We show that the three conformational states of integrin a5b1
have discrete free energies and define activation by measuring
intrinsic affinities for ligand of each state and the equilibria linking
them. The 5,000-fold higher affinity of the extended-open state
than the bent-closed and extended-closed states demonstrates
profound regulation of affinity. Free energy requirements for activation
are defined with protein fragments and intact a5b1. On the
surface of K562 cells, a5b1 is 99.8% bent-closed. Stabilization of the
bent conformation by integrin transmembrane and cytoplasmic
domains must be overcome by cellular energy input to stabilize
extension. Following extension, headpiece opening is energetically
favo... More
We show that the three conformational states of integrin a5b1
have discrete free energies and define activation by measuring
intrinsic affinities for ligand of each state and the equilibria linking
them. The 5,000-fold higher affinity of the extended-open state
than the bent-closed and extended-closed states demonstrates
profound regulation of affinity. Free energy requirements for activation
are defined with protein fragments and intact a5b1. On the
surface of K562 cells, a5b1 is 99.8% bent-closed. Stabilization of the
bent conformation by integrin transmembrane and cytoplasmic
domains must be overcome by cellular energy input to stabilize
extension. Following extension, headpiece opening is energetically
favored. N-glycans and leg domains in each subunit that connect
the ligand-binding head to the membrane repel or crowd one
another and regulate conformational equilibria in favor of headpiece
opening. The results suggest new principles for regulating
signaling in the large class of receptors built from extracellular
domains in tandem with single-span transmembrane domains.
