Ribonuclease T1: Struktur, Funktion und Stabilität

Osmium Tag for Post-transcriptionally Modified RNA

5-Methylcytidine (m⁵ C) and 5-methyluridine (m⁵ U) are highly abundant post-transcriptionally modified nucleotides that are observed in various natural RNAs. Such nucleotides were labeled through a chemical approach, as both underwent oxidation at the C5=C6 double bond, leading to the formation of osmium-bipyridine complexes, which could be identified by mass spectrometry. This osmium tag made it possible to distinguished m⁵ C and m⁵ U from their isomers, 2'-O-methylcytidine and 2'-O-methyluridine, respectively. Queuosine and 2-methylthio-N⁶ -isopentenyladenosine in tRNA were also tagged through complex formation.

Polymerase-Mediated Site-Specific Incorporation of a Synthetic Fluorescent Isomorphic G Surrogate into RNA

An enzyme-mediated approach for the assembly of singly modified RNA constructs in which specific G residues are replaced with th G, an emissive isomorphic G surrogate, is reported. Transcription in the presence of th G and native nucleoside triphosphates enforces initiation with the unnatural analogue, yielding 5'-end modified transcripts that can be mono-phosphorylated and ligated to provide longer site-specifically modified RNA constructs. The scope of this unprecedented enzymatic approach to non-canonical purine-containing RNAs is explored via the assembly of several altered hammerhead (HH) ribozymes and a singly modified HH substrate. By strategically modifying key positions, a mechanistic insight into the ribozyme-mediated cleavage is gained. Additionally, the emissive features of the modified nucleoside and its responsiveness to environmental changes can be used to monitor cleavage in real time by steady state fluorescence spectroscopy.

Studying salt effects on protein stability using ribonuclease t1 as a model system

Salt ions affect protein stability in a variety of ways. In general, these effects have either been interpreted from a charge solvation/charge screening standpoint or they have been considered to be the result of ion-specific interactions with a particular protein. Recent theoretical work suggests that a major contribution to salt effects on proteins is through the interaction of salt ions that are located near the protein surface and their induced point image charges that are located in the low-dielectric protein cavity. These interactions form the basis of "salting-out" interactions. Salt ions induce an image charge of the same sign in the low dielectric protein medium. The interaction between the induced charge and its mirror charge is repulsive and consequently thermodynamically destabilizing. However, a folded protein that has a much smaller surface area will be less destabilized than the unfolded state. Consequently, the folded state will be stabilized relative to the unfolded state. This work analyzes salt effects in the model enzyme ribonuclease t1, and demonstrates that interactions between salt ions and their induced point charges provide a major contribution to the observed salt-induced increase in protein stability. This work also demonstrates that in the case of weakly-binding ions (ions with binding constants that are in the order of 50 M(-1) and less), salting-out effects should still be considered in order to provide a more realistic interpretation of ion binding. These results should therefore be considered when salt effects are used to analyze electrostatic contributions to protein structure or are used to study the thermodynamics of proteins associated with halophillic organisms.

Activating an Enzyme by an Engineered Coiled Coil Switch

We designed a de novo protein based on a circular permutant of RNaseT1, in which the enzymatic activity can be manipulated by engineered peptide binding. The circular permutant of RNaseT1 was obtained by tethering the original C- and N-termini with a GPAG linker and cleaving the molecule between Glu82 and Asn83. This mutant lacked enzymatic activity, due to the destabilization of entire protein structure. We previously reported the construction of ABC-type heterotrimeric coiled coil peptides, in which the A- and B-type peptides cannot form the folded trimeric structure without the C-type peptide. The introduction of the A- and B-type coiled coil peptides to the C- and N-termini of the circular permutant of RNaseT1, respectively, and the subsequent addition of the C-type coiled coil peptide enabled the RNaseT1 domain to refold properly, thus, restoring the enzymatic activity. The formation of the trimeric coiled coil structure should bring the cleaved sites of RNaseT1 close enough to refold the RNaseT1 domain spontaneously.

Conformation of thermally denatured RNase T1 with intact disulfide bonds: a study by small-angle X-ray scattering

Small-angle X-ray scattering of RNase T1 with intact disulfide bonds was measured at 20 degrees and 60 degrees C in order to get insight into the structural changes of the protein caused by thermal denaturation. The radius of gyration increases from R(G)= 1.43 nm to R(G) = 2.21 nm. The conformations of the molecules at 60 degrees C are similar to those of ring-shaped random walk chains. However, the molecules are more compact than one would expect under theta conditions due to attractive interactions between the chain segments. The volume needed for free rotation of the thermally unfolded protein molecules about any axis in solution is five times greater than in the native state whereas the hydrodynamic effective volume is increasing only two times.

Limits of NMR structure determination using variable target function calculations: ribonuclease T1, a case study

Limits of NMR structure determination using multidimensional NMR spectroscopy, variable target function calculations and relaxation matrix analysis were explored using the model protein ribonuclease T1 (RNase T1). The enzyme consists of 104 amino acid residues and has a molecular mass of approximately 11 kDa. Primary experimental data comprise 1856 assigned NOE intensities, 493 3J coupling constants and 62 values of amid proton exchange rates. From these data, 2580 distance bounds, 168 allowed ranges for torsional angles and stereospecific assignments for 75% of beta-methylene protons as well as for 80% of diastereotopic methyl groups were derived. Whenever possible, the distance restraints were refined in a relaxation matrix analysis including amid proton exchange data for improvement of lower distance limits. Description of side-chain conformations were based on various models of motional averaging of 3J coupling constants. The final structure ensemble was selected from the starting ensemble comparing the global precision of structures with order parameters derived from 15N relaxation time measurements. Significant differences between the structure of RNase T1 in solution and in the crystal became apparent from a comparison of the two highly resolved structures.

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.

Conformation of valine side chains in ribonuclease T1 determined by NMR studies of homonuclear and heteronuclear 3J coupling constants

A conformational analysis of the valine side chains of ribonuclease T1 (RNase T1) was performed using NMR spectroscopy, in particular homonuclear (1H, 1H and 13C, 13C) and heteronuclear (1H, 15N and 1H, 13C) vicinal spin-spin coupling constants as obtained from E.COSY-type NMR experiments. The coupling constants related to the chi 1 dihedral angle in valine, 3JH alpha H beta, 3JNH beta, 3JC'H beta, 3JH alpha C gamma 1, 3JH alpha C gamma 2, 3JC'C gamma 1, and 3JC'C gamma 2, were evaluated in a quantitative manner. The analysis of 3J data allowed for the stereospecific assignment of the valine methyl resonances. On the basis of various models for motional averaging of coupling constants, a fit of the torsion angles chi 1 to a set of the experimental 3J coupling constants (3JH alpha H beta, 3JNH beta, 3JC'H beta) was carried out. The resulting side-chain conformations were examined with respect to NOE distance informations. Single rotameric states emerged for Val16, Val67, Val79, and Val101, while conformational equilibria between staggered rotamers were found for Val33 and Val78. Using a different model approach, Val52 and Val89 are also likely to exhibit unimodal chi 1 angle distributions. The analysis was found to depend critically on the set of Karplus parameters used. Except for Val52 and Val78, the predominant rotamers obtained from 3J coupling informations agree with the conformation in the crystal structure of ribonuclease T1 (Martinez-Oyanedel et al., 1991).