Your search keyword '"Gorkin, David U."' showing total 216 results

1. Mapping genetic effects on cell type-specific chromatin accessibility and annotating complex immune trait variants using single nucleus ATAC-seq in peripheral blood

Author

Benaglio, Paola, Newsome, Jacklyn, Han, Jee Yun, Chiou, Joshua, Aylward, Anthony, Corban, Sierra, Miller, Michael, Okino, Mei-Lin, Kaur, Jaspreet, Preissl, Sebastian, Gorkin, David U, and Gaulton, Kyle J

Subjects

Biological Sciences, Genetics, Human Genome, 1.1 Normal biological development and functioning, Aetiology, 2.1 Biological and endogenous factors, Underpinning research, Metabolic and endocrine, Humans, Chromatin, Chromatin Immunoprecipitation Sequencing, Multifactorial Inheritance, Leukocytes, Mononuclear, Quantitative Trait Loci, Developmental Biology

Abstract

Gene regulation is highly cell type-specific and understanding the function of non-coding genetic variants associated with complex traits requires molecular phenotyping at cell type resolution. In this study we performed single nucleus ATAC-seq (snATAC-seq) and genotyping in peripheral blood mononuclear cells from 13 individuals. Clustering chromatin accessibility profiles of 96,002 total nuclei identified 17 immune cell types and sub-types. We mapped chromatin accessibility QTLs (caQTLs) in each immune cell type and sub-type using individuals of European ancestry which identified 6,901 caQTLs at FDR < .10 and 4,220 caQTLs at FDR < .05, including those obscured from assays of bulk tissue such as with divergent effects on different cell types. For 3,941 caQTLs we further annotated putative target genes of variant activity using single cell co-accessibility, and caQTL variants were significantly correlated with the accessibility level of linked gene promoters. We fine-mapped loci associated with 16 complex immune traits and identified immune cell caQTLs at 622 candidate causal variants, including those with cell type-specific effects. At the 6q15 locus associated with type 1 diabetes, in line with previous reports, variant rs72928038 was a naïve CD4+ T cell caQTL linked to BACH2 and we validated the allelic effects of this variant on regulatory activity in Jurkat T cells. These results highlight the utility of snATAC-seq for mapping genetic effects on accessible chromatin in specific cell types.

Published

2023

2. Author Correction: Expanded encyclopaedias of DNA elements in the human and mouse genomes

Author

Moore, Jill E, Purcaro, Michael J, Pratt, Henry E, Epstein, Charles B, Shoresh, Noam, Adrian, Jessika, Kawli, Trupti, Davis, Carrie A, Dobin, Alexander, Kaul, Rajinder, Halow, Jessica, Van Nostrand, Eric L, Freese, Peter, Gorkin, David U, Shen, Yin, He, Yupeng, Mackiewicz, Mark, Pauli-Behn, Florencia, Williams, Brian A, Mortazavi, Ali, Keller, Cheryl A, Zhang, Xiao-Ou, Elhajjajy, Shaimae I, Huey, Jack, Dickel, Diane E, Snetkova, Valentina, Wei, Xintao, Wang, Xiaofeng, Rivera-Mulia, Juan Carlos, Rozowsky, Joel, Zhang, Jing, Chhetri, Surya B, Zhang, Jialing, Victorsen, Alec, White, Kevin P, Visel, Axel, Yeo, Gene W, Burge, Christopher B, Lécuyer, Eric, Gilbert, David M, Dekker, Job, Rinn, John, Mendenhall, Eric M, Ecker, Joseph R, Kellis, Manolis, Klein, Robert J, Noble, William S, Kundaje, Anshul, Guigó, Roderic, Farnham, Peggy J, Cherry, J Michael, Myers, Richard M, Ren, Bing, Graveley, Brenton R, Gerstein, Mark B, Pennacchio, Len A, Snyder, Michael P, Bernstein, Bradley E, Wold, Barbara, Hardison, Ross C, Gingeras, Thomas R, Stamatoyannopoulos, John A, and Weng, Zhiping

Subjects

ENCODE Project Consortium, General Science & Technology

Abstract

In the version of this article initially published, two members of the ENCODE Project Consortium were missing from the author list. Rizi Ai (Department of Chemistry and Biochemistry, University of California, San Diego, La Jolla, CA, USA) and Shantao Li (Program in Computational Biology and Bioinformatics, Yale University, New Haven, CT, USA) are now included in the author list. These errors have been corrected in the online version of the article.

Published

2022

3. Integrative analysis of the 3D genome and epigenome in mouse embryonic tissues

Author

Yu, Miao, Zemke, Nathan R, Chen, Ziyin, Juric, Ivan, Hu, Rong, Raviram, Ramya, Abnousi, Armen, Fang, Rongxin, Zhang, Yanxiao, Gorkin, David U, Li, Yang, Zhao, Yuan, Lee, Lindsay, Schmitt, Anthony D, Qiu, Yunjiang, Dickel, Diane E, Visel, Axel, Pennacchio, Len A, Hu, Ming, and Ren, Bing

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Genetics, Human Genome, Biotechnology, 1.1 Normal biological development and functioning, Aetiology, 2.1 Biological and endogenous factors, Underpinning research, Generic health relevance

Abstract

While a rich set of putative cis -regulatory sequences involved in mouse fetal development has been annotated recently based on chromatin accessibility and histone modification patterns, delineating their role in developmentally regulated gene expression continues to be challenging. To fill this gap, we mapped chromatin contacts between gene promoters and distal sequences genome-wide in seven mouse fetal tissues, and for one of them, across six developmental stages. We identified 248,620 long-range chromatin interactions centered at 14,138 protein-coding genes and characterized their tissue-to-tissue variations as well as developmental dynamics. Integrative analysis of the interactome with previous epigenome and transcriptome datasets from the same tissues revealed a strong correlation between the chromatin contacts and chromatin state at distal enhancers, as well as gene expression patterns at predicted target genes. We predicted target genes of 15,098 candidate enhancers, and used them to annotate target genes of homologous candidate enhancers in the human genome that harbor risk variants of human diseases. We present evidence that schizophrenia and other adult disease risk variants are frequently found in fetal enhancers, providing support for the hypothesis of fetal origins of adult diseases.

Published

2022

4. Coding and noncoding variants in EBF3 are involved in HADDS and simplex autism

Author

Padhi, Evin M, Hayeck, Tristan J, Cheng, Zhang, Chatterjee, Sumantra, Mannion, Brandon J, Byrska-Bishop, Marta, Willems, Marjolaine, Pinson, Lucile, Redon, Sylvia, Benech, Caroline, Uguen, Kevin, Audebert-Bellanger, Séverine, Le Marechal, Cédric, Férec, Claude, Efthymiou, Stephanie, Rahman, Fatima, Maqbool, Shazia, Maroofian, Reza, Houlden, Henry, Musunuri, Rajeeva, Narzisi, Giuseppe, Abhyankar, Avinash, Hunter, Riana D, Akiyama, Jennifer, Fries, Lauren E, Ng, Jeffrey K, Mehinovic, Elvisa, Stong, Nick, Allen, Andrew S, Dickel, Diane E, Bernier, Raphael A, Gorkin, David U, Pennacchio, Len A, Zody, Michael C, and Turner, Tychele N

Subjects

Biological Sciences, Genetics, Neurosciences, Brain Disorders, Pediatric, Mental Health, Intellectual and Developmental Disabilities (IDD), Biotechnology, Autism, Behavioral and Social Science, Human Genome, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Neurological, Autistic Disorder, Enhancer Elements, Genetic, Exome, Female, Gene Regulatory Networks, Genetic Predisposition to Disease, Humans, Male, Muscle Hypotonia, Mutation, Neurodevelopmental Disorders, Neurons, Transcription Factors, Neurodevelopmental disorder, Enhancer, Gene regulatory network, EBF3, hs737, Genome, Variant, De novo, Genetics & Heredity, Biochemistry and cell biology

Abstract

BackgroundPrevious research in autism and other neurodevelopmental disorders (NDDs) has indicated an important contribution of protein-coding (coding) de novo variants (DNVs) within specific genes. The role of de novo noncoding variation has been observable as a general increase in genetic burden but has yet to be resolved to individual functional elements. In this study, we assessed whole-genome sequencing data in 2671 families with autism (discovery cohort of 516 families, replication cohort of 2155 families). We focused on DNVs in enhancers with characterized in vivo activity in the brain and identified an excess of DNVs in an enhancer named hs737.ResultsWe adapted the fitDNM statistical model to work in noncoding regions and tested enhancers for excess of DNVs in families with autism. We found only one enhancer (hs737) with nominal significance in the discovery (p = 0.0172), replication (p = 2.5 × 10-3), and combined dataset (p = 1.1 × 10-4). Each individual with a DNV in hs737 had shared phenotypes including being male, intact cognitive function, and hypotonia or motor delay. Our in vitro assessment of the DNVs showed they all reduce enhancer activity in a neuronal cell line. By epigenomic analyses, we found that hs737 is brain-specific and targets the transcription factor gene EBF3 in human fetal brain. EBF3 is genome-wide significant for coding DNVs in NDDs (missense p = 8.12 × 10-35, loss-of-function p = 2.26 × 10-13) and is widely expressed in the body. Through characterization of promoters bound by EBF3 in neuronal cells, we saw enrichment for binding to NDD genes (p = 7.43 × 10-6, OR = 1.87) involved in gene regulation. Individuals with coding DNVs have greater phenotypic severity (hypotonia, ataxia, and delayed development syndrome [HADDS]) in comparison to individuals with noncoding DNVs that have autism and hypotonia.ConclusionsIn this study, we identify DNVs in the hs737 enhancer in individuals with autism. Through multiple approaches, we find hs737 targets the gene EBF3 that is genome-wide significant in NDDs. By assessment of noncoding variation and the genes they affect, we are beginning to understand their impact on gene regulatory networks in NDDs.

