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2. Molecular Anatomy of the Developing Human Retina

Author

Hoshino, Akina, Ratnapriya, Rinki, Brooks, Matthew J., Chaitankar, Vijender, Wilken, Matthew S., Zhang, Chi, Starostik, Margaret R., Gieser, Linn, La Torre, Anna, Nishio, Mario, Bates, Olivia, Walton, Ashley, Bermingham-McDonogh, Olivia, Glass, Ian A., Wong, Rachel O.L., Swaroop, Anand, and Reh, Thomas A.

Published
2017
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8. Mouse regulatory DNA landscapes reveal global principles of cis-regulatory evolution

Author

Vierstra, Jeff, Rynes, Eric, Sandstrom, Richard, Zhang, Miaohua, Canfield, Theresa, Hansen, R. Scott, Stehling-Sun, Sandra, Sabo, Peter J., Byron, Rachel, Humbert, Richard, Thurman, Robert E., Johnson, Audra K., Vong, Shinny, Lee, Kristen, Bates, Daniel, Neri, Fidencio, Diegel, Morgan, Giste, Erika, Haugen, Eric, Dunn, Douglas, Wilken, Matthew S., Josefowicz, Steven, Samstein, Robert, Chang, Kai-Hsin, Eichler, Evan E., De Bruijn, Marella, Reh, Thomas A., Skoultchi, Arthur, Rudensky, Alexander, Orkin, Stuart H., Papayannopoulou, Thalia, Treuting, Piper M., Selleri, Licia, Kaul, Rajinder, Groudine, Mark, Bender, M. A., and Stamatoyannopoulos, John A.

Published
2014

9. A comparative encyclopedia of DNA elements in the mouse genome

Author

Yue, Feng, Cheng, Yong, Breschi, Alessandra, Vierstra, Jeff, Wu, Weisheng, Ryba, Tyrone, Sandstrom, Richard, Ma, Zhihai, Davis, Carrie, Pope, Benjamin D., Shen, Yin, Pervouchine, Dmitri D., Djebali, Sarah, Thurman, Robert E., Kaul, Rajinder, Rynes, Eric, Kirilusha, Anthony, Marinov, Georgi K., Williams, Brian A., Trout, Diane, Amrhein, Henry, Fisher-Aylor, Katherine, Antoshechkin, Igor, DeSalvo, Gilberto, See, Lei-Hoon, Fastuca, Meagan, Drenkow, Jorg, Zaleski, Chris, Dobin, Alex, Prieto, Pablo, Lagarde, Julien, Bussotti, Giovanni, Tanzer, Andrea, Denas, Olgert, Li, Kanwei, Bender, M. A., Zhang, Miaohua, Byron, Rachel, Groudine, Mark T., McCleary, David, Pham, Long, Ye, Zhen, Kuan, Samantha, Edsall, Lee, Wu, Yi-Chieh, Rasmussen, Matthew D., Bansal, Mukul S., Kellis, Manolis, Keller, Cheryl A., Morrissey, Christapher S., Mishra, Tejaswini, Jain, Deepti, Dogan, Nergiz, Harris, Robert S., Cayting, Philip, Kawli, Trupti, Boyle, Alan P., Euskirchen, Ghia, Kundaje, Anshul, Lin, Shin, Lin, Yiing, Jansen, Camden, Malladi, Venkat S., Cline, Melissa S., Erickson, Drew T., Kirkup, Vanessa M., Learned, Katrina, Sloan, Cricket A., Rosenbloom, Kate R., Lacerda de Sousa, Beatriz, Beal, Kathryn, Pignatelli, Miguel, Flicek, Paul, Lian, Jin, Kahveci, Tamer, Lee, Dongwon, James Kent, W., Ramalho Santos, Miguel, Herrero, Javier, Notredame, Cedric, Johnson, Audra, Vong, Shinny, Lee, Kristen, Bates, Daniel, Neri, Fidencio, Diegel, Morgan, Canfield, Theresa, Sabo, Peter J., Wilken, Matthew S., Reh, Thomas A., Giste, Erika, Shafer, Anthony, Kutyavin, Tanya, Haugen, Eric, Dunn, Douglas, Reynolds, Alex P., Neph, Shane, Humbert, Richard, Scott Hansen, R., De Bruijn, Marella, Selleri, Licia, Rudensky, Alexander, Josefowicz, Steven, Samstein, Robert, Eichler, Evan E., Orkin, Stuart H., Levasseur, Dana, Papayannopoulou, Thalia, Chang, Kai-Hsin, Skoultchi, Arthur, Gosh, Srikanta, Disteche, Christine, Treuting, Piper, Wang, Yanli, Weiss, Mitchell J., Blobel, Gerd A., Cao, Xiaoyi, Zhong, Sheng, Wang, Ting, Good, Peter J., Lowdon, Rebecca F., Adams, Leslie B., Zhou, Xiao-Qiao, Pazin, Michael J., Feingold, Elise A., Wold, Barbara, Taylor, James, Mortazavi, Ali, Weissman, Sherman M., Stamatoyannopoulos, John A., Snyder, Michael P., Guigo, Roderic, Gingeras, Thomas R., Gilbert, David M., Hardison, Ross C., Beer, Michael A., and Ren, Bing

