Abstract
A protected linear polypeptide of 124 amino acid residues with the sequence of bovine pancreatic ribonuclease A was synthesized by the solid phase method. The polypeptide was removed from the solid support and purified, and the four disulfide bonds were closed by air oxidation of the reduced form. The synthetic enzyme was fractionated by gel filtration and ion exchange chromatography, and the material that eluted at the same position as natural reduced-reoxidized RNase A was isolated. The product was further purified by incubation with trypsin and removal of the enzymically degraded components. A fractional precipitation with (NH4)2·SO4 gave a purified synthetic RNase A with a specific activity of 78%. The synthetic RNase A was indistinguishable from natural bovine pancreatic RNase A by gel filtration on Sephadex G-75, by chromatography on carboxymethylcellulose, and by electrophoresis. Amino acid analyses, peptide maps of tryptic digests, and the Michaelis constant agreed well with those of the natural enzyme. The synthetic enzyme showed the high substrate specificity to be expected of RNase A. It was highly active against yeast RNA and 2', 3'-cyclic cytidine phosphate and was completely inactive toward DNA, 2', 3'-cyclic guanosine phosphate, and the dinucleotides 5'-(3'-guanylyl)-cytidylic acid and 5'-(3'-adenylyl)-adenylic acid. During the synthesis, samples were removed after 99 and 104 residues had been coupled and the corresponding polypeptides, des-(21-25)S-protein and S-protein, were isolated. They were then reduced and reoxidized in the presence of natural or synthetic S-peptide to give RNase S and des-(21-25)RNase S. The specific activities of the two products were approximately equal, thus indicating that the five NH2-terminal residues of S-protein are not required for the protein to oxidize and fold in the presence of S-peptide to give an active enzyme.
Highlights
The successful synthesis of ribonuclease A by the solid phase method required that there be enough space within the resin beads to accommodate a protected polypeptide of 19,791 molecular weight (Fig. 1)
A new and independent kind of evidence is provided for the view that the primary structure of a protein determines its tertiary structure
The original hypothesis (11,13) was based on the observation that native ribonuclease could be reduced and unfolded in urea and that upon removal of the urea and reoxidation in air it would spontaneously refold into its original conformation, would re-form the proper disulfide bonds, and would regenerate its full enzymic activity
Summary
A protected linear polypeptide of 124 amino acid residues with the sequence of bovine pancreatic ribonuclease A was synthesized by the solid phase method. Samples were removed after 99 and 104 residues had been coupled and the corresponding polypeptides, des-(Zl-25)S-protein and S-protein, were isolated. They were reduced and reoxidized in the presence of natural or synthetic S-peptide to give RNase S and des(21-25)RNase S. Ribonuclease A was selected because it was a relatively small, stable, crystalline protein which had been studied in great detail in many laboratories (l-3) Both its linear amino acid sequence (4-8) and its crystallographic structure (9, 10) were known. The details of our original synthesis together with some further findings are described here
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