Your search keyword '"Philine Guckelberger"' showing total 7 results

1. Mapping the convergence of genes for coronary artery disease onto endothelial cell programs

Author

Gavin R. Schnitzler, Helen Kang, Vivian S. Lee-Kim, X. Rosa Ma, Tony Zeng, Ramcharan S. Angom, Shi Fang, Shamsudheen Karuthedath Vellarikkal, Ronghao Zhou, Katherine Guo, Oscar Sias-Garcia, Alex Bloemendal, Glen Munson, Philine Guckelberger, Tung H. Nguyen, Drew T. Bergman, Nathan Cheng, Brian Cleary, Krishna Aragam, Debabrata Mukhopadhyay, Eric S. Lander, Hilary K. Finucane, Rajat M. Gupta, and Jesse M. Engreitz

Abstract

Genome-wide association studies (GWAS) have discovered thousands of risk loci for common, complex diseases, each of which could point to genes and gene programs that influence disease. For some diseases, it has been observed that GWAS signals converge on a smaller number of biological programs, and that this convergence can help to identify causal genes1–6. However, identifying such convergence remains challenging: each GWAS locus can have many candidate genes, each gene might act in one or more possible programs, and it remains unclear which programs might influence disease risk. Here, we developed a new approach to address this challenge, by creating unbiased maps to link disease variants to genes to programs (V2G2P) in a given cell type. We applied this approach to study the role of endothelial cells in the genetics of coronary artery disease (CAD). To link variants to genes, we constructed enhancer-gene maps using the Activity-by-Contact model7,8. To link genes to programs, we applied CRISPRi-Perturb-seq9–12to knock down all expressed genes within ±500 Kb of 306 CAD GWAS signals13,14and identify their effects on gene expression programs using single-cell RNA-sequencing. By combining these variant-to-gene and gene-to-program maps, we find that 43 of 306 CAD GWAS signals converge onto 5 gene programs linked to the cerebral cavernous malformations (CCM) pathway—which is known to coordinate transcriptional responses in endothelial cells15, but has not been previously linked to CAD risk. The strongest regulator of these programs isTLNRD1, which we show is a new CAD gene and novel regulator of the CCM pathway.TLNRD1loss-of-function alters actin organization and barrier function in endothelial cellsin vitro, and heart development in zebrafishin vivo. Together, our study identifies convergence of CAD risk loci into prioritized gene programs in endothelial cells, nominates new genes of potential therapeutic relevance for CAD, and demonstrates a generalizable strategy to connect disease variants to functions.

Published

2022

2. HyPR-seq: Single-cell quantification of chosen RNAs via hybridization and sequencing of DNA probes

Author

Drew T. Bergman, Philine Guckelberger, Eric S. Lander, Jesse M. Engreitz, Qingbo Wang, Vidya Subramanian, Anna Greka, Linlin M. Chen, Benjamin R. Doughty, Joseph Nasser, Sarah Mangiameli, Jamie L. Marshall, Teia Noel, K. Zhang, Fei Chen, Charles P. Fulco, Elizabeth J. Grinkevich, and Samuel G. Rodriques

Subjects

Time Factors, THP-1 Cells, Gene Expression, Genomics, Computational biology, Biology, Kidney, Polyadenylation, Mice, 03 medical and health sciences, 0302 clinical medicine, Gene expression, Animals, Humans, RNA, Messenger, Gene, 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Multidisciplinary, Hybridization probe, Intron, High-Throughput Nucleotide Sequencing, Nucleic Acid Hybridization, RNA, Biological Sciences, Amplicon, Introns, CRISPR-Cas Systems, Single-Cell Analysis, DNA Probes, K562 Cells, 030217 neurology & neurosurgery

Abstract

Single-cell quantification of RNAs is important for understanding cellular heterogeneity and gene regulation, yet current approaches suffer from low sensitivity for individual transcripts, limiting their utility for many applications. Here we present Hybridization of Probes to RNA for sequencing (HyPR-seq), a method to sensitively quantify the expression of hundreds of chosen genes in single cells. HyPR-seq involves hybridizing DNA probes to RNA, distributing cells into nanoliter droplets, amplifying the probes with PCR, and sequencing the amplicons to quantify the expression of chosen genes. HyPR-seq achieves high sensitivity for individual transcripts, detects nonpolyadenylated and low-abundance transcripts, and can profile more than 100,000 single cells. We demonstrate how HyPR-seq can profile the effects of CRISPR perturbations in pooled screens, detect time-resolved changes in gene expression via measurements of gene introns, and detect rare transcripts and quantify cell-type frequencies in tissue using low-abundance marker genes. By directing sequencing power to genes of interest and sensitively quantifying individual transcripts, HyPR-seq reduces costs by up to 100-fold compared to whole-transcriptome single-cell RNA-sequencing, making HyPR-seq a powerful method for targeted RNA profiling in single cells.

