Your search keyword '"Vierstra, Jeff"' showing total 12 results

1. Discrete regulatory modules instruct hematopoietic lineage commitment and differentiation.

Author

Georgolopoulos, Grigorios, Psatha, Nikoletta, Iwata, Mineo, Nishida, Andrew, Som, Tannishtha, Yiangou, Minas, Stamatoyannopoulos, John A., and Vierstra, Jeff

Subjects

CHROMATIN, TRANSCRIPTION factors, TRANSCRIPTOMES, ERYTHROPOIESIS, GENE expression profiling

Abstract

Lineage commitment and differentiation is driven by the concerted action of master transcriptional regulators at their target chromatin sites. Multiple efforts have characterized the key transcription factors (TFs) that determine the various hematopoietic lineages. However, the temporal interactions between individual TFs and their chromatin targets during differentiation and how these interactions dictate lineage commitment remains poorly understood. Here we perform dense, daily, temporal profiling of chromatin accessibility (DNase I-seq) and gene expression changes (total RNA-seq) along ex vivo human erythropoiesis to comprehensively define developmentally regulated DNase I hypersensitive sites (DHSs) and transcripts. We link both distal DHSs to their target gene promoters and individual TFs to their target DHSs, revealing that the regulatory landscape is organized in distinct sequential regulatory modules that regulate lineage restriction and maturation. Finally, direct comparison of transcriptional dynamics (bulk and single-cell) and lineage potential between erythropoiesis and megakaryopoiesis uncovers differential fate commitment dynamics between the two lineages as they exit the stem and progenitor stage. Collectively, these data provide insights into the temporally regulated synergy of the cis- and the trans-regulatory components underlying hematopoietic lineage commitment and differentiation. Lineage differentiation and commitment is driven by transcription regulators and chromatin changes. Here the authors report daily profiling of chromatin accessibility and transcriptome changes during human erythropoiesis, relating these changes to lineage potential between erythropoiesis and megakaryopoieis. [ABSTRACT FROM AUTHOR]

Published

2021

2. Index and biological spectrum of human DNase I hypersensitive sites.

Author

Meuleman, Wouter, Muratov, Alexander, Rynes, Eric, Halow, Jessica, Lee, Kristen, Bates, Daniel, Diegel, Morgan, Dunn, Douglas, Neri, Fidencio, Teodosiadis, Athanasios, Reynolds, Alex, Haugen, Eric, Nelson, Jemma, Johnson, Audra, Frerker, Mark, Buckley, Michael, Sandstrom, Richard, Vierstra, Jeff, Kaul, Rajinder, and Stamatoyannopoulos, John

Abstract

DNase I hypersensitive sites (DHSs) are generic markers of regulatory DNA1–5 and contain genetic variations associated with diseases and phenotypic traits6–8. We created high-resolution maps of DHSs from 733 human biosamples encompassing 438 cell and tissue types and states, and integrated these to delineate and numerically index approximately 3.6 million DHSs within the human genome sequence, providing a common coordinate system for regulatory DNA. Here we show that these maps highly resolve the cis-regulatory compartment of the human genome, which encodes unexpectedly diverse cell- and tissue-selective regulatory programs at very high density. These programs can be captured comprehensively by a simple vocabulary that enables the assignment to each DHS of a regulatory barcode that encapsulates its tissue manifestations, and global annotation of protein-coding and non-coding RNA genes in a manner orthogonal to gene expression. Finally, we show that sharply resolved DHSs markedly enhance the genetic association and heritability signals of diseases and traits. Rather than being confined to a small number of distal elements or promoters, we find that genetic signals converge on congruently regulated sets of DHSs that decorate entire gene bodies. Together, our results create a universal, extensible coordinate system and vocabulary for human regulatory DNA marked by DHSs, and provide a new global perspective on the architecture of human gene regulation. High-resolution maps of DNase I hypersensitive sites from 733 human biosamples are used to identify and index regulatory DNA within the human genome. [ABSTRACT FROM AUTHOR]

Published

2020

3. Global reference mapping of human transcription factor footprints.

Author

Vierstra, Jeff, Lazar, John, Sandstrom, Richard, Halow, Jessica, Lee, Kristen, Bates, Daniel, Diegel, Morgan, Dunn, Douglas, Neri, Fidencio, Haugen, Eric, Rynes, Eric, Reynolds, Alex, Nelson, Jemma, Johnson, Audra, Frerker, Mark, Buckley, Michael, Kaul, Rajinder, Meuleman, Wouter, and Stamatoyannopoulos, John A.

