Frontiers in Molecular Biosciences (Feb 2023)

Opto-APC: Engineering of cells that display phytochrome B on their surface for optogenetic studies of cell-cell interactions

  • Marissa Russ,
  • Marissa Russ,
  • Anna K. Ehret,
  • Anna K. Ehret,
  • Anna K. Ehret,
  • Maximilian Hörner,
  • Daniel Peschkov,
  • Rebecca Bohnert,
  • Vincent Idstein,
  • Vincent Idstein,
  • Vincent Idstein,
  • Susana Minguet,
  • Susana Minguet,
  • Wilfried Weber,
  • Björn F. Lillemeier,
  • O. Sascha Yousefi,
  • Wolfgang W. Schamel,
  • Wolfgang W. Schamel

DOI
https://doi.org/10.3389/fmolb.2023.1143274
Journal volume & issue
Vol. 10

Abstract

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The kinetics of a ligand-receptor interaction determine the responses of the receptor-expressing cell. One approach to experimentally and reversibly change this kinetics on demand is optogenetics. We have previously developed a system in which the interaction of a modified receptor with an engineered ligand can be controlled by light. In this system the ligand is a soluble Phytochrome B (PhyB) tetramer and the receptor is fused to a mutated PhyB-interacting factor (PIFS). However, often the natural ligand is not soluble, but expressed as a membrane protein on another cell. This allows ligand-receptor interactions in two dimensions. Here, we developed a strategy to generate cells that display PhyB as a membrane-bound protein by expressing the SpyCatcher fused to a transmembrane domain in HEK-293T cells and covalently coupling purified PhyB-SpyTag to these cells. As proof-of-principle, we use Jurkat T cells that express a GFP-PIFS-T cell receptor and show that these cells can be stimulated by the PhyB-coupled HEK-293T cells in a light dependent manner. Thus, we call the PhyB-coupled cells opto-antigen presenting cells (opto-APCs). Our work expands the toolbox of optogenetic technologies, allowing two-dimensional ligand-receptor interactions to be controlled by light.

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