Published

2020

3. Genome-wide enhancer maps link risk variants to disease genes

Author

Tejal A. Patwardhan, Fritz Lekschas, Jesse M. Engreitz, Alkes L. Price, Hanspeter Pfister, Mark J. Daly, Glen Munson, Michael Kane, Jacob C. Ulirsch, Helen Y. Kang, Nir Hacohen, Ramnik J. Xavier, Anshul Kundaje, Heini M. Natri, Elle M. Weeks, Tung T. Nguyen, Drew T. Bergman, Benjamin R. Doughty, Thouis R. Jones, Eric S. Lander, Joseph Nasser, Kristy Mualim, Thomas Eisenhaure, Ryan L. Collins, Philine Guckelberger, Kushal K. Dey, John P. Ray, Ang Cui, Hilary K. Finucane, Charles P. Fulco, Hailiang Huang, Charles B. Epstein, and Institute for Molecular Medicine Finland

Subjects

Male, Genomics, Genome-wide association study, Computational biology, Biology, Genome, Article, Cell Line, 03 medical and health sciences, Cyclophilins, 0302 clinical medicine, CRISPR, Humans, Genetic Predisposition to Disease, Enhancer, Gene, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Translational bioinformatics, Chromosomes, Human, Pair 10, Genome, Human, Macrophages, 1184 Genetics, developmental biology, physiology, Genetic Variation, Dendritic Cells, Inflammatory Bowel Diseases, Human genetics, Mitochondria, Enhancer Elements, Genetic, Phenotype, Organ Specificity, Female, 3111 Biomedicine, 030217 neurology & neurosurgery, Genome-Wide Association Study

Abstract

Genome-wide association studies (GWAS) have identified thousands of noncoding loci that are associated with human diseases and complex traits, each of which could reveal insights into the mechanisms of disease1. Many of the underlying causal variants may affect enhancers2,3, but we lack accurate maps of enhancers and their target genes to interpret such variants. We recently developed the activity-by-contact (ABC) model to predict which enhancers regulate which genes and validated the model using CRISPR perturbations in several cell types4. Here we apply this ABC model to create enhancer–gene maps in 131 human cell types and tissues, and use these maps to interpret the functions of GWAS variants. Across 72 diseases and complex traits, ABC links 5,036 GWAS signals to 2,249 unique genes, including a class of 577 genes that appear to influence multiple phenotypes through variants in enhancers that act in different cell types. In inflammatory bowel disease (IBD), causal variants are enriched in predicted enhancers by more than 20-fold in particular cell types such as dendritic cells, and ABC achieves higher precision than other regulatory methods at connecting noncoding variants to target genes. These variant-to-function maps reveal an enhancer that contains an IBD risk variant and that regulates the expression of PPIF to alter the membrane potential of mitochondria in macrophages. Our study reveals principles of genome regulation, identifies genes that affect IBD and provides a resource and generalizable strategy to connect risk variants of common diseases to their molecular and cellular functions. Mapping enhancer regulation across human cell types and tissues illuminates genome function and provides a resource to connect risk variants for common diseases to their molecular and cellular functions.

Published

2021

4. Genome-wide maps of enhancer regulation connect risk variants to disease genes

Author

Tejal A. Patwardhan, Tom M. Eisenhaure, Benjamin R. Doughty, Jacob C. Ulirsch, Thouis R. Jones, Tung T. Nguyen, Michael Kane, Kushal K. Dey, Helen Y. Kang, Philine Guckelberger, Mark J. Daly, Elle M. Weeks, Joseph Nasser, Drew T. Bergman, Anshul Kundaje, Jesse M. Engreitz, Ang Cui, Hilary K. Finucane, Alkes L. Price, Glen Munson, John P. Ray, Nir Hacohen, Kristy Mualim, Eric S. Lander, Heini M. Natri, Charles B. Epstein, Ramnik J. Xavier, Charles P. Fulco, Hailiang Huang, and Ryan L. Collins

Subjects

PPIF, CRISPR, Genome-wide association study, Computational biology, Biology, Enhancer, Genome, Gene, Phenotype, Genetic association

