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Your search keyword '"Hodges, Emily"' showing total 13 results
Start Over Author "Hodges, Emily" Publisher cold spring harbor laboratory press
13 results on '"Hodges, Emily"'

1. A single Hox locus in Drosophila produces functional microRNAs from opposite DNA strands

Author

Bushati, Natascha, Stark, Alexander, Kheradpour, Pouya, Jan, Calvin H., Brennecke, Julius, Hodges, Emily, Cohen, Stephen M., Bartel, David P., and Kellis, Manolis

Subjects
Drosophila -- Research, Drosophila -- Genetic aspects, RNA -- Synthesis, RNA -- Research, Biological sciences
Abstract

The production of two distinct functional microRNAs from opposite DNA strands by a single Hox locus in Drosophila is discussed.

Published
2008

3. Conservation of small RNA pathways in platypus

Author

Murchison, Elizabeth P., Kheradpour, Pouya, Sachidanandam, Ravi, Smith, Carly, Hodges, Emily, Zhenyu Xuan, Kellis, Manolis, Grutzner, Frank, Stark, Alexander, and Hannon, Gregory J.

Subjects
RNA -- Research, Platypus -- Genetic aspects, Nucleotide sequence -- Analysis, Health
Abstract

The investigation of the small RNA pathways of monotremes by deep sequencing of six platypus and echidna tissues is described. It is observed that the highly conserved microRNA species exhibit their signature tissue-specific expression patterns and also large quickly evolving cluster of microRNAs on platypus chromosomes XI, which is distinct to monotremes are seen.

Published
2008

4. Systematic discovery and characterization of fly microRNAs using 12 Drosophila genomes

Author

Stark, Alexander, Kheradpour, Pouya, Parts, Leopold, Brennecke, Julius, Hodges, Emily, Hannon, Gregory J., and Kellis, Manolis

Subjects
Drosophila -- Genetic aspects, Gene expression -- Research, RNA -- Research, Health
Abstract

The results from studies of 12 Drosophila genomes, which provide insight into structural and evolutionary signatures of microRNA regulation and development, are presented.

Published
2007

5. Two waves of de novo methylation during mouse germ cell development.

Author

Molaro, Antoine, Falciatori, Ilaria, Hodges, Emily, Aravin, Alexei A., Marran, Krista, Rafii, Shahin, McCombie, W. Richard, Smith, Andrew D., and Hannon, Gregory J.

Subjects
*DNA methylation, *GERM cells, *METHYLATION, *RETROTRANSPOSONS, *GENETIC transcription
Abstract

During development, mammalian germ cells reprogram their epigenomes via a genome-wide erasure and de novo rewriting of DNA methylation marks. We know little of how methylation patterns are specifically determined. The piRNA pathway is thought to target the bulk of retrotransposon methylation. Here we show that most retrotransposon sequences are modified by default de novo methylation. However, potentially active retrotransposon copies evade this initial wave, likely mimicking features of protein-coding genes. These elements remain transcriptionally active and become targets of piRNA-mediated methylation. Thus, we posit that these two waves play essential roles in resetting germ cell epigenomes at each generation. [ABSTRACT FROM AUTHOR]

Published
2014
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6. Exome sequencing and disease-network analysis of a single family implicate a mutation in KIF1A in hereditary spastic paraparesis.

Author

Erlich, Yaniv, Edvardson, Simon, Hodges, Emily, Zenvirt, Shamir, Thekkat, Pramod, Shaag, Avraham, Dor, Talya, Hannon, Gregory J., and Elpeleg, Orly

Subjects
*NUCLEOTIDE sequence, *NUCLEIC acid analysis, *PARAPARESIS, *GENETIC mutation, *BIOLOGICAL variation
Abstract

Whole exome sequencing has become a pivotal methodology for rapid and cost-effective detection of pathogenic variations in Mendelian disorders. A major challenge of this approach is determining the causative mutation from a substantial number of bystander variations that do not play any role in the disease etiology. Current strategies to analyze variations have mainly relied on genetic and functional arguments such as mode of inheritance, conservation, and loss of function prediction. Here, we demonstrate that disease-network analysis provides an additional layer of information to stratify variations even in the presence of incomplete sequencing coverage, a known limitation of exome sequencing. We studied a case of Hereditary Spastic Paraparesis (HSP) in a single inbred Palestinian family. HSP is a group of neuropathological disorders that are characterized by abnormal gait and spasticity of the lower limbs. Forty-five loci have been associated with HSP and lesions in 20 genes have been documented to induce the disorder. We used whole exome sequencing and homozygosity mapping to create a list of possible candidates. After exhausting the genetic and functional arguments, we stratified the remaining candidates according to their similarity to the previously known disease genes. Our analysis implicated the causative mutation in the motor domain of KIF1A, a gene that has not yet associated with HSP, which functions in anterograde axonal transportation. Our strategy can be useful for a large class of disorders that are characterized by locus heterogeneity, particularly when studying disorders in single families. [ABSTRACT FROM AUTHOR]

Published
2011
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7. De novo DNA demethylation and noncoding transcription define active intergenic regulatory elements.

