Searching journal content for articles similar to Naish and Henderson 34 (2): 161.

Displaying results 1-10 of 283
For checked items
  1. Research: Adaptation of centromeres to breakage through local genomic and epigenomic remodeling in wheat
    • Jingwei Zhou,
    • Yuhong Huang,
    • Huan Ma,
    • Yiqian Chen,
    • Chuanye Chen,
    • Fangpu Han,
    • and Handong Su
    Genome Res. November 2025 35: 2461-2471; Published in Advance September 30, 2025, doi:10.1101/gr.280913.125
    ...nucleosome remodeling and is accompanied by local transcription changes and chromatin reorganization, and subsequently may contribute to the stabilization of broken chromosomes. Our findings highlight the resilience and adaptability of plant chromosomes in response to centromere breakage and provide valuable...
  2. Research: Candida albicans isolates contain frequent heterozygous structural variants and transposable elements within genes and centromeres
    • Ursula Oggenfuss,
    • Robert T. Todd,
    • Natthapon Soisangwan,
    • Bailey Kemp,
    • Alison Guyer,
    • Annette Beach,
    • and Anna Selmecki
    Genome Res. April 2025 35: 824-838; Published in Advance October 22, 2024, doi:10.1101/gr.279301.124
    ...-resistant clinical isolates and can form isochromosome structures with breakpoints near the centromere. Further screening of 100 clinical isolates confirms the widespread presence of centromeric SVs in C. albicans, often appearing in a heterozygous state, indicating that SVs are contributing to centromere evolution...
  3. Research: Dynamic evolution of satellite DNAs drastically differentiates the genomes of Tribolium sibling species
    • Damira Veseljak,
    • Evelin Despot-Slade,
    • Marin Volarić,
    • Lucija Horvat,
    • Tanja Vojvoda Zeljko,
    • Nevenka Meštrović,
    • and Brankica Mravinac
    Genome Res. November 2025 35: 2445-2460; Published in Advance September 16, 2025, doi:10.1101/gr.280516.125
    ...DNAs highlighted dyad symmetry as the most conspicuous feature. Dyad symmetries within satellite monomers can form secondary structures such as hairpins or cruciforms, and enrichment in predicted non-B-form DNA structures was found in centromeric repeats of diverse animal and plant species (Kasinathan and Henikoff...
  4. Research: Plant genome evolution in the genus Eucalyptus is driven by structural rearrangements that promote sequence divergence
    • Scott Ferguson,
    • Ashley Jones,
    • Kevin Murray,
    • Rose Andrew,
    • Benjamin Schwessinger,
    • and Justin Borevitz
    Genome Res. April 2024 34: 606-619; Published in Advance April 8, 2024, doi:10.1101/gr.277999.123
    ...Plant evolution in the genus Eucalyptus is driven by structural rearrangements that promote sequence divergence Scott Ferguson1,4, Ashley Jones1,4, Kevin Murray1,2, Rose Andrew3, Benjamin Schwessinger1 and Justin Borevitz1 1Research School of Biology, Australian National University, Canberra...
    OPEN ACCESS ARTICLE
  5. Perspective: The genetics and epigenetics of satellite centromeres
    • Paul B. Talbert and
    • Steven Henikoff
    Genome Res. April 2022 32: 608-615; Published in Advance March 31, 2022, doi:10.1101/gr.275351.121
    ...to segregate chromosomes, are typically found within satellite arrays in plants and animals. Satellite arrays have been difficult to analyze because they comprise megabases of tandem head-to-tail highly repeated DNA sequences. Much evidence suggests that centromeres are epigenetically defined by the location...
    OPEN ACCESS ARTICLE
  6. Research: Long-read genomics reveal extensive nuclear-specific evolution and allele-specific expression in a dikaryotic fungus
    • Rita Tam,
    • Mareike Möller,
    • Runpeng Luo,
    • Zhenyan Luo,
    • Ashley Jones,
    • Sambasivam Periyannan,
    • John P. Rathjen,
    • and Benjamin Schwessinger
    Genome Res. June 2025 35: 1364-1376; Published in Advance April 11, 2025, doi:10.1101/gr.280359.124
    ...), as well as nuclear-level transcriptomic and epigenetic differences similar to findings in button mushroom Agaricus bisporus (Gehrmann et al. 2018), although key questions remain around the impact of dikaryotic organization on the evolution of centromeres, rDNA repeats, detailed inter-haplotype variations...