Subjects
Genetic aspects, Comparative analysis, Genetic research, Humans -- Genetic aspects, Genomes -- Comparative analysis, House mouse -- Genetic aspects, Man -- Genetic aspects, Human beings -- Genetic aspects, Mice -- Genetic aspects
Abstract

Author(s): Feng Yue [1, 2]; Yong Cheng [3]; Alessandra Breschi [4]; Jeff Vierstra [5]; Weisheng Wu [6]; Tyrone Ryba [7]; Richard Sandstrom [5]; Zhihai Ma [3]; Carrie Davis [8]; Benjamin [...], The laboratory mouse shares the majority of its protein-coding genes with humans, making it the premier model organism in biomedical research, yet the two mammals differ in significant ways. To gain greater insights into both shared and species-specific transcriptional and cellular regulatory programs in the mouse, the Mouse ENCODE Consortium has mapped transcription, DNase I hypersensitivity, transcription factor binding, chromatin modifications and replication domains throughout the mouse genome in diverse cell and tissue types. By comparing with the human genome, we not only confirm substantial conservation in the newly annotated potential functional sequences, but also find a large degree of divergence of sequences involved in transcriptional regulation, chromatin state and higher order chromatin organization. Our results illuminate the wide range of evolutionary forces acting on genes and their regulatory regions, and provide a general resource for research into mammalian biology and mechanisms of human diseases.

Published
2014
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10. Conservation of trans-acting circuitry during mammalian regulatory evolution

Author

Stergachis, Andrew B., Neph, Shane, Sandstrom, Richard, Haugen, Eric, Reynolds, Alex P., Zhang, Miaohua, Byron, Rachel, Canfield, Theresa, Stelhing-Sun, Sandra, Lee, Kristen, Thurman, Robert E., Vong, Shinny, Bates, Daniel, Neri, Fidencio, Diegel, Morgan, Giste, Erika, Dunn, Douglas, Vierstra, Jeff, Hansen, R. Scott, Johnson, Audra K., Sabo, Peter J., Wilken, Matthew S., Reh, Thomas A., Treuting, Piper M., Kaul, Rajinder, Groudine, Mark, Bender, M. A., Borenstein, Elhanan, and Stamatoyannopoulos, John A.

