NMR studies of model peptides of PHGGGWGQ repeats within the N-terminus of prion proteins: a loop conformation with histidine and tryptophan in close proximity.

The N-terminal region of the prion protein from human and mouse contains five tandem repeats with the consensus sequence of PHGGGWGQ. NMR studies were performed in water for two cyclic peptides, cyclo-[C(1)R(2)Q(3)P(4)H(5)G(6)G(7)S(8)W(9)G(10)Q(11)R(12)D(13)C(14)] (C1) and cyclo-[C(1)R(2)D(3)P(4)H(5)G(6)G(7)G(8)W(9)G(10)Q(11)P(12)H(13)G(14)G (15)G(16)W(17)G(18)Q(19)R(20)D(21)C(22)] (C2), which are cyclized by a disulfide bridge between the Cys residues at the N- and C-termini, and for their corresponding linear peptides (L1 and L2) which are formed by reduction. The patterns of the C(alpha)H chemical shift difference of these four peptide mimetics were very similar to those observed for the tandem repeats of human prion protein reported by other researchers. The medium-range NOE connectivities were found between the C(beta)H of the H5 and the proton of the W9 side chain for L1. The corresponding NOEs were also observed in H5-W9 and H13-W17 of L2 with ambiguity. These observations indicate that histidine (i) is in close proximity to tryptophan (i+4). d(alphaN) (i,i+2) NOE connectivities were observed between W9 and Q11 of L1 and L2, and d(NN) (i,i+1) NOE connectivities were also observed for G10-Q11 of L1 and L2 and for G18-Q19 of L2. Significantly lower temperature coefficients of amide proton chemical shifts were obtained for Q11 and Q19 of L2 and C2. Structure calculations for L1 showed that HGG(G/S)W and (G/S)WGQ adopt a loop conformation and a beta-turn, respectively. These results strongly suggest that the tandem repeats within prion protein adopt a non-random structure.