Bacterial
photoactivated adenylyl cyclase (bPAC) has been widely
used in signal transduction research. However, due to its low two-photon
absorption, bPAC cannot be efficiently activated by two-photon (2P)
excitation. Taking advantage of the high two-photon absorption of
monomeric teal fluorescent protein 1 (mTFP1), we herein developed
2P-activatable bPAC (2pabPAC), a fusion protein consisting of bPAC
and mTFP1. In 2pabPAC, the energy absorbed by mTFP1 excites bPAC by
Fürster resonance energy transfer (FRET) at ca. 43% efficiency. The light-induced increase in cAMP was monitored
by a red-shifted FRET biosensor for PKA. In 3D MDCK cells and mouse
liver, PKA was activated at single-cell resolution under a 2P microscope.
We found that PKA activation in a single hepatocyte caused PKA activation
in neighboring cells, indicating the propagation of PKA activation.
Thus, 2pabPAC will provide a versatile platform for controlling the
cAMP signaling pathway and investigating cell-to-cell communication in vivo.