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A high-resolution protein architecture of the budding yeast genome

Author

Listed:
  • Matthew J. Rossi

    (The Pennsylvania State University)

  • Prashant K. Kuntala

    (The Pennsylvania State University)

  • William K. M. Lai

    (The Pennsylvania State University
    Cornell University)

  • Naomi Yamada

    (The Pennsylvania State University)

  • Nitika Badjatia

    (The Pennsylvania State University)

  • Chitvan Mittal

    (The Pennsylvania State University
    Cornell University)

  • Guray Kuzu

    (The Pennsylvania State University)

  • Kylie Bocklund

    (The Pennsylvania State University)

  • Nina P. Farrell

    (The Pennsylvania State University)

  • Thomas R. Blanda

    (The Pennsylvania State University)

  • Joshua D. Mairose

    (The Pennsylvania State University)

  • Ann V. Basting

    (The Pennsylvania State University)

  • Katelyn S. Mistretta

    (The Pennsylvania State University)

  • David J. Rocco

    (The Pennsylvania State University)

  • Emily S. Perkinson

    (The Pennsylvania State University)

  • Gretta D. Kellogg

    (The Pennsylvania State University
    Cornell University)

  • Shaun Mahony

    (The Pennsylvania State University)

  • B. Franklin Pugh

    (The Pennsylvania State University
    Cornell University)

Abstract

The genome-wide architecture of chromatin-associated proteins that maintains chromosome integrity and gene regulation is not well defined. Here we use chromatin immunoprecipitation, exonuclease digestion and DNA sequencing (ChIP–exo/seq)1,2 to define this architecture in Saccharomyces cerevisiae. We identify 21 meta-assemblages consisting of roughly 400 different proteins that are related to DNA replication, centromeres, subtelomeres, transposons and transcription by RNA polymerase (Pol) I, II and III. Replication proteins engulf a nucleosome, centromeres lack a nucleosome, and repressive proteins encompass three nucleosomes at subtelomeric X-elements. We find that most promoters associated with Pol II evolved to lack a regulatory region, having only a core promoter. These constitutive promoters comprise a short nucleosome-free region (NFR) adjacent to a +1 nucleosome, which together bind the transcription-initiation factor TFIID to form a preinitiation complex. Positioned insulators protect core promoters from upstream events. A small fraction of promoters evolved an architecture for inducibility, whereby sequence-specific transcription factors (ssTFs) create a nucleosome-depleted region (NDR) that is distinct from an NFR. We describe structural interactions among ssTFs, their cognate cofactors and the genome. These interactions include the nucleosomal and transcriptional regulators RPD3-L, SAGA, NuA4, Tup1, Mediator and SWI–SNF. Surprisingly, we do not detect interactions between ssTFs and TFIID, suggesting that such interactions do not stably occur. Our model for gene induction involves ssTFs, cofactors and general factors such as TBP and TFIIB, but not TFIID. By contrast, constitutive transcription involves TFIID but not ssTFs engaged with their cofactors. From this, we define a highly integrated network of gene regulation by ssTFs.

Suggested Citation

  • Matthew J. Rossi & Prashant K. Kuntala & William K. M. Lai & Naomi Yamada & Nitika Badjatia & Chitvan Mittal & Guray Kuzu & Kylie Bocklund & Nina P. Farrell & Thomas R. Blanda & Joshua D. Mairose & An, 2021. "A high-resolution protein architecture of the budding yeast genome," Nature, Nature, vol. 592(7853), pages 309-314, April.
  • Handle: RePEc:nat:nature:v:592:y:2021:i:7853:d:10.1038_s41586-021-03314-8
    DOI: 10.1038/s41586-021-03314-8
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    Citations

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    Cited by:

    1. Yi Li & James Lee & Lu Bai, 2024. "DNA methylation-based high-resolution mapping of long-distance chromosomal interactions in nucleosome-depleted regions," Nature Communications, Nature, vol. 15(1), pages 1-16, December.
    2. Rina Hirano & Haruhiko Ehara & Tomoya Kujirai & Tamami Uejima & Yoshimasa Takizawa & Shun-ichi Sekine & Hitoshi Kurumizaka, 2022. "Structural basis of RNA polymerase II transcription on the chromatosome containing linker histone H1," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    3. Sai Li & Michael R. Wasserman & Olga Yurieva & Lu Bai & Michael E. O’Donnell & Shixin Liu, 2022. "Nucleosome-directed replication origin licensing independent of a consensus DNA sequence," Nature Communications, Nature, vol. 13(1), pages 1-15, December.
    4. Joana Segura & Ofelia Díaz-Ingelmo & Belén Martínez-García & Alba Ayats-Fraile & Christoforos Nikolaou & Joaquim Roca, 2024. "Nucleosomal DNA has topological memory," Nature Communications, Nature, vol. 15(1), pages 1-10, December.

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