Published

2021

5. Interpreting type 1 diabetes risk with genetics and single-cell epigenomics

Author

Chiou, Joshua, Geusz, Ryan J, Okino, Mei-Lin, Han, Jee Yun, Miller, Michael, Melton, Rebecca, Beebe, Elisha, Benaglio, Paola, Huang, Serina, Korgaonkar, Katha, Heller, Sandra, Kleger, Alexander, Preissl, Sebastian, Gorkin, David U, Sander, Maike, and Gaulton, Kyle J

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Genetics, Epidemiology, Health Sciences, Autoimmune Disease, Prevention, Biotechnology, Human Genome, Diabetes, Pediatric, Aetiology, 2.1 Biological and endogenous factors, Metabolic and endocrine, Generic health relevance, Good Health and Well Being, Chromatin, Cystic Fibrosis Transmembrane Conductance Regulator, Diabetes Mellitus, Type 1, Epigenomics, Female, Gene Expression Regulation, Genetic Predisposition to Disease, Genome-Wide Association Study, Humans, Immunity, Male, Pancreatic Ducts, Single-Cell Analysis, General Science & Technology

Abstract

Genetic risk variants that have been identified in genome-wide association studies of complex diseases are primarily non-coding1. Translating these risk variants into mechanistic insights requires detailed maps of gene regulation in disease-relevant cell types2. Here we combined two approaches: a genome-wide association study of type 1 diabetes (T1D) using 520,580 samples, and the identification of candidate cis-regulatory elements (cCREs) in pancreas and peripheral blood mononuclear cells using single-nucleus assay for transposase-accessible chromatin with sequencing (snATAC-seq) of 131,554 nuclei. Risk variants for T1D were enriched in cCREs that were active in T cells and other cell types, including acinar and ductal cells of the exocrine pancreas. Risk variants at multiple T1D signals overlapped with exocrine-specific cCREs that were linked to genes with exocrine-specific expression. At the CFTR locus, the T1D risk variant rs7795896 mapped to a ductal-specific cCRE that regulated CFTR; the risk allele reduced transcription factor binding, enhancer activity and CFTR expression in ductal cells. These findings support a role for the exocrine pancreas in the pathogenesis of T1D and highlight the power of large-scale genome-wide association studies and single-cell epigenomics for understanding the cellular origins of complex disease.

Published

2021

6. Single-cell chromatin accessibility identifies pancreatic islet cell type– and state-specific regulatory programs of diabetes risk

Author

Chiou, Joshua, Zeng, Chun, Cheng, Zhang, Han, Jee Yun, Schlichting, Michael, Miller, Michael, Mendez, Robert, Huang, Serina, Wang, Jinzhao, Sui, Yinghui, Deogaygay, Allison, Okino, Mei-Lin, Qiu, Yunjiang, Sun, Ying, Kudtarkar, Parul, Fang, Rongxin, Preissl, Sebastian, Sander, Maike, Gorkin, David U, and Gaulton, Kyle J

Subjects

Human Genome, Genetics, Stem Cell Research, Diabetes, 2.1 Biological and endogenous factors, Aetiology, Underpinning research, 1.1 Normal biological development and functioning, Metabolic and endocrine, Blood Glucose, Cell Differentiation, Chromatin, Diabetes Mellitus, Type 2, Epigenomics, Fasting, Gene Expression Profiling, Genome-Wide Association Study, Glucagon-Secreting Cells, High-Throughput Nucleotide Sequencing, Human Embryonic Stem Cells, Humans, Insulin-Secreting Cells, KCNQ1 Potassium Channel, Multigene Family, Pancreatic Polypeptide-Secreting Cells, Polymorphism, Genetic, Single-Cell Analysis, Somatostatin-Secreting Cells, Transcription Factors, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

Single-nucleus assay for transposase-accessible chromatin using sequencing (snATAC-seq) creates new opportunities to dissect cell type-specific mechanisms of complex diseases. Since pancreatic islets are central to type 2 diabetes (T2D), we profiled 15,298 islet cells by using combinatorial barcoding snATAC-seq and identified 12 clusters, including multiple alpha, beta and delta cell states. We cataloged 228,873 accessible chromatin sites and identified transcription factors underlying lineage- and state-specific regulation. We observed state-specific enrichment of fasting glucose and T2D genome-wide association studies for beta cells and enrichment for other endocrine cell types. At T2D signals localized to islet-accessible chromatin, we prioritized variants with predicted regulatory function and co-accessibility with target genes. A causal T2D variant rs231361 at the KCNQ1 locus had predicted effects on a beta cell enhancer co-accessible with INS and genome editing in embryonic stem cell-derived beta cells affected INS levels. Together our findings demonstrate the power of single-cell epigenomics for interpreting complex disease genetics.

Published

2021

7. Author Correction: An atlas of dynamic chromatin landscapes in mouse fetal development

Author

Gorkin, David U, Barozzi, Iros, Zhao, Yuan, Zhang, Yanxiao, Huang, Hui, Lee, Ah Young, Li, Bin, Chiou, Joshua, Wildberg, Andre, Ding, Bo, Zhang, Bo, Wang, Mengchi, Strattan, J Seth, Davidson, Jean M, Qiu, Yunjiang, Afzal, Veena, Akiyama, Jennifer A, Plajzer-Frick, Ingrid, Novak, Catherine S, Kato, Momoe, Garvin, Tyler H, Pham, Quan T, Harrington, Anne N, Mannion, Brandon J, Lee, Elizabeth A, Fukuda-Yuzawa, Yoko, He, Yupeng, Preissl, Sebastian, Chee, Sora, Han, Jee Yun, Williams, Brian A, Trout, Diane, Amrhein, Henry, Yang, Hongbo, Cherry, J Michael, Wang, Wei, Gaulton, Kyle, Ecker, Joseph R, Shen, Yin, Dickel, Diane E, Visel, Axel, Pennacchio, Len A, and Ren, Bing

Subjects

Reproductive Medicine, Biomedical and Clinical Sciences, Pediatric, General Science & Technology

Abstract

A Correction to this paper has been published: https://doi.org/10.1038/s41586-020-03089-4.

Published

2021

8. Author Correction: An atlas of dynamic chromatin landscapes in mouse fetal development

Author

Gorkin, David U, Barozzi, Iros, Zhao, Yuan, Zhang, Yanxiao, Huang, Hui, Lee, Ah Young, Li, Bin, Chiou, Joshua, Wildberg, Andre, Ding, Bo, Zhang, Bo, Wang, Mengchi, Strattan, J Seth, Davidson, Jean M, Qiu, Yunjiang, Afzal, Veena, Akiyama, Jennifer A, Plajzer-Frick, Ingrid, Novak, Catherine S, Kato, Momoe, Garvin, Tyler H, Pham, Quan T, Harrington, Anne N, Mannion, Brandon J, Lee, Elizabeth A, Fukuda-Yuzawa, Yoko, He, Yupeng, Preissl, Sebastian, Chee, Sora, Han, Jee Yun, Williams, Brian A, Trout, Diane, Amrhein, Henry, Yang, Hongbo, Cherry, J Michael, Wang, Wei, Gaulton, Kyle, Ecker, Joseph R, Shen, Yin, Dickel, Diane E, Visel, Axel, Pennacchio, Len A, and Ren, Bing

Subjects

Reproductive Medicine, Biomedical and Clinical Sciences, General Science & Technology

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

9. De Novo Mutation in an Enhancer of EBF3 in simplex autism

Author

Padhi, Evin M, Hayeck, Tristan J, Mannion, Brandon, Chatterjee, Sumantra, Byrska-Bishop, Marta, Musunuri, Rajeeva, Narzisi, Giuseppe, Abhyankar, Avinash, Cheng, Zhang, Hunter, Riana D, Akiyama, Jennifer, Fries, Lauren E, Ng, Jeffrey, Stong, Nick, Allen, Andrew S, Dickel, Diane E, Bernier, Raphael A, Gorkin, David U, Pennacchio, Len A, Zody, Michael C, and Turner, Tychele N

Abstract

AbstractPrevious research in autism and other neurodevelopmental disorders (NDDs) has indicated an important contribution of de novo protein-coding variants within specific genes. The role of de novo noncoding variation has been observable as a general increase in genetic burden but has yet to be resolved to individual functional elements. In this study, we assessed whole-genome sequencing data in 2,671 families with autism, with a specific focus on de novo variation in enhancers with previously characterized in vivo activity. We identified three independent de novo mutations limited to individuals with autism in the enhancer hs737. These mutations result in similar phenotypic characteristics, affect enhancer activity in vitro, and preferentially occur in AAT motifs in the enhancer with predicted disruptions of transcription factor binding. We also find that hs737 is enriched for copy number variation in individuals with NDDs, is dosage sensitive in the human population, is brain-specific, and targets the NDD gene EBF3 that is genome-wide significant for protein coding de novo variants, demonstrating the importance of understanding all forms of variation in the genome.One Sentence SummaryWhole-genome sequencing in thousands of families reveals variants relevant to simplex autism in a brain enhancer of the well-established neurodevelopmental disorder gene EBF3.

Published

2020

10. Spatiotemporal DNA methylome dynamics of the developing mouse fetus

Author

He, Yupeng, Hariharan, Manoj, Gorkin, David U, Dickel, Diane E, Luo, Chongyuan, Castanon, Rosa G, Nery, Joseph R, Lee, Ah Young, Zhao, Yuan, Huang, Hui, Williams, Brian A, Trout, Diane, Amrhein, Henry, Fang, Rongxin, Chen, Huaming, Li, Bin, Visel, Axel, Pennacchio, Len A, Ren, Bing, and Ecker, Joseph R

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Genetics, Human Genome, Pediatric, Biotechnology, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Animals, Newborn, Chromatin, DNA Methylation, Disease, Down-Regulation, Enhancer Elements, Genetic, Epigenetic Repression, Epigenome, Female, Fetus, Gene Silencing, Humans, Mice, Mice, Inbred C57BL, Models, Animal, Molecular Sequence Annotation, Polymorphism, Single Nucleotide, Spatio-Temporal Analysis, General Science & Technology

Abstract

Cytosine DNA methylation is essential for mammalian development but understanding of its spatiotemporal distribution in the developing embryo remains limited1,2. Here, as part of the mouse Encyclopedia of DNA Elements (ENCODE) project, we profiled 168 methylomes from 12 mouse tissues or organs at 9 developmental stages from embryogenesis to adulthood. We identified 1,808,810 genomic regions that showed variations in CG methylation by comparing the methylomes of different tissues or organs from different developmental stages. These DNA elements predominantly lose CG methylation during fetal development, whereas the trend is reversed after birth. During late stages of fetal development, non-CG methylation accumulated within the bodies of key developmental transcription factor genes, coinciding with their transcriptional repression. Integration of genome-wide DNA methylation, histone modification and chromatin accessibility data enabled us to predict 461,141 putative developmental tissue-specific enhancers, the human orthologues of which were enriched for disease-associated genetic variants. These spatiotemporal epigenome maps provide a resource for studies of gene regulation during tissue or organ progression, and a starting point for investigating regulatory elements that are involved in human developmental disorders.

