Your search keyword '"André L. Martins"' showing total 9 results

1. Identification of active transcriptional regulatory elements from GRO-seq data

Author

Adam Siepel, Charles G. Danko, Vivian G. Cheung, W. Lee Kraus, André L. Martins, Colin T. Waters, John T. Lis, Hyung Won Lee, Stephanie L. Hyland, and Leighton J. Core

Subjects

Genetics, Regulation of gene expression, biology, Genomics, Cell Biology, Quantitative trait locus, Biochemistry, Histone, Transcription (biology), Gene expression, Expression quantitative trait loci, biology.protein, Molecular Biology, Transcription factor, Biotechnology

Abstract

Modifications to the global run-on and sequencing (GRO-seq) protocol that enrich for 5'-capped RNAs can be used to reveal active transcriptional regulatory elements (TREs) with high accuracy. Here, we introduce discriminative regulatory-element detection from GRO-seq (dREG), a sensitive machine learning method that uses support vector regression to identify active TREs from GRO-seq data without requiring cap-based enrichment (https://github.com/Danko-Lab/dREG/). This approach allows TREs to be assayed together with gene expression levels and other transcriptional features in a single experiment. Predicted TREs are more enriched for several marks of transcriptional activation—including expression quantitative trait loci, disease-associated polymorphisms, acetylated histone 3 lysine 27 (H3K27ac) and transcription factor binding—than those identified by alternative functional assays. Using dREG, we surveyed TREs in eight human cell types and provide new insights into global patterns of TRE function.

Published

2015

2. Universal correction of enzymatic sequence bias reveals molecular signatures of protein/DNA interactions

Author

Chongzhi Zang, Ninad M. Walavalkar, Warren D. Anderson, Michael J. Guertin, and André L. Martins

Subjects

0301 basic medicine, Sequence analysis, genetic processes, Genomics, Computational biology, Biology, Genome, DNA sequencing, 03 medical and health sciences, chemistry.chemical_compound, Bias, RNA polymerase, Genetics, natural sciences, Transcription factor, Sequence (medicine), Deoxyribonucleases, Computational Biology, High-Throughput Nucleotide Sequencing, Reproducibility of Results, DNA, DNA-Directed RNA Polymerases, 030104 developmental biology, chemistry, Nucleic acid, Methods Online, Identification (biology), Algorithms, Protein Binding, Transcription Factors

Abstract

Coupling molecular biology to high throughput sequencing has revolutionized the study of biology. Molecular genomics techniques are continually refined to provide higher resolution mapping of nucleic acid interactions and structure. Sequence preferences of enzymes can interfere with the accurate interpretation of these data. We developed seqOutBias to characterize enzymatic sequence bias from experimental data and scale individual sequence reads to correct intrinsic enzymatic sequence biases. SeqOutBias efficiently corrects DNase-seq, TACh-seq, ATAC-seq, MNase-seq, and PRO-seq data. We show that seqOutBias correction facilitates identification of true molecular signatures resulting from transcription factors and RNA polymerase interacting with DNA.

Published

2017

3. Analysis of nascent RNA identifies a unified architecture of initiation regions at mammalian promoters and enhancers

Author

Leighton J. Core, Adam Siepel, John T. Lis, André L. Martins, Colin T. Waters, and Charles G. Danko

Subjects

Transcription, Genetic, RNA Splicing, RNA polymerase II, Enhancer RNAs, Computational biology, Regulatory Sequences, Nucleic Acid, Insulator (genetics), Histones, Genetics, Humans, Nucleosome, Promoter Regions, Genetic, Enhancer, Transcription factor, B-Lymphocytes, Binding Sites, Models, Genetic, biology, Promoter, Chromatin, Markov Chains, Nucleosomes, Enhancer Elements, Genetic, TAF2, biology.protein, RNA, Transcription Initiation Site, K562 Cells

Abstract

Despite the conventional distinction between them, promoters and enhancers share many features in mammals, including divergent transcription and similar modes of transcription factor binding. Here we examine the architecture of transcription initiation through comprehensive mapping of transcription start sites (TSSs) in human lymphoblastoid B cell (GM12878) and chronic myelogenous leukemic (K562) ENCODE Tier 1 cell lines. Using a nuclear run-on protocol called GRO-cap, which captures TSSs for both stable and unstable transcripts, we conduct detailed comparisons of thousands of promoters and enhancers in human cells. These analyses identify a common architecture of initiation, including tightly spaced (110 bp apart) divergent initiation, similar frequencies of core promoter sequence elements, highly positioned flanking nucleosomes and two modes of transcription factor binding. Post-initiation transcript stability provides a more fundamental distinction between promoters and enhancers than patterns of histone modification and association of transcription factors or co-activators. These results support a unified model of transcription initiation at promoters and enhancers.

