Synthesis and NMR spectroscopy of peptides containing either phosphorylated or phosphonylated cis- or trans-4-hydroxy-L-proline

Characterization of O-phosphohydroxyproline in rat {alpha}-crystallin A

Post-translational modifications have major importance for the structure and function of a multiplicity of proteins. Phosphorylation is a widespread phenomenon among eukaryotic proteins. Whereas O-phosphorylation on the side chains of serine, threonine, and tyrosine in proteins is well known and has been studied extensively, to our knowledge the endogenous phosphorylation of hydroxyproline has not previously been reported. In the present work, we provide evidence for the first time that O-phosphohydroxyproline (Hyp(P)) is a proteinogenic amino acid. To detect Hyp(P) in proteins we generated a Hyp(P)-specific polyclonal antibody. We could identify Hyp(P) in various proteins by Western blot analysis, and we characterized the sequence position of Hyp(P) in the protein α-crystallin A by electrospray ionization-tandem mass spectrometry. Our experiments clearly demonstrate hydroxylation and subsequent phosphorylation of a proline residue in α-crystallin A in the eye as well as in heart tissue of rat.

Synthesis and characterization of a collagen model delta-O-phosphohydroxylysine-containing peptide

The existence of delta-O-phosphohydroxylysine (HylP) residues in collagen has been reported. However, such phosphorylated residues have not been isolated nor has their location within the protein sequence been identified. To develop the analytical chemistry necessary for the identification of HylP in proteins, a model HylP-containing peptide, Phe-dl-HylP-Gly-Gln-Pro-Ala-Ile-Gly-Phe (I), was synthesized. The peptide was assembled using 9-fluorenylmethyloxycarbonyl (Fmoc)-based solid-phase synthesis; N(alpha)-Fmoc-dl-hydroxy-dl-Lys(N(epsilon)-tert-butyloxycarbonyl)-OH was used to incorporate Hyl, and global phosphitylation/oxidation was used to introduce the phosphate group. The pK(a2) of the phosphate group, as determined using 31P NMR, was 5.6. Phosphoamino acid analysis of I was performed using either dabsyl chloride or phenylisothiocyanate derivatization followed by microbore reversed-phase HPLC separation of N(alpha, epsilon)-didabsyl-HylP or N(alpha, epsilon)-diphenylthiocarbamyl-HylP. HylP was found to be relatively resistant to acid hydrolysis, allowing for its quantitation. Solid-phase Edman degradation of I was used for positive identification of N(alpha)-phenylthiohydantoin-N(epsilon)-phenylthiocarbamyl-HylP. The masses of the phenylthiohydantoin and dabsyl derivatives of HylP were confirmed by electrospray ionization triple-quadrupole (ESI-MS). Peptide I was positively identified as a phosphopeptide by ESI-MS/precursor-ion scanning. Low-energy ESI-MS/MS confirmed the position of HylP within the sequence of I. Phosphorylation of Hyl led to complete resistance of I to lysine-specific endopeptidases.

1H-NMR parameters of common amino acid residues measured in aqueous solutions of the linear tetrapeptides Gly-Gly-X-Ala at pressures between 0.1 and 200 MPa

For the interpretation of chemical shift changes induced by pressure in proteins, a comparison with random-coil data is important. For providing such a data basis, the pressure dependence of the 1H-NMR chemical shifts of the amino acids X in the random-coil model peptides Gly-Gly-X-Ala were studied for the 20 common amino acids at two pH values (pH 5.0 and 5.4) at 305 K, in the pressure range from 0.1 to 200 MPa. The largest shift changes deltadelta with pressure p can be observed for the backbone amide protons. The average linear pressure coefficient delta(deltap) is 0.38 ppm GPa(-1), with a root mean square deviation of 0.2 ppm GPa(-1). In contrast to the downfield shift typical for amide protons, the H(alpha)-resonances typically shift upfield, with a pressure coefficient of -0.025 ppm GPa(-1) and a root mean square deviation of 0.05 ppm GPa(-1). The side chain resonances are only weakly influenced by pressure, on average they are shifted by 0.014 ppm GPa(-1)) with a root mean square deviation of 0.14 ppm GPa(-1). The exceptions are the side chain amide protons of asparagine and glutamine. Here, values of 0.214 (Asn H(delta21)), 0.417 (Asn H(delta22)), 0.260 (Gln H(varepsilon21)) and 0.395 (Gln H(varepsilon22)) ppm GPa(-1) can be observed. In both cases, the pressure dependent shift is larger for the pro-E proton than for the pro-Z proton. Within the limits of error the equilibrium constant for the trans- and cis-conformers at the proline peptide bond is independent of pressure in the pressure range studied.