Mapping the Cytochrome C Folding Landscape

Citation

Lyubovitsky, Julia Gennadievna (2003) Mapping the Cytochrome C Folding Landscape. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/W2R9-Y195. https://resolver.caltech.edu/CaltechETD:etd-04102003-004657

Abstract

The solution to the riddle of how a protein folds is encoded in the conformational energy landscape for the constituent polypeptide. Employing fluorescence energy transfer kinetics, we have mapped the S. cerevisiae iso-1 cytochrome c landscape by monitoring the distance between a C-terminal fluorophore and the heme during folding. Within 1 ms after denaturant dilution to native conditions, unfolded protein molecules have evolved into two distinct and rapidly equilibrating populations: a collection of collapsed structures with an average fluorophore-heme distance (r) of 27 A and a roughly equal population of extended polypeptides with r > 50 A. Molecules with the native fold appear on a timescale regulated by heme ligation events (~300 ms, pH 7). The experimentally derived landscape for folding has a narrow central funnel with a flat upper rim on which collapsed and extended polypeptides interchange rapidly in a search for the native structure.

Nonnative states of proteins are involved in a variety of cellular processes, including translocation of proteins across membranes and formation of amyloid fibrils. Probes that report on the structural heterogeneity of a polypeptide ensemble could resolve ambiguities in the classification of these states. We have shown that added anions shift the equilibrium between the compact and extended polypeptide structures that are present during refolding of Saccaromyces cerevisiae iso-1 cytochrome c. Specifically, at high salt concentrations (>= 700 mM), all the polypeptides are compact with a mean C-terminal fluorophore-heme separation quite close to that in the native protein (25 A). Addition of chemical detaturants, on the other hand, tends to shift the equilibrium towards unfolded structures.

Folding of modified Fe(II) cyt c was probed by fluorescence in presence of imidazole with NADH as photochemical sensitizer. At very high imidazole concentrations (400 mM), protein was still found to fold but the rate that coincides with Met80 ligation was slowed down significantly.

Reductive flash-quench/scavenge experiments, in which ascorbic acid was used to scavenge MeODMAA+, were shown to keep ferrocyt c reduced for up to 500 ms. Electron injection into unfolded modified yeast Fe(III)cyt c was fast in comparison to injection using NADH as photochemical sensitizer. The overall electron transfer process was reversible. This photoreduction system could be used to trigger folding of Fe(II) cyt c to monitor the changes in dansyl fluorescence intensity on ms time scales.

Item Type:	Thesis (Dissertation (Ph.D.))
Subject Keywords:	cytochrome c; cytochrome c molten globule; cytochrome c mutants; electron transfer triggered folding; energy; energy landscape; energy surface; energy surface; fluorescence; fluorescence energy transfer kinetics; folding; folding kinetics; folding landscape; kinetics; life time measurements; molten globule; protein; protein folding; transfer
Degree Grantor:	California Institute of Technology
Division:	Chemistry and Chemical Engineering
Major Option:	Chemistry
Thesis Availability:	Public (worldwide access)
Research Advisor(s):	Gray, Harry B.
Thesis Committee:	Okumura, Mitchio (chair) Rees, Douglas C. Gray, Harry B. Richards, John H. Winkler, Jay Richmond Lewis, Nathan Saul
Defense Date:	20 March 2003
Record Number:	CaltechETD:etd-04102003-004657
Persistent URL:	https://resolver.caltech.edu/CaltechETD:etd-04102003-004657
DOI:	10.7907/W2R9-Y195
Default Usage Policy:	No commercial reproduction, distribution, display or performance rights in this work are provided.
ID Code:	1322
Collection:	CaltechTHESIS
Deposited By:	Imported from ETD-db
Deposited On:	15 Apr 2003
Last Modified:	19 Feb 2021 00:33