Bovine pancreatic ribonuclease became a common model system in the study of proteins largely because it was extremely stable and could be purified in large quantities. In the 1940s Armour and Company purified a kilogram of protein - a very large quantity, particularly by the protein purification standards of the time - and offered samples at low cost to interested scientists.[4] The ability to have a single lot of purified enzyme made it a predominant model system for protein studies. It remains commonly referred to as ribonuclease A or RNase A as the most prominent member of its protein family, known variously as pancreatic ribonuclease, ribonuclease A, or ribonuclease I.
RNase A was the first enzyme for which a correct catalytic mechanism was proposed, even before its structure was known.[6] RNase A was the first protein for showing the effects of non-native isomers of peptide bonds preceding proline residues in protein folding.[7]
Bovine pancreatic ribonuclease was also the model protein used to work out many spectroscopic methods for assaying protein structure, including absorbance, circular dichroism, Raman, electron paramagnetic resonance (EPR) and nuclear magnetic resonance (NMR) spectroscopy. It was the first model protein for the development of chemical methods for the study of proteins, such as chemical modification of exposed side chains, antigenic recognition, and limited proteolysis of disordered segments. Ribonuclease S, which is RNase A that has been treated with the proteasesubtilisin, was the third protein to have its crystallographic structure solved, in 1967.[8]
Structure and properties
RNase A is a relatively small protein (124 residues, ~13.7 kDa). It can be characterized as a two-layer protein with a deep cleft for binding the RNA substrate. The first layer is composed of three alpha helices (residues 3-13, 24-34 and 50-60) from the N-terminal half of the protein. The second layer consist of three β-hairpins (residues 61-74, 79-104 and 105-124 from the C-terminal half) arranged in two β-sheets. The hairpins 61-74 and 105-124 form a four-stranded, antiparallel β-sheet that lies on helix 3 (residues 50-60). The longest β-hairpin 79-104 mates with a short β-strand (residues 42-45) to form a three-stranded, antiparallel β-sheet that lies on helix 2 (residues 24-34).
RNase A has four disulfide bonds in its native state: Cys26-Cys84, Cys58-110, Cys40-95 and Cys65-72. The first two (26-84 and 58-110) are essential for conformational folding; each joins an alpha helix of the first layer to a beta sheet of the second layer, forming a small hydrophobic core in its vicinity. The latter two disulfide bonds (40-95 and 65-72) are less essential for folding; either one can be reduced (but not both) without affecting the native structure under physiological conditions. These disulfide bonds connect loop segments and are relatively exposed to solvent. The 65-72 disulfide bond has an extraordinarily high propensity to form, significantly more than would be expected from its loop entropy, both as a peptide and in the full-length protein. This suggests that the 61-74 β-hairpin has a high propensity to fold conformationally.
RNase A is a basic protein (pI = 9.63); its many positive charges are consistent with its binding to RNA (a poly-anion). More generally, RNase A is unusually polar or, rather, unusually lacking in hydrophobic groups, especially aliphatic ones. This may account for its need of four disulfide bonds to stabilize its structure.
The low hydrophobic content may also serve to reduce the physical repulsion between highly charged groups (its own and those of its substrate RNA) and regions of low dielectric constant (the nonpolar residues).
The N-terminal α-helix of RNase A (residues 3-13) is connected to the rest of RNase A by a flexible linker (residues 16-23). As shown by F. M. Richards, this linker may be cleaved by subtilisin between residues 20 and 21 without causing the N-terminal helix to dissociate from the rest of RNase A. The peptide-protein complex is called "RNase S", the peptide (residues 1-20) is called the "S-peptide" and the remainder (residues 21-124) is called the "S-protein". The dissociation constant of the S-peptide for the S-protein is roughly 30 pM; this tight binding can be exploited for protein purification by attaching the S-peptide to the protein of interest and passing a mixture over an affinity column with bound S-protein. [A smaller C-peptide (residues 1-13) also works.] The RNase S model system has also been used for studying protein folding by coupling folding and association. The S-peptide was the first peptide from a native protein shown to have (flickering) secondary structure in isolation (by Klee and Brown in 1967).
RNase A cleaves specifically after pyrimidine nucleotides.[9] Cleavage takes place in two steps: first, the 3’,5’-phosphodiester bond is cleaved to generate a 2’,3’-cyclic phosphodiester intermediate; second, the cyclic phosphodiester is hydrolyzed to a 3’-monophosphate.[10] It can be inhibited by ribonuclease inhibitor protein, by heavy metal ions, and by uridine-vanadate complexes.[10]
Enzymatic mechanism
The positive charges of RNase A lie mainly in a deep cleft between two lobes. The RNA substrate lies in this cleft and is cleaved by two catalytic histidine residues, His12 and His119, to form a 2',3'-cyclic phosphate intermediate that is stabilized by nearby Lys41.
Kartha, G.; Bello, J.; Harker, D. (1967). Tertiary Structure of Ribonuclease. Boston: Nature. ISBN0-12-588945-3.
Scheraga HA, Wedemeyer WJ, Welker E (2001). "Bovine Pancreatic Ribonuclease A: Oxidative and Conformational Folding Studies". Ribonucleases - Part A. Methods in Enzymology. Vol. 341. pp. 189–221. doi:10.1016/S0076-6879(01)41153-0. ISBN9780121822422. PMID11582778.