posted on 2017-06-09, 00:00authored bySeth A. Lieblich, Katharine Y. Fang, Jackson K. B. Cahn, Jeffrey Rawson, Jeanne LeBon, H. Teresa Ku, David A. Tirrell
Daily injections of insulin provide
lifesaving benefits to millions
of diabetics. But currently available prandial insulins are suboptimal:
The onset of action is delayed by slow dissociation of the insulin
hexamer in the subcutaneous space, and insulin forms amyloid fibrils
upon storage in solution. Here we show, through the use of noncanonical
amino acid mutagenesis, that replacement of the proline residue at
position 28 of the insulin B-chain (ProB28) by (4S)-hydroxyproline (Hzp) yields an active form of insulin that dissociates
more rapidly, and fibrillates more slowly, than the wild-type protein.
Crystal structures of dimeric and hexameric insulin preparations suggest
that a hydrogen bond between the hydroxyl group of Hzp and a backbone
amide carbonyl positioned across the dimer interface may be responsible
for the altered behavior. The effects of hydroxylation are stereospecific;
replacement of ProB28 by (4R)-hydroxyproline (Hyp)
causes little change in the rates of fibrillation and hexamer disassociation.
These results demonstrate a new approach that fuses the concepts of
medicinal chemistry and protein design, and paves the way to further
engineering of insulin and other therapeutic proteins.