Abstract

Combinatorial binding of transcription factors to regulatory DNA underpins gene regulation in all organisms. Genetic variation in regulatory regions has been connected with diseases and diverse phenotypic traits1, but it remains challenging to distinguish variants that affect regulatory function2. Genomic DNase I footprinting enables the quantitative, nucleotide-resolution delineation of sites of transcription factor occupancy within native chromatin3–6. However, only a small fraction of such sites have been precisely resolved on the human genome sequence6. Here, to enable comprehensive mapping of transcription factor footprints, we produced high-density DNase I cleavage maps from 243 human cell and tissue types and states and integrated these data to delineate about 4.5 million compact genomic elements that encode transcription factor occupancy at nucleotide resolution. We map the fine-scale structure within about 1.6 million DNase I-hypersensitive sites and show that the overwhelming majority are populated by well-spaced sites of single transcription factor–DNA interaction. Cell-context-dependent cis-regulation is chiefly executed by wholesale modulation of accessibility at regulatory DNA rather than by differential transcription factor occupancy within accessible elements. We also show that the enrichment of genetic variants associated with diseases or phenotypic traits in regulatory regions1,7 is almost entirely attributable to variants within footprints, and that functional variants that affect transcription factor occupancy are nearly evenly partitioned between loss- and gain-of-function alleles. Unexpectedly, we find increased density of human genetic variation within transcription factor footprints, revealing an unappreciated driver of cis-regulatory evolution. Our results provide a framework for both global and nucleotide-precision analyses of gene regulatory mechanisms and functional genetic variation. A high-density DNase I cleavage map from 243 human cell and tissue types provides a genome-wide, nucleotide-resolution map of human transcription factor footprints. [ABSTRACT FROM AUTHOR]

Published

2020

4. eFORGE v2.0: updated analysis of cell type-specific signal in epigenomic data.

Author

Breeze, Charles E, Reynolds, Alex P, Dongen, Jenny van, Dunham, Ian, Lazar, John, Neph, Shane, Vierstra, Jeff, Bourque, Guillaume, Teschendorff, Andrew E, Stamatoyannopoulos, John A, and Beck, Stephan

Subjects

CELL analysis, DNA methylation, GENE enhancers, TRANSCRIPTION factors, DNA analysis, HISTONE methylation

Abstract

Summary The Illumina Infinium EPIC BeadChip is a new high-throughput array for DNA methylation analysis, extending the earlier 450k array by over 400 000 new sites. Previously, a method named eFORGE was developed to provide insights into cell type-specific and cell-composition effects for 450k data. Here, we present a significantly updated and improved version of eFORGE that can analyze both EPIC and 450k array data. New features include analysis of chromatin states, transcription factor motifs and DNase I footprints, providing tools for epigenome-wide association study interpretation and epigenome editing. Availability and implementation eFORGE v2.0 is implemented as a web tool available from https://eforge.altiusinstitute.org and https://eforge-tf.altiusinstitute.org/. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published

2019

5. Methylated Cytosines Mutate to Transcription Factor Binding Sites that Drive Tetrapod Evolution.

Author

Ximiao He, Tillo, Desiree, Vierstra, Jeff, Syed, Khund-Sayeed, Deng, Callie, Ray, G. Jordan, Stamatoyannopoulos, John, FitzGerald, Peter C., and Vinson, Charles

Subjects

TRANSCRIPTION factors, GENOMICS, GENOMES, BIOLOGY, EVOLUTIONARY theories

Abstract

Inmammals, the cytosine inCGdinucleotides is typically methylated producing 5-methylcytosine (5mC), a chemically less stable form of cytosine that can spontaneously deaminate to thymidine resulting in a T•G mismatched base pair. Unlike other eukaryotes that efficiently repair this mismatched base pair back to C•G, in mammals, 5mCG deamination is mutagenic, sometimes producing TG dinucleotides, explaining the depletion of CG dinucleotides in mammalian genomes. It was suggested that new TG dinucleotides generate genetic diversity that may be critical for evolutionary change. We tested this conjecture by examining the DNA sequence properties of regulatory sequences identified by DNase I hypersensitive sites (DHSs) in humanandmouse genomes. We hypothesized that the newTG dinucleotides generate transcription factor binding sites (TFBS) that become tissue-specificDHSs (TS-DHSs).We find that 8-mers containing the CG dinucleotide are enriched in DHSs in both species. However, 8-mers containing a TG and no CG dinucleotide are preferentially enriched in TS-DHSs when compared with 8-mers with neither a TG nor a CG dinucleotide. Themost enriched 8-mer with a TG and no CG dinucleotide in tissue-specific regulatory regions in both genomes is the AP-1 motif (TGA C/G TCAN), and we find evidence that TG dinucleotides in the AP-1 motif arose from CG dinucleotides. Additional TS-DHS-enriched TFBS containing the TG/CA dinucleotide are the E-Box motif (GCAGCTGC), the NF-1 motif (GGCA--TGCC), and the GR (glucocorticoid receptor) motif (G-ACA--TGT-C). Our results support the suggestion that cytosine methylation is mutagenic in tetrapods producing TG dinucleotides that create TFBS that drive evolution. [ABSTRACT FROM AUTHOR]

