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Convergent genes shape budding yeast pericentromeres

Author

Listed:
  • Flora Paldi

    (School of Biological Sciences, University of Edinburgh)

  • Bonnie Alver

    (School of Biological Sciences, University of Edinburgh)

  • Daniel Robertson

    (School of Biological Sciences, University of Edinburgh)

  • Stephanie A. Schalbetter

    (University of Sussex)

  • Alastair Kerr

    (School of Biological Sciences, University of Edinburgh)

  • David A. Kelly

    (School of Biological Sciences, University of Edinburgh)

  • Jonathan Baxter

    (University of Sussex)

  • Matthew J. Neale

    (University of Sussex)

  • Adele L. Marston

    (School of Biological Sciences, University of Edinburgh)

Abstract

The three-dimensional architecture of the genome governs its maintenance, expression and transmission. The cohesin protein complex organizes the genome by topologically linking distant loci, and is highly enriched in specialized chromosomal domains surrounding centromeres, called pericentromeres1–6. Here we report the three-dimensional structure of pericentromeres in budding yeast (Saccharomyces cerevisiae) and establish the relationship between genome organization and function. We find that convergent genes mark pericentromere borders and, together with core centromeres, define their structure and function by positioning cohesin. Centromeres load cohesin, and convergent genes at pericentromere borders trap it. Each side of the pericentromere is organized into a looped conformation, with border convergent genes at the base. Microtubule attachment extends a single pericentromere loop, size-limited by convergent genes at its borders. Reorienting genes at borders into a tandem configuration repositions cohesin, enlarges the pericentromere and impairs chromosome biorientation during mitosis. Thus, the linear arrangement of transcriptional units together with targeted cohesin loading shapes pericentromeres into a structure that is competent for chromosome segregation. Our results reveal the architecture of the chromosomal region within which kinetochores are embedded, as well as the restructuring caused by microtubule attachment. Furthermore, we establish a direct, causal relationship between the three-dimensional genome organization of a specific chromosomal domain and cellular function.

Suggested Citation

  • Flora Paldi & Bonnie Alver & Daniel Robertson & Stephanie A. Schalbetter & Alastair Kerr & David A. Kelly & Jonathan Baxter & Matthew J. Neale & Adele L. Marston, 2020. "Convergent genes shape budding yeast pericentromeres," Nature, Nature, vol. 582(7810), pages 119-123, June.
    • Handle: RePEc:nat:nature:v:582:y:2020:i:7810:d:10.1038_s41586-020-2244-6
    DOI: 10.1038/s41586-020-2244-6
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    Cited by:

    1. Ayantika Sen Gupta & Chris Seidel & Dai Tsuchiya & Sean McKinney & Zulin Yu & Sarah E. Smith & Jay R. Unruh & Jennifer L. Gerton, 2023. "Defining a core configuration for human centromeres during mitosis," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    2. Catherine Naughton & Covadonga Huidobro & Claudia R. Catacchio & Adam Buckle & Graeme R. Grimes & Ryu-Suke Nozawa & Stefania Purgato & Mariano Rocchi & Nick Gilbert, 2022. "Human centromere repositioning activates transcription and opens chromatin fibre structure," Nature Communications, Nature, vol. 13(1), pages 1-16, December.

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