Published

2020

11. An atlas of dynamic chromatin landscapes in mouse fetal development

Author

Gorkin, David U, Barozzi, Iros, Zhao, Yuan, Zhang, Yanxiao, Huang, Hui, Lee, Ah Young, Li, Bin, Chiou, Joshua, Wildberg, Andre, Ding, Bo, Zhang, Bo, Wang, Mengchi, Strattan, J Seth, Davidson, Jean M, Qiu, Yunjiang, Afzal, Veena, Akiyama, Jennifer A, Plajzer-Frick, Ingrid, Novak, Catherine S, Kato, Momoe, Garvin, Tyler H, Pham, Quan T, Harrington, Anne N, Mannion, Brandon J, Lee, Elizabeth A, Fukuda-Yuzawa, Yoko, He, Yupeng, Preissl, Sebastian, Chee, Sora, Han, Jee Yun, Williams, Brian A, Trout, Diane, Amrhein, Henry, Yang, Hongbo, Cherry, J Michael, Wang, Wei, Gaulton, Kyle, Ecker, Joseph R, Shen, Yin, Dickel, Diane E, Visel, Axel, Pennacchio, Len A, and Ren, Bing

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Genetics, Human Genome, Biotechnology, Pediatric, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Generic health relevance, Animals, Chromatin, Chromatin Immunoprecipitation Sequencing, Datasets as Topic, Disease, Enhancer Elements, Genetic, Female, Fetal Development, Gene Expression Regulation, Developmental, Genetic Variation, Histones, Humans, Male, Mice, Mice, Inbred C57BL, Molecular Sequence Annotation, Organ Specificity, Regulatory Sequences, Nucleic Acid, Reproducibility of Results, Transposases, General Science & Technology

Abstract

The Encyclopedia of DNA Elements (ENCODE) project has established a genomic resource for mammalian development, profiling a diverse panel of mouse tissues at 8 developmental stages from 10.5 days after conception until birth, including transcriptomes, methylomes and chromatin states. Here we systematically examined the state and accessibility of chromatin in the developing mouse fetus. In total we performed 1,128 chromatin immunoprecipitation with sequencing (ChIP-seq) assays for histone modifications and 132 assay for transposase-accessible chromatin using sequencing (ATAC-seq) assays for chromatin accessibility across 72 distinct tissue-stages. We used integrative analysis to develop a unified set of chromatin state annotations, infer the identities of dynamic enhancers and key transcriptional regulators, and characterize the relationship between chromatin state and accessibility during developmental gene regulation. We also leveraged these data to link enhancers to putative target genes and demonstrate tissue-specific enrichments of sequence variants associated with disease in humans. The mouse ENCODE data sets provide a compendium of resources for biomedical researchers and achieve, to our knowledge, the most comprehensive view of chromatin dynamics during mammalian fetal development to date.

Published

2020

12. Expanded encyclopaedias of DNA elements in the human and mouse genomes

Author

Moore, Jill E, Purcaro, Michael J, Pratt, Henry E, Epstein, Charles B, Shoresh, Noam, Adrian, Jessika, Kawli, Trupti, Davis, Carrie A, Dobin, Alexander, Kaul, Rajinder, Halow, Jessica, Van Nostrand, Eric L, Freese, Peter, Gorkin, David U, Shen, Yin, He, Yupeng, Mackiewicz, Mark, Pauli-Behn, Florencia, Williams, Brian A, Mortazavi, Ali, Keller, Cheryl A, Zhang, Xiao-Ou, Elhajjajy, Shaimae I, Huey, Jack, Dickel, Diane E, Snetkova, Valentina, Wei, Xintao, Wang, Xiaofeng, Rivera-Mulia, Juan Carlos, Rozowsky, Joel, Zhang, Jing, Chhetri, Surya B, Zhang, Jialing, Victorsen, Alec, White, Kevin P, Visel, Axel, Yeo, Gene W, Burge, Christopher B, Lécuyer, Eric, Gilbert, David M, Dekker, Job, Rinn, John, Mendenhall, Eric M, Ecker, Joseph R, Kellis, Manolis, Klein, Robert J, Noble, William S, Kundaje, Anshul, Guigó, Roderic, Farnham, Peggy J, Cherry, J Michael, Myers, Richard M, Ren, Bing, Graveley, Brenton R, Gerstein, Mark B, Pennacchio, Len A, Snyder, Michael P, Bernstein, Bradley E, Wold, Barbara, Hardison, Ross C, Gingeras, Thomas R, Stamatoyannopoulos, John A, and Weng, Zhiping

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, 1.1 Normal biological development and functioning, Animals, Chromatin, DNA, DNA Footprinting, DNA Methylation, DNA Replication Timing, Databases, Genetic, Deoxyribonuclease I, Genome, Genome, Human, Genomics, Histones, Humans, Mice, Mice, Transgenic, Molecular Sequence Annotation, RNA-Binding Proteins, Registries, Regulatory Sequences, Nucleic Acid, Transcription, Genetic, Transposases, ENCODE Project Consortium, General Science & Technology

Abstract

The human and mouse genomes contain instructions that specify RNAs and proteins and govern the timing, magnitude, and cellular context of their production. To better delineate these elements, phase III of the Encyclopedia of DNA Elements (ENCODE) Project has expanded analysis of the cell and tissue repertoires of RNA transcription, chromatin structure and modification, DNA methylation, chromatin looping, and occupancy by transcription factors and RNA-binding proteins. Here we summarize these efforts, which have produced 5,992 new experimental datasets, including systematic determinations across mouse fetal development. All data are available through the ENCODE data portal (https://www.encodeproject.org), including phase II ENCODE1 and Roadmap Epigenomics2 data. We have developed a registry of 926,535 human and 339,815 mouse candidate cis-regulatory elements, covering 7.9 and 3.4% of their respective genomes, by integrating selected datatypes associated with gene regulation, and constructed a web-based server (SCREEN; http://screen.encodeproject.org) to provide flexible, user-defined access to this resource. Collectively, the ENCODE data and registry provide an expansive resource for the scientific community to build a better understanding of the organization and function of the human and mouse genomes.

Published

2020

13. Expanded encyclopaedias of DNA elements in the human and mouse genomes.

Author

ENCODE Project Consortium, Moore, Jill E, Purcaro, Michael J, Pratt, Henry E, Epstein, Charles B, Shoresh, Noam, Adrian, Jessika, Kawli, Trupti, Davis, Carrie A, Dobin, Alexander, Kaul, Rajinder, Halow, Jessica, Van Nostrand, Eric L, Freese, Peter, Gorkin, David U, Shen, Yin, He, Yupeng, Mackiewicz, Mark, Pauli-Behn, Florencia, Williams, Brian A, Mortazavi, Ali, Keller, Cheryl A, Zhang, Xiao-Ou, Elhajjajy, Shaimae I, Huey, Jack, Dickel, Diane E, Snetkova, Valentina, Wei, Xintao, Wang, Xiaofeng, Rivera-Mulia, Juan Carlos, Rozowsky, Joel, Zhang, Jing, Chhetri, Surya B, Zhang, Jialing, Victorsen, Alec, White, Kevin P, Visel, Axel, Yeo, Gene W, Burge, Christopher B, Lécuyer, Eric, Gilbert, David M, Dekker, Job, Rinn, John, Mendenhall, Eric M, Ecker, Joseph R, Kellis, Manolis, Klein, Robert J, Noble, William S, Kundaje, Anshul, Guigó, Roderic, Farnham, Peggy J, Cherry, J Michael, Myers, Richard M, Ren, Bing, Graveley, Brenton R, Gerstein, Mark B, Pennacchio, Len A, Snyder, Michael P, Bernstein, Bradley E, Wold, Barbara, Hardison, Ross C, Gingeras, Thomas R, Stamatoyannopoulos, John A, and Weng, Zhiping

Subjects

ENCODE Project Consortium, Chromatin, Animals, Mice, Transgenic, Humans, Mice, Deoxyribonuclease I, Transposases, RNA-Binding Proteins, Histones, DNA, Registries, DNA Footprinting, Genomics, DNA Methylation, DNA Replication Timing, Transcription, Genetic, Regulatory Sequences, Nucleic Acid, Genome, Genome, Human, Databases, Genetic, Molecular Sequence Annotation, Human Genome, HIV/AIDS, Vaccine Related, Biotechnology, Genetics, Immunization, Vaccine Related (AIDS), Prevention, 1.1 Normal biological development and functioning, Generic health relevance, General Science & Technology

Abstract

The human and mouse genomes contain instructions that specify RNAs and proteins and govern the timing, magnitude, and cellular context of their production. To better delineate these elements, phase III of the Encyclopedia of DNA Elements (ENCODE) Project has expanded analysis of the cell and tissue repertoires of RNA transcription, chromatin structure and modification, DNA methylation, chromatin looping, and occupancy by transcription factors and RNA-binding proteins. Here we summarize these efforts, which have produced 5,992 new experimental datasets, including systematic determinations across mouse fetal development. All data are available through the ENCODE data portal (https://www.encodeproject.org), including phase II ENCODE1 and Roadmap Epigenomics2 data. We have developed a registry of 926,535 human and 339,815 mouse candidate cis-regulatory elements, covering 7.9 and 3.4% of their respective genomes, by integrating selected datatypes associated with gene regulation, and constructed a web-based server (SCREEN; http://screen.encodeproject.org) to provide flexible, user-defined access to this resource. Collectively, the ENCODE data and registry provide an expansive resource for the scientific community to build a better understanding of the organization and function of the human and mouse genomes.

