Folding Of Ribonuclease Research Articles

Comparative study on tertiary contacts and folding of RNase P RNAs from a psychrophilic, a mesophilic/radiation-resistant, and a thermophilic bacterium

In most bacterial type A RNase P RNAs (P RNAs), two major loop-helix tertiary contacts (L8–P4 and L18–P8) help to orient the two independently folding S- and C-domains for concerted recognition of precursor tRNA substrates. Here, we analyze the effects of mutations in these tertiary contacts in P RNAs from three different species: (i) the psychrophilic bacterium Pseudoalteromonas translucida (Ptr), (ii) the mesophilic radiation-resistant bacterium Deinococcus radiodurans (Dra), and (iii) the thermophilic bacterium Thermus thermophilus (Tth). We show by UV melting experiments that simultaneous disruption of these two interdomain contacts has a stabilizing effect on all three P RNAs. This can be inferred from reduced RNA unfolding at lower temperatures and a more concerted unfolding at higher temperatures. Thus, when the two domains tightly interact via the tertiary contacts, one domain facilitates structural transitions in the other. P RNA mutants with disrupted interdomain contacts showed severe kinetic defects that were most pronounced upon simultaneous disruption of the L8–P4 and L18–P8 contacts. At 37°C, the mildest effects were observed for the thermostable Tth RNA. A third interdomain contact, L9–P1, makes only a minor contribution to P RNA tertiary folding. Furthermore, D. radiodurans RNase P RNA forms an additional pseudoknot structure between the P9 and P12 of its S-domain. This interaction was found to be particularly crucial for RNase P holoenzyme activity at near-physiological Mg2+ concentrations (2 mM). We further analyzed an exceptionally stable folding trap of the G,C-rich Tth P RNA.

Evidence for the sequential folding mechanism in RNase H from an ensemble-based model.

The number of distinct protein folding pathways starting from an unfolded ensemble, and hence, the folding mechanism is an intricate function of protein size, sequence complexity, and stability conditions. This has traditionally been a contentious issue particularly because of the ensemble nature of conventional experiments that can mask the complexity of the underlying folding landscape. Recent hydrogen-exchange experiments combined with mass spectrometry (HX-MS) reveal that the folding of RNase H proceeds in a hierarchical fashion with distinct intermediates and following a single discrete path. In our current work, we provide computational evidence for this unique folding mechanism by employing a structure-based statistical mechanical model. Upon calibrating the energetic terms of the model with equilibrium measurements, we predict multiple intermediate states in the folding of RNase H that closely resemble experimental observations. Remarkably, a simplified landscape representation adequately captures the folding complexity and predicts the possibility of a well-defined sequence of folding events. We supplement the statistical model study with both explicit solvent molecular simulations of the helical units and electrostatic calculations to provide structural and energetic insights into the early and late stages of RNase H folding that hint at the frustrated nature of its folding landscape.

The Chaperonopathies - Diseases with Defective Molecular Chaperones

In the mid 1950's the Nobel Prize Laureate Christian B. Anfinsen from his research on the folding of ribonuclease A, began to concentrate on the problem of the relationship between structure and function in enzymes. On the basis of studies on ribonuclease, he proposed that the information determining the tertiary structure of a protein resides in the chemistry of its amino acid sequence....

Transient interactions of a slow‐folding protein with the Hsp70 chaperone machinery

Most known proteins have at least one local Hsp70 chaperone binding site. Does this mean that all proteins interact with Hsp70 as they fold? This study makes an initial step to address the above question by examining the interaction of the E.coli Hsp70 chaperone (known as DnaK) and its co-chaperones DnaJ and GrpE with a slow-folding E.coli substrate, RNase H(D). Importantly, this protein is a nonobligatory client, and it is able to fold in vitro even in the absence of chaperones. We employ stopped-flow mixing, chromatography, and activity assays to analyze the kinetic perturbations induced by DnaK/DnaJ/GrpE (K/J/E) on the folding of RNase H(D). We find that K/J/E slows down RNase H(D)'s apparent folding, consistent with the presence of transient chaperone-substrate interactions. However, kinetic retardation is moderate for this slow-folding client and it is expected to be even smaller for faster-folding substrates. Given that the interaction of folding-competent substrates such as RNase H(D) with the K/J/E chaperones is relatively short-lived, it does not significantly interfere with the timely production of folded biologically active substrate. The above mode of action is important because it preserves K/J/E bioavailability, enabling this chaperone system to act primarily by assisting the folding of other misfolded and (or) aggregation-prone cellular proteins that are unable to fold independently. When refolding is carried out in the presence of K/J and absence of the nucleotide exchange factor GrpE, some of the substrate population becomes trapped as a chaperone-bound partially unfolded state.

