Conformational studies of an undecapeptide reproducing the consensus sequence around the cleavage site of the RXVRG endoprotease from Xenopus laevis skin.
Biopolymers 1994;
34:1419-31. [PMID:
7948725 DOI:
10.1002/bip.360341013]
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Abstract
Two synthetic fragments, corresponding to the 4-9 and 4-14 sequences of a tetradecapeptide used as a model to test the RXVRG-endoprotease activity from Xenopus laevis skin, have been studied by two-dimensional nmr spectroscopies, correlated spectroscopy, and nuclear Overhauser effect (NOE) spectroscopy. Both peptides wore the 5-9 consensus sequence found in several hormonal precursors. The nmr data for the 4-9 hexapeptide did not indicate any particular organization, either in water or in dimethylsulfoxide (DMSO), whereas, the 4-14 undecapeptide, a substrate for the RXVRG endoprotease, showed, in DMSO solution, significant trends of structural organization involving the amino acids pertaining to the consensus domain. From variations of integrated NOE peaks with temperature, the apparent interproton correlation times tau c were estimated and the maxima observed with Val7, the central residue in the consensus sequence. A defined tertiary structure in that domain was also supported by medium- and long-range NOEs between Asp6 and Arg8, Glu4 and Gly9, and by the likely involvement of Arg8 and Gly9 NHs in intramolecular hydrogen bonds. Most of these observations could be rationalized by an equilibrium between a 5-8 beta-turn and a 9 > 4 H-bonded loop. The predominance of one rotamer for the C alpha-C beta bond was established in four residues. Finally, the average phi and psi angles were derived from two models taking, or not, into account variations in the correlation times along the sequence. This allowed us to discuss the artefacts generated by using an average correlation time through the whole molecule.
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