Published

2020

14. Common DNA sequence variation influences 3-dimensional conformation of the human genome

Author

Gorkin, David U, Qiu, Yunjiang, Hu, Ming, Fletez-Brant, Kipper, Liu, Tristin, Schmitt, Anthony D, Noor, Amina, Chiou, Joshua, Gaulton, Kyle J, Sebat, Jonathan, Li, Yun, Hansen, Kasper D, and Ren, Bing

Subjects

Cancer, Human Genome, Stem Cell Research, Genetics, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Base Sequence, Epigenome, Genetic Variation, Genome, Human, Humans, Nucleic Acid Conformation, Quantitative Trait Loci, Transcriptome, Environmental Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics

Abstract

BACKGROUND:The 3-dimensional (3D) conformation of chromatin inside the nucleus is integral to a variety of nuclear processes including transcriptional regulation, DNA replication, and DNA damage repair. Aberrations in 3D chromatin conformation have been implicated in developmental abnormalities and cancer. Despite the importance of 3D chromatin conformation to cellular function and human health, little is known about how 3D chromatin conformation varies in the human population, or whether DNA sequence variation between individuals influences 3D chromatin conformation. RESULTS:To address these questions, we perform Hi-C on lymphoblastoid cell lines from 20 individuals. We identify thousands of regions across the genome where 3D chromatin conformation varies between individuals and find that this variation is often accompanied by variation in gene expression, histone modifications, and transcription factor binding. Moreover, we find that DNA sequence variation influences several features of 3D chromatin conformation including loop strength, contact insulation, contact directionality, and density of local cis contacts. We map hundreds of quantitative trait loci associated with 3D chromatin features and find evidence that some of these same variants are associated at modest levels with other molecular phenotypes as well as complex disease risk. CONCLUSION:Our results demonstrate that common DNA sequence variants can influence 3D chromatin conformation, pointing to a more pervasive role for 3D chromatin conformation in human phenotypic variation than previously recognized.

Published

2019

15. Multi-platform discovery of haplotype-resolved structural variation in human genomes.

Author

Chaisson, Mark JP, Sanders, Ashley D, Zhao, Xuefang, Malhotra, Ankit, Porubsky, David, Rausch, Tobias, Gardner, Eugene J, Rodriguez, Oscar L, Guo, Li, Collins, Ryan L, Fan, Xian, Wen, Jia, Handsaker, Robert E, Fairley, Susan, Kronenberg, Zev N, Kong, Xiangmeng, Hormozdiari, Fereydoun, Lee, Dillon, Wenger, Aaron M, Hastie, Alex R, Antaki, Danny, Anantharaman, Thomas, Audano, Peter A, Brand, Harrison, Cantsilieris, Stuart, Cao, Han, Cerveira, Eliza, Chen, Chong, Chen, Xintong, Chin, Chen-Shan, Chong, Zechen, Chuang, Nelson T, Lambert, Christine C, Church, Deanna M, Clarke, Laura, Farrell, Andrew, Flores, Joey, Galeev, Timur, Gorkin, David U, Gujral, Madhusudan, Guryev, Victor, Heaton, William Haynes, Korlach, Jonas, Kumar, Sushant, Kwon, Jee Young, Lam, Ernest T, Lee, Jong Eun, Lee, Joyce, Lee, Wan-Ping, Lee, Sau Peng, Li, Shantao, Marks, Patrick, Viaud-Martinez, Karine, Meiers, Sascha, Munson, Katherine M, Navarro, Fabio CP, Nelson, Bradley J, Nodzak, Conor, Noor, Amina, Kyriazopoulou-Panagiotopoulou, Sofia, Pang, Andy WC, Qiu, Yunjiang, Rosanio, Gabriel, Ryan, Mallory, Stütz, Adrian, Spierings, Diana CJ, Ward, Alistair, Welch, AnneMarie E, Xiao, Ming, Xu, Wei, Zhang, Chengsheng, Zhu, Qihui, Zheng-Bradley, Xiangqun, Lowy, Ernesto, Yakneen, Sergei, McCarroll, Steven, Jun, Goo, Ding, Li, Koh, Chong Lek, Ren, Bing, Flicek, Paul, Chen, Ken, Gerstein, Mark B, Kwok, Pui-Yan, Lansdorp, Peter M, Marth, Gabor T, Sebat, Jonathan, Shi, Xinghua, Bashir, Ali, Ye, Kai, Devine, Scott E, Talkowski, Michael E, Mills, Ryan E, Marschall, Tobias, Korbel, Jan O, Eichler, Evan E, and Lee, Charles

Subjects

Humans, Chromosome Mapping, Genomics, Haplotypes, Genome, Human, Algorithms, Databases, Genetic, INDEL Mutation, Genomic Structural Variation, High-Throughput Nucleotide Sequencing, Whole Genome Sequencing, Genome, Human, Databases, Genetic

Abstract

The incomplete identification of structural variants (SVs) from whole-genome sequencing data limits studies of human genetic diversity and disease association. Here, we apply a suite of long-read, short-read, strand-specific sequencing technologies, optical mapping, and variant discovery algorithms to comprehensively analyze three trios to define the full spectrum of human genetic variation in a haplotype-resolved manner. We identify 818,054 indel variants (

Published

2019

16. N 6 -methyladenine DNA Modification in Glioblastoma

Author

Xie, Qi, Wu, Tao P, Gimple, Ryan C, Li, Zheng, Prager, Briana C, Wu, Qiulian, Yu, Yang, Wang, Pengcheng, Wang, Yinsheng, Gorkin, David U, Zhang, Cheng, Dowiak, Alexis V, Lin, Kaixuan, Zeng, Chun, Sui, Yinghui, Kim, Leo JY, Miller, Tyler E, Jiang, Li, Lee-Poturalski, Christine, Huang, Zhi, Fang, Xiaoguang, Zhai, Kui, Mack, Stephen C, Sander, Maike, Bao, Shideng, Kerstetter-Fogle, Amber E, Sloan, Andrew E, Xiao, Andrew Z, and Rich, Jeremy N

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Genetics, Brain Cancer, Brain Disorders, Rare Diseases, Cancer, Biotechnology, Aetiology, 2.1 Biological and endogenous factors, Adenine, Adult, Aged, AlkB Homolog 1, Histone H2a Dioxygenase, Animals, Astrocytes, Brain Neoplasms, Cell Hypoxia, Child, DNA Methylation, Epigenomics, Female, Glioblastoma, Heterochromatin, Histones, Humans, Kaplan-Meier Estimate, Male, Mice, Middle Aged, Neoplastic Stem Cells, RNA Interference, RNA, Small Interfering, Tumor Suppressor Protein p53, DNA methylation, H3K9me3, N(6)-methyladenine, brain tumor, cancer stem cell, chromatin, epigenetics, glioblastoma, heterochromatin, neuro-oncology, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

Genetic drivers of cancer can be dysregulated through epigenetic modifications of DNA. Although the critical role of DNA 5-methylcytosine (5mC) in the regulation of transcription is recognized, the functions of other non-canonical DNA modifications remain obscure. Here, we report the identification of novel N6-methyladenine (N6-mA) DNA modifications in human tissues and implicate this epigenetic mark in human disease, specifically the highly malignant brain cancer glioblastoma. Glioblastoma markedly upregulated N6-mA levels, which co-localized with heterochromatic histone modifications, predominantly H3K9me3. N6-mA levels were dynamically regulated by the DNA demethylase ALKBH1, depletion of which led to transcriptional silencing of oncogenic pathways through decreasing chromatin accessibility. Targeting the N6-mA regulator ALKBH1 in patient-derived human glioblastoma models inhibited tumor cell proliferation and extended the survival of tumor-bearing mice, supporting this novel DNA modification as a potential therapeutic target for glioblastoma. Collectively, our results uncover a novel epigenetic node in cancer through the DNA modification N6-mA.

Published

2018

17. Author Correction: Single-nucleus analysis of accessible chromatin in developing mouse forebrain reveals cell-type-specific transcriptional regulation

Author

Preissl, Sebastian, Fang, Rongxin, Huang, Hui, Zhao, Yuan, Raviram, Ramya, Gorkin, David U, Zhang, Yanxiao, Sos, Brandon C, Afzal, Veena, Dickel, Diane E, Kuan, Samantha, Visel, Axel, Pennacchio, Len A, Zhang, Kun, and Ren, Bing

Subjects

Biomedical and Clinical Sciences, Neurosciences, Genetics, Psychology, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology

Abstract

In the version of this article initially published online, the accession code was given as GSE1000333. The correct code is GSE100033. The error has been corrected in the print, HTML and PDF versions of the article.

Published

2018

18. Single-nucleus analysis of accessible chromatin in developing mouse forebrain reveals cell-type-specific transcriptional regulation

Author

Preissl, Sebastian, Fang, Rongxin, Huang, Hui, Zhao, Yuan, Raviram, Ramya, Gorkin, David U, Zhang, Yanxiao, Sos, Brandon C, Afzal, Veena, Dickel, Diane E, Kuan, Samantha, Visel, Axel, Pennacchio, Len A, Zhang, Kun, and Ren, Bing

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, Human Genome, Genetics, 1.1 Normal biological development and functioning, Animals, Cell Line, Chromatin, DNA-Binding Proteins, Female, Gene Expression Regulation, Developmental, Mice, Mice, Inbred C57BL, Nerve Tissue Proteins, Neurons, Nuclear Proteins, Pregnancy, Prosencephalon, Single-Cell Analysis, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology

Abstract

Analysis of chromatin accessibility can reveal transcriptional regulatory sequences, but heterogeneity of primary tissues poses a significant challenge in mapping the precise chromatin landscape in specific cell types. Here we report single-nucleus ATAC-seq, a combinatorial barcoding-assisted single-cell assay for transposase-accessible chromatin that is optimized for use on flash-frozen primary tissue samples. We apply this technique to the mouse forebrain through eight developmental stages. Through analysis of more than 15,000 nuclei, we identify 20 distinct cell populations corresponding to major neuronal and non-neuronal cell types. We further define cell-type-specific transcriptional regulatory sequences, infer potential master transcriptional regulators and delineate developmental changes in forebrain cellular composition. Our results provide insight into the molecular and cellular dynamics that underlie forebrain development in the mouse and establish technical and analytical frameworks that are broadly applicable to other heterogeneous tissues.