Author

Schlesinger, Felix, Smith, Andrew D., Gingeras, Thomas R., Hannon, Gregory J., and Hodges, Emily

Subjects
*DNA demethylation, *NON-coding DNA, *GENOMES, *GENE expression, *CHROMATIN
Abstract

Deep sequencing of mammalian DNA methylomes has uncovered a previously unpredicted number of discrete hypomethylated regions in intergenic space (iHMRs). Here, we combined whole-genome bisulfite sequencing data with extensive gene expression and chromatin-state data to define functional classes of iHMRs, and to reconstruct the dynamics of their establishment in a developmental setting. Comparing HMR profiles in embryonic stem and primary blood cells, we show that iHMRs mark an exclusive subset of active DNase hypersensitive sites (DHS), and that both developmentally constitutive and cell-type-specific iHMRs display chromatin states typical of distinct regulatory elements. We also observe that iHMR changes are more predictive of nearby gene activity than the promoter HMR itself, and that expression of noncoding RNAs within the iHMR accompanies full activation and complete demethylation of mature B cell enhancers. Conserved sequence features corresponding to iHMR transcript start sites, including a discernible TATA motif, suggest a conserved, functional role for transcription in these regions. Similarly, we explored both primate-specific and human population variation at iHMRs, finding that while enhancer iHMRs are more variable in sequence and methylation status than any other functional class, conservation of the TATA box is highly predictive of iHMR maintenance, reflecting the impact of sequence plasticity and transcriptional signals on iHMR establishment. Overall, our analysis allowed us to construct a three-step timeline in which (1) intergenic DHS are pre-established in the stem cell, (2) partial demethylation of blood-specific intergenic DHSs occurs in blood progenitors, and (3) complete iHMR formation and transcription coincide with enhancer activation in lymphoid-specified cells. [ABSTRACT FROM AUTHOR]

Published
2013
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8. A single Hox locus in Drosophila produces functional microRNAs from opposite DNA strands.

Author

Stark, Alexander, Bushati, Natascha, Jan, Calvin H., Kheradpour, Pouya, Hodges, Emily, Brennecke, Julius, Bartel, David P., Cohen, Stephen M., and Kellis, Manolis

Subjects
*DROSOPHILA, *RNA, *DNA, *GENES, *GENETIC transformation
Abstract

MicroRNAs (miRNAs) are 22-nucleotide RNAs that are processed from characteristic precursor hairpins and pair to sites in messages of protein-coding genes to direct post-transcriptional repression. Here, we report that the miRNA iab-4 locus in the Drosophila Hox cluster is transcribed convergently from both DNA strands, giving rise to two distinct functional miRNAs. Both sense and antisense miRNA products target neighboring Hox genes via highly conserved sites, leading to homeotic transformations when ectopically expressed. We also report sense/antisense miRNAs in mouse and find antisense transcripts close to many miRNAs in both flies and mammals, suggesting that additional sense/antisense pairs exist. [ABSTRACT FROM AUTHOR]

Published
2008
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9. ATAC-STARR-seq reveals transcription factor-bound activators and silencers within chromatin-accessible regions of the human genome.

Author

Hansen TJ and Hodges E

Subjects
Humans, Chromatin Immunoprecipitation Sequencing methods, Transposases metabolism, Transposases genetics, High-Throughput Nucleotide Sequencing, Sequence Analysis, DNA methods, Binding Sites, Silencer Elements, Transcriptional, Genome, Human, Chromatin metabolism, Chromatin genetics, Transcription Factors metabolism, Transcription Factors genetics
Abstract

Massively parallel reporter assays (MPRAs) test the capacity of putative gene regulatory elements to drive transcription on a genome-wide scale. Most gene regulatory activity occurs within accessible chromatin, and recently described methods have combined assays that capture these regions-such as assay for transposase-accessible chromatin using sequencing (ATAC-seq)-with self-transcribing active regulatory region sequencing (STARR-seq) to selectively assay the regulatory potential of accessible DNA (ATAC-STARR-seq). Here, we report an integrated approach that quantifies activating and silencing regulatory activity, chromatin accessibility, and transcription factor (TF) occupancy with one assay using ATAC-STARR-seq. Our strategy, including important updates to the ATAC-STARR-seq assay and workflow, enabled high-resolution testing of ∼50 million unique DNA fragments tiling ∼101,000 accessible chromatin regions in human lymphoblastoid cells. We discovered that 30% of all accessible regions contain an activator, a silencer, or both. Although few MPRA studies have explored silencing activity, we demonstrate that silencers occur at similar frequencies to activators, and they represent a distinct functional group enriched for unique TF motifs and repressive histone modifications. We further show that Tn5 cut-site frequencies are retained in the ATAC-STARR plasmid library compared to standard ATAC-seq, enabling TF occupancy to be ascertained from ATAC-STARR data. With this approach, we found that activators and silencers cluster by distinct TF footprint combinations, and these groups of activity represent different gene regulatory networks of immune cell function. Altogether, these data highlight the multilayered capabilities of ATAC-STARR-seq to comprehensively investigate the regulatory landscape of the human genome all from a single DNA fragment source., (© 2022 Hansen and Hodges; Published by Cold Spring Harbor Laboratory Press.)

