Searching journal content for articles similar to Warren et al. 25 (12): 1921.

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  1. Research: Stable genome structures in living fossil fishes
    • Cheng Wang,
    • Chase D. Brownstein,
    • Wenjun Chen,
    • Zufa Ding,
    • Dan Yu,
    • Yu Deng,
    • Chenguang Feng,
    • Thomas J. Near,
    • Shunping He,
    • and Liandong Yang
    Genome Res. February 2026 36: 318-329; Published in Advance January 13, 2026, doi:10.1101/gr.280800.125
    ...contributed equally to this work. Corresponding authors: thomas.near@yale.edu, clad@ihb.ac.cn, yangliandong1987@163.comAbstractGenomic evolution can propel and restrict species diversification. Rapid molecular evolution and genomic rearrangement is often associated with increased species diversification...
  2. Method: Pangenome-based genome inference using integer programming
    • Ghanshyam Chandra,
    • Md Helal Hossen,
    • Stephan Scholz,
    • Alexander T. Dilthey,
    • Daniel Gibney,
    • and Chirag Jain
    Genome Res. December 2025 35: 2661-2670; Published in Advance August 21, 2025, doi:10.1101/gr.280567.125
    ...: chirag@iisc.ac.inAbstractAffordable genotyping methods are essential in genomics. Commonly used genotyping methods primarily support single-nucleotide variants and short indels but neglect structural variants. Additionally, accuracy of read alignments to a reference is unreliable in highly polymorphic...
  3. Research: Loss of multilevel 3D genome organization during breast cancer progression
    • Roberto Rossini,
    • Saleh Oshaghi,
    • Maxim Nekrasov,
    • Aurélie Bellanger,
    • Renae Domaschenz,
    • Yasmin Dijkwel,
    • Mohamed Abdelhalim,
    • Rahul Agrawal,
    • Marit Ledsaak,
    • Philippe Collas,
    • Ragnhild Eskeland,
    • David Tremethick,
    • and Jonas Paulsen
    Genome Res. January 2026 36: 20-37; Published in Advance October 9, 2025, doi:10.1101/gr.280791.125
    ...and Jonas Paulsen1 1Department of Biosciences, Faculty of Mathematics and Natural Sciences, University of Oslo, 0316 Oslo, Norway; 2Department of Genome Sciences, The John Curtin School of Medical Research, The Australian National University, Canberra, Australian Capital Territory 2601, Australia; 3...
  4. Mini-Review: Evolution of genome-wide methylation profiling technologies
    • Carolina Montano and
    • Winston Timp
    Genome Res. April 2025 35: 572-582; doi:10.1101/gr.278407.123
    ....Cytosine methylation plays a critical role in genomic imprinting, gene regulation, X-Chromosome inactivation (XCI), cellular differentiation, aging, and tumorigenesis. Cells have an extensive system of proteins that establish these methylation patterns through de novo methylation or demethylation, copy methylation...
    OPEN ACCESS ARTICLE
  5. Method: OMKar automates genome karyotyping using optical maps to identify constitutional abnormalities
    • Siavash Raeisi Dehkordi,
    • Zhaoyang Jia,
    • Joey Estabrook,
    • Jen Hauenstein,
    • Neil Miller,
    • Naz Güleray-Lafci,
    • Jürgen Neesen,
    • Alex Hastie,
    • Alka Chaubey,
    • Andy Wing Chun Pang,
    • Paul Dremsek,
    • and Vineet Bafna
    Genome Res. December 2025 35: 2671-2681; Published in Advance November 14, 2025, doi:10.1101/gr.280536.125
    ...Bafna1,4 1Department of Computer Science and Engineering, University of California San Diego, La Jolla, California 92093, USA; 2Bionano Genomics, Incorporated, San Diego, California 92121, USA; 3Institute of Medical Genetics, Center for Pathobiochemistry and Genetics, Medical University of Vienna, 1090...
    OPEN ACCESS ARTICLE
  6. Resource: CGC1, a new reference genome for Caenorhabditis elegans
    • Kazuki Ichikawa,
    • Massa J. Shoura,
    • Karen L. Artiles,
    • Dae-Eun Jeong,
    • Chie Owa,
    • Haruka Kobayashi,
    • Yoshihiko Suzuki,
    • Manami Kanamori,
    • Yu Toyoshima,
    • Yuichi Iino,
    • Ann E. Rougvie,
    • Lamia Wahba,
    • Andrew Z. Fire,
    • Erich M. Schwarz,
    • and Shinichi Morishita
    Genome Res. August 2025 35: 1902-1918; Published in Advance July 15, 2025, doi:10.1101/gr.280274.124
    ...the N2-derived strain VC2010. Moreover, genetically divergent versions of N2 have arisen over decades of research and hindered reproducibility of C. elegans genetics and genomics. Here we provide a 106.4 Mb gap-free, telomere-to-telomere assembly of C. elegans, generated from CGC1, an isogenic...
    OPEN ACCESS ARTICLE
  7. Research: Genome-wide nucleosome and transcription factor responses to genetic perturbations reveal chromatin-mediated mechanisms of transcriptional regulation
    • Kevin Moyung,
    • Yulong Li,
    • Heather K. MacAlpine,
    • Alexander J. Hartemink,
    • and David M. MacAlpine
    Genome Res. January 2026 36: 115-128; Published in Advance December 9, 2025, doi:10.1101/gr.279637.124
    ...length as a function of the location of the midpoint of each fragment and colored the points based on their local density. The result is a near-nucleotide-resolution -wide view of chromatin occupancy for each deletion strain (Fig. 1D–F).View larger version: In this window In a new window Figure 1. Genome...
  8. Research: H3K27 and H3K9 methylation mask potential CTCF binding sites to maintain 3D genome integrity
    • Kei Fukuda,
    • Chikako Shimura,
    • and Yoichi Shinkai
    Genome Res. October 2025 35: 2199-2210; Published in Advance August 5, 2025, doi:10.1101/gr.280732.125
    ..., Yamanashi 400-8510, Japan Corresponding authors: yshinkai@riken.jp, k.fukuda@yamanashi.ac.jpAbstractThe three-dimensional (3D) structure is essential for gene regulation and various genomic functions. CTCF plays a key role in organizing topologically associated domains (TADs) and promoter-enhancer loops...
  9. Resource: Building better genome annotations across the tree of life
    • Adam H. Freedman and
    • Timothy B. Sackton
    Genome Res. May 2025 35: 1261-1276; Published in Advance April 15, 2025, doi:10.1101/gr.280377.124
    ...of bioinformatics tools and resources to interrogate s for evolutionary patterns and features of biomedical interest. But even as s became available for other model organisms such as mouse (Mus musculus) (Mouse Genome Sequencing Consortium et al. 2002) and rhesus macaque (Macaca mulatta) (Rhesus Macaque Genome...
  10. Method: KAS-ATAC reveals the genome-wide single-stranded accessible chromatin landscape of the human genome
    • Samuel H. Kim,
    • Georgi K. Marinov,
    • and William J. Greenleaf
    Genome Res. January 2025 35: 124-134; Published in Advance November 21, 2024, doi:10.1101/gr.279621.124
    ...abundances of accessible ssDNA and accessible DNA). (C) KAS-seq, ATAC-seq, and KAS-ATAC mitochondrial profiles in human GM12878 cells. (D) Fragment length distribution in biotin-ATAC-seq and KAS-ATAC libraries (GM12878 cells). (E) Genome-wide TSS metaprofiles for biotin-ATAC-seq and KAS-ATAC libraries (GM...
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