Subjects
Genetic aspects, Methods, Mammals -- Genetic aspects, Evolution (Biology) -- Genetic aspects, Genetic regulation -- Methods, Evolution -- Genetic aspects
Abstract

Author(s): Andrew B. Stergachis [1]; Shane Neph [1]; Richard Sandstrom [1]; Eric Haugen [1]; Alex P. Reynolds [1]; Miaohua Zhang [2]; Rachel Byron [2]; Theresa Canfield [1]; Sandra Stelhing-Sun [1]; [...], The basic body plan and major physiological axes have been highly conserved during mammalian evolution, yet only a small fraction of the human genome sequence appears to be subject to evolutionary constraint. To quantify cis- versus trans-acting contributions to mammalian regulatory evolution, we performed genomic DNase I footprinting of the mouse genome across 25 cell and tissue types, collectively defining [similar]8.6 million transcription factor (TF) occupancy sites at nucleotide resolution. Here we show that mouse TF footprints conjointly encode a regulatory lexicon that is [similar]95% similar with that derived from human TF footprints. However, only [similar]20% of mouse TF footprints have human orthologues. Despite substantial turnover of the cis-regulatory landscape, nearly half of all pairwise regulatory interactions connecting mouse TF genes have been maintained in orthologous human cell types through evolutionary innovation of TF recognition sequences. Furthermore, the higher-level organization of mouse TF-to-TF connections into cellular network architectures is nearly identical with human. Our results indicate that evolutionary selection on mammalian gene regulation is targeted chiefly at the level of trans-regulatory circuitry, enabling and potentiating cis-regulatory plasticity.

Published
2014
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11. MOUSE GENOMICS: Mouse regulatory DNA landscapes reveal global principles of cis-regulatory evolution

Author

Vierstra, Jeff, Rynes, Eric, Sandstrom, Richard, Zhang, Miaohua, Canfield, Theresa, Hansen, Scott R., Stehling-Sun, Sandra, Sabo, Peter J., Byron, Rachel, Humbert, Richard, Thurman, Robert E., Johnson, Audra K., Vong, Shinny, Lee, Kristen, Bates, Daniel, Neri, Fidencio, Diegel, Morgan, Giste, Erika, Haugen, Eric, Dunn, Douglas, Wilken, Matthew S., Josefowicz, Steven, Samstein, Robert, Chang, Kai-Hsin, Eichler, Evan E., De Bruijn, Marella, Reh, Thomas A., Skoultchi, Arthur, Rudensky, Alexander, Orkin, Stuart H., Papayannopoulou, Thalia, Treuting, Piper M., Selleri, Licia, Kaul, Rajinder, Groudine, Mark, Bender, M. A., and Stamatoyannopoulos, John A.

Published
2014
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12. Stimulation of functional neuronal regeneration from Mller glia in adult mice

Author

Jorstad, Nikolas L., Wilken, Matthew S., Grimes, William N., Wohl, Stefanie G., VandenBosch, Leah S., Yoshimatsu, Takeshi, Wong, Rachel O., Rieke, Fred, and Reh, Thomas A.

Subjects
Care and treatment, Physiological aspects, Methods, Neurogenesis -- Methods, Nerve regeneration -- Methods, Retinal diseases -- Care and treatment, Retinal ganglion cells -- Physiological aspects
Abstract

Author(s): Nikolas L. Jorstad [1, 2]; Matthew S. Wilken [1]; William N. Grimes [3]; Stefanie G. Wohl [1]; Leah S. VandenBosch [1]; Takeshi Yoshimatsu [1]; Rachel O. Wong [1]; Fred [...]

Published
2017
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14. Regulatory DNA keyholes enable specific and persistent multi-gene expression programs in primary T cells without genome modification

Author

Wilken, Matthew S., Ciarlo, Christie, Pearl, Jocelynn, Bloom, Jordan, Schanzer, Elaine, Liao, Hanna, Boyken, Scott E., Van Biber, Benjamin, Queitsch, Konstantin, Heberlein, Gregory, Federation, Alexander, Acosta, Reyes, Vong, Shinny, Otterman, Ericka, Dunn, Douglass, Wang, Hao, Zrazhevskey, Pavel, Nandakumar, Vivek, Bates, Daniel, Sandstrom, Richard, Chen, Zibo, Urnov, Fyodor D., Baker, David, Funnell, Alister, Green, Shon, and Stamatoyannopoulos, John A.