Published

2018

19. Removing unwanted variation between samples in Hi-C experiments

Author

Fletez-Brant, Kipper, primary, Qiu, Yunjiang, additional, Gorkin, David U, additional, Hu, Ming, additional, and Hansen, Kasper D, additional

Published

2024

20. Improved regulatory element prediction based on tissue-specific local epigenomic signatures

Author

He, Yupeng, Gorkin, David U, Dickel, Diane E, Nery, Joseph R, Castanon, Rosa G, Lee, Ah Young, Shen, Yin, Visel, Axel, Pennacchio, Len A, Ren, Bing, and Ecker, Joseph R

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Bioengineering, Human Genome, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Generic health relevance, Algorithms, Computational Biology, DNA Methylation, Enhancer Elements, Genetic, Epigenesis, Genetic, Epigenomics, Gene Expression Regulation, Genomics, Histone Code, Histones, Humans, Transcription, Genetic, enhancer prediction, DNA methylation, bioinformatics, gene regulation, epigenetics

Abstract

Accurate enhancer identification is critical for understanding the spatiotemporal transcriptional regulation during development as well as the functional impact of disease-related noncoding genetic variants. Computational methods have been developed to predict the genomic locations of active enhancers based on histone modifications, but the accuracy and resolution of these methods remain limited. Here, we present an algorithm, regulatory element prediction based on tissue-specific local epigenetic marks (REPTILE), which integrates histone modification and whole-genome cytosine DNA methylation profiles to identify the precise location of enhancers. We tested the ability of REPTILE to identify enhancers previously validated in reporter assays. Compared with existing methods, REPTILE shows consistently superior performance across diverse cell and tissue types, and the enhancer locations are significantly more refined. We show that, by incorporating base-resolution methylation data, REPTILE greatly improves upon current methods for annotation of enhancers across a variety of cell and tissue types. REPTILE is available at https://github.com/yupenghe/REPTILE/.

Published

2017

21. Spatiotemporal DNA Methylome Dynamics of the Developing Mammalian Fetus

Author

He, Yupeng, Hariharan, Manoj, Gorkin, David U, Dickel, Diane E, Luo, Chongyuan, Castanon, Rosa G, Nery, Joseph R, Lee, Ah Young, Williams, Brian A, Trout, Diane, Amrhein, Henry, Fang, Rongxin, Chen, Huaming, Li, Bin, Visel, Axel, Pennacchio, Len A, Ren, Bing, and Ecker, Joseph R

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Genetics, Reproductive Medicine, Biotechnology, Pediatric, Human Genome, 1.1 Normal biological development and functioning, Generic health relevance

Abstract

Summary Genetic studies have revealed an essential role for cytosine DNA methylation in mammalian development. However, its spatiotemporal distribution in the developing embryo remains obscure. Here, we profiled the methylome landscapes of 12 mouse tissues/organs at 8 developmental stages spanning from early embryogenesis to birth. Indepth analysis of these spatiotemporal epigenome maps systematically delineated ~2 million methylation variant regions and uncovered widespread methylation dynamics at nearly one-half million tissue-specific enhancers, whose human counterparts were enriched for variants involved in genetic diseases. Strikingly, these predicted regulatory elements predominantly lose CG methylation during fetal development, whereas the trend is reversed after birth. Accumulation of non-CG methylation within gene bodies of key developmental transcription factors coincided with their transcriptional repression during later stages of fetal development. These spatiotemporal epigenomic maps provide a valuable resource for studying gene regulation during mammalian tissue/organ progression and for pinpointing regulatory elements involved in human developmental diseases.

Published

2017

22. Single nucleus analysis of the chromatin landscape in mouse forebrain development

Author

Preissl, Sebastian, Fang, Rongxin, Zhao, Yuan, Raviram, Ramya, Zhang, Yanxiao, Sos, Brandon C, Huang, Hui, Gorkin, David U, Afzal, Veena, Dickel, Diane E, Kuan, Samantha, Visel, Axel, Pennacchio, Len A, Zhang, Kun, and Ren, Bing

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, Neurosciences, Biotechnology, 1.1 Normal biological development and functioning

Abstract

ABSTRACT Genome-wide analysis of chromatin accessibility in primary tissues has uncovered millions of candidate regulatory sequences in the human and mouse genomes 1–4 . However, the heterogeneity of biological samples used in previous studies has prevented a precise understanding of the dynamic chromatin landscape in specific cell types. Here, we show that analysis of the transposase-accessible-chromatin in single nuclei isolated from frozen tissue samples can resolve cellular heterogeneity and delineate transcriptional regulatory sequences in the constituent cell types. Our strategy is based on a combinatorial barcoding assisted single cell assay for transposase-accessible chromatin 5 and is optimized for nuclei from flash-frozen primary tissue samples (snATAC-seq). We used this method to examine the mouse forebrain at seven development stages and in adults. From snATAC-seq profiles of more than 15,000 high quality nuclei, we identify 20 distinct cell populations corresponding to major neuronal and non-neuronal cell-types in foetal and adult forebrains. We further define cell-type specific cis regulatory sequences and infer potential master transcriptional regulators of each cell population. Our results demonstrate the feasibility of a general approach for identifying cell-type-specific cis regulatory sequences in heterogeneous tissue samples, and provide a rich resource for understanding forebrain development in mammals.

Published

2017

23. Genome-wide compendium and functional assessment of in vivo heart enhancers.

Author

Dickel, Diane E, Barozzi, Iros, Zhu, Yiwen, Fukuda-Yuzawa, Yoko, Osterwalder, Marco, Mannion, Brandon J, May, Dalit, Spurrell, Cailyn H, Plajzer-Frick, Ingrid, Pickle, Catherine S, Lee, Elizabeth, Garvin, Tyler H, Kato, Momoe, Akiyama, Jennifer A, Afzal, Veena, Lee, Ah Young, Gorkin, David U, Ren, Bing, Rubin, Edward M, Visel, Axel, and Pennacchio, Len A

Subjects

Heart, Animals, Mice, Inbred C57BL, Mice, Knockout, Humans, Mice, Histones, Echocardiography, Gene Expression Profiling, Gene Expression Regulation, Gene Expression Regulation, Developmental, Phenotype, Mutation, Genome, Human, Female, Male, Enhancer Elements, Genetic, Epigenomics, Inbred C57BL, Knockout, Developmental, Genome, Human, Enhancer Elements, Genetic, Cardiovascular, Genetics, Human Genome, Biotechnology, Heart Disease, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors

Abstract

Whole-genome sequencing is identifying growing numbers of non-coding variants in human disease studies, but the lack of accurate functional annotations prevents their interpretation. We describe the genome-wide landscape of distant-acting enhancers active in the developing and adult human heart, an organ whose impairment is a predominant cause of mortality and morbidity. Using integrative analysis of >35 epigenomic data sets from mouse and human pre- and postnatal hearts we created a comprehensive reference of >80,000 putative human heart enhancers. To illustrate the importance of enhancers in the regulation of genes involved in heart disease, we deleted the mouse orthologs of two human enhancers near cardiac myosin genes. In both cases, we observe in vivo expression changes and cardiac phenotypes consistent with human heart disease. Our study provides a comprehensive catalogue of human heart enhancers for use in clinical whole-genome sequencing studies and highlights the importance of enhancers for cardiac function.

Published

2016

24. Chromatin Domains: The Unit of Chromosome Organization

Author

Dixon, Jesse R, Gorkin, David U, and Ren, Bing

Subjects

Biochemistry and Cell Biology, Biological Sciences, Genetics, Human Genome, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Cell Nucleus, Chromatin, Chromatin Assembly and Disassembly, Chromosomes, Gene Expression Regulation, Genome, Genomics, Humans, Interphase, Nucleic Acid Conformation, Protein Conformation, Structure-Activity Relationship, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

How eukaryotic chromosomes fold inside the nucleus is an age-old question that remains unanswered today. Early biochemical and microscopic studies revealed the existence of chromatin domains and loops as a pervasive feature of interphase chromosomes, but the biological implications of such organizational features were obscure. Genome-wide analysis of pair-wise chromatin interactions using chromatin conformation capture (3C)-based techniques has shed new light on the organization of chromosomes in interphase nuclei. Particularly, the finding of cell-type invariant, evolutionarily conserved topologically associating domains (TADs) in a broad spectrum of cell types has provided a new molecular framework for the study of animal development and human diseases. Here, we review recent progress in characterization of such chromatin domains and delineation of mechanisms of their formation in animal cells.

Published

2016

25. CRISPR Inversion of CTCF Sites Alters Genome Topology and Enhancer/Promoter Function

Author

Guo, Ya, Xu, Quan, Canzio, Daniele, Shou, Jia, Li, Jinhuan, Gorkin, David U, Jung, Inkyung, Wu, Haiyang, Zhai, Yanan, Tang, Yuanxiao, Lu, Yichao, Wu, Yonghu, Jia, Zhilian, Li, Wei, Zhang, Michael Q, Ren, Bing, Krainer, Adrian R, Maniatis, Tom, and Wu, Qiang

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Genetics, Biological Sciences, Biotechnology, Human Genome, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Binding Sites, CCCTC-Binding Factor, Cadherins, Cell Cycle Proteins, Chromosomal Proteins, Non-Histone, Chromosomes, Clustered Regularly Interspaced Short Palindromic Repeats, DNA, Enhancer Elements, Genetic, Gene Expression, Genetic Techniques, Genome, Human, Humans, K562 Cells, Mice, Promoter Regions, Genetic, Repressor Proteins, beta-Globins, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

CTCF and the associated cohesin complex play a central role in insulator function and higher-order chromatin organization of mammalian genomes. Recent studies identified a correlation between the orientation of CTCF-binding sites (CBSs) and chromatin loops. To test the functional significance of this observation, we combined CRISPR/Cas9-based genomic-DNA-fragment editing with chromosome-conformation-capture experiments to show that the location and relative orientations of CBSs determine the specificity of long-range chromatin looping in mammalian genomes, using protocadherin (Pcdh) and β-globin as model genes. Inversion of CBS elements within the Pcdh enhancer reconfigures the topology of chromatin loops between the distal enhancer and target promoters and alters gene-expression patterns. Thus, although enhancers can function in an orientation-independent manner in reporter assays, in the native chromosome context, the orientation of at least some enhancers carrying CBSs can determine both the architecture of topological chromatin domains and enhancer/promoter specificity. These findings reveal how 3D chromosome architecture can be encoded by linear genome sequences.

