Your search keyword '"Rieke Kempfer"' showing total 7 results

1. GAMIBHEAR: whole-genome haplotype reconstruction from Genome Architecture Mapping data

Author

Rieke Kempfer, Julia Markowski, Roland F. Schwarz, Ibai Irastorza-Azcarate, Alexander Kukalev, Ana Pombo, Sven Rahmann, Gesa Loof, Birte Kehr, and Ponty, Yann (Herausgeber*in)

Subjects

0303 health sciences, Cancer Research, AcademicSubjects/SCI01060, Computer science, Software maintainer, 0206 medical engineering, Haplotype, Medizin, Statistical model, 02 engineering and technology, Computational biology, Original Papers, Genome, Chromatin, Data mapping, Chromosome conformation capture, 03 medical and health sciences, Cardiovascular and Metabolic Diseases, Allele, Sequence Analysis, 020602 bioinformatics, 030304 developmental biology

Abstract

MotivationGenome Architecture Mapping (GAM) was recently introduced as a digestion- and ligation-free method to detect chromatin conformation. Orthogonal to existing approaches based on chromatin conformation capture (3C), GAM’s ability to capture both inter- and intra-chromosomal contacts from low amounts of input data makes it particularly well suited for allele-specific analyses in a clinical setting. Allele-specific analyses are powerful tools to investigate the effects of genetic variants on many cellular phenotypes including chromatin conformation, but require the haplotypes of the individuals under study to be known a-priori. So far however, no algorithm exists for haplotype reconstruction and phasing of genetic variants from GAM data, hindering the allele-specific analysis of chromatin contact points in non-model organisms or individuals with unknown haplotypes.ResultsWe present GAMIBHEAR, a tool for accurate haplotype reconstruction from GAM data. GAMIBHEAR aggregates allelic co-observation frequencies from GAM data and employs a GAM-specific probabilistic model of haplotype capture to optimise phasing accuracy. Using a hybrid mouse embryonic stem cell line with known haplotype structure as a benchmark dataset, we assess correctness and completeness of the reconstructed haplotypes, and demonstrate the power of GAMIBHEAR to infer accurate genome-wide haplotypes from GAM data.AvailabilityGAMIBHEAR is available as an R package under the open source GPL-2 license athttps://bitbucket.org/schwarzlab/gamibhearMaintainer:julia.markowski@mdc-berlin.de

Published

2021

2. Methods for mapping 3D chromosome architecture

Author

Rieke Kempfer and Ana Pombo

Subjects

0303 health sciences, Chromosome, Computational biology, Biology, Genome, Chromatin, Chromosome conformation capture, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, RNA splicing, Genetics, medicine, Nuclear lamina, Molecular Biology, Nucleus, 030217 neurology & neurosurgery, Genetics (clinical), Topology (chemistry), 030304 developmental biology

Abstract

Determining how chromosomes are positioned and folded within the nucleus is critical to understanding the role of chromatin topology in gene regulation. Several methods are available for studying chromosome architecture, each with different strengths and limitations. Established imaging approaches and proximity ligation-based chromosome conformation capture (3C) techniques (such as DNA-FISH and Hi-C, respectively) have revealed the existence of chromosome territories, functional nuclear landmarks (such as splicing speckles and the nuclear lamina) and topologically associating domains. Improvements to these methods and the recent development of ligation-free approaches, including GAM, SPRITE and ChIA-Drop, are now helping to uncover new aspects of 3D genome topology that confirm the nucleus to be a complex, highly organized organelle.

Published

2019

3. Comparison of the Hi-C, GAM and SPRITE methods using polymer models of chromatin

Author

Andrea M. Chiariello, Mattia Conte, Alexander Kukalev, Simona Bianco, Francesco Musella, Rieke Kempfer, Ana Pombo, Andrea Esposito, Luca Fiorillo, Alex Abraham, Mario Nicodemi, Antonella Prisco, Ibai Irastorza-Azcarate, Fiorillo, L., Musella, F., Conte, M., Kempfer, R., Chiariello, A. M., Bianco, S., Kukalev, A., Irastorza-Azcarate, I., Esposito, A., Abraham, A., Prisco, A., Pombo, A., and Nicodemi, M.

Subjects

Sprite (computer graphics), Computer science, In silico, Computational biology, Biochemistry, Genome, 03 medical and health sciences, Mice, Computer Simulation, Inverse power law, Polymer, Molecular Biology, 030304 developmental biology, 0303 health sciences, Animal, Chromosome Mapping, Cell Biology, Replicate, Chromatin, Single Molecule Imaging, Single-Cell Analysi, Models, Chemical, Cardiovascular and Metabolic Diseases, Benchmark (computing), Genome architecture, Biotechnology, Human

