, Elisabeth B., additional, Miller, Timothy, additional, Mooney, Rachael, additional, Morello, Gaetano, additional, Muñoz, Eduardo, additional, Murray, Michael, additional, Ngai, Hoi Wa, additional, Park, Joseph, additional, Pierce, Dustin, additional, Portnow, Jana, additional, Powers, Evan T., additional, Quinti, Luisa, additional, Ravits, John, additional, Romba, Meghan, additional, Sampath, Rajesh, additional, Sardi, S. Pablo, additional, Schactman, Mark, additional, Shahnawaz, Mohammad, additional, Smith, Richard A., additional, Smoot, Kyle E., additional, Soto, Claudio, additional, Svendsen, Clive N., additional, Svendsen, Soshana P., additional, Tanzi, Rudolph E., additional, Taylor, Albert A., additional, Wolfe, Gil I., additional, Wright, Clinton B., additional, Yakatan, Gerald, additional, and Zach, Neta, additional
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- 2021
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41. Neonatal immune-tolerance in mice does not prevent xenograft rejection
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Mattis, Virginia B, Wakeman, Dustin R, Tom, Colton, Dodiya, Hemraj B, Yeung, Sylvia Y, Tran, Andrew H, Bernau, Ksenija, Ornelas, Loren, Sahabian, Anais, Reidling, Jack, Sareen, Dhruv, Thompson, Leslie M, Kordower, Jeffrey H, and Svendsen, Clive N
- Subjects
Biomedical and Clinical Sciences ,Immunology ,Neurosciences ,Pediatric ,Stem Cell Research ,Stem Cell Research - Nonembryonic - Non-Human ,Transplantation ,Prevention ,Perinatal Period - Conditions Originating in Perinatal Period ,Organ Transplantation ,Biotechnology ,Human Fetal Tissue ,Inflammatory and immune system ,Animals ,Animals ,Newborn ,Animals ,Outbred Strains ,Cells ,Cultured ,Corpus Striatum ,Disease Models ,Animal ,Female ,Graft Rejection ,Graft Survival ,Heterografts ,Humans ,Huntingtin Protein ,Huntington Disease ,Immune Tolerance ,Male ,Mice ,Mice ,Inbred NOD ,Mice ,SCID ,Mice ,Transgenic ,Nerve Tissue Proteins ,Neural Stem Cells ,Nuclear Proteins ,Transplantation ,Heterologous ,Neonatal tolerance ,Neonatal immunity ,Xenograft ,Huntington's disease ,Immune rejection ,Clinical Sciences ,Psychology ,Neurology & Neurosurgery ,Biological psychology - Abstract
Assessing the efficacy of human stem cell transplantation in rodent models is complicated by the significant immune rejection that occurs. Two recent reports have shown conflicting results using neonatal tolerance to xenografts in rats. Here we extend this approach to mice and assess whether neonatal tolerance can prevent the rapid rejection of xenografts. In three strains of neonatal immune-intact mice, using two different brain transplant regimes and three independent stem cell types, we conclusively show that there is rapid rejection of the implanted cells. We also address specific challenges associated with the generation of humanized mouse models of disease.
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- 2014
42. Human Neural Progenitors Expressing GDNF Enhance Retinal Protection in a Rodent Model of Retinal Degeneration
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Shahin, Saba, primary, Tan, Patrick, additional, Chetsawang, Jason, additional, Lu, Bin, additional, Svendsen, Soshana, additional, Ramirez, Stephany, additional, Conniff, Trevor, additional, Alfaro, Jorge S, additional, Fernandez, Michael, additional, Fulton, Aaron, additional, Laperle, Alexander H, additional, Svendsen, Clive N, additional, and Wang, Shaomei, additional
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- 2023
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43. Genome-wide Analyses Identify KIF5A as a Novel ALS Gene