    OPEN ACCESS ARTICLE
  7. Method: Gapless assembly of complete human and plant chromosomes using only nanopore sequencing
    • Sergey Koren,
    • Zhigui Bao,
    • Andrea Guarracino,
    • Shujun Ou,
    • Sara Goodwin,
    • Katharine M. Jenike,
    • Julian Lucas,
    • Brandy McNulty,
    • Jimin Park,
    • Mikko Rautiainen,
    • Arang Rhie,
    • Dick Roelofs,
    • Harrie Schneiders,
    • Ilse Vrijenhoek,
    • Koen Nijbroek,
    • Olle Nordesjo,
    • Sergey Nurk,
    • Mike Vella,
    • Katherine R. Lawrence,
    • Doreen Ware,
    • Michael C. Schatz,
    • Erik Garrison,
    • Sanwen Huang,
    • William Richard McCombie,
    • Karen H. Miga,
    • Alexander H.J. Wittenberg,
    • and Adam M. Phillippy
    Genome Res. November 2024 34: 1919-1930; Published in Advance November 6, 2024, doi:10.1101/gr.279334.124
    ...KeyGene, 6708 PW Wageningen, Netherlands; 10Oxford Nanopore Technologies, Oxford OX4 4DQ, United Kingdom; 11USDA ARS NEA Plant, Soil and Nutrition Laboratory Research Unit, Ithaca, New York 14853, USA; 12State Key Laboratory of Tropical Crop Breeding, Chinese Academy of Tropical Agricultural Sciences...
  8. Research: Hierarchical architecture of neo-sex chromosomes and accelerated adaptive evolution in tortricid moths
    • Fangyuan Yang,
    • Li-Jun Cao,
    • Petr Nguyen,
    • Zhong-Zheng Ma,
    • Jin-Cui Chen,
    • Wei Song,
    • and Shu-Jun Wei
    Genome Res. January 2025 35: 66-77; Published in Advance January 6, 2025, doi:10.1101/gr.279569.124
    ...to a general feature of karyotype evolution of Lepidoptera: SA fusion–SCDC–Accelerated evolution. In the presented study, one accelerated gene, ABCC4, may be involved in host adaptation (Wei et al. 2021; Beran and Petschenka 2022) and thus favor the coprosperity of the Tortricidae with their host plant (Fagua...
  9. Research: Rapid evolution of piRNA clusters in the Drosophila melanogaster ovary
    • Satyam P. Srivastav,
    • Cédric Feschotte,
    • and Andrew G. Clark
    Genome Res. May 2024 34: 711-724; Published in Advance May 15, 2024, doi:10.1101/gr.278062.123
    ...in Drosophila melanogaster, much less is known about the origin and evolution of piCs in this or any other species. To investigate piC origin and evolution, we use a population genomic approach to compare piC activity and sequence composition across eight geographically distant strains of D. melanogaster...
  10. Research: Telomeric repeat evolution in the phylum Nematoda revealed by high-quality genome assemblies and subtelomere structures
    • Jiseon Lim,
    • Wonjoo Kim,
    • Jun Kim,
    • and Junho Lee
    Genome Res. November 2023 33: 1947-1957; Published in Advance November 2, 2023, doi:10.1101/gr.278124.123
    ...Telomeric repeat evolution in the phylum Nematoda revealed by high-quality assemblies and subtelomere structures Jiseon Lim1,2, Wonjoo Kim1,2, Jun Kim1,3,4 and Junho Lee1,2,3 1Department of Biological Sciences, Seoul National University, Gwanak-gu, Seoul 08826, South Korea; 2Institute of Molecular...
    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