Published

2014

4. Natural Selection has Shaped Coding and Non-coding Transcription in Primate CD4+ T-cells

Author

Wojno Edt, John T. Lis, Adam Siepel, Tinyi Chu, W. Lee Kraus, Noah Dukler, Brooke A. Marks, Lauren A. Choate, Edward J. Rice, André L. Martins, Charles G. Danko, Scott A. Coonrod, and Zhong Wang

Subjects

Genetics, 0303 health sciences, General transcription factor, Response element, E-box, Promoter, Enhancer RNAs, Biology, DNA binding site, 03 medical and health sciences, 0302 clinical medicine, Sp3 transcription factor, Enhancer, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Transcriptional regulatory changes have been shown to contribute to phenotypic differences between species, but many questions remain about how gene expression evolves. Here we report the first comparative study of nascent transcription in primates. We used PRO-seq to map actively transcribing RNA polymerases in resting and activated CD4+ T-cells in multiple human, chimpanzee, and rhesus macaque individuals, with rodents as outgroups. This approach allowed us to measure transcription separately from post-transcriptional processes. We observed general conservation in coding and non-coding transcription, punctuated by numerous differences between species, particularly at distal enhancers and non-coding RNAs. We found evidence that transcription factor binding sites are a primary determinant of transcriptional differences between species, that stabilizing selection maintains gene expression levels despite frequent changes at distal enhancers, and that adaptive substitutions have driven lineage-specific transcription. Finally, we found strong correlations between evolutionary rates and long-range chromatin interactions. These observations clarify the role of primary transcription in regulatory evolution.

Published

2016

5. A Unified Model Describing The Architecture And Creation Of Promoters And Enhancers

Author

Fabiana M. Duarte, Gregory T. Booth, Leighton J. Core, John T. Lis, Charles G. Danko, Dig Bijay Mahat, Adam Siepel, and André L. Martins

Subjects

Computer science, Genetics, Promoter, Unified Model, Computational biology, Architecture, Enhancer, Molecular Biology, Biochemistry, Biotechnology

Published

2015

6. GAGA Factor Maintains Nucleosome-Free Regions and Has a Role in RNA Polymerase II Recruitment to Promoters

Author

Sumeet Sharma, John T. Lis, André L. Martins, Nicholas J. Fuda, Adam Siepel, Charles G. Danko, and Michael J. Guertin

Subjects

Cancer Research, lcsh:QH426-470, Transcription, Genetic, RNA polymerase II, behavioral disciplines and activities, chemistry.chemical_compound, Transcription (biology), RNA polymerase, mental disorders, Genetics, Transcriptional regulation, Nucleosome, Animals, Drosophila Proteins, Eye Proteins, Promoter Regions, Genetic, Molecular Biology, Transcription factor, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Polymerase, Binding Sites, biology, Promoter, Nucleosomes, DNA-Binding Proteins, lcsh:Genetics, Drosophila melanogaster, chemistry, Gene Knockdown Techniques, biology.protein, RNA Polymerase II, Research Article, Transcription Factors

Abstract

Previous studies have shown that GAGA Factor (GAF) is enriched on promoters with paused RNA Polymerase II (Pol II), but its genome-wide function and mechanism of action remain largely uncharacterized. We assayed the levels of transcriptionally-engaged polymerase using global run-on sequencing (GRO-seq) in control and GAF-RNAi Drosophila S2 cells and found promoter-proximal polymerase was significantly reduced on a large subset of paused promoters where GAF occupancy was reduced by knock down. These promoters show a dramatic increase in nucleosome occupancy upon GAF depletion. These results, in conjunction with previous studies showing that GAF directly interacts with nucleosome remodelers, strongly support a model where GAF directs nucleosome displacement at the promoter and thereby allows the entry Pol II to the promoter and pause sites. This action of GAF on nucleosomes is at least partially independent of paused Pol II because intergenic GAF binding sites with little or no Pol II also show GAF-dependent nucleosome displacement. In addition, the insulator factor BEAF, the BEAF-interacting protein Chriz, and the transcription factor M1BP are strikingly enriched on those GAF-associated genes where pausing is unaffected by knock down, suggesting insulators or the alternative promoter-associated factor M1BP protect a subset of GAF-bound paused genes from GAF knock-down effects. Thus, GAF binding at promoters can lead to the local displacement of nucleosomes, but this activity can be restricted or compensated for when insulator protein or M1BP complexes also reside at GAF bound promoters., Author Summary Transcriptional regulation is critical for proper gene expression in response to environmental changes and developmental programs. Eukaryotes have evolved multiple mechanisms by which transcription factors regulate transcription. One mechanism is the reorganization of chromatin to allow Pol II recruitment. Another is the release of promoter-proximal paused Pol II, where Pol II transcription that is halted 20–60 bases downstream of the transcription start site (TSS) is allowed to enter into productive elongation through the gene body. The Drosophila transcription factor GAF binds to genes that undergo pausing and interacts with nucleosome remodelers and the pausing factor NELF. Thus, GAF can regulate multiple points necessary for transcription, but its mechanistic role is not fully understood genome-wide. We depleted GAF from cells and examined the genome-wide changes in Pol II and nucleosome distributions across genes. We found that GAF depletion reduces polymerase density at genes where GAF binds just upstream of the TSS, and results in nucleosomes moving into the promoter region. Our results show that GAF is important for maintaining the promoter accessibility, allowing Pol II to be recruited to promoters and enter the pause sites downstream of the TSS. Thus, GAF is critical for providing the chromatin environment necessary for the proper control of gene expression.