Using Enzyme Folding to Explore the Mechanism of Therapeutic Touch: A Feasibility Study

The goal of this research is to design a novel model using protein folding to study Therapeutic Touch, a noncontact form of energy manipulation healing. Presented is a feasibility study suggesting that the denaturation path of ribonuclease A may be a useful model to study the energy exchange underlying therapeutic touch. The folding of ribonuclease A serves as a controlled energy-requiring system in which energy manipulation can be measured by the degree of folding achieved. A kinetic assay and fluorescence spectroscopy are used to assess the enzyme-folding state. The data suggest that the kinetic assay is a useful means of assessing the degree of refolding, and specifically, the enzyme function. However, fluorescence spectroscopy was not shown to be an effective measurement of enzyme structure for the purposes of this work. More research is needed to assess the underlying mechanism of therapeutic touch to complement the existing studies. An enzyme-folding model may provide a useful means of studying the energy exchange in therapeutic touch.

The effect of additional disulfide bonds on the stability and folding of ribonuclease A

The significant contribution of disulfide bonds to the conformational stability of proteins is generally considered to result from an entropic destabilization of the unfolded state causing a faster escape of the molecules to the native state. However, the introduction of extra disulfide bonds into proteins as a general approach to protein stabilization yields rather inconsistent results. By modeling studies, we selected positions to introduce additional disulfide bonds into ribonuclease A at regions that had proven to be crucial for the initiation of the folding or unfolding process, respectively. However, only two out of the six variants proved to be more stable than unmodified ribonuclease A. The comparison of the thermodynamic and kinetic data disclosed a more pronounced effect on the unfolding reaction for all variants regardless of the position of the extra disulfide bond. Native-state proteolysis indicated a perturbation of the native state of the destabilized variants that obviously counterbalances the stability gain by the extra disulfide bond.

The Oxidase DsbA Folds a Protein with a Nonconsecutive Disulfide

One of the last unsolved problems of molecular biology is how the sequential amino acid information leads to a functional protein. Correct disulfide formation within a protein is hereby essential. We present periplasmic ribonuclease I (RNase I) from Escherichia coli as a new endogenous substrate for the study of oxidative protein folding. One of its four disulfides is between nonconsecutive cysteines. In general view, the folding of proteins with nonconsecutive disulfides requires the protein disulfide isomerase DsbC. In contrast, our study with RNase I shows that DsbA is a sufficient catalyst for correct disulfide formation in vivo and in vitro. DsbA is therefore more specific than generally assumed. Further, we show that the redox potential of the periplasm depends on the presence of glutathione and the Dsb proteins to maintain it at-165 mV. We determined the influence of this redox potential on the folding of RNase I. Under the more oxidizing conditions of dsb(-) strains, DsbC becomes necessary to correct non-native disulfides, but it cannot substitute for DsbA. Altogether, DsbA folds a protein with a nonconsecutive disulfide as long as no incorrect disulfides are formed.

Ultrarapid mixing experiments shed new light on the characteristics of the initial conformational ensemble during the folding of ribonuclease A

The earliest folding events in single-tryptophan mutants of RNase A were investigated by fluorescence measurements by using a combination of stopped-flow and continuous-flow mixing experiments covering the time range from 70 micros to 10 s. An ultrarapid double-jump mixing protocol was used to study refolding from an unfolded ensemble containing only native proline isomers. The continuous-flow measurements revealed a series of kinetic events on the submillisecond time scale that account for the burst-phase signal observed in previous stopped-flow experiments. An initial increase in fluorescence within the 70-micros dead time of the continuous-flow experiment is consistent with a relatively nonspecific collapse of the polypeptide chain whereas a subsequent decrease in fluorescence with a time constant of approximately 80 micros is indicative of a more specific structural event. These rapid conformational changes are not observed if RNase A is allowed to equilibrate under denaturing conditions, resulting in formation of nonnative proline isomers. Thus, contrary to previous expectations, the isomerization state of proline peptide bonds can have a major impact on the structural events during early stages of folding.