Abstract

Non-invasive epigenome editing is a promising strategy for engineering gene expression programs, yet potency, specificity, and persistence remain challenging. Here we show that effective epigenome editing is gated at single-base precision via ‘keyhole’ sites in endogenous regulatory DNA. Synthetic repressors targeting promoter keyholes can ablate gene expression in up to 99% of primary cells with single-gene specificity and can seamlessly repress multiple genes in combination. Transient exposure of primary T cells to keyhole repressors confers mitotically heritable silencing that persists to the limit of primary cultures in vitro and for at least 4 weeks in vivo , enabling manufacturing of cell products with enhanced therapeutic efficacy. DNA recognition and effector domains can be encoded as separate proteins that reassemble at keyhole sites and function with the same efficiency as single chain effectors, enabling gated control and rapid screening for novel functional domains that modulate endogenous gene expression patterns. Our results provide a powerful and exponentially flexible system for programming gene expression and therapeutic cell products.

Published
2020
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15. De novo design of protein logic gates.

Author

Zibo Chen, Kibler, Ryan D., Hunt, Andrew, Busch, Florian, Pearl, Jocelynn, Mengxuan Jia, VanAernum, Zachary L., Wicky, Basile I. M., Dods, Galen, Liao, Hanna, Wilken, Matthew S., Ciarlo, Christie, Green, Shon, El-Samad, Hana, Stamatoyannopoulos, John, Wysocki, Vicki H., Jewett, Michael C., Boyken, Scott E., and Baker, David

Published
2020
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16. Transgenic expression of the proneural transcription factor Ascl1 in Müller glia stimulates retinal regeneration in young mice.

Author

Yumi Ueki, Wilken, Matthew S., Cox, Kristen E., Chipman, Laura, Jorstad, Nikolas, Sternhagen, Kristen, Simic, Milesa, Ullom, Kristy, Masato Nakafuku, and Reh, Thomas A.

Subjects
*NEUROGLIA, *REGENERATION (Biology), *RETINAL injuries, *BIRDS, *FISHES
Abstract

Müller glial cells are the source of retinal regeneration in fish and birds; although this process is efficient in fish, it is less so in birds and very limited in mammals. It has been proposed that factors necessary for providing neurogenic competence to Müller glia in fish and birds after retinal injury are not expressed in mammals. One such factor, the proneural transcription factor Ascl1, is necessary for retinal regeneration in fish but is not expressed after retinal damage in mice. We previously reported that forced expression of Ascl1 in vitro reprograms Müller glia to a neurogenic state. We now test whether forced expression of Ascl1 in mouse Müller glia in vivo stimulates their capacity for retinal regeneration. We find that transgenic expression of Ascl1 in adult Müller glia in undamaged retina does not overtly affect their phenotype; however, when the retina is damaged, the Ascl1-expressing glia initiate a response that resembles the early stages of retinal regeneration in zebrafish. The reaction to injury is even more pronounced in Müller glia in young mice, where the Ascl1-expressing Müller glia give rise to amacrine and bipolar cells and photoreceptors. DNaseI-seq analysis of the retina and Müller glia shows progressive reduction in accessibility of progenitor gene cis-regulatory regions consistent with the reduction in their reprogramming. These results show that at least one of the differences between mammal and fish Müller glia that bears on their difference in regenerative potential is the proneural transcription factor Ascl1. [ABSTRACT FROM AUTHOR]

Published
2015
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17. DNase I hypersensitivity analysis of the mouse brain and retina identifies region-specific regulatory elements.

Author

Wilken, Matthew S., Brzezinski, Joseph A., La Torre, Anna, Siebenthall, Kyle, Thurman, Robert, Sabo, Peter, Sandstrom, Richard S., Vierstra, Jeff, Canfield, Theresa K., Scott Hansen, R., Bender, Michael A., Stamatoyannopoulos, John, and Reh, Thomas A.