Abstract

Hi-C, split-pool recognition of interactions by tag extension (SPRITE) and genome architecture mapping (GAM) are powerful technologies utilized to probe chromatin interactions genome wide, but how faithfully they capture three-dimensional (3D) contacts and how they perform relative to each other is unclear, as no benchmark exists. Here, we compare these methods in silico in a simplified, yet controlled, framework against known 3D structures of polymer models of murine and human loci, which can recapitulate Hi-C, GAM and SPRITE experiments and multiplexed fluorescence in situ hybridization (FISH) single-molecule conformations. We find that in silico Hi-C, GAM and SPRITE bulk data are faithful to the reference 3D structures whereas single-cell data reflect strong variability among single molecules. The minimal number of cells required in replicate experiments to return statistically similar contacts is different across the technologies, being lowest in SPRITE and highest in GAM under the same conditions. Noise-to-signal levels follow an inverse power law with detection efficiency and grow with genomic distance differently among the three methods, being lowest in GAM for genomic separations >1 Mb. This Analysis reports a computational approach to implement Hi-C, SPRITE and GAM, which allows researchers to assess the performances of the three technologies to capture DNA contacts in chromatin three-dimensional models.

Published

2021

4. Multiplex-GAM: genome-wide identification of chromatin contacts yields insights not captured by Hi-C

Author

D.C.A. Kramer, Yingnan Zhang, Markus Schueler, Antonio Scialdone, Rieke Kempfer, Andrea M. Chiariello, Robert A. Beagrie, Christoph J. Thieme, C. Baugher, Lonnie R. Welch, Ana Pombo, Alexander Kukalev, S. Bianco, Yichao Li, Mario Nicodemi, and Carlo Annunziatella

Subjects

Regulation of gene expression, Sequence assembly, Identification (biology), Multiplex, Computational biology, Biology, Genome, Gene, Genome architecture, Chromatin

Abstract

SummaryTechnologies for measuring 3D genome topology are increasingly important for studying mechanisms of gene regulation, for genome assembly and for mapping of genome rearrangements. Hi-C and other ligation-based methods have become routine but have specific biases. Here, we develop multiplex-GAM, a faster and more affordable version of Genome Architecture Mapping (GAM), a ligation-free technique to map chromatin contacts genome-wide. We perform a detailed comparison of contacts obtained by multiplex-GAM and Hi-C using mouse embryonic stem (mES) cells. We find that both methods detect similar topologically associating domains (TADs). However, when examining the strongest contacts detected by either method, we find that only one third of these are shared. The strongest contacts specifically found in GAM often involve “active” regions, including many transcribed genes and super-enhancers, whereas in Hi-C they more often contain “inactive” regions. Our work shows that active genomic regions are involved in extensive complex contacts that currently go under-estimated in genome-wide ligation-based approaches, and highlights the need for orthogonal advances in genome-wide contact mapping technologies.

Published

2020

5. Single-cell-resolved dynamics of chromatin architecture delineate cell and regulatory states in wildtype andcloche/npas4lmutant zebrafish embryos

Author

Ilija Bilic, Wolfgang Kopp, Rieke Kempfer, Scott A. Lacadie, Uwe Ohler, Daniela Panáková, Ana Pombo, David A. Garfield, A.M. Merks, Kenny Mattonet, Jan Philipp Junker, A.C. McGarvey, Didier Y.R. Stainier, Altuna Akalin, Alexandra Trinks, Antje Hirsekorn, and Dubravka Vucicevic

Subjects

chemistry.chemical_compound, Histone, biology, chemistry, Cellular differentiation, Mutant, biology.protein, Genome, Gene, DNA, Cell biology, Chromatin, Genomic organization

Abstract

DNA accessibility of cis regulatory elements (CREs) dictates transcriptional activity and drives cell differentiation during development. While many of the genes that regulate embryonic development have been described, the underlying CRE dynamics controlling their expression remain largely unknown. To address this, we applied single-cell combinatorial indexing ATAC-seq (sci-ATAC-seq) to whole 24 hours post fertilization (hpf) stage zebrafish embryos and developed a new computational tool, ScregSeg, that selects informative genome segments and classifies complex accessibility dynamics. We integrated the ScregSeg output with bulk measurements for histone post-translational modifications and 3D genome organization, expanding knowledge of regulatory principles between chromatin modalities. Sci-ATAC-seq profiling ofnpas4l/clochemutant embryos revealed novel cellular roles for this hemato-vascular transcriptional master regulator and suggests an intricate mechanism regulating its expression. Our work constitutes a valuable resource for future studies in developmental, molecular, and computational biology.

Published

2020

6. Cell-type specialization in the brain is encoded by specific long-range chromatin topologies

Author

Mark A. Ungless, Izabela Harabula, Sarah A. Teichmann, Georg Dechant, Leonid Serebreni, Mandy Meijer, Vedran Franke, Luna Zea Redondo, Warren Winick-Ng, Andreas Abentung, Aleksandra A. Kolodziejczyk, Gonçalo Castelo-Branco, Rieke Kempfer, Christoph J. Thieme, Francesco Musella, Mario Nicodemi, Alexander Kukalev, Simona Bianco, Ana Pombo, Elena Torlai Triglia, Galina Apostolova, Luca Fiorillo, Eleanor J. Paul, Dominik Szabo, Ehsan Irani, Ibai Irastorza Azcarate, Andrea M. Chiariello, and Altuna Akalin