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Logullo, Francesco O., Simone, Isabella, Logroscino, Giancarlo, Salvi, Fabrizio, Bartolomei, Ilaria, Borghero, Giuseppe, Murru, Maria Rita, Costantino, Emanuela, Pani, Carla, Puddu, Roberta, Caredda, Carla, Piras, Valeria, Tranquilli, Stefania, Cuccu, Stefania, Corongiu, Daniela, Melis, Maurizio, Milia, Antonio, Marrosu, Francesco, Marrosu, Maria Giovanna, Floris, Gianluca, Cannas, Antonino, Capasso, Margherita, Caponnetto, Claudia, Mancardi, Gianluigi, Origone, Paola, Mandich, Paola, Conforti, Francesca L., Cavallaro, Sebastiano, Mora, Gabriele, Marinou, Kalliopi, Sideri, Riccardo, Penco, Silvana, Mosca, Lorena, Lunetta, Christian, Pinter, Giuseppe Lauria, Corbo, Massimo, Riva, Nilo, Carrera, Paola, Volanti, Paolo, Mandrioli, Jessica, Fini, Nicola, Fasano, Antonio, Tremolizzo, Lucio, Arosio, Alessandro, Ferrarese, Carlo, Trojsi, Francesca, Tedeschi, Gioacchino, Monsurrò, Maria Rosaria, Piccirillo, Giovanni, Femiano, Cinzia, Ticca, Anna, Ortu, Enzo, La Bella, Vincenzo, Spataro, Rossella, Colletti, Tiziana, Sabatelli, Mario, Zollino, Marcella, Conte, Amelia, Luigetti, Marco, Lattante, Serena, Marangi, Giuseppe, Santarelli, Marialuisa, Petrucci, Antonio, Pugliatti, Maura, Pirisi, Angelo, Parish, Leslie D., Occhineri, Patrizia, Giannini, Fabio, Battistini, Stefania, Ricci, Claudia, Benigni, Michele, Cau, Tea B., Loi, Daniela, Calvo, Andrea, Moglia, Cristina, Brunetti, Maura, Barberis, Marco, Restagno, Gabriella, Casale, Federico, Marrali, Giuseppe, Fuda, Giuseppe, Ossola, Irene, Cammarosano, Stefania, Canosa, Antonio, Ilardi, Antonio, Manera, Umberto, Grassano, Maurizio, Tanel, Raffaella, Pisano, Fabrizio, Harms, Matthew B., Goldstein, David B., Shneider, Neil A., Goutman, Stephen, Simmons, Zachary, Miller, Timothy M., Chandran, Siddharthan, Pal, Suvankar, Manousakis, Georgios, Appel, Stanley H., Simpson, Ericka, Wang, Leo, Baloh, Robert H., Gibson, Summer, Bedlack, Richard, Lacomis, David, Sareen, Dhruv, Sherman, Alexander, Bruijn, Lucie, Penny, Michelle, Allen, Andrew S., Appel, Stanley, Bedlack, Richard S., Boone, Braden E., Brown, Robert, Carulli, John P., Chesi, Alessandra, Chung, Wendy K., Cirulli, Elizabeth T., Cooper, Gregory M., Couthouis, Julien, Day-Williams, Aaron G., Dion, Patrick A., Gitler, Aaron D., Glass, Jonathan D., Han, Yujun, Harris, Tim, Hayes, Sebastian D., Jones, Angela L., Keebler, Jonathan, Krueger, Brian J., Lasseigne, Brittany N., Levy, Shawn E., Lu, Yi-Fan, Maniatis, Tom, McKenna-Yasek, Diane, Myers, Richard M., Petrovski, Slavé, Pulst, Stefan M., Raphael, Alya R., Ravits, John M., Ren, Zhong, Rouleau, Guy A., Sapp, Peter C., Sims, Katherine B., Staropoli, John F., Waite, Lindsay L., Wang, Quanli, Wimbish, Jack R., Xin, Winnie W., Phatnani, Hemali, Kwan, Justin, Broach, James R., Arcila-Londono, Ximena, Lee, Edward B., Van Deerlin, Vivianna M., Fraenkel, Ernest, Ostrow, Lyle W., Baas, Frank, Zaitlen, Noah, Berry, James D., Malaspina, Andrea, Fratta, Pietro, Cox, Gregory A., Thompson, Leslie M., Finkbeiner, Steve, Dardiotis, Efthimios, Hornstein, Eran, MacGowan, Daniel J., Heiman-Patterson, Terry, Hammell, Molly G., Patsopoulos, Nikolaos A., Dubnau, Joshua, Nath, Avindra, Kaye, Julia, Finkbeiner, Steven, Wyman, Stacia, LeNail, Alexander, Lima, Leandro, Rothstein, Jeffrey D., Svendsen, Clive N., Van Eyk, Jenny, Maragakis, Nicholas J., Kolb, Stephen J., Cudkowicz, Merit, Baxi, Emily, Benatar, Michael, Taylor, J. Paul, Wu, Gang, Rampersaud, Evadnie, Wuu, Joanne, Rademakers, Rosa, Züchner, Stephan, Schule, Rebecca, McCauley, Jacob, Hussain, Sumaira, Cooley, Anne, Wallace, Marielle, Clayman, Christine, Barohn, Richard, Statland, Jeffrey, Ravits, John, Swenson, Andrea, Jackson, Carlayne, Trivedi, Jaya, Khan, Shaida, Katz, Jonathan, Jenkins, Liberty, Burns, Ted, Gwathmey, Kelly, Caress, James, McMillan, Corey, Elman, Lauren, Pioro, Erik, Heckmann, Jeannine, So, Yuen, Walk, David, Maiser, Samuel, Zhang, Jinghui, Silani, Vincenzo, Ticozzi, Nicola, Gellera, Cinzia, Ratti, Antonia, Taroni, Franco, Lauria, Giuseppe, Verde, Federico, Fogh, Isabella, Tiloca, Cinzia, Comi, Giacomo