Subjects
*ALLERGIES, *SPINAL cord, *CENTRAL nervous system, *RETINA, *GENOMES
Abstract

Background: The brain, spinal cord, and neural retina comprise the central nervous system (CNS) of vertebrates. Understanding the regulatory mechanisms that underlie the enormous cell-type diversity of the CNS is a significant challenge. Whole-genome mapping of DNase I-hypersensitive sites (DHSs) has been used to identify cis-regulatory elements in many tissues. We have applied this approach to the mouse CNS, including developing and mature neural retina, whole brain, and two well-characterized brain regions, the cerebellum and the cerebral cortex. Results: For the various regions and developmental stages of the CNS that we analyzed, there were approximately the same number of DHSs; however, there were many DHSs unique to each CNS region and developmental stage. Many of the DHSs are likely to mark enhancers that are specific to the specific CNS region and developmental stage. We validated the DNase I mapping approach for identification of CNS enhancers using the existing VISTA Browser database and with in vivo and in vitro electroporation of the retina. Analysis of transcription factor consensus sites within the DHSs shows distinct region-specific profiles of transcriptional regulators particular to each region. Clustering developmentally dynamic DHSs in the retina revealed enrichment of developmental stagespecific transcriptional regulators. Additionally, we found reporter gene activity in the retina driven from several previously uncharacterized regulatory elements surrounding the neurodevelopmental gene Otx2. Identification of DHSs shared between mouse and human showed region-specific differences in the evolution of cis-regulatory elements. Conclusions: Overall, our results demonstrate the potential of genome-wide DNase I mapping to cis-regulatory questions regarding the regional diversity within the CNS. These data represent an extensive catalogue of potential cis-regulatory elements within the CNS that display region and temporal specificity, as well as a set of DHSs common to CNS tissues. Further examination of evolutionary conservation of DHSs between CNS regions and different species may reveal important cis-regulatory elements in the evolution of the mammalian CNS. [ABSTRACT FROM AUTHOR]

Published
2015
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18. A transient wave of BMP signaling in the retina is necessary for Mü ller glial differentiation.

Author

Ueki, Yumi, Wilken, Matthew S., Cox, Kristen E., Chipman, Laura B., Bermingham-McDonogh, Olivia, and Reh, Thomas A.

Subjects
*NEUROGLIA, *NERVE tissue, *NOGGIN (Protein), *CELL differentiation, *BONE morphogenetic proteins
Abstract

The primary glial cells in the retina, the Mü ller glia, differentiate from retinal progenitors in the first postnatal week. CNTF/LIF/STAT3 signaling has been shown to promote their differentiation; however, another key glial differentiation signal, BMP, has not been examined during this period of Mü ller glial differentiation. In the course of our analysis of the BMP signaling pathway, we observed a transient wave of Smad1/5/8 signaling in the inner nuclear layer at the end of the first postnatal week, from postnatal day (P) 5 to P9, after the end of neurogenesis. To determine the function of this transient wave, we blocked BMP signaling during this period in vitro or in vivo, using either a BMP receptor antagonist or noggin (Nog). Either treatment leads to a reduction in expression of the Mü ller glia-specific genes Rlbp1 and Glul, and the failure of many of the Mü ller glia to repress the bipolar/photoreceptor gene Otx2. These changes in normal Mü ller glial differentiation result in permanent disruption of the retina, including defects in the outer limiting membrane, rosette formation and a reduction in functional acuity. Our results thus show that Mü ller glia require a transient BMP signal at the end of neurogenesis to fully repress the neural gene expression program and to promote glial gene expression. [ABSTRACT FROM AUTHOR]

Published
2015
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19. ASCL1 reprograms mouse Müller glia into neurogenic retinal progenitors.

Author

Pollak, Julia, Wilken, Matthew S., Ueki, Yumi, Cox, Kristen E., Sullivan, Jane M., Taylor, Russell J., Levine, Edward M., and Reh, Thomas A.