Published

2015

26. The 3D Genome in Transcriptional Regulation and Pluripotency

Author

Gorkin, David U, Leung, Danny, and Ren, Bing

Subjects

Biochemistry and Cell Biology, Genetics, Biological Sciences, Stem Cell Research, Stem Cell Research - Nonembryonic - Non-Human, Human Genome, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Cell Differentiation, Cell Lineage, Gene Expression Regulation, Genome, Humans, Pluripotent Stem Cells, Transcription, Genetic, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

It can be convenient to think of the genome as simply a string of nucleotides, the linear order of which encodes an organism's genetic blueprint. However, the genome does not exist as a linear entity within cells where this blueprint is actually utilized. Inside the nucleus, the genome is organized in three-dimensional (3D) space, and lineage-specific transcriptional programs that direct stem cell fate are implemented in this native 3D context. Here, we review principles of 3D genome organization in mammalian cells. We focus on the emerging relationship between genome organization and lineage-specific transcriptional regulation, which we argue are inextricably linked.

Published

2014

27. The EN-TEx resource of multi-tissue personal epigenomes & variant-impact models

Author

Rozowsky, Joel, primary, Gao, Jiahao, additional, Borsari, Beatrice, additional, Yang, Yucheng T., additional, Galeev, Timur, additional, Gürsoy, Gamze, additional, Epstein, Charles B., additional, Xiong, Kun, additional, Xu, Jinrui, additional, Li, Tianxiao, additional, Liu, Jason, additional, Yu, Keyang, additional, Berthel, Ana, additional, Chen, Zhanlin, additional, Navarro, Fabio, additional, Sun, Maxwell S., additional, Wright, James, additional, Chang, Justin, additional, Cameron, Christopher J.F., additional, Shoresh, Noam, additional, Gaskell, Elizabeth, additional, Drenkow, Jorg, additional, Adrian, Jessika, additional, Aganezov, Sergey, additional, Aguet, François, additional, Balderrama-Gutierrez, Gabriela, additional, Banskota, Samridhi, additional, Corona, Guillermo Barreto, additional, Chee, Sora, additional, Chhetri, Surya B., additional, Cortez Martins, Gabriel Conte, additional, Danyko, Cassidy, additional, Davis, Carrie A., additional, Farid, Daniel, additional, Farrell, Nina P., additional, Gabdank, Idan, additional, Gofin, Yoel, additional, Gorkin, David U., additional, Gu, Mengting, additional, Hecht, Vivian, additional, Hitz, Benjamin C., additional, Issner, Robbyn, additional, Jiang, Yunzhe, additional, Kirsche, Melanie, additional, Kong, Xiangmeng, additional, Lam, Bonita R., additional, Li, Shantao, additional, Li, Bian, additional, Li, Xiqi, additional, Lin, Khine Zin, additional, Luo, Ruibang, additional, Mackiewicz, Mark, additional, Meng, Ran, additional, Moore, Jill E., additional, Mudge, Jonathan, additional, Nelson, Nicholas, additional, Nusbaum, Chad, additional, Popov, Ioann, additional, Pratt, Henry E., additional, Qiu, Yunjiang, additional, Ramakrishnan, Srividya, additional, Raymond, Joe, additional, Salichos, Leonidas, additional, Scavelli, Alexandra, additional, Schreiber, Jacob M., additional, Sedlazeck, Fritz J., additional, See, Lei Hoon, additional, Sherman, Rachel M., additional, Shi, Xu, additional, Shi, Minyi, additional, Sloan, Cricket Alicia, additional, Strattan, J Seth, additional, Tan, Zhen, additional, Tanaka, Forrest Y., additional, Vlasova, Anna, additional, Wang, Jun, additional, Werner, Jonathan, additional, Williams, Brian, additional, Xu, Min, additional, Yan, Chengfei, additional, Yu, Lu, additional, Zaleski, Christopher, additional, Zhang, Jing, additional, Ardlie, Kristin, additional, Cherry, J Michael, additional, Mendenhall, Eric M., additional, Noble, William S., additional, Weng, Zhiping, additional, Levine, Morgan E., additional, Dobin, Alexander, additional, Wold, Barbara, additional, Mortazavi, Ali, additional, Ren, Bing, additional, Gillis, Jesse, additional, Myers, Richard M., additional, Snyder, Michael P., additional, Choudhary, Jyoti, additional, Milosavljevic, Aleksandar, additional, Schatz, Michael C., additional, Bernstein, Bradley E., additional, Guigó, Roderic, additional, Gingeras, Thomas R., additional, and Gerstein, Mark, additional

Published

2023

28. Author Correction: Expanded encyclopaedias of DNA elements in the human and mouse genomes

Author

ENCODE Project Consortium, Moore, Jill E, Purcaro, Michael J, Pratt, Henry E, Epstein, Charles B, Shoresh, Noam, Adrian, Jessika, Kawli, Trupti, Davis, Carrie A, Dobin, Alexander, Kaul, Rajinder, Halow, Jessica, Van Nostrand, Eric L, Freese, Peter, Gorkin, David U, Shen, Yin, He, Yupeng, Mackiewicz, Mark, Pauli-Behn, Florencia, Williams, Brian A, Mortazavi, Ali, Keller, Cheryl A, Zhang, Xiao-Ou, Elhajjajy, Shaimae I, Huey, Jack, Dickel, Diane E, Snetkova, Valentina, Wei, Xintao, Wang, Xiaofeng, Rivera-Mulia, Juan Carlos, Rozowsky, Joel, Zhang, Jing, Chhetri, Surya B, Zhang, Jialing, Victorsen, Alec, White, Kevin P, Visel, Axel, Yeo, Gene W, Burge, Christopher B, Lécuyer, Eric, Gilbert, David M, Dekker, Job, Rinn, John, Mendenhall, Eric M, Ecker, Joseph R, Kellis, Manolis, Klein, Robert J, Noble, William S, Kundaje, Anshul, Guigó, Roderic, Farnham, Peggy J, Cherry, J Michael, Myers, Richard M, Ren, Bing, Graveley, Brenton R, Gerstein, Mark B, Pennacchio, Len A, Snyder, Michael P, Bernstein, Bradley E, Wold, Barbara, Hardison, Ross C, Gingeras, Thomas R, Stamatoyannopoulos, John A, and Weng, Zhiping

Subjects

ENCODE Project Consortium, General Science & Technology

Abstract

In the version of this article initially published, two members of the ENCODE Project Consortium were missing from the author list. Rizi Ai (Department of Chemistry and Biochemistry, University of California, San Diego, La Jolla, CA, USA) and Shantao Li (Program in Computational Biology and Bioinformatics, Yale University, New Haven, CT, USA) are now included in the author list. These errors have been corrected in the online version of the article.

Published

2022

29. Rapid changes in chromatin structure during dedifferentiation of primary hepatocytes in vitro

Author

Seirup, Morten, primary, Sengupta, Srikumar, additional, Swanson, Scott, additional, McIntosh, Brian E., additional, Collins, Mike, additional, Chu, Li-Fang, additional, Cheng, Zhang, additional, Gorkin, David U., additional, Duffin, Bret, additional, Bolin, Jennifer M., additional, Argus, Cara, additional, Stewart, Ron, additional, and Thomson, James A., additional

Published

2022

30. Integrative analysis of the 3D genome and epigenome in mouse embryonic tissues

Author

Yu, Miao, primary, Zemke, Nathan R., additional, Chen, Ziyin, additional, Juric, Ivan, additional, Hu, Rong, additional, Raviram, Ramya, additional, Abnousi, Armen, additional, Fang, Rongxin, additional, Zhang, Yanxiao, additional, Gorkin, David U., additional, Li, Yang, additional, Zhao, Yuan, additional, Lee, Lindsay, additional, Schmitt, Anthony D., additional, Qiu, Yunjiang, additional, Dickel, Diane E., additional, Visel, Axel, additional, Pennacchio, Len A., additional, Hu, Ming, additional, and Ren, Bing, additional

Published

2022

31. Interpreting type 1 diabetes risk with genetics and single-cell epigenomics

Author

Chiou, Joshua, primary, Geusz, Ryan J, additional, Okino, Mei-Lin, additional, Han, Jee Yun, additional, Miller, Michael, additional, Melton, Rebecca, additional, Beebe, Elisha, additional, Benaglio, Paola, additional, Huang, Serina, additional, Korgaonkar, Katha, additional, Heller, Sandra, additional, Kleger, Alexander, additional, Preissl, Sebastian, additional, Gorkin, David U, additional, Sander, Maike, additional, and Gaulton, Kyle J, additional

Published

2021

32. Genomic analysis reveals distinct mechanisms and functional classes of SOX10-regulated genes in melanocytes

Author

Fufa, Temesgen D., Harris, Melissa L., Watkins-Chow, Dawn E., Levy, Denise, Gorkin, David U., Gildea, Derek E., Song, Lingyun, Safi, Alexias, Crawford, Gregory E., Sviderskaya, Elena V., Bennett, Dorothy C., Mccallion, Andrew S., Loftus, Stacie K., and Pavan, William J.

Published

2015

33. Additional file 2 of Coding and noncoding variants in EBF3 are involved in HADDS and simplex autism

Author

Padhi, Evin M., Hayeck, Tristan J., Cheng, Zhang, Chatterjee, Sumantra, Mannion, Brandon J., Byrska-Bishop, Marta, Willems, Marjolaine, Pinson, Lucile, Redon, Sylvia, Benech, Caroline, Uguen, Kevin, Audebert-Bellanger, Séverine, Le Marechal, Cédric, Férec, Claude, Efthymiou, Stephanie, Rahman, Fatima, Maqbool, Shazia, Maroofian, Reza, Houlden, Henry, Musunuri, Rajeeva, Narzisi, Giuseppe, Abhyankar, Avinash, Hunter, Riana D., Akiyama, Jennifer, Fries, Lauren E., Ng, Jeffrey K., Mehinovic, Elvisa, Stong, Nick, Allen, Andrew S., Dickel, Diane E., Bernier, Raphael A., Gorkin, David U., Pennacchio, Len A., Zody, Michael C., and Turner, Tychele N.

Abstract

Additional file 2: Fig S1. Polygenic risk scores (PRS) for the three individuals with hs737 mutations. Fig. S2. Zoom in on the hs737 enhancer with annotations from other datasets. The enhancer is in a PsychEncode fetal enhancer, contains central nervous system DNaseI hypersensitive sites, contains conserved transcription factor binding sites, and is highly conserved across the vertebrate lineage. Also shown are the locations of the hs737 de novo mutations identified in individuals with autism. Fig S3. String-db network analysis, predicts interactions between EBF3 and SPAST, CSNK2A1, HNRNPU, CHD7, KDM6A, KDM6B. Table S2. fitDNM results for de novo mutations in VISTA enhancers driving brain expression. Table S3. Other de novo SNVs/indels seen in individuals with hs737 enhancer mutations. Table S4. Other copy number variation in individuals with hs737 de novo mutations. Table S5. Statistical significance calculations for the luciferase assays. Table S6. Expression of transcription factors potentially binding at variant locations in the hs737 enhancers.

