X-ray crystallographic and calorimetric studies of the effects of the mutation Trp59-->Tyr in ribonuclease T1

Purine activity of RNase T1RV is further improved by substitution of Trp59 by tyrosine

Ribonuclease T1 is an enzyme that cleaves single-stranded RNA with high specificity after guanylyl residues. Although this enzyme is a very good characterized protein with respect to structure and enzymatic function, we were only recently successful in generating RNase T1-RV, a variant where the specificity was changed from guanine to purine. As this change of substrate specificity was made at the cost of activity, the aim was now to further improve the overall activity of the enzyme. Therefore, we have substituted the tryptophan in position 59 by tyrosine. This substitution led to an increase of enzymatic activity in comparison to variant RV to 425%. As the extent of this enhancement is unique so far we have crystallized and analyzed the structure of this variant in order to get more insights into the reasons for this. Here, we present the crystal structure of this so-called RNase T1-R2 at 2.1A resolution. The structure was determined by molecular replacement using the coordinates of the RV variant (PDB entry: 1Q9E). The data were refined to an R-factor of 18.7% and R(free) of 24%, respectively. The asymmetric unit contains three molecules and the crystal packing is very similar to that of variant RV.

Effect of surface hydrophobicity distribution on retention of ribonucleases in hydrophobic interaction chromatography

The effect of surface hydrophobicity distribution of proteins on retention in hydrophobic interaction chromatography (HIC) was investigated. Average surface hydrophobicity as well as hydrophobic contact area between protein and matrix were estimated using a classical thermodynamic model. The applicability of the model to predict protein retention in HIC was investigated on ribonucleases with similar average surface hydrophobicity but different surface hydrophobicity distribution. It was shown experimentally that surface hydrophobicity distribution could have an important effect on protein retention in HIC. The parameter "hydrophobic contact area," which comes from the thermodynamic model, was able to represent well the protein retention in HIC with salt gradient elution. Location and size of the hydrophobic patches can therefore have an important effect on protein retention in HIC, and the hydrophobic contact area adequately describes this.

Analysis of a water mediated protein-protein interactions within RNase T1

Buried and well-ordered solvent molecules are an integral part of each folded protein. For a few individual water molecules, the exchange kinetics with solvent have been described in great detail. So far, little is known about the energetics of this exchange process. Here, we present an experimental approach to investigate water-mediated intramolecular protein-protein interactions by use of double mutant cycles. As a first example, we analyzed the interdependence of the contribution of two side chains (Asn9 and Thr93) to the conformational stability of RNase T1. In the folded state, both side chains are involved in the "solvation of the same water molecule WAT1. The coupling of the contributions of Asn9 and Thr93 to the conformational stability of RNase T1 was measured by urea unfolding and differential scanning calorimetry. The structural integrity of each mutant was analyzed by X-ray crystallography. We find that the effects of the Asn9Ala and the Thr93Ala mutations on the conformational stability are additive in the corresponding double mutant. We conclude that the free energy of the WAT1 mediated intramolecular protein-protein interaction in the folded state is very similar to solvent mediated protein-protein interaction in the unfolded state.

Structural analysis of an RNase T1 variant with an altered guanine binding segment

The ribonuclease T1 variant 9/5 with a guanine recognition segment, altered from the wild-type amino acid sequence 41-KYNNYE-46 to 41-EFRNWQ-46, has been cocrystallised with the specific inhibitor 2'-GMP. The crystal structure has been refined to a crystallographic R factor of 0.198 at 2.3 A resolution. Despite a size reduction of the binding pocket, pushing the inhibitor outside by 1 A, 2'-GMP is fixed to the primary recognition site due to increased aromatic stacking interactions. The phosphate group of 2'-GMP is located about 4.2 A apart from its position in wild-type ribonuclease T1-2'-GMP complexes, allowing a Ca(2+), coordinating this phosphate group, to enter the binding pocket. The crystallographic data can be aligned with the kinetic characterisation of the variant, showing a reduction of both, guanine affinity and turnover rate. The presence of Ca(2+) was shown to inhibit variant 9/5 and wild-type enzyme to nearly the same extent.

Thermally induced hydrogen exchange processes in small proteins as seen by FTIR spectroscopy

Fourier-transform infrared (FTIR) spectroscopy has been used to study the thermally induced exchange characteristics of those backbone amide protons which persist H-D exchange at ambient conditions in ribonuclease A, in wild type ribonuclease T1 and some of its variants, and in the histone-like protein HBsu. The H-D exchange processes were induced by increasing the thermal energy of the protein solutions in two ways: (i) by linearly increasing the temperature, and (ii) by a temperature jump. To trace the H-D exchange in the proteins, various infrared absorption bands known to be sensitive to H-D exchange were used as specific monitors. Characteristic H-D exchange curves were obtained from which the endpoints (TH/D) of H-D exchange could be determined. The H-D exchange curves, the TH/D-values and the phase transition temperatures Tm were used to estimate the structural flexibility and stability of the given proteins. It is suggested that time-resolved FTIR spectroscopy can be used to determine global stability parameters of proteins.

Calorimetric investigation of thermal stability and ligand-binding characteristics of disulfide-bond-cleaved ribonuclease T1

A combination of differential titration calorimetry and differential scanning calorimetry was used to study the effect of disulfide bond cleavage and reaction with iodoacetamide of ribonuclease T1 on both the binding of nucleotides and the thermal stability of the free enzyme species. Although guanosine monophosphates still bind to the active site of the modified protein the transition temperature of unfolding and the transition enthalpy decrease drastically indicating a relatively loose structure. The calorimetric data presented in this study suggest a cooperative linkage between the site of the disulfide bonds, the ligand-binding site, and the general thermodynamic stability of the enzyme.