Small assemblies of unmodified amyloid β-protein are the proximate neurotoxin in Alzheimer’s disease

Pioneering work in the 1950s by Christian Anfinsen on the folding of ribonuclease has shown that the primary structure of a protein “encodes” all of the information necessary for a nascent polypeptide to fold into its native, physiologically active, three-dimensional conformation (for his classic review, see [Science 181 (1973) 223]). In Alzheimer’s disease (AD), the amyloid β-protein (Aβ) appears to play a seminal role in neuronal injury and death. Recent data have suggested that the proximate effectors of neurotoxicity are oligomeric Aβ assemblies. A fundamental question, of relevance both to the development of therapeutic strategies for AD and to understanding basic laws of protein folding, is how Aβ assembly state correlates with biological activity. Evidence suggests, as argued by Anfinsen, that the formation of toxic Aβ structures is an intrinsic feature of the peptide’s amino acid sequence—one requiring no post-translational modification or invocation of peptide-associated enzymatic activity.

Small assemblies of unmodified amyloid $beta;-protein are the proximate neurotoxin in Alzheimer?s disease

Pioneering work in the 1950s by Christian Anfinsen on the folding of ribonuclease has shown that the primary structure of a protein “encodes” all of the information necessary for a nascent polypeptide to fold into its native, physiologically active, three-dimensional conformation (for his classic review, see [Science 181 (1973) 223]). In Alzheimer’s disease (AD), the amyloid β-protein (Aβ) appears to play a seminal role in neuronal injury and death. Recent data have suggested that the proximate effectors of neurotoxicity are oligomeric Aβ assemblies. A fundamental question, of relevance both to the development of therapeutic strategies for AD and to understanding basic laws of protein folding, is how Aβ assembly state correlates with biological activity. Evidence suggests, as argued by Anfinsen, that the formation of toxic Aβ structures is an intrinsic feature of the peptide’s amino acid sequence—one requiring no post-translational modification or invocation of peptide-associated enzymatic activity.

Development of a novel method to populate native disulfide-bonded intermediates for structural characterization of proteins: implications for the mechanism of oxidative folding of RNase A.

RNase A, a model protein for oxidative folding studies, has four native disulfide bonds. The roles of des [40-95] and des [65-72], the two native-like structured three-disulfide-bonded intermediates populated between 8 and 25 degrees C during the oxidative folding of RNase A, are well characterized. Recent work focuses on both the formation of these structured disulfide intermediates from their unstructured precursors and on the subsequent oxidation of the structured species to form the native protein. The major obstacles in this work are the very low concentration of the precursor species and the difficulty of isolating some of the structured intermediates. Here, we demonstrate a novel method that enables the native disulfide-bonded intermediates to be populated and studied regardless of whether they have stable structure and/or are present at low concentrations during the oxidative folding or reductive unfolding process. The application of this method enabled us to populate and, in turn, study the key intermediates with two native disulfide bonds on the oxidative folding pathway of RNase A; it also facilitated the isolation of des [58-110] and des [26-84], the other two native-like structured des species whose isolation had thus far not been possible.

Atomic resolution structures of ribonuclease A at six pH values.

The diffraction pattern of protein crystals extending to atomic resolution guarantees a very accurate picture of the molecular structure and enables the study of subtle phenomena related to protein functionality. Six structures of bovine pancreatic ribonuclease at the pH* values 5.2, 5.9, 6.3, 7.1, 8.0 and 8.8 and at resolution limits in the range 1.05-1.15A have been refined. An overall description of the six structures and several aspects, mainly regarding pH-triggered conformational changes, are described here. Since subtle variations were expected, a thorough validation assessment of the six refined models was first carried out. Some stereochemical parameters, such as the N[bond]C(alpha)[bond]C angle and the pyramidalization at the carbonyl C atoms, indicate that the standard target values and their weights typically used in refinement may need revision. A detailed comparison of the six structures has provided experimental evidence on the role of Lys41 in catalysis. Furthermore, insights are given into the structural effects related to the pH-dependent binding of a sulfate anion, which mimics the phosphate group of RNA, in the active site. Finally, the results support a number of thermodynamic and kinetic experimental data concerning the role of the disulfide bridge between Cys65 and Cys72 in the folding of RNase A.

Structural determinants of oxidative folding in proteins.