Subjects
*PROGENITOR cells, *NEUROGLIA, *NERVOUS system regeneration, *GENETIC code, *CELL differentiation, *TRANSCRIPTION factors
Abstract

Non-mammalian vertebrates have a robust ability to regenerate injured retinal neurons from Müller glia (MG) that activate the gene encoding the proneural factor Achaete-scute homolog 1 (Ascl1; also known as Mash1 in mammals) and de-differentiate into progenitor cells. By contrast, mammalian MG have a limited regenerative response and fail to upregulate Ascl1 after injury. To test whether ASCL1 could restore neurogenic potential to mammalian MG, we overexpressed ASCL1 in dissociated mouse MG cultures and intact retinal explants. ASCL1-infected MG upregulated retinal progenitor-specific genes and downregulated glial genes. Furthermore, ASCL1 remodeled the chromatin at its targets from a repressive to an active configuration. MG-derived progenitors differentiated into cells that exhibited neuronal morphologies, expressed retinal subtype-specific neuronal markers and displayed neuron-like physiological responses. These results indicate that a single transcription factor, ASCL1, can induce a neurogenic state in mature MG. [ABSTRACT FROM AUTHOR]

Published
2013
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20. Clonal deletion of thymocytes can occur in the cortex with no involvement of the medulla.

Author

McCaughtry TM, Baldwin TA, Wilken MS, and Hogquist KA

Subjects
Animals, CD11c Antigen metabolism, Dendritic Cells metabolism, Epithelial Cells immunology, Flow Cytometry, Fluorescent Antibody Technique, Male, Mice, Mice, Transgenic, Thymus Gland immunology, Apoptosis immunology, Clonal Deletion immunology, Epithelial Cells cytology, Models, Biological, Receptors, Antigen, T-Cell metabolism, Thymus Gland cytology
Abstract

The thymic medulla is generally held to be a specialized environment for negative selection. However, many self-reactive thymocytes first encounter ubiquitous self-antigens in the cortex. Cortical epithelial cells are vital for positive selection, but whether such cells can also promote negative selection is controversial. We used the HY(cd4) model, where T cell receptor for antigen (TCR) expression is appropriately timed and a ubiquitous self-antigen drives clonal deletion in male mice. We demonstrated unambiguously that this deletion event occurs in the thymic cortex. However, the kinetics in vivo indicated that apoptosis was activated asynchronously relative to TCR activation. We found that radioresistant antigen-presenting cells and, specifically, cortical epithelial cells do not efficiently induce apoptosis, although they do cause TCR activation. Rather, thymocytes undergoing clonal deletion were preferentially associated with rare CD11c(+) cortical dendritic cells, and elimination of such cells impaired deletion.

Published
2008
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21. Thymic emigration revisited.

Author

McCaughtry TM, Wilken MS, and Hogquist KA

Subjects
Animals, CD4 Antigens immunology, CD4-Positive T-Lymphocytes immunology, Cell Movement, Genes, Reporter, Green Fluorescent Proteins genetics, Humans, Immunologic Memory, Killer Cells, Natural immunology, Mice, Thymus Gland cytology, T-Lymphocytes immunology, Thymus Gland immunology
Abstract

Conventional alphabeta T cell precursors undergo positive selection in the thymic cortex. When this is successful, they migrate to the medulla and are exposed to tissue-specific antigens (TSA) for purposes of central tolerance, and they undergo maturation to become functionally responsive T cells. It is commonly understood that thymocytes spend up to 2 wk in the medulla undergoing these final maturation steps before emigrating to peripheral lymphoid tissues. In addition, emigration is thought to occur via a stochastic mechanism whereby some progenitors leave early and others leave late-a so-called "lucky dip" process. However, recent research has revealed that medullary thymocytes are a heterogeneous mix of naive alphabeta T cell precursors, memory T cells, natural killer T cells, and regulatory T cells. Given this, we revisited the question of how long it takes naive alphabeta T cell precursors to emigrate. We combined the following three approaches to study this question: BrdU labeling, intrathymic injection of a cellular tag, and RAG2p-GFP reporter mice. We established that, on average, naive alphabeta T cell precursors emigrate only 4-5 d after becoming single-positive (SP) thymocytes. Furthermore, emigration occurs via a strict "conveyor belt" mechanism, where the oldest thymocytes leave first.

Published
2007
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