Published

2015

7. Accurate Identification of Active Transcriptional Regulatory Elements from Global Run-On and Sequencing Data

Author

Hyung Won Lee, Leighton J. Core, W. Lee Kraus, Adam Siepel, Vivian G. Cheung, Colin T. Waters, André L. Martins, Charles G. Danko, Stephanie L. Hyland, and John T. Lis

Subjects

DNA binding site, Genetics, Transcriptional Regulatory Elements, Transcription (biology), Run-on, Single-nucleotide polymorphism, Genomics, Promoter, Computational biology, Biology, Enhancer

Abstract

Identification of the genomic regions that regulate transcription remains an important open problem. We have recently shown that global run-on and sequencing (GRO-seq) with enrichment for 5′-capped RNAs reveals patterns of divergent transcription that accurately mark active transcriptional regulatory elements (TREs), including enhancers and promoters. Here, we demonstrate that active TREs can be identified with comparable accuracy by applying sensitive machine-learning methods to standard GRO-seq and PRO-seq data, allowing TREs to be assayed together with transcription levels, elongation rates, and other transcriptional features, in a single experiment. Our method, called discriminative Regulatory Element detection from GRO-seq (dREG), summarizes GRO-seq read counts at multiple scales and uses support vector regression to predict active TREs. The predicted TREs are strongly enriched for marks associated with functional elements, including H3K27ac, transcription factor binding sites, eQTLs, and GWAS-associated SNPs. Using dREG, we survey TREs in eight cell types and provide new insights into global patterns of TRE assembly and function.

Published

2014

8. GAGA factor maintains nucleosome-free regions and has a role in RNA polymerase II recruitment to promoters.

Author

Nicholas J Fuda, Michael J Guertin, Sumeet Sharma, Charles G Danko, André L Martins, Adam Siepel, and John T Lis

Subjects

Genetics, QH426-470

Abstract

Previous studies have shown that GAGA Factor (GAF) is enriched on promoters with paused RNA Polymerase II (Pol II), but its genome-wide function and mechanism of action remain largely uncharacterized. We assayed the levels of transcriptionally-engaged polymerase using global run-on sequencing (GRO-seq) in control and GAF-RNAi Drosophila S2 cells and found promoter-proximal polymerase was significantly reduced on a large subset of paused promoters where GAF occupancy was reduced by knock down. These promoters show a dramatic increase in nucleosome occupancy upon GAF depletion. These results, in conjunction with previous studies showing that GAF directly interacts with nucleosome remodelers, strongly support a model where GAF directs nucleosome displacement at the promoter and thereby allows the entry Pol II to the promoter and pause sites. This action of GAF on nucleosomes is at least partially independent of paused Pol II because intergenic GAF binding sites with little or no Pol II also show GAF-dependent nucleosome displacement. In addition, the insulator factor BEAF, the BEAF-interacting protein Chriz, and the transcription factor M1BP are strikingly enriched on those GAF-associated genes where pausing is unaffected by knock down, suggesting insulators or the alternative promoter-associated factor M1BP protect a subset of GAF-bound paused genes from GAF knock-down effects. Thus, GAF binding at promoters can lead to the local displacement of nucleosomes, but this activity can be restricted or compensated for when insulator protein or M1BP complexes also reside at GAF bound promoters.

Published

2015

9. Accurate prediction of inducible transcription factor binding intensities in vivo.

Author

Michael J Guertin, André L Martins, Adam Siepel, and John T Lis

Subjects

Genetics, QH426-470

Abstract

DNA sequence and local chromatin landscape act jointly to determine transcription factor (TF) binding intensity profiles. To disentangle these influences, we developed an experimental approach, called protein/DNA binding followed by high-throughput sequencing (PB-seq), that allows the binding energy landscape to be characterized genome-wide in the absence of chromatin. We applied our methods to the Drosophila Heat Shock Factor (HSF), which inducibly binds a target DNA sequence element (HSE) following heat shock stress. PB-seq involves incubating sheared naked genomic DNA with recombinant HSF, partitioning the HSF-bound and HSF-free DNA, and then detecting HSF-bound DNA by high-throughput sequencing. We compared PB-seq binding profiles with ones observed in vivo by ChIP-seq and developed statistical models to predict the observed departures from idealized binding patterns based on covariates describing the local chromatin environment. We found that DNase I hypersensitivity and tetra-acetylation of H4 were the most influential covariates in predicting changes in HSF binding affinity. We also investigated the extent to which DNA accessibility, as measured by digital DNase I footprinting data, could be predicted from MNase-seq data and the ChIP-chip profiles for many histone modifications and TFs, and found GAGA element associated factor (GAF), tetra-acetylation of H4, and H4K16 acetylation to be the most predictive covariates. Lastly, we generated an unbiased model of HSF binding sequences, which revealed distinct biophysical properties of the HSF/HSE interaction and a previously unrecognized substructure within the HSE. These findings provide new insights into the interplay between the genomic sequence and the chromatin landscape in determining transcription factor binding intensity.

Published

2012