Published

2021

34. Expanded encyclopaedias of DNA elements in the human and mouse genomes

Author

Moore, Jill E., Purcaro, Michael J., Pratt, Henry E., Epstein, Charles B., Shoresh, Noam, Adrian, Jessika, Kawli, Trupti, Davis, Carrie A., Dobin, Alexander, Kaul, Rajinder, Halow, Jessica, Van Nostrand, Eric L., Freese, Peter Dale, Gorkin, David U., Shen, Yin, He, Yupeng, Mackiewicz, Mark, Pauli-Behn, Florencia, Williams, Brian A., Mortazavi, Ali, Keller, Cheryl A., Zhang, Xiao-Ou, Elhajjajy, Shaimae I., Huey, Jack, Dickel, Diane E., Snetkova, Valentina, Wei, Xintao, Wang, Xiaofeng, Rivera-Mulia, Juan Carlos, Rozowsky, Joel, Zhang, Jing, Chhetri, Surya B., Zhang, Jialing, Victorsen, Alec, White, Kevin P., Visel, Axel, Yeo, Gene W., Burge, Christopher B, Lécuyer, Eric, Gilbert, David M., Dekker, Job, Rinn, John, Mendenhall, Eric M., Ecker, Joseph R., Kellis, Manolis, Klein, Robert J., Noble, William S., Kundaje, Anshul, Guigó, Roderic, Farnham, Peggy J., Cherry, J. Michael, Myers, Richard M., Ren, Bing, Graveley, Brenton R., Gerstein, Mark B., Pennacchio, Len A., Snyder, Michael P., Bernstein, Bradley E., Wold, Barbara, Hardison, Ross C., Gingeras, Thomas R., Stamatoyannopoulos, John A., Weng, Zhiping, Moore, Jill E., Purcaro, Michael J., Pratt, Henry E., Epstein, Charles B., Shoresh, Noam, Adrian, Jessika, Kawli, Trupti, Davis, Carrie A., Dobin, Alexander, Kaul, Rajinder, Halow, Jessica, Van Nostrand, Eric L., Freese, Peter Dale, Gorkin, David U., Shen, Yin, He, Yupeng, Mackiewicz, Mark, Pauli-Behn, Florencia, Williams, Brian A., Mortazavi, Ali, Keller, Cheryl A., Zhang, Xiao-Ou, Elhajjajy, Shaimae I., Huey, Jack, Dickel, Diane E., Snetkova, Valentina, Wei, Xintao, Wang, Xiaofeng, Rivera-Mulia, Juan Carlos, Rozowsky, Joel, Zhang, Jing, Chhetri, Surya B., Zhang, Jialing, Victorsen, Alec, White, Kevin P., Visel, Axel, Yeo, Gene W., Burge, Christopher B, Lécuyer, Eric, Gilbert, David M., Dekker, Job, Rinn, John, Mendenhall, Eric M., Ecker, Joseph R., Kellis, Manolis, Klein, Robert J., Noble, William S., Kundaje, Anshul, Guigó, Roderic, Farnham, Peggy J., Cherry, J. Michael, Myers, Richard M., Ren, Bing, Graveley, Brenton R., Gerstein, Mark B., Pennacchio, Len A., Snyder, Michael P., Bernstein, Bradley E., Wold, Barbara, Hardison, Ross C., Gingeras, Thomas R., Stamatoyannopoulos, John A., and Weng, Zhiping

Abstract

The human and mouse genomes contain instructions that specify RNAs and proteins and govern the timing, magnitude, and cellular context of their production. To better delineate these elements, phase III of the Encyclopedia of DNA Elements (ENCODE) Project has expanded analysis of the cell and tissue repertoires of RNA transcription, chromatin structure and modification, DNA methylation, chromatin looping, and occupancy by transcription factors and RNA-binding proteins. Here we summarize these efforts, which have produced 5,992 new experimental datasets, including systematic determinations across mouse fetal development. All data are available through the ENCODE data portal (https://www.encodeproject.org), including phase II ENCODE1 and Roadmap Epigenomics2 data. We have developed a registry of 926,535 human and 339,815 mouse candidate cis-regulatory elements, covering 7.9 and 3.4% of their respective genomes, by integrating selected datatypes associated with gene regulation, and constructed a web-based server (SCREEN; http://screen.encodeproject.org) to provide flexible, user-defined access to this resource. Collectively, the ENCODE data and registry provide an expansive resource for the scientific community to build a better understanding of the organization and function of the human and mouse genomes., NIH (Grants U01HG007019, U01HG007033, U01HG007036, U01HG007037, U41HG006992, U41HG006993, U41HG006994, U41HG006995, U41HG006996, U41HG006997, U41HG006998, U41HG006999, U41HG007000, U41HG007001, U41HG007002, U41HG007003, U54HG006991, U54HG006997, U54HG006998, U54HG007004, U54HG007005, U54HG007010 and UM1HG009442)

Published

2021

35. GENETICS: Closing the distance on obesity culprits

Author

Gorkin, David U. and Ren, Bing

Published

2014

36. The EN-TEx resource of multi-tissue personal epigenomes & variant-impact models

Author

Rozowsky, Joel, primary, Drenkow, Jorg, additional, Yang, Yucheng T, additional, Gursoy, Gamze, additional, Galeev, Timur, additional, Borsari, Beatrice, additional, Epstein, Charles B, additional, Xiong, Kun, additional, Xu, Jinrui, additional, Gao, Jiahao, additional, Yu, Keyang, additional, Berthel, Ana, additional, Chen, Zhanlin, additional, Navarro, Fabio, additional, Liu, Jason, additional, Sun, Maxwell S, additional, Wright, James, additional, Chang, Justin, additional, Cameron, Christopher JF, additional, Shoresh, Noam, additional, Gaskell, Elizabeth, additional, Adrian, Jessika, additional, Aganezov, Sergey, additional, Aguet, François, additional, Balderrama-Gutierrez, Gabriela, additional, Banskota, Samridhi, additional, Corona, Guillermo Barreto, additional, Chee, Sora, additional, Chhetri, Surya B, additional, Cortez Martins, Gabriel Conte, additional, Danyko, Cassidy, additional, Davis, Carrie A, additional, Farid, Daniel, additional, Farrell, Nina P, additional, Gabdank, Idan, additional, Gofin, Yoel, additional, Gorkin, David U, additional, Gu, Mengting, additional, Hecht, Vivian, additional, Hitz, Benjamin C, additional, Issner, Robbyn, additional, Kirsche, Melanie, additional, Kong, Xiangmeng, additional, Lam, Bonita R, additional, Li, Shantao, additional, Li, Bian, additional, Li, Tianxiao, additional, Li, Xiqi, additional, Lin, Khine Zin, additional, Luo, Ruibang, additional, Mackiewicz, Mark, additional, Moore, Jill E, additional, Mudge, Jonathan, additional, Nelson, Nicholas, additional, Nusbaum, Chad, additional, Popov, Ioann, additional, Pratt, Henry E, additional, Qiu, Yunjiang, additional, Ramakrishnan, Srividya, additional, Raymond, Joe, additional, Salichos, Leonidas, additional, Scavelli, Alexandra, additional, Schreiber, Jacob M, additional, Sedlazeck, Fritz J, additional, See, Lei Hoon, additional, Sherman, Rachel M, additional, Shi, Xu, additional, Shi, Minyi, additional, Sloan, Cricket Alicia, additional, Strattan, J Seth, additional, Tan, Zhen, additional, Tanaka, Forrest Y, additional, Vlasova, Anna, additional, Wang, Jun, additional, Werner, Jonathan, additional, Williams, Brian, additional, Xu, Min, additional, Yan, Chengfei, additional, Yu, Lu, additional, Zaleski, Christopher, additional, Zhang, Jing, additional, Ardlie, Kristin, additional, Cherry, J Michael, additional, Mendenhall, Eric M, additional, Noble, William S, additional, Weng, Zhiping, additional, Levine, Morgan E, additional, Dobin, Alexander, additional, Wold, Barbara, additional, Mortazavi, Ali, additional, Ren, Bing, additional, Gillis, Jesse, additional, Myers, Richard M, additional, Snyder, Michael P, additional, Choudhary, Jyoti, additional, Milosavljevic, Aleksandar, additional, Schatz, Michael C, additional, Guigó, Roderic, additional, Bernstein, Bradley E, additional, Gingeras, Thomas R, additional, and Gerstein, Mark, additional

Published

2021

37. An atlas of dynamic chromatin landscapes in mouse fetal development

Author

Gorkin, David U., Williams, Brian A., Trout, Diane, and Amrhein, Henry

Abstract

The Encyclopedia of DNA Elements (ENCODE) project has established a genomic resource for mammalian development, profiling a diverse panel of mouse tissues at 8 developmental stages from 10.5 days after conception until birth, including transcriptomes, methylomes and chromatin states. Here we systematically examined the state and accessibility of chromatin in the developing mouse fetus. In total we performed 1,128 chromatin immunoprecipitation with sequencing (ChIP–seq) assays for histone modifications and 132 assay for transposase-accessible chromatin using sequencing (ATAC–seq) assays for chromatin accessibility across 72 distinct tissue-stages. We used integrative analysis to develop a unified set of chromatin state annotations, infer the identities of dynamic enhancers and key transcriptional regulators, and characterize the relationship between chromatin state and accessibility during developmental gene regulation. We also leveraged these data to link enhancers to putative target genes and demonstrate tissue-specific enrichments of sequence variants associated with disease in humans. The mouse ENCODE data sets provide a compendium of resources for biomedical researchers and achieve, to our knowledge, the most comprehensive view of chromatin dynamics during mammalian fetal development to date.

