<p>Intensity and duration of biological signals encode a few pathways to direct diverse cellular behaviors, yet quantifying these features in single cells remains difficult. To address this challenge, we developed INSCRIBE, which uses a CRISPR base editor to mutate genomic targets at rates proportional to signaling activity. Edits are recovered at the endpoint through a new ratiometric readout strategy from images of two fluorescence channels. We engineered human cells to record WNT and BMP activity. Following defined exogenous stimulations, INSCRIBE accurately recovered signal intensity in dose–response experiments and exposure duration in time-course experiments. Applying INSCRIBE revealed a persistent memory in the BMP pathway, where progeny of high-responding cells remained more sensitive to subsequent BMP stimulation for up to 3 weeks. Together, our results establish a scalable platform for genetic recording and in situ readout of signaling activity in single cells, advancing quantitative analysis of cell–cell communication during development and disease.</p><p></p>

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Genetic recording and in situ readout of single-cell signaling memory

  • Kai Hao,
  • Yunzheng Liu,
  • Mykel Barrett,
  • Zainalabedin Samadi,
  • Amirhossein Zarezadeh,
  • Yuka McGrath,
  • Magdalena Zernicka-Goetz,
  • Amjad Askary

摘要

Intensity and duration of biological signals encode a few pathways to direct diverse cellular behaviors, yet quantifying these features in single cells remains difficult. To address this challenge, we developed INSCRIBE, which uses a CRISPR base editor to mutate genomic targets at rates proportional to signaling activity. Edits are recovered at the endpoint through a new ratiometric readout strategy from images of two fluorescence channels. We engineered human cells to record WNT and BMP activity. Following defined exogenous stimulations, INSCRIBE accurately recovered signal intensity in dose–response experiments and exposure duration in time-course experiments. Applying INSCRIBE revealed a persistent memory in the BMP pathway, where progeny of high-responding cells remained more sensitive to subsequent BMP stimulation for up to 3 weeks. Together, our results establish a scalable platform for genetic recording and in situ readout of signaling activity in single cells, advancing quantitative analysis of cell–cell communication during development and disease.