A method for determining the kinetic fate of structured disulfide species (i.e., whether they are preferentially oxidized or reshuffle back to an unstructured disulfide species) is introduced. The method relies on the sensitivity of unstructured disulfide species to low concentrations of reducing agents. Because a structured des species that preferentially reshuffles generally first rearranges to an unstructured species, a small concentration of reduced DTT (e.g., 260 microM) suffices to distinguish on-pathway intermediates from dead-end species. We apply this method to the oxidative folding of bovine pancreatic ribonuclease A (RNase A) and show that des[40-95] and des[65-72] are productive intermediates, whereas des[26-84] and des[58-110] are metastable dead-end species that preferentially reshuffle. The key factor in determining the kinetic fate of these des species is the relative accessibility of both their thiol groups and disulfide bonds. Productive intermediates tend to be disulfide-secure, meaning that their structural fluctuations preferentially expose their thiol groups, while keeping their disulfide bonds buried. By contrast, dead-end species tend to be disulfide-insecure, in that their structural fluctuations expose their disulfide bonds in concert with their thiol groups. This distinction leads to four generic types of oxidative folding pathways. We combine these results with those of earlier studies to suggest a general three-stage model of oxidative folding of RNase A and other single-domain proteins with multiple disulfide bonds.

Temperature Induced Protein Unfolding and Folding of RNase a Studied by Time-Resolved Infrared Spectroscopy

When a protein finds its native three-dimensional structure from the unstructured amino-acid chain various processes spanning a large time range are relevant. To understand the mechanism of protein folding one needs to cover the entire folding/ refolding (U↔N) reaction on a structural level. In the case of RNase A, the main structural changes occur in the ms time range, that can be monitored with rapid-scan- FTIR spectroscopy combined with rapid mixing techniques. To induce unfolding we inject aqueous protein solution into a hot IR cuvette and record the time course of the spectral changes. A lag phase is found when the unfolding conditions are relatively weak, suggesting an unfolding intermediate.

Initial hydrophobic collapse is not necessary for folding RNase A

One of the main distinctions between different theories describing protein folding is the predicted sequence of secondary structure formation and compaction during the folding process. Whether secondary structure formation precedes compaction of the protein molecules or secondary structure formation is driven by a hydrophobic collapse cannot be decided unequivocally on the basis of existing experimental data. In this study, we investigate the refolding of chemically denatured, disulfide-intact ribonuclease A (RNase A) by monitoring compaction and secondary structure formation using stopped-flow dynamic light scattering and stopped-flow CD, respectively. Our data reveal the formation of a considerable amount of secondary structure early in the refolding of the slow folding species of RNase A without a significant compaction of the molecules. A simultaneous formation of secondary structure and compaction is observed in the subsequent rate-limiting step of folding. During folding of RNase A an initial global hydrophobicity is not observed, which contradicts the view that this is a general requirement for protein folding. This folding behavior could be typical of similar, moderately hydrophobic proteins.

Conformational study on proline-containing tripeptides of ribonuclease T1

In order to investigate the role of the cis/trans isomerization of the X-Pro peptide bonds in the folding of ribonuclease T 1 (RNase T 1 ), conformational free energy calculations using an empirical potential ECEPP/2 and the hydration shell model were carried out on the terminally blocked tripeptides Ac-Tyr-Pro-His-NHMe, Ac-Ser-Pro-Tyr-NHMe, Ac-Trp-Pro-Ile-NHMe, and Ac-Ser-Pro-Gly-NHMe and on related dipeptides in the unhydrated and hydrated states. These tripeptides correspond to residues 38-40, 5456, 59-61, and 72-74 of native RNase T 1 , respectively. The conformational entropy computed using a harmonic method was included in the free energy of each minimum in both states

Kinetic coupling between protein folding and prolyl isomerization: II. Folding of ribonuclease A and ribonuclease T 1

The folding and unfolding kinetics within the transition region were measured for RNase A and for RNase T 1. The data were used to evaluate the theoretical models for the influence of prolyl isomerization on the observed folding kinetics. These two proteins were selected, since the folding reaction of RNase A is faster than prolyl isomerization, wherease in RNase T 1, folding is slower than isomerization in the transition region. Folding of RNase T 1 was investigated for three variants with different numbers of cis prolyl residues. The results indicate that in the transition region the folding rates are indeed strongly dependent on the number of prolyl residues. The variant of RNase T 1 that contains only one cis prolyl residue folds about ten times faster than two variants that contain two cis prolyl residues. For both RNase A and RNase T 1, the apparent rates of folding and unfolding as well as the corresponding amplitudes depend on the concentration of denaturant in a manner that was predicted by the model calculations. When refolding was started from the fast-folding species, additional kinetic phases could be observed in the transition region for both proteins. The obtained values could be used to calculate the microscopic rate constants of folding and isomerization on the basis of theoretical models.

The mechanism of folding of pancreatic ribonucleases is independent of the presence of covalently linked carbohydrate.