P., Sorarù, Gianni, Cereda, Cristina, D’Alfonso, Sandra, Corrado, Lucia, De Marchi, Fabiola, Corti, Stefania, Ceroni, Mauro, Mazzini, Letizia, Siciliano, Gabriele, Filosto, Massimiliano, Inghilleri, Maurizio, Peverelli, Silvia, Colombrita, Claudia, Poletti, Barbara, Maderna, Luca, Del Bo, Roberto, Gagliardi, Stella, Querin, Giorgia, Bertolin, Cinzia, Pensato, Viviana, Castellotti, Barbara, Camu, William, Mouzat, Kevin, Lumbroso, Serge, Corcia, Philippe, Meininger, Vincent, Besson, Gérard, Lagrange, Emmeline, Clavelou, Pierre, Guy, Nathalie, Couratier, Philippe, Vourch, Patrick, Danel, Véronique, Bernard, Emilien, Lemasson, Gwendal, Al Kheifat, Ahmad, Al-Chalabi, Ammar, Andersen, Peter, Basak, A. Nazli, Blair, Ian P., Chio, Adriano, Cooper-Knock, Jonathan, de Carvalho, Mamede, Dekker, Annelot, Drory, Vivian, Redondo, Alberto Garcia, Gotkine, Marc, Hardiman, Orla, Hide, Winston, Iacoangeli, Alfredo, Glass, Jonathan, Kenna, Kevin, Kiernan, Matthew, Kooyman, Maarten, Landers, John, McLaughlin, Russell, Middelkoop, Bas, Mill, Jonathan, Neto, Miguel Mitne, Moisse, Mattieu, Pardina, Jesus Mora, Morrison, Karen, Newhouse, Stephen, Pinto, Susana, Pulit, Sara, Robberecht, Wim, Shatunov, Aleksey, Shaw, Pamela, Shaw, Chris, Sproviero, William, Tazelaar, Gijs, van Damme, Philip, van den Berg, Leonard, van der Spek, Rick, van Eijk, Kristel, van Es, Michael, van Rheenen, Wouter, van Vugt, Joke, Veldink, Jan, Weber, Markus, Williams, Kelly L., Zatz, Mayana, Bauer, Denis C., Twine, Natalie A., Nicolas, Aude, Kenna, Kevin P., Renton, Alan E., Faghri, Faraz, Chia, Ruth, Dominov, Janice A., Kenna, Brendan J., Nalls, Mike A., Keagle, Pamela, Rivera, Alberto M., Murphy, Natalie A., van Vugt, Joke J.F.A., Geiger, Joshua T., Van der Spek, Rick A., Pliner, Hannah A., Shankaracharya, Smith, Bradley N., Topp, Simon D., Abramzon, Yevgeniya, Gkazi, Athina Soragia, Eicher, John D., Kenna, Aoife, Messina, Sonia, Simone, Isabella L., Ferrucci, Luigi, Moreno, Cristiane de Araujo Martins, Kamalakaran, Sitharthan, Musunuri, Rajeeva Lochan, Evani, Uday Shankar, Abhyankar, Avinash, Zody, Michael C., Wyman, Stacia K., LeNail, Alex, Van Eyk, Jennifer E., Laaksovirta, Hannu, Myllykangas, Liisa, Jansson, Lilja, Valori, Miko, Ealing, John, Hamdalla, Hisham, Rollinson, Sara, Pickering-Brown, Stuart, Orrell, Richard W., Sidle, Katie C., Hardy, John, Singleton, Andrew B., Johnson, Janel O., Arepalli, Sampath, Polak, Meraida, Asress, Seneshaw, Al-Sarraj, Safa, King, Andrew, Troakes, Claire, Vance, Caroline, de Belleroche, Jacqueline, ten Asbroek, Anneloor L.M.A., Muñoz-Blanco, José Luis, Hernandez, Dena G., Ding, Jinhui, Gibbs, J. Raphael, Scholz, Sonja W., Floeter, Mary Kay, Campbell, Roy H., Landi, Francesco, Bowser, Robert, MacGowan, Daniel J.L., Kirby, Janine, Pioro, Erik P., Pamphlett, Roger, Broach, James, Gerhard, Glenn, Dunckley, Travis L., Brady, Christopher B., Kowall, Neil W., Troncoso, Juan C., Le Ber, Isabelle, Heiman-Patterson, Terry D., Kamel, Freya, Van Den Bosch, Ludo, Strom, Tim M., Meitinger, Thomas, Van Eijk, Kristel R., Moisse, Matthieu, McLaughlin, Russell L., Van Es, Michael A., Boylan, Kevin B., Van Blitterswijk, Marka, Morrison, Karen E., Mora, Jesús S., Drory, Vivian E., Shaw, Pamela J., Turner, Martin R., Talbot, Kevin, Fifita, Jennifer A., Nicholson, Garth A., Esteban-Pérez, Jesús, García-Redondo, Alberto, Rogaeva, Ekaterina, Zinman, Lorne, Cooper-Knock, Johnathan, Brice, Alexis, Goutman, Stephen A., Feldman, Eva L., Gibson, Summer B., Van Damme, Philip, Ludolph, Albert C., Andersen, Peter M., Weishaupt, Jochen H., Trojanowski, John Q., Brown, Robert H., Jr., van den Berg, Leonard H., Veldink, Jan H., Stone, David J., Tienari, Pentti, Chiò, Adriano, Shaw, Christopher E., Traynor, Bryan J., and Landers, John E.