Published
2022
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10. Sequencing in High Definition Drives a Changing Worldview of the Epigenome.

Author

Hodges E

Subjects
Chromatin chemistry, Genome-Wide Association Study, Humans, DNA Methylation, Epigenesis, Genetic, Genome, Human, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, DNA methods
Abstract

Single-molecule sequencing approaches have transformed the study of the human epigenome, accelerating efforts to describe genome function beyond the sequences that encode proteins. The post-genome era has ignited strong interest in the noncoding genome and profiling epigenetic signatures genome-wide have been critical for the identification and characterization of noncoding gene-regulatory sequences in various cellular and developmental contexts. These technologies enable quantification of epigenetic marks through digital assessment of DNA fragments. With the capacity to probe both the DNA sequence and count DNA molecules at once with unparalleled throughput and sensitivity, deep sequencing has been especially transformative to the study of DNA methylation. This review will discuss advances in epigenome profiling with a particular focus on DNA methylation, highlighting how deep sequencing has generated new insights into the role of DNA methylation in gene regulation. Technical aspects of profiling DNA methylation, remaining challenges, and the future of DNA methylation sequencing are also described., (Copyright © 2019 Cold Spring Harbor Laboratory Press; all rights reserved.)

Published
2019
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11. Molecular regulation of peripheral B cells and their progeny in immunity.

Author

Boothby MR, Hodges E, and Thomas JW

Subjects
Animals, DNA Methylation, Genetic Variation, Humans, B-Lymphocytes cytology, B-Lymphocytes immunology, Cell Differentiation genetics, Cell Differentiation immunology, Gene Expression Regulation immunology
Abstract

Mature B lymphocytes are crucial components of adaptive immunity, a system essential for the evolutionary fitness of mammals. Adaptive lymphocyte function requires an initially naïve cell to proliferate extensively and its progeny to have the capacity to assume a variety of fates. These include either terminal differentiation (the long-lived plasma cell) or metastable transcriptional reprogramming (germinal center and memory B cells). In this review, we focus principally on the regulation of differentiation and functional diversification of the "B2" subset. An overview is combined with an account of more recent advances, including initial work on mechanisms that eliminate DNA methylation and potential links between intracellular metabolites and chromatin editing., (© 2019 Boothby et al.; Published by Cold Spring Harbor Laboratory Press.)

Published
2019
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13. Evolutionary expansion of DNA hypomethylation in the mammalian germline genome.

Author

Qu J, Hodges E, Molaro A, Gagneux P, Dean MD, Hannon GJ, and Smith AD

Subjects
Animals, CpG Islands genetics, Germ Cells, Gorilla gorilla genetics, Humans, Macaca mulatta genetics, Mammals, Mice, Pan troglodytes genetics, DNA Methylation genetics, Epigenesis, Genetic, Evolution, Molecular, Genome genetics
Abstract

DNA methylation in the germline is among the most important factors influencing the evolution of mammalian genomes. Yet little is known about its evolutionary rate or the fraction of the methylome that has undergone change. We compared whole-genome, single-CpG DNA methylation profiles in sperm of seven species-human, chimpanzee, gorilla, rhesus macaque, mouse, rat, and dog-to investigate epigenomic evolution. We developed a phylo-epigenetic model for DNA methylation that accommodates the correlation of states at neighboring sites and allows for inference of ancestral states. Applying this model to the sperm methylomes, we uncovered an overall evolutionary expansion of the hypomethylated fraction of the genome, driven both by the birth of new hypomethylated regions and by extensive widening of hypomethylated intervals in ancestral species. This expansion shows strong lineage-specific aspects, most notably that hypomethylated intervals around transcription start sites have evolved to be considerably wider in primates and dog than in rodents, whereas rodents show evidence of a greater trend toward birth of new hypomethylated regions. Lineage-specific hypomethylated regions are enriched near sets of genes with common developmental functions and significant overlap across lineages. Rodent-specific and primate-specific hypomethylated regions are enriched for binding sites of similar transcription factors, suggesting that the plasticity accommodated by certain regulatory factors is conserved, despite substantial change in the specific sites of regulation. Overall our results reveal substantial global epigenomic change in mammalian sperm methylomes and point to a divergence in trans -epigenetic mechanisms that govern the organization of epigenetic states at gene promoters., (© 2018 Qu et al.; Published by Cold Spring Harbor Laboratory Press.)

Published
2018
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