Cell Reports (Jul 2019)

Molecular Mechanisms Driving Switch Behavior in Xylem Cell Differentiation

  • Gina M. Turco,
  • Joel Rodriguez-Medina,
  • Stefan Siebert,
  • Diane Han,
  • Miguel Á. Valderrama-Gómez,
  • Hannah Vahldick,
  • Christine N. Shulse,
  • Benjamin J. Cole,
  • Celina E. Juliano,
  • Diane E. Dickel,
  • Michael A. Savageau,
  • Siobhan M. Brady

Journal volume & issue
Vol. 28, no. 2
pp. 342 – 351.e4

Abstract

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Summary: Plant xylem cells conduct water and mineral nutrients. Although most plant cells are totipotent, xylem cells are unusual and undergo terminal differentiation. Many genes regulating this process are well characterized, including the Vascular-related NAC Domain 7 (VND7), MYB46, and MYB83 transcription factors, which are proposed to act in interconnected feedforward loops (FFLs). Less is known regarding the molecular mechanisms underlying the terminal transition to xylem cell differentiation. Here, we generate whole-root and single-cell data, which demonstrate that VND7 initiates sharp switching of root cells to xylem cell identity. Based on these data, we identified 4 candidate VND7 downstream target genes capable of generating this switch. Although MYB46 responds to VND7 induction, it is not among these targets. This system provides an important model to study the emergent properties that may give rise to totipotency relative to terminal differentiation and reveals xylem cell subtypes. : Turco et al. demonstrate that VND7 initiates sharp switching of root cells to xylem cell identity. The authors identify four candidate VND7 downstream target genes capable of generating this switch. This work provides a framework for models that give rise to totipotency relative to terminal differentiation. Keywords: xylem, single cell, totipotent, differentiation, switch, single cell