The role of asparagine-linked oligosaccharides for the mechanism of protein folding was investigated. We compared the stability and folding kinetics for two sets of pancreatic ribonucleases (RNases) with identical amino acid sequences and differences in glycosylation. First the folding of RNases A (carbohydrate free) and B (a single N-linked oligosaccharide) from bovine pancreas was investigated. The kinetics of refolding were identical under a wide range of conditions. The rate of unfolding by guanidinium chloride was decreased in RNase B. In further experiments the folding of porcine RNase (three carbohydrate chains at Asn-21, -34, and -76) was compared with the corresponding data for the deglycosylated protein. Even for this RNase with almost 40% carbohydrate content the mechanism of refolding is independent of glycosylation. Although the folding mechanism is conserved, the rates of individual steps in folding are decreased about 2-fold upon deglycosylation. We interpret this to originate from a slight destabilization of folding intermediates by carbohydrate depletion. In control experiments with nonglycosylated bovine RNase A it was ascertained that treatment with HF (as used for deglycosylation) did not affect the folding kinetics. The in vitro folding mechanism of glycosylated RNases apparently does not depend on the presence of N-linked oligosaccharide chains. The information for the folding of glycoproteins is contained exclusively in the protein moiety, i.e. in the amino acid sequence. Carbohydrate chains are attached at chain positions which remain solvent exposed. This ensures that the presence of oligosaccharides does not interfere with correct folding of the polypeptide chain.

Amide proton exchange used to monitor the formation of a stable α-helix by residues 3 to 13 during folding of ribonuclease S

We make use of the known exchange rates of individual amide protons in the S-peptide moiety of ribonuclease S (RNAase S) to determine when during folding the α-helix formed by residues 3 to 13 becomes stable. The method is based on pulse-labeling with [ 3H]H 2O during the folding followed by an exchange-out step after folding that removes 3H from all amide protons of the S-peptide except from residues 7 to 14, after which S-peptide is separated rapidly from S-protein by high performance liquid chromatography. The slow-folding species of unfolded RNAase S are studied. Folding takes place in strongly native conditions (pH 6.0. 10 °C). The seven H-bonded amide protons of the 3–13 helix become stable to exchange at a late stage in folding at the same time as the tertiary structure of RNAase S is formed, as monitored by tyrosine absorbance. At this stage in folding, the isomerization reaction that creates the major slow-folding species has not yet been reversed. Our result for the 3–13 helix is consistent with the finding of Labhardt (1984), who has studied the kinetics of folding of RNAase S at 32 °C by fast circular dichroism. He finds the dichroic change expected for formation of the 3–13 helix occurring when the tertiary structure is formed. Protected amide protons are found in the S-protein moiety earlier in folding. Formation or stabilization of this folding intermediate depends upon S-peptide: the intermediate is not observed when S-protein folds alone, and folding of S-protein is twice as slow in the absence of S-peptide. Although S-peptide combines with S-protein early in folding and is needed to stabilize an S-protein folding intermediate, the S-peptide helix does not itself become stable until the tertiary structure of RNAase S is formed.

Folding of ribonuclease A from a partially disordered conformation. Kinetic study under transition conditions.

Bovine pancreative ribonuclease A (RNase A), denatured by 3.5 M LiClO4 (pH 3.0), has some ordered conformation as indicated by a high retention of alpha-helix and compact structure. This effect of LiClO4 was confirmed by the observation that the alpha-helix of isolated S-peptide is stabilized in the presence of 3.5 M LiClO4 (pH 3.0), as measured by circular dichroism and nuclear magnetic resonance. The effect of the retained alpha-helices and compact structure on the folding kinetics of RNase A was studied by comparison with the kinetic folding from urea-denatured RNase A, which has no ordered structure. In contrast to our previous study under folding conditions [Denton, J.B., Konishi, Y., & Scheraga, H. A. (1982) Biochemistry 21, 5155], the kinetic folding/unfolding experiments were carried out here in the transition regions between native and LiClO4-denatured RNase A and between native and urea-denatured RNase A. The measured relaxation times were extrapolated to the triple point, where native RNase A, LiClO4-denatured RNase A, and urea-denatured RNase A have the same thermodynamic stability and are at the same concentration, in order to compare the rates of these two processes under the same solvent conditions. Under these conditions, both folding and unfolding pathways are studied simultaneously without any accumulated intermediates. No significant acceleration of folding was observed from LiClO4-denatured RNase A as compared to that from urea-denatured RNase A. This indicates that all ordered structures in RNase A are not equivalent in their influence on the folding pathway; some may play an essential role and some may not.(ABSTRACT TRUNCATED AT 250 WORDS)