Abstract
Nerve growth factor (NGF) binding to the receptor tyrosine kinase, TrkA, drives neurotrophic signaling essential for neuronal development and survival. This interaction simultaneously drives peripheral pain, making this pathway an attractive but complicated therapeutic target for chronic pain. By integrating single-molecule microscopy, structural and electrophysiology analyses, with a human NGF variant, NGF (painless) , which retains neurotrophic effects but abolishes pain, we delineate the molecular mechanisms that bias TrkA signaling towards neurotrophic functions without triggering nociception. We show that, unlike wild-type NGF, NGF (painless) fails to sensitize TRPV1 channels to capsaicin, thus disengaging TrkA from the nociceptive pathway. We further show that this selective loss of nociceptive TrkA signaling by NGF (painless) results from its reduced ability to activate PLCγ1 and trigger calcium release compared to NGF, while still preserving the ERK and AKT signaling essential for neurotrophic functions. This biased signaling arises from reduced electrostatic complementarity at the TrkA:NGF (painless) complex interface, which shortens the lifetime of this functional complex on native membranes. Mutations in TrkA that restore the electrostatic complementarity at the TrkA:NGF (painless) interface eliminate biased signaling. This mechanistic understanding of TrkA binding by NGF (painless) , and how it differs from NGF, will spur the development of two therapeutic classes of molecules - one that selectively suppresses nociceptive signaling while preserving neurotrophic functions in chronic pain, and another that enhances neurotrophic activity without evoking peripheral pain in neurodegenerative conditions.