Dg. Mccafferty et al., ENGINEERING OF A 129-RESIDUE TRIPOD PROTEIN BY CHEMOSELECTIVE LIGATION OF PROLINE-II HELICES, Tetrahedron, 51(36), 1995, pp. 9859-9872
A 129-residue tripod protein was designed, synthesized, and biophysica
lly characterized. This receptor-adhesive modular protein contained th
ree 30-residue proline-II helices linked to a 9-residue proline-II hel
ix through thioether bonds. Coupling of 6-maleimidohexanoic acid succi
nimido ester to cis-N-alpha-Boc-4-amino-L-proline furnished in 77% yie
ld the maleimido ac id cis-N-Boc-4-(6-maleimidohexanamido)-L-proline (
Boc-Prm), which was used in the solid-phase synthesis of the linker pe
ptide CH3-CO-Pro(3)-Prm(3)-Pro(3)-NH2. The leg peptide, the 40-residue
thiol y-Arg-Gly-Asp-Ser-Pro-Gly-Tyr-Gly-Pro(30)-Cys-NH2, was also mad
e by solid-phase synthesis. The tripod protein was prepared by Michael
addition of the thiol groups of three leg peptides to the three malei
mide groups of the linker peptide. By C-13 NMR spectrometry, the linke
r peptide was a proline-II helix, as indicated by the presence of only
trans Pro-Pro resonances for its beta and gamma carbons. By circular
dichroic spectroscopy, the model peptide CH3-CO-Pro(9)-NH2, the linker
peptide, the leg peptide, and the tripod protein each contained subst
antial proline-II helix, as indicated by a strong negative band at 205
nm and a weak positive band at 226 nm. Since the Pro(30) proline-II h
elix of each leg is about 93 Angstrom long, two Arg-Gly-Asp sites on d
ifferent legs of the tripod protein could be as much as similar to 250
Angstrom apart.