Published

2015

6. Functional footprinting of regulatory DNA.

Author

Vierstra, Jeff, Reik, Andreas, Chang, Kai-Hsin, Stehling-Sun, Sandra, Zhou, Yuanyue, Hinkley, Sarah J, Paschon, David E, Zhang, Lei, Psatha, Nikoletta, Bendana, Yuri R, O'Neil, Colleen M, Song, Alexander H, Mich, Andrea K, Liu, Pei-Qi, Lee, Gary, Bauer, Daniel E, Holmes, Michael C, Orkin, Stuart H, Papayannopoulou, Thalia, and Stamatoyannopoulos, George

Subjects

TRANSCRIPTION factors, GENOME editing, NUCLEOTIDE sequence, TRANSCRIPTIONAL repressor CTCF, SINGLE nucleotide polymorphisms

Abstract

Regulatory regions harbor multiple transcription factor (TF) recognition sites; however, the contribution of individual sites to regulatory function remains challenging to define. We describe an approach that exploits the error-prone nature of genome editing-induced double-strand break repair to map functional elements within regulatory DNA at nucleotide resolution. We demonstrate the approach on a human erythroid enhancer, revealing single TF recognition sites that gate the majority of downstream regulatory function. [ABSTRACT FROM AUTHOR]

Published

2015

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

Author

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

Subjects

ALLERGIES, SPINAL cord, CENTRAL nervous system, RETINA, GENOMES

Abstract

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

Published

2015

8. Conservation of trans-acting circuitry during mammalian regulatory evolution.

Author

Stergachis, Andrew B., Neph, Shane, Sandstrom, Richard, Haugen, Eric, Reynolds, Alex P., Canfield, Theresa, Stelhing-Sun, Sandra, Lee, Kristen, Thurman, Robert E., Vong, Shinny, Bates, Daniel, Neri, Fidencio, Diegel, Morgan, Giste, Erika, Dunn, Douglas, Vierstra, Jeff, Johnson, Audra K., Sabo, Peter J., Zhang, Miaohua, and Byron, Rachel

Subjects

MAMMAL evolution, HUMAN genome, CIS-trans isomerism, DEOXYRIBONUCLEASE genetics, GENETIC regulation

Abstract

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

Published

2014

9. Coupling transcription factor occupancy to nucleosome architecture with DNase-FLASH.

Author

Vierstra, Jeff, Wang, Hao, John, Sam, Sandstrom, Richard, and Stamatoyannopoulos, John A

Subjects

TRANSCRIPTION factors, CHROMATIN, GENOMICS, DEOXYRIBONUCLEASES, GENETIC regulation, COUPLING reactions (Chemistry)

Abstract

It is currently not possible to resolve the genome-wide relationship of transcription factors (TFs) and nucleosomes at the level of individual chromatin templates despite rapidly increasing data on TF and nucleosome occupancy in the human genome. Here we describe DNase I-released fragment-length analysis of hypersensitivity (DNase-FLASH), an approach that directly couples mapping of TF occupancy, via quantification of DNA microfragments released from individual TF recognition sites in regulatory DNA, to the surrounding nucleosome architecture, via analysis of larger DNA fragments, in a single assay. DNase-FLASH enables coupling of individual TF footprints to nucleosome occupancy, identifying TFs that precisely demarcate the regulatory DNA-nucleosome interface. [ABSTRACT FROM AUTHOR]

Published

2014

10. The accessible chromatin landscape of the human genome.

Author

Thurman, Robert E., Rynes, Eric, Humbert, Richard, Vierstra, Jeff, Maurano, Matthew T., Haugen, Eric, Sheffield, Nathan C., Stergachis, Andrew B., Wang, Hao, Vernot, Benjamin, Garg, Kavita, John, Sam, Sandstrom, Richard, Bates, Daniel, Boatman, Lisa, Canfield, Theresa K., Diegel, Morgan, Dunn, Douglas, Ebersol, Abigail K., and Frum, Tristan

Subjects

CHROMATIN, HUMAN genome, GENETIC markers, GENE enhancers, PROMOTERS (Genetics), HUMAN gene mapping, HUMAN variation (Biology)