Subjects

Regulation of gene expression, 0303 health sciences, Cell type, Cellular differentiation, Biology, Genome, Oligodendrocyte, Chromatin, Cell biology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, medicine, Compartment (development), Gene, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Neurons and oligodendrocytes are terminally differentiated cells that perform highly specialized functions, which depend on cascades of gene activation and repression to retain homeostatic control over a lifespan. Gene expression is regulated by three-dimensional (3D) genome organisation, from local levels of chromatin compaction to the organisation of topological domains and chromosome compartments. Whereas our understanding of 3D genome architecture has vastly increased in the past decade, it remains difficult to study specialized cells in their native environment without disturbing their activity. To develop the application of Genome Architecture Mapping (GAM) in small numbers of specialized cells in complex tissues, we combined GAM with immunoselection. We applied immunoGAM to map the genome architecture of specific cell populations in the juvenile/adult mouse brain: dopaminergic neurons (DNs) from the midbrain, pyramidal glutamatergic neurons (PGNs) from the hippocampus, and oligodendrocyte lineage cells (OLGs) from the cortex. We integrate 3D genome organisation with single-cell transcriptomics data, and find specific chromatin structures that relate with cell-type specific patterns of gene expression. We discover abundant changes in compartment organisation, especially a strengthening of heterochromatin compartments which establish strong contacts spanning tens of megabases, especially in brain cells. These compartments contain olfactory and taste receptor genes, which are de-repressed in a subpopulation of PGNs with molecular signatures of long-term potentiation (LTP). We also show extensive reorganisation of topological domains where activation of neuronal or oligodendrocyte genes coincides with formation of new TAD borders. Finally, we discover loss of TAD organisation, or ‘TAD melting’, at long (>1Mb) neuronal genes when they are most highly expressed. Our work shows that the 3D organisation of the genome is highly cell-type specific in terminally differentiated cells of the brain, and essential to better understand brain-specific mechanisms of gene regulation.

Published

2020

7. Formation of novel chromatin domains determines pathogenicity of genomic duplications

Author

Orsetta Zuffardi, Rieke Kempfer, Martin Vingron, Wing Lee Chan, Wibke Schwarzer, Stefan Mundlos, Katerina Kraft, Verena Heinrich, Francesco Brancati, Daniel M. Ibrahim, Paola Cambiaso, Gunnar Houge, Robert Schöpflin, Bernd Timmermann, Martin Franke, Ingo Kurth, Lindsay Lambie, Lars Wittler, Ana Pombo, Guillaume Andrey, François Spitz, Malte Spielmann, and Ivana Jerković

Subjects

0301 basic medicine, Foot Deformities, Male, Foot Deformities, Congenital, DNA Copy Number Variations, Gene Expression, Genomics, Biology, DNA/genetics, DNA Copy Number Variations/genetics, Genome, Gene Duplication/genetics, Chromosome conformation capture, Fingers, 03 medical and health sciences, Congenital, Mice, Gene Duplication, Gene duplication, Animals, Disease, Copy-number variation, Gene, ChIA-PET, Genetics, Congenital/genetics, Multidisciplinary, Medicine (all), Chromatin Assembly and Disassembly/genetics, Facies, SOX9 Transcription Factor, DNA, Fibroblasts, Hand Deformities, Chromatin Assembly and Disassembly, Chromatin, SOX9 Transcription Factor/genetics, Fingers/abnormalities, 030104 developmental biology, Phenotype, Disease/genetics, Evolutionary biology, Female, Hand Deformities, Congenital

Abstract

Chromosome conformation capture methods have identified subchromosomal structures of higher-order chromatin interactions called topologically associated domains (TADs) that are separated from each other by boundary regions1, 2. By subdividing the genome into discrete regulatory units, TADs restrict the contacts that enhancers establish with their target genes3, 4, 5. However, the mechanisms that underlie partitioning of the genome into TADs remain poorly understood. Here we show by chromosome conformation capture (capture Hi-C and 4C-seq methods) that genomic duplications in patient cells and genetically modified mice can result in the formation of new chromatin domains (neo-TADs) and that this process determines their molecular pathology. Duplications of non-coding DNA within the mouse Sox9 TAD (intra-TAD) that cause female to male sex reversal in humans6, showed increased contact of the duplicated regions within the TAD, but no change in the overall TAD structure. In contrast, overlapping duplications that extended over the next boundary into the neighbouring TAD (inter-TAD), resulted in the formation of a new chromatin domain (neo-TAD) that was isolated from the rest of the genome. As a consequence of this insulation, inter-TAD duplications had no phenotypic effect. However, incorporation of the next flanking gene, Kcnj2, in the neo-TAD resulted in ectopic contacts of Kcnj2 with the duplicated part of the Sox9 regulatory region, consecutive misexpression of Kcnj2, and a limb malformation phenotype. Our findings provide evidence that TADs are genomic regulatory units with a high degree of internal stability that can be sculptured by structural genomic variations. This process is important for the interpretation of copy number variations, as these variations are routinely detected in diagnostic tests for genetic disease and cancer. This finding also has relevance in an evolutionary setting because copy-number differences are thought to have a crucial role in the evolution of genome complexity.

Published

2016