Secondary structure in ribonuclease. II. Relations between folding kinetics and secondary structure elements

Kinetics of formation of hydrophobic regions during refolding of bovine serum albumin

The rate of formation of hydrophobic regions during refolding of bovine serum albumin was studied using 1-anilinonaphthalene-8-sulfonate as the hydrophobic fluorescent probe. The refolding of serum albumin exhibited a sigmoidal behavior. The exhibition of a lag phase followed by a faster kinetic phase suggested that the refolding is a cooperative, sequential process. Refolding under reducing conditions almost completely inhibited the regeneration of hydrophobic binding regions, suggesting that the formation of disulfide bonds plays an important role in the refolding of serum albumin. The rate and the extent of refolding was apparently maximum at about 20 degrees; at 37 degrees the extent of refolding was very low compared to that at the other temperatures studied. Based on the results, the mechanism of albumin refolding is interpreted in terms of domain structures and interdomain interactions.

Effects of denaturants on amide proton exchange rates: a test for structure in protein fragments and folding intermediates

A method for detecting structure in marginally stable forms of a protein is described. The principle is to measure amide proton exchange rates in the absence and presence of varying concentrations of a denaturant. Unfolding of structure by the denaturant is reflected by an acceleration of amide proton exchange rates, after correction for the effects of the denaturant on the intrinsic rate of exchange. This exchange-rate test for structure makes no assumptions about the rate of exchange in the unfolded state. The effects of 0-8 M urea and 0-6 M guanidinium chloride (GdmCl) on acid- and base-catalyzed exchange from model compounds have been calibrated. GdmCl does not appear to be well-suited for use in the exchange-rate test; model compound studies show that the effects of GdmCl on intrinsic exchange rates are complicated. In contrast, the effects of urea are a more uniform function of denaturant concentration. Urea increases acid-catalyzed, and decreases base-catalyzed, rates in model compounds. The exchange-rate test is used here to study structure formation in the S-protein (residues 21-124 of ribonuclease A). In conditions where an equilibrium folding intermediate of S-protein (I3) is known to be populated (pH 1.7, 0 degree C), the exchange-rate test for structure is positive. At higher temperatures (greater than 32 degrees C) I3 is unfolded, but circular dichroism data suggest that residual structure remains [Labhardt, A. M. (1982) J. Mol. Biol. 157, 357-371].(ABSTRACT TRUNCATED AT 250 WORDS)

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

We make use of the known exchange rates of individual amide proton in the S-peptide moiety of ribonuclease S (RNAase S) to determine when during folding the alpha-helix formed by residues 3 to 13 becomes stable. The method is based on pulse-labeling with [3H]H2O 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 degrees 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 degrees 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.

Kinetic circular dichroism shows that the S-peptide alpha-helix of ribonuclease S unfolds fast and refolds slowly

It is shown that circular dichroism (CD) can distinguish between the S-peptide and the S-protein fragments of RNase S at 225 nm and 235 nm. The conformational source for the strong CD at 225 nm is the S-peptide alpha-helix. The structural assignment of the CD at 235 nm is not clear but it is shown to be largely due to the S-protein moiety. This situation is utilized to monitor the kinetics of pH-induced unfolding and refolding of the two moieties. It is observed that major changes occur both in the fast and slow phases of unfolding as well as refolding. Specifically, the S-peptide alpha-helix unzippering is a fast reaction, followed by slow kinetics only at 235 nm. These latter kinetics parallel the appearance of the slow-folding species commonly attributed to the accumulation of non-native proline isomers. In refolding, a large fraction of the CD of S-protein at 235 nm recovers rapidly. The S-peptide alpha-helix zippers up last. These results are unexpected and their implications for the folding mechanism of ribonuclease are discussed.