Published

2020

38. Additional file 1 of Common DNA sequence variation influences 3-dimensional conformation of the human genome

Author

Gorkin, David U., Yunjiang Qiu, Hu, Ming, Kipper Fletez-Brant, Liu, Tristin, Schmitt, Anthony D., Noor, Amina, Chiou, Joshua, Gaulton, Kyle J., Sebat, Jonathan, Li, Yun, Hansen, Kasper D., and Ren, Bing

Abstract

Additional file 1: Figure S1. Hi-C derived molecular phenotypes measured across 20 LCLs. FigureS2. FIRE measures density of local interactions. Figure S3. Aggregate looping interactions in each sample. Figure S4. 3D chromatin variation among 20 LCLs and H1-derived lineages. Figure S5. Characterization of variable regions of 3D chromatin conformation. Figure S6. Additional characterization of variable regions of 3D chromatin conformation. FigureS7. Coordinated variation between 3D chromatin conformation and multiple molecular phenotypes. Figure S8. Correlations between 3D genome phenotypes and other molecular phenotypes. Figure S9. 3D chromatin QTLs. Figure S10. Influence of 3D chromatin QTLs on epigenomic and disease phenotypes.

Published

2020

39. Large-scale genetic association and single cell accessible chromatin mapping defines cell type-specific mechanisms of type 1 diabetes risk

Author

Chiou, Joshua, primary, Geusz, Ryan J, additional, Okino, Mei-Lin, additional, Han, Jee Yun, additional, Miller, Michael, additional, Benaglio, Paola, additional, Huang, Serina, additional, Korgaonkar, Katha, additional, Heller, Sandra, additional, Kleger, Alexander, additional, Preissl, Sebastian, additional, Gorkin, David U, additional, Sander, Maike, additional, and Gaulton, Kyle J, additional

Published

2021

40. Mapping genetic effects on cell type-specific chromatin accessibility and annotating complex trait variants using single nucleus ATAC-seq

Author

Benaglio, Paola, primary, Newsome, Jacklyn, additional, Han, Jee Yun, additional, Chiou, Joshua, additional, Aylward, Anthony, additional, Corban, Sierra, additional, Okino, Mei-Lin, additional, Kaur, Jaspreet, additional, Gorkin, David U, additional, and Gaulton, Kyle J, additional

Published

2020

41. Rapid changes in chromatin structure during dedifferentiation of primary hepatocytes in vitro

Author

Seirup, Morten, primary, Sengupta, Srikumar, additional, Swanson, Scott, additional, McIntosh, Brian E., additional, Colins, Mike, additional, Chu, Li-Fang, additional, Cheng, Zhang, additional, Gorkin, David U., additional, Duffin, Bret, additional, Bolin, Jennifer M., additional, Argus, Cara, additional, Stewart, Ron, additional, and Thomson, James A., additional

Published

2020

42. De Novo Mutation in an Enhancer of EBF3 in simplex autism

Author

Padhi, Evin M., primary, Hayeck, Tristan J., additional, Mannion, Brandon, additional, Chatterjee, Sumantra, additional, Byrska-Bishop, Marta, additional, Musunuri, Rajeeva, additional, Narzisi, Giuseppe, additional, Abhyankar, Avinash, additional, Cheng, Zhang, additional, Hunter, Riana D., additional, Akiyama, Jennifer, additional, Fries, Lauren E., additional, Ng, Jeffrey, additional, Stong, Nick, additional, Allen, Andrew S., additional, Dickel, Diane E., additional, Bernier, Raphael A., additional, Gorkin, David U., additional, Pennacchio, Len A., additional, Zody, Michael C., additional, and Turner, Tychele N., additional

Published

2020

43. Closing the distance on obesity culprits

Author

Gorkin, David U. and Ren, Bing

Published

2014

44. N6-methyladenine DNA Modification in Glioblastoma

Author

Xie, Qi, Wu, Tao P, Gimple, Ryan C, Li, Zheng, Prager, Briana C, Wu, Qiulian, Yu, Yang, Wang, Pengcheng, Wang, Yinsheng, Gorkin, David U, Zhang, Cheng, Dowiak, Alexis V, Lin, Kaixuan, Zeng, Chun, Sui, Yinghui, Kim, Leo JY, Miller, Tyler E, Jiang, Li, Lee-Poturalski, Christine, Huang, Zhi, Fang, Xiaoguang, Zhai, Kui, Mack, Stephen C, Sander, Maike, Bao, Shideng, Kerstetter-Fogle, Amber E, Sloan, Andrew E, Xiao, Andrew Z, and Rich, Jeremy N

Subjects

Adult, Male, Epigenomics, cancer stem cell, Kaplan-Meier Estimate, Small Interfering, Medical and Health Sciences, H3K9me3, Histones, Mice, AlkB Homolog 1, Rare Diseases, Heterochromatin, Genetics, Animals, Humans, 2.1 Biological and endogenous factors, Aetiology, Child, Histone H2a Dioxygenase, Aged, Cancer, DNA methylation, epigenetics, Brain Neoplasms, Adenine, glioblastoma, Middle Aged, Biological Sciences, Cell Hypoxia, Brain Disorders, Brain Cancer, N(6)-methyladenine, Astrocytes, Neoplastic Stem Cells, RNA, chromatin, RNA Interference, Female, Tumor Suppressor Protein p53, neuro-oncology, brain tumor, Biotechnology, Developmental Biology

Abstract

Genetic drivers of cancer can be dysregulated through epigenetic modifications of DNA. Although the critical role of DNA 5-methylcytosine (5mC) inthe regulation of transcription is recognized, the functions of other non-canonical DNA modifications remain obscure. Here, we report the identification of novel N6-methyladenine (N6-mA) DNA modifications in human tissues and implicate this epigenetic mark in human disease, specifically thehighly malignant brain cancer glioblastoma. Glioblastoma markedly upregulated N6-mA levels, which co-localized with heterochromatic histone modifications, predominantly H3K9me3. N6-mA levels were dynamically regulated by the DNA demethylase ALKBH1, depletion of which led to transcriptional silencing of oncogenic pathways through decreasing chromatin accessibility. Targeting the N6-mA regulator ALKBH1 in patient-derived human glioblastoma models inhibited tumor cell proliferation and extended the survival of tumor-bearing mice, supporting this novel DNA modificationas a potential therapeutic target for glioblastoma. Collectively, our results uncover a novel epigenetic node in cancer through the DNA modification N6-mA.

Published

2018

45. N-methyladenine DNA Modification in Glioblastoma

Author

Xie, Qi, primary, Wu, Tao P., additional, Gimple, Ryan C., additional, Li, Zheng, additional, Prager, Briana C., additional, Wu, Qiulian, additional, Yu, Yang, additional, Wang, Pengcheng, additional, Wang, Yinsheng, additional, Gorkin, David U., additional, Zhang, Cheng, additional, Dowiak, Alexis V., additional, Lin, Kaixuan, additional, Zeng, Chun, additional, Sui, Yinghui, additional, Kim, Leo J.Y., additional, Miller, Tyler E., additional, Jiang, Li, additional, Lee, Christine H., additional, Huang, Zhi, additional, Fang, Xiaoguang, additional, Zhai, Kui, additional, Mack, Stephen C., additional, Sander, Maike, additional, Bao, Shideng, additional, Kerstetter-Fogle, Amber E., additional, Sloan, Andrew E., additional, Xiao, Andrew Z., additional, and Rich, Jeremy N., additional

Published

2018

46. Removing unwanted variation between samples in Hi-C experiments

Author

Fletez-Brant, Kipper, primary, Qiu, Yunjiang, additional, Gorkin, David U, additional, Hu, Ming, additional, and Hansen, Kasper D, additional

Published

2017

47. Systematic mapping of chromatin state landscapes during mouse development

Author

Gorkin, David U., primary, Barozzi, Iros, additional, Zhang, Yanxiao, additional, Lee, Ah Young, additional, Li, Bin, additional, Zhao, Yuan, additional, Wildberg, Andre, additional, Ding, Bo, additional, Zhang, Bo, additional, Wang, Mengchi, additional, Strattan, J. Seth, additional, Davidson, Jean M., additional, Qiu, Yunjiang, additional, Afzal, Veena, additional, Akiyama, Jennifer A., additional, Plajzer-Frick, Ingrid, additional, Pickle, Catherine S., additional, Kato, Momoe, additional, Garvin, Tyler H., additional, Pham, Quan T., additional, Harrington, Anne N., additional, Mannion, Brandon J., additional, Lee, Elizabeth A., additional, Fukuda-Yuzawa, Yoko, additional, He, Yupeng, additional, Preissl, Sebastian, additional, Chee, Sora, additional, Williams, Brian A., additional, Trout, Diane, additional, Amrhein, Henry, additional, Yang, Hongbo, additional, Cherry, J. Michael, additional, Shen, Yin, additional, Ecker, Joseph R., additional, Wang, Wei, additional, Dickel, Diane E., additional, Visel, Axel, additional, Pennacchio, Len A., additional, and Ren, Bing, additional

Published

2017

48. Spatiotemporal DNA Methylome Dynamics of the Developing Mammalian Fetus

Author

He, Yupeng, primary, Hariharan, Manoj, additional, Gorkin, David U., additional, Dickel, Diane E., additional, Luo, Chongyuan, additional, Castanon, Rosa G., additional, Nery, Joseph R., additional, Lee, Ah Young, additional, Williams, Brian A., additional, Trout, Diane, additional, Amrhein, Henry, additional, Fang, Rongxin, additional, Chen, Huaming, additional, Li, Bin, additional, Visel, Axel, additional, Pennacchio, Len A., additional, Ren, Bing, additional, and Ecker, Joseph R., additional

Published

2017

49. Single nucleus analysis of the chromatin landscape in mouse forebrain development

Author

Preissl, Sebastian, primary, Fang, Rongxin, additional, Zhao, Yuan, additional, Raviram, Ramya, additional, Zhang, Yanxiao, additional, Sos, Brandon C., additional, Huang, Hui, additional, Gorkin, David U., additional, Afzal, Veena, additional, Dickel, Diane E., additional, Kuan, Samantha, additional, Visel, Axel, additional, Pennacchio, Len A., additional, Zhang, Kun, additional, and Ren, Bing, additional

Published

2017

50. A method to predict the impact of regulatory variants from DNA sequence

Author

Lee, Dongwon, primary, Gorkin, David U, additional, Baker, Maggie, additional, Strober, Benjamin J, additional, Asoni, Alessandro L, additional, McCallion, Andrew S, additional, and Beer, Michael A, additional

Published

2015