Communications Biology (Jun 2024)

High-affinity tuning of single fluorescent protein-type indicators by flexible linker length optimization in topology mutant

  • Yusuke Hara,
  • Aya Ichiraku,
  • Tomoki Matsuda,
  • Ayuko Sakane,
  • Takuya Sasaki,
  • Takeharu Nagai,
  • Kazuki Horikawa

DOI
https://doi.org/10.1038/s42003-024-06394-0
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 10

Abstract

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Abstract Genetically encoded Ca2+ indicators (GECIs) are versatile for live imaging of cellular activities. Besides the brightness and dynamic range of signal change of GECIs, Ca2+ affinity is another critical parameter for successful Ca2+ imaging, as the concentration range of Ca2+ dynamics differs from low nanomolar to sub-millimolar depending on the celltype and organism. However, ultrahigh-affinity GECIs, particularly the single fluorescent protein (1FP)-type, are lacking. Here, we report a simple strategy that increases Ca2+ affinity through the linker length optimization in topology mutants of existing 1FP-type GECIs. The resulting ultrahigh-affinity GECIs, CaMPARI-nano, BGECO-nano, and RCaMP-nano (K d = 17–25 nM), enable unique biological applications, including the detection of low nanomolar Ca2+ dynamics, highlighting active signaling cells, and multi-functional imaging with other second messengers. The linker length optimization in topology mutants could be applied to other 1FP-type indicators of glutamate and potassium, rendering it a widely applicable technique for modulating indicator affinity.