User:R. Jeremy Johnson/RNaseA: Difference between revisions

RNase A is made up of a single polypeptide chain of 124 residues. Of the 20 natural amino acids, RNase A possesses 19 of them, excluding tryptophan. This single polypeptide chain is cross-linked internally by four disulfide linkages, which contribute to the stability of RNase A. Long four-stranded anti-parallel <scene name='Sandbox_Reserved_192/Beta_sheet/4'>ß-sheets</scene> and three short <scene name='Sandbox_Reserved_192/Alpha_helices/2'>α-helices</scene> make up the <scene name='Sandbox_Reserved_192/Secondary_structure/3'>secondary structure</scene> of RNase A (Raines). The amino acid sequence was discovered to determine the three-dimensional structure of RNase A by Christian Anfinsen in the 1950s. Urea was used to denature RNase A, and mercaptoethanol was used to reduce and cleave the four disulfide bonds in RNase A to yield eight Cys residues. Catalytic activity was lost due to denaturation. When the urea and mercaptoethanol were removed, the denatured ribonuclease refolded spontaneously into its correct tertiary structure with restoration of its catalytic activity. Disulfide bonds were also reformed in the same position. The Anfinsen experiment provided evidence that the amino acid sequence contained all the information required for the protein to fold into its native three-dimensional structure. Anfinsen received the 1972 Nobel Prize in Chemistry for his work with RNase A. Nevertheless, ensuing work showed some proteins require further assistance, such as molecular chaperones, to fold into their native structure.