The kinetics of regain of the native ellipticity in the far- and near-UV spectra have been investigated during the refolding at pH 7.8 and 20 degrees C of guanidine-unfolded, nonreduced hen egg white lysozyme. Stopped-flow studies showed that the ellipticities at 260 and 289.5 nm exhibit biphasic kinetics with rate constants of about 50 s-1 and 2.5 s-1 for the rapid and slow phase, respectively. The ellipticity in the far-UV obeyed triphasic kinetics. In addition to a rapid and a slow phase with rate constants similar to those observed in the near-UV, a "burst" of ellipticity was shown to occur in the dead time of the experiments. The effects of low pH and of concentrations of guanidine ranging from 0.075 to 1.5 M on the rapid and slow rate constants were studied. Under all conditions investigated, the rate constants observed in the far- and near-UV for a given phase were the same, thus suggesting that the molecular events observed in the two regions of the UV spectrum are either identical or strongly coupled. Continuous-flow experiments at different wavelengths between 214 and 240 nm under conditions where the dead time for the observation was only 4 ms, followed by a detailed analysis of the kinetics of ellipticity change at each wavelength, provided the spectrum of the molecular species formed at the end of the burst phase. This spectrum was found to closely fit that predicted from the secondary structure of native lysozyme.(ABSTRACT TRUNCATED AT 250 WORDS)
The isolated F2-V8 peptide corresponding to the 101 C-terminal residues of Escherichia coli tryptophan synthase beta chains folds into a heat-stable, yet fluctuating, condensed state that contains a lot of secondary structure. However, this state has non-native-like secondary and supersecondary structures [Chaffotte, A., Guillou, Y., Delepierre, M., Hinz, H.-J., & Goldberg, M. E. (1991) Biochemistry 30, 8067-8074]. To characterize the rate of appearance of this state, stopped-flow studies on the far-ultraviolet circular dichroism (CD) and on the binding of 1-anilino-8-naphthalenesulfonate (ANS) have been conducted during the folding of guanidine-unfolded F2-V8. It was shown that both the CD signal at 222 nm and the ANS binding properties of folded isolated F2-V8 were regained, at 20 degrees C, within the dead time of the stopped-flow apparatus, which was 4 ms. At 12 degrees C, the binding of ANS was also completed within this dead time, but the ellipticity showed some minor later changes. After a rapid overshoot of the CD signal that occurred during the 4-ms dead time, a small readjustment of the ellipticity to the final value occurred more slowly and was completed after about 25 ms. Thus, even at 12 degrees C, the hydrophobic core and most of the secondary structure of folded F2-V8 were formed in less than 4 ms. These observations strongly suggest that the previously described condensed non-native-like state of F2-V8 results from a very rapid, nonspecific, hydrophobic collapse. It is proposed that such a state may be a general early intermediate in protein folding.
Proteolysis of the beta 2-subunit of Escherichia coli tryptophan synthase by the endoproteinase Glu C from Staphylococcus aureus V8 yields a peptide, F2, corresponding to the C-terminal 101 residues of the beta-chain. The conformation and stability of isolated F2 in phosphate buffer at pH 7.8 (where native beta 2 is stable) have been investigated. Circular dichroism spectra in the far-UV showed the presence of large amounts of secondary structure (19% alpha-helices, 34% extended beta-structures). Circular dichroism spectra in the near-UV and sedimentation velocity studies indicated an open globular structure with the aromatic side chains in a symmetric (or disordered) environment. NMR spectra and rates of amide proton exchange showed that F2 fluctuates rapidly between several conformations. The thermal denaturation of F2 observed by the loss of far-UV circular dichroism with increasing temperature appeared noncooperative, and indicates a high thermal stability (Tm = 70 degrees C). Differential scanning microcalorimetry confirmed the absence of cooperativity and indicated a very low value for the calorimetric enthalpy of denaturation (delta H = 17 kJ/mol). All these properties were compatible with a molten globule. However, the low sedimentation coefficient of F2 suggested a very hydrated and/or expanded structure, and the secondary structure content of isolated F2 (see above) differed widely from that reported in the literature for F2 within the context of native beta 2 (49% alpha-helices and 13% extended beta-structures). Thus, neither the secondary nor the tertiary structure of isolated F2 resembled those of native F2. In this respect, isolated F2 is not a "molten globule".(ABSTRACT TRUNCATED AT 250 WORDS)
This study represents the first physicochemical analysis of the recently cloned methionine repressor protein (Met aporepressor) from Escherichia coli. Infrared spectrometry was used to investigate the secondary structure and the hydrogen-deuterium exchange behavior of the E. coli Met aporepressor. The secondary structure of the native bacterial protein was derived by analysis of the amide I mode. The amide I band contour was found to consist of five major component bands (at 1625, 1639, 1653, 1665, and 1676 cm-1) which reflect the presence of various substructures. The relative areas of these component bands are consistent with a high alpha-helical content of the peptide chain secondary structure in solution (43%) and a small amount of beta-sheet structure (7%). The remaining substructure is assigned to turns (10%) and to unordered (or less ordered) structures (40%). The temperature dependence of the infrared spectra of native Met aporepressor in D2O medium over the temperature interval 20-80 degrees C indicates that there are two discrete thermal events: the first thermal event, centered at 42 degrees C, is associated with the hydrogen-deuterium exchange of the hard-to-exchange alpha-helical peptide bonds accompanied by a partial denaturation of the protein, while the second event, centered around 50 degrees C, represents the irreversible thermal denaturation of the protein.
In vitro folding studies of several proteins revealed the formation, within 2-4 msec, of transient intermediates with a large far-UV ellipticity but no amide proton protection. To solve the contradiction between the secondary structure contents estimated by these two methods, we characterized the isolated C-terminal fragment F2 of the tryptophan synthase beta 2 subunit. In beta 2, F2 forms its tertiary interactions with the F1 N-terminal region. Hence, in the absence of F1, isolated F2 should remain at an early folding stage with no long-range interactions. We shall show that isolated F2 folds into, and remains in, a "state" called the pre-molten globule, that indeed corresponds to a 2- to 4-msec intermediate. This condensed, but not compact, "state" corresponds to an array of conformations in rapid equilibrium comprising native as well as nonnative secondary structures. It fits the "new view" on the folding process.
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