- Published
- 2018
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44. Enhanced Utilization of Induced Pluripotent Stem Cell–Derived Human Intestinal Organoids Using Microengineered Chips
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Workman, Michael J., Gleeson, John P., Troisi, Elissa J., Estrada, Hannah Q., Kerns, S. Jordan, Hinojosa, Christopher D., Hamilton, Geraldine A., Targan, Stephan R., Svendsen, Clive N., and Barrett, Robert J.
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- 2018
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45. Rapid genetic targeting of pial surface neural progenitors and immature neurons by neonatal electroporation
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Breunig, Joshua J, Gate, David, Levy, Rachelle, Rodriguez, Javier, Kim, Gi, Danielpour, Moise, Svendsen, Clive N, and Town, Terrence
- Abstract
AbstractBackgroundRecent findings have indicated the presence of a progenitor domain at the marginal zone/layer 1 of the cerebral cortex, and it has been suggested that these progenitors have neurogenic and gliogenic potential. However, their contribution to the histogenesis of the cortex remains poorly understood due to difficulties associated with genetically manipulating these unique cells in a population-specific manner.ResultsWe have adapted the electroporation technique to target pial surface cells for rapid genetic manipulation at postnatal day 2. In vivo data show that most of these cells proliferate and progressively differentiate into both neuronal and glial subtypes. Furthermore, these cells localize to the superficial layers of the optic tectum and cerebral cortex prior to migration away from the surface.ConclusionsWe provide a foundation upon which future studies can begin to elucidate the molecular controls governing neural progenitor fate, migration, differentiation, and contribution to cortical and tectal histogenesis. Furthermore, specific genetic targeting of such neural progenitor populations will likely be of future clinical interest.
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- 2012
46. Mitotic and Neurogenic Effects of Dehydroepiandrosterone (DHEA) on Human Neural Stem Cell Cultures Derived from the Fetal Cortex
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Suzuki, Masatoshi, Wright, Lynda S., Marwah, Padma, Lardy, Henry A., and Svendsen, Clive N.
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- 2004
47. Organ-Chips Enhance the Maturation of Human iPSC-Derived Dopamine Neurons
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Otero, Maria G., primary, Bell, Shaughn, additional, Laperle, Alexander H., additional, Lawless, George, additional, Myers, Zachary, additional, Castro, Marian A., additional, Villalba, Jaquelyn M., additional, and Svendsen, Clive N., additional
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- 2023
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48. Rejuvenating the blood and bone marrow to slow aging-associated cognitive decline and Alzheimer’s disease
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Kang, Seokjo, Moser, V. Alexandra, Svendsen, Clive N., and Goodridge, Helen S.
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- 2020
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49. Cortical neurons derived from human pluripotent stem cells lacking FMRP display altered spontaneous firing patterns
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Das Sharma, Shreya, Pal, Rakhi, Reddy, Bharath Kumar, Selvaraj, Bhuvaneish T., Raj, Nisha, Samaga, Krishna Kumar, Srinivasan, Durga J., Ornelas, Loren, Sareen, Dhruv, Livesey, Matthew R., Bassell, Gary J., Svendsen, Clive N., Kind, Peter C., Chandran, Siddharthan, Chattarji, Sumantra, and Wyllie, David J. A.
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- 2020
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50. Recent advances in human iPSC-derived models of the blood–brain barrier
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Workman, Michael J. and Svendsen, Clive N.
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- 2020
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