Abstract

Genome-wide association studies have now identified tens of thousands of noncoding loci associated with human diseases and complex traits, each of which could reveal insights into biological mechanisms of disease. Many of the underlying causal variants are thought to affect enhancers, but we have lacked genome-wide maps of enhancer-gene regulation to interpret such variants. We previously developed the Activity-by-Contact (ABC) Model to predict enhancer-gene connections and demonstrated that it can accurately predict the results of CRISPR perturbations across several cell types. Here, we apply this ABC Model to create enhancer-gene maps in 131 cell types and tissues, and use these maps to interpret the functions of fine-mapped GWAS variants. For inflammatory bowel disease (IBD), causal variants are >20-fold enriched in enhancers in particular cell types, and ABC outperforms other regulatory methods at connecting noncoding variants to target genes. Across 72 diseases and complex traits, ABC links 5,036 GWAS signals to 2,249 unique genes, including a class of 577 genes that appear to influence multiple phenotypes via variants in enhancers that act in different cell types. Guided by these variant-to-function maps, we show that an enhancer containing an IBD risk variant regulates the expression ofPPIFto tune mitochondrial membrane potential. Together, our study reveals insights into principles of genome regulation, illuminates mechanisms that influence IBD, and demonstrates a generalizable strategy to connect common disease risk variants to their molecular and cellular functions.

Published

2020

5. HyPR-seq: Single-cell quantification of chosen RNAs via hybridization and sequencing of DNA probes

Author

Joseph Nasser, Linlin M. Chen, Qingbo Wang, Benjamin R. Doughty, Jamie L. Marshall, Samuel G. Rodriques, Teia Noel, Sarah Mangiameli, Jesse M. Engreitz, Eric S. Lander, Anna Greka, Vidya Subramanian, Fei Chen, Philine Guckelberger, Elizabeth J. Grinkevich, Charles P. Fulco, and K. Zhang

Subjects

Regulation of gene expression, Hybridization probe, genetic processes, Gene expression, Intron, RNA, CRISPR, natural sciences, Computational biology, Biology, Amplicon, Gene

Abstract

Single-cell quantification of RNAs is important for understanding cellular heterogeneity and gene regulation, yet current approaches suffer from low sensitivity for individual transcripts, limiting their utility for many applications. Here we present Hybridization of Probes to RNA for sequencing (HyPR-seq), a method to sensitively quantify the expression of up to 100 chosen genes in single cells. HyPR-seq involves hybridizing DNA probes to RNA, distributing cells into nanoliter droplets, amplifying the probes with PCR, and sequencing the amplicons to quantify the expression of chosen genes. HyPR-seq achieves high sensitivity for individual transcripts, detects nonpolyadenylated and low-abundance transcripts, and can profile more than 100,000 single cells. We demonstrate how HyPR-seq can profile the effects of CRISPR perturbations in pooled screens, detect time-resolved changes in gene expression via measurements of gene introns, and detect rare transcripts and quantify cell type frequencies in tissue using low-abundance marker genes. By directing sequencing power to genes of interest and sensitively quantifying individual transcripts, HyPR-seq reduces costs by up to 100-fold compared to whole-transcriptome scRNA-seq, making HyPR-seq a powerful method for targeted RNA profiling in single cells.

Published

2020

6. Preformed chromatin topology assists transcriptional robustness of Shh during limb development

Author

Guillaume Andrey, Verena Heinrich, Martin Vingron, Carlo Annunziatella, Christina Paliou, Lars Wittler, Norbert Brieske, Ivana Jerković, Johannes Helmuth, Andrea M. Chiariello, Robert Schöpflin, Stefan A. Haas, Stefan Mundlos, Mario Nicodemi, Bernd Timmermann, Andrea Esposito, Philine Guckelberger, Simona Bianco, Paliou, C., Guckelberger, P., Schopflin, R., Heinrich, V., Esposito, A., Chiariello, A. M., Bianco, S., Annunziatella, C., Helmuth, J., Haas, S., Jerkovic, I., Brieske, N., Wittler, L., Timmermann, B., Nicodemi, M., Vingron, M., Mundlos, S., and Andrey, G.