Abstract

DNase?I hypersensitive sites (DHSs) are markers of regulatory DNA and have underpinned the discovery of all classes of cis-regulatory elements including enhancers, promoters, insulators, silencers and locus control regions. Here we present the first extensive map of human DHSs identified through genome-wide profiling in 125 diverse cell and tissue types. We identify ?2.9 million DHSs that encompass virtually all known experimentally validated cis-regulatory sequences and expose a vast trove of novel elements, most with highly cell-selective regulation. Annotating these elements using ENCODE data reveals novel relationships between chromatin accessibility, transcription, DNA methylation and regulatory factor occupancy patterns. We connect ?580,000 distal DHSs with their target promoters, revealing systematic pairing of different classes of distal DHSs and specific promoter types. Patterning of chromatin accessibility at many regulatory regions is organized with dozens to hundreds of co-activated elements, and the transcellular DNase?I sensitivity pattern at a given region can predict cell-type-specific functional behaviours. The DHS landscape shows signatures of recent functional evolutionary constraint. However, the DHS compartment in pluripotent and immortalized cells exhibits higher mutation rates than that in highly differentiated cells, exposing an unexpected link between chromatin accessibility, proliferative potential and patterns of human variation. [ABSTRACT FROM AUTHOR]

Published

2012

11. An expansive human regulatory lexicon encoded in transcription factor footprints.

Author

Neph, Shane, Vierstra, Jeff, Stergachis, Andrew B., Reynolds, Alex P., Haugen, Eric, Vernot, Benjamin, Thurman, Robert E., John, Sam, Sandstrom, Richard, Johnson, Audra K., Maurano, Matthew T., Humbert, Richard, Rynes, Eric, Wang, Hao, Vong, Shinny, Lee, Kristen, Bates, Daniel, Diegel, Morgan, Roach, Vaughn, and Dunn, Douglas

Subjects

NUCLEOTIDES, FOOTPRINTS, DNA-binding proteins, CHROMATIN, DNA methylation

Abstract

Regulatory factor binding to genomic DNA protects the underlying sequence from cleavage by DNase I, leaving nucleotide-resolution footprints. Using genomic DNase I footprinting across 41 diverse cell and tissue types, we detected 45 million transcription factor occupancy events within regulatory regions, representing differential binding to 8.4 million distinct short sequence elements. Here we show that this small genomic sequence compartment, roughly twice the size of the exome, encodes an expansive repertoire of conserved recognition sequences for DNA-binding proteins that nearly doubles the size of the human cis-regulatory lexicon. We find that genetic variants affecting allelic chromatin states are concentrated in footprints, and that these elements are preferentially sheltered from DNA methylation. High-resolution DNase I cleavage patterns mirror nucleotide-level evolutionary conservation and track the crystallographic topography of protein-DNA interfaces, indicating that transcription factor structure has been evolutionarily imprinted on the human genome sequence. We identify a stereotyped 50-base-pair footprint that precisely defines the site of transcript origination within thousands of human promoters. Finally, we describe a large collection of novel regulatory factor recognition motifs that are highly conserved in both sequence and function, and exhibit cell-selective occupancy patterns that closely parallel major regulators of development, differentiation and pluripotency. [ABSTRACT FROM AUTHOR]

Published

2012

12. BEDOPS: high-performance genomic feature operations.

Author

Neph, Shane, Kuehn, M. Scott, Reynolds, Alex P., Haugen, Eric, Thurman, Robert E., Johnson, Audra K., Rynes, Eric, Maurano, Matthew T., Vierstra, Jeff, Thomas, Sean, Sandstrom, Richard, Humbert, Richard, and Stamatoyannopoulos, John A.

Subjects

GENOMICS, BIOINFORMATICS, PERFORMANCE evaluation, COMPARATIVE studies, INFORMATION storage & retrieval systems, COMPUTER software, DATA extraction

Abstract

Summary: The large and growing number of genome-wide datasets highlights the need for high-performance feature analysis and data comparison methods, in addition to efficient data storage and retrieval techniques. We introduce BEDOPS, a software suite for common genomic analysis tasks which offers improved flexibility, scalability and execution time characteristics over previously published packages. The suite includes a utility to compress large inputs into a lossless format that can provide greater space savings and faster data extractions than alternatives.Availability: http://code.google.com/p/bedops/ includes binaries, source and documentation.Contact: sjn@u.washington.edu and jstam@u.washington.eduSupplementary information: Supplementary data are available at Bioinformatics online. [ABSTRACT FROM PUBLISHER]

Published

2012