Searching journal content for articles similar to GuhaThakurta et al. 14 (12): 2457.

Displaying results 1-10 of 484
For checked items
  1. Resource: Binding profiles for 961 Drosophila and C. elegans transcription factors reveal tissue-specific regulatory relationships
    • Michelle Kudron,
    • Louis Gevirtzman,
    • Alec Victorsen,
    • Bridget C. Lear,
    • Jiahao Gao,
    • Jinrui Xu,
    • Swapna Samanta,
    • Emily Frink,
    • Adri Tran-Pearson,
    • Chau Huynh,
    • Dionne Vafeados,
    • Ann Hammonds,
    • William Fisher,
    • Martha Wall,
    • Greg Wesseling,
    • Vanessa Hernandez,
    • Zhichun Lin,
    • Mary Kasparian,
    • Kevin White,
    • Ravi Allada,
    • Mark Gerstein,
    • LaDeana Hillier,
    • Susan E. Celniker,
    • Valerie Reinke,
    • and Robert H. Waterston
    Genome Res. December 2024 34: 2319-2334; Published in Advance October 22, 2024, doi:10.1101/gr.279037.124
    ...including ENCODE (Encyclopedia of DNA Elements) for humans and mice (The ENCODE Project Consortium et al. 2020) and modENCODE (model organism Encyclopedia of DNA Elements) and modERN (model organism Encyclopedia of Regulatory Networks) for Caenorhabditis elegans and Drosophila (Celniker et al. 2009...
  2. Research: Cohesin organizes 3D DNA contacts surrounding active enhancers in C. elegans
    • Jun Kim,
    • Haoyu Wang,
    • and Sevinç Ercan
    Genome Res. May 2025 35: 1108-1123; Published in Advance April 10, 2025, doi:10.1101/gr.279365.124
    ...communication between cis-regulatory elements. Many organisms, including S. cerevisiae, C. elegans, and A. thaliana contain cohesin but lack CTCF. Here, we used C. elegans to investigate the function of cohesin in 3D organization in the absence of CTCF. Using Hi-C data, we observe cohesin-dependent features...
  3. Research: Systematic transcriptome analysis associated with physiological and chronological aging in Caenorhabditis elegans
    • Seokjin Ham,
    • Sieun S. Kim,
    • Sangsoon Park,
    • Eun Ji E. Kim,
    • Sujeong Kwon,
    • Hae-Eun H. Park,
    • Yoonji Jung,
    • and Seung-Jae V. Lee
    Genome Res. November/December 2022 32: 2003-2014; Published in Advance November 9, 2022, doi:10.1101/gr.276515.121
    ...chronological and physiological ages at the transcriptomic level has been a challenge because of its complexity. We analyzed the transcriptomic features associated with physiological and chronological aging using Caenorhabditis elegans as a model. Many structural and functional transcript elements...
  4. Research: Developmental transcriptomics in Pristionchus reveals the environmental responsiveness of a plasticity gene-regulatory network
    • Shelley Reich,
    • Tobias Loschko,
    • Julie Jung,
    • Samantha Nestel,
    • Ralf J. Sommer,
    • and Michael S. Werner
    Genome Res. July 2025 35: 1560-1573; Published in Advance June 9, 2025, doi:10.1101/gr.279783.124
    ...and difficulties in laboratory rearing.The nematode Pristionchus pacificus was introduced as a model system for studying developmental plasticity in 2010 (Bento et al. 2010). Similar to Caenorhabditis elegans, P. pacificus has four larval stages (J1–J4), although the first stage remains enclosed in the egg...
    OPEN ACCESS ARTICLE
  5. Resource: Genome-wide discovery of active regulatory elements and transcription factor footprints in Caenorhabditis elegans using DNase-seq
    • Margaret C.W. Ho,
    • Porfirio Quintero-Cadena,
    • and Paul W. Sternberg
    Genome Res. December 2017 27: 2108-2119; Published in Advance October 26, 2017, doi:10.1101/gr.223735.117
    ...–treated chromatin (DNase-seq) allows high-resolution measurement of chromatin accessibility to DNase I cleavage, permitting identification of de novo active cis-regulatory modules (CRMs) and individual transcription factor (TF) binding sites. We adapted DNase-seq to nuclei isolated from C. elegans embryos and L1...
  6. Research: Integrating genetic variation with deep learning provides context for variants impacting transcription factor binding during embryogenesis