Subjects

CCCTC-Binding Factor, Transcription, Genetic, statistical physic, Chromosomal Proteins, Non-Histone, Polymer modelling, Down-Regulation, Cell Cycle Proteins, Development, Limb, Mice, 03 medical and health sciences, 0302 clinical medicine, Genetic, Transcription (biology), Gene expression, Animals, Limb development, Hedgehog Proteins, Promoter Regions, Genetic, Enhancer, Loss function, 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Binding Sites, Multidisciplinary, Chemistry, Membrane Proteins, Extremities, Promoter, respiratory system, Chromatin, 3D genome, Cell biology, Gene regulation, Enhancer Elements, Genetic, PNAS Plus, 030217 neurology & neurosurgery

Abstract

Long-range gene regulation involves physical proximity between enhancers and promoters to generate precise patterns of gene expression in space and time. However, in some cases, proximity coincides with gene activation, whereas, in others, preformed topologies already exist before activation. In this study, we investigate the preformed configuration underlying the regulation of the Shh gene by its unique limb enhancer, the ZRS , in vivo during mouse development. Abrogating the constitutive transcription covering the ZRS region led to a shift within the Shh–ZRS contacts and a moderate reduction in Shh transcription. Deletion of the CTCF binding sites around the ZRS resulted in the loss of the Shh–ZRS preformed interaction and a 50% decrease in Shh expression but no phenotype, suggesting an additional, CTCF-independent mechanism of promoter–enhancer communication. This residual activity, however, was diminished by combining the loss of CTCF binding with a hypomorphic ZRS allele, resulting in severe Shh loss of function and digit agenesis. Our results indicate that the preformed chromatin structure of the Shh locus is sustained by multiple components and acts to reinforce enhancer–promoter communication for robust transcription.

Published

2019

7. Dynamic 3D chromatin architecture contributes to enhancer specificity and limb morphogenesis

Author

Carlo Annunziatella, Verena Heinrich, Guillaume Andrey, Robert Schöpflin, Martin Franke, Christina Paliou, Katerina Kraft, Philine Guckelberger, Michael Pechstein, Bjørt K Kragesteen, Andrea M. Chiariello, Lars Wittler, Malte Spielmann, Bernd Timmermann, Stefan Mundlos, Andrea Esposito, Axel Visel, Ivana Jerković, Darío G. Lupiáñez, Martin Vingron, Simona Bianco, Mario Nicodemi, Wing Lee Chan, Izabela Harabula, Kragesteen, B. K., Spielmann, M., Paliou, C., Riedel, FRANK HEINRICH, Schoepflin, R., Esposito, Andrea, Annunziatella, Carlo, Bianco, Simona, Chiariello, ANDREA MARIA, Jerkovic, I., Harabula, I., Guckelberger, P., Pechstein, M., Wittler, L., Chan, W. -L., Franke, M., Lupianez, D. G., Kraft, K., Timmermann, B., Vingron, M., Visel, A., Nicodemi, Mario, Mundlos, S., and Andrey, G.

Subjects

0301 basic medicine, animal structures, Enhancer Elements, Regulator, Molecular Conformation, Mice, Transgenic, Biology, Medical and Health Sciences, Transgenic, Article, 03 medical and health sciences, Mice, Genetic, Forelimb, Genetics, Morphogenesis, Animals, Paired Box Transcription Factors, Developmental, computer simulations, Enhancer, Gene, Transcription factor, Regulation of gene expression, Mammalian, Gene Expression Regulation, Developmental, Promoter, DNA, Biological Sciences, Chromatin Assembly and Disassembly, Embryo, Mammalian, Chromatin, Cell biology, Hindlimb, 030104 developmental biology, Enhancer Elements, Genetic, Gene Expression Regulation, Embryo, Nucleic Acid Conformation, Polymer physic, CRISPR-Cas Systems, Limb morphogenesis, Developmental Biology

Abstract

The regulatory specificity of enhancers and their interaction with gene promoters is thought to be controlled by their sequence and the binding of transcription factors. By studying Pitx1, a regulator of hindlimb development, we show that dynamic changes in chromatin conformation can restrict the activity of enhancers. Inconsistent with its hindlimb-restricted expression, Pitx1 is controlled by an enhancer (Pen) that shows activity in forelimbs and hindlimbs. By Capture Hi-C and three-dimensional modeling of the locus, we demonstrate that forelimbs and hindlimbs have fundamentally different chromatin configurations, whereby Pen and Pitx1 interact in hindlimbs and are physically separated in forelimbs. Structural variants can convert the inactive into the active conformation, thereby inducing Pitx1 misexpression in forelimbs, causing partial arm-to-leg transformation in mice and humans. Thus, tissue-specific three-dimensional chromatin conformation can contribute to enhancer activity and specificity in vivo and its disturbance can result in gene misexpression and disease.

Published

2018