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MaizeCODE reveals bi-directionally expressed enhancers that harbor molecular signatures of maize domestication

Author

Listed:
  • Jonathan Cahn

    (Cold Spring Harbor Laboratory)

  • Michael Regulski

    (Cold Spring Harbor Laboratory)

  • Jason Lynn

    (Cold Spring Harbor Laboratory)

  • Evan Ernst

    (Cold Spring Harbor Laboratory)

  • Cristiane Santis Alves

    (Cold Spring Harbor Laboratory)

  • Srividya Ramakrishnan

    (Johns Hopkins University; 1900 E. Monument Street)

  • Kapeel Chougule

    (Cold Spring Harbor Laboratory)

  • Sharon Wei

    (Cold Spring Harbor Laboratory)

  • Zhenyuan Lu

    (Cold Spring Harbor Laboratory)

  • Xiaosa Xu

    (Cold Spring Harbor Laboratory
    University of California)

  • Umamaheswari Ramu

    (Cold Spring Harbor Laboratory)

  • Jorg Drenkow

    (Cold Spring Harbor Laboratory)

  • Melissa Kramer

    (Cold Spring Harbor Laboratory)

  • Arun Seetharam

    (Iowa State University)

  • Matthew B. Hufford

    (Iowa State University)

  • W. Richard McCombie

    (Cold Spring Harbor Laboratory)

  • Doreen Ware

    (Cold Spring Harbor Laboratory
    USDA ARS Robert W. Holley Center for Agriculture and Health Cornell University)

  • David Jackson

    (Cold Spring Harbor Laboratory)

  • Michael C. Schatz

    (Cold Spring Harbor Laboratory
    Johns Hopkins University; 1900 E. Monument Street)

  • Thomas R. Gingeras

    (Cold Spring Harbor Laboratory)

  • Robert A. Martienssen

    (Cold Spring Harbor Laboratory)

Abstract

Modern maize (Zea mays ssp. mays) was domesticated from Teosinte parviglumis (Zea mays ssp. parviglumis), with subsequent introgressions from Teosinte mexicana (Zea mays ssp. mexicana), yielding increased kernel row number, loss of the hard fruit case and dissociation from the cob upon maturity, as well as fewer tillers. Molecular approaches have identified transcription factors controlling these traits, yet revealed that a complex regulatory network is at play. MaizeCODE deploys ENCODE strategies to catalog regulatory regions in the maize genome, generating histone modification and transcription factor ChIP-seq in parallel with transcriptomics datasets in 5 tissues of 3 inbred lines which span the phenotypic diversity of maize, as well as the teosinte inbred TIL11. Transcriptomic analysis reveals that pollen grains share features with endosperm, and express dozens of “proto-miRNAs” potential vestiges of gene drive and hybrid incompatibility. Integrated analysis with chromatin modifications results in the identification of a comprehensive set of regulatory regions in each tissue of each inbred, and notably of distal enhancers expressing non-coding enhancer RNAs bi-directionally, reminiscent of “super enhancers” in animal genomes. Furthermore, the morphological traits selected during domestication are recapitulated, both in gene expression and within regulatory regions containing enhancer RNAs, while highlighting the conflict between enhancer activity and silencing of the neighboring transposable elements.

Suggested Citation

  • Jonathan Cahn & Michael Regulski & Jason Lynn & Evan Ernst & Cristiane Santis Alves & Srividya Ramakrishnan & Kapeel Chougule & Sharon Wei & Zhenyuan Lu & Xiaosa Xu & Umamaheswari Ramu & Jorg Drenkow , 2024. "MaizeCODE reveals bi-directionally expressed enhancers that harbor molecular signatures of maize domestication," Nature Communications, Nature, vol. 15(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-55195-w
    DOI: 10.1038/s41467-024-55195-w
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    References listed on IDEAS

    as
    1. Run Jin & Samantha Klasfeld & Yang Zhu & Meilin Fernandez Garcia & Jun Xiao & Soon-Ki Han & Adam Konkol & Doris Wagner, 2021. "LEAFY is a pioneer transcription factor and licenses cell reprogramming to floral fate," Nature Communications, Nature, vol. 12(1), pages 1-14, December.
    2. Satoyo Oya & Mayumi Takahashi & Kazuya Takashima & Tetsuji Kakutani & Soichi Inagaki, 2022. "Transcription-coupled and epigenome-encoded mechanisms direct H3K4 methylation," Nature Communications, Nature, vol. 13(1), pages 1-16, December.
    3. Benjamin Berube & Evan Ernst & Jonathan Cahn & Benjamin Roche & Cristiane Santis Alves & Jason Lynn & Armin Scheben & Daniel Grimanelli & Adam Siepel & Jeffrey Ross-Ibarra & Jerry Kermicle & Robert A., 2024. "Teosinte Pollen Drive guides maize diversification and domestication by RNAi," Nature, Nature, vol. 633(8029), pages 380-388, September.
    4. Zhaobin Dong & Yuguo Xiao & Rajanikanth Govindarajulu & Regina Feil & Muriel L. Siddoway & Torrey Nielsen & John E. Lunn & Jennifer Hawkins & Clinton Whipple & George Chuck, 2019. "The regulatory landscape of a core maize domestication module controlling bud dormancy and growth repression," Nature Communications, Nature, vol. 10(1), pages 1-15, December.
    5. Huai Wang & Tina Nussbaum-Wagler & Bailin Li & Qiong Zhao & Yves Vigouroux & Marianna Faller & Kirsten Bomblies & Lewis Lukens & John F. Doebley, 2005. "The origin of the naked grains of maize," Nature, Nature, vol. 436(7051), pages 714-719, August.
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