    • Olga M. Sigalova,
    • Mattia Forneris,
    • Frosina Stojanovska,
    • Bingqing Zhao,
    • Rebecca R. Viales,
    • Adam Rabinowitz,
    • Fayrouz Hammal,
    • Benoît Ballester,
    • Judith B. Zaugg,
    • and Eileen E.M. Furlong
    Genome Res. May 2025 35: 1138-1153; Published in Advance April 15, 2025, doi:10.1101/gr.279652.124
    ...variants occur in the noncoding (Edwards et al. 2013; Buniello et al. 2019) and likely affect gene regulation (Claringbould and Zaugg 2021). One mechanism by which mutations impact transcriptional programs is through the disruption of transcription factor (TF) binding sites within regulatory elements...
    OPEN ACCESS ARTICLE
  7. Research: The role of transposon activity in shaping cis-regulatory element evolution after whole-genome duplication
    • Øystein Monsen,
    • Lars Grønvold,
    • Alex Datsomor,
    • Thomas Harvey,
    • James Kijas,
    • Alexander Suh,
    • Torgeir R. Hvidsten,
    • and Simen Rød Sandve
    Genome Res. March 2025 35: 475-488; Published in Advance February 12, 2025, doi:10.1101/gr.278931.124
    ...The role of transposon activity in shaping cis-regulatory element evolution after whole- duplication Øystein Monsen1,6, Lars Grønvold1,6, Alex Datsomor1, Thomas Harvey1, James Kijas2, Alexander Suh3,4,7, Torgeir R. Hvidsten5 and Simen Rød Sandve1 1Department of Animal and Aquacultural Sciences...
  8. Research: A low-abundance class of Dicer-dependent siRNAs produced from a variety of features in C. elegans
    • Thiago L. Knittel,
    • Brooke E. Montgomery,
    • Alex J. Tate,
    • Ennis W. Deihl,
    • Anastasia S. Nawrocki,
    • Frederic J. Hoerndli,
    • and Taiowa A. Montgomery
    Genome Res. December 2024 34: 2203-2216; Published in Advance December 2, 2024, doi:10.1101/gr.279083.124
    ...from double-stranded RNA (dsRNA) by Dicer and associate with Argonautes to direct RNA silencing. In Caenorhabditis elegans, 22G-RNAs and 26G-RNAs are often referred to as siRNAs but display distinct characteristics. For example, 22G-RNAs do not originate from dsRNA and do not depend on Dicer, whereas...
  9. Resource: Comprehensive characterization of tissue-specific chromatin accessibility in L2 Caenorhabditis elegans nematodes
    • Timothy J. Durham,
    • Riza M. Daza,
    • Louis Gevirtzman,
    • Darren A. Cusanovich,
    • Olubusayo Bolonduro,
    • William Stafford Noble,
    • Jay Shendure,
    • and Robert H. Waterston
    Genome Res. October 2021 31: 1952-1969; Published in Advance April 22, 2021, doi:10.1101/gr.271791.120
    ...cell types.DiscussionWe used the sci-ATAC-seq assay to assemble the first cell type–resolved map of regulatory elements in C. elegans. We found 38,017 peaks, which we used to assign 24,503 of our 30,930 cells to one of 37 different clusters (Fig. 3) that represent distinct, differentiated tissues...
    OPEN ACCESS ARTICLE
  10. Research: Transposable elements drive the evolution of metazoan zinc finger genes
    • Jonathan N. Wells,
    • Ni-Chen Chang,
    • John McCormick,
    • Caitlyn Coleman,
    • Nathalie Ramos,
    • Bozhou Jin,
    • and Cédric Feschotte
    Genome Res. August 2023 33: 1325-1339; Published in Advance September 15, 2023, doi:10.1101/gr.277966.123
    ...contributed equally to this work. Corresponding authors: jnw72@cornell.edu, cf458@cornell.eduAbstractCys2-His2 zinc finger genes (ZNFs) form the largest family of transcription factors in metazoans. ZNF evolution is highly dynamic and characterized by the rapid expansion and contraction of numerous...
    OPEN ACCESS ARTICLE
For checked items

Search Results

Next 10 » New Search

Modify Results

Citation format:
Results / page:
Results order:

This search

  • Alert me when new articles matching this search are published
  • Download all citations on this page to my citation manager

Preprint Server



Current Issue

  1. March 2026, 36 (3)
  1. Current Issue
  1. Alert me to new issues of Genome Research