Neşe Kurt scite author profile

Virtually nothing is known about the interaction of co-translationally active chaperones with nascent polypeptides and the resulting effects on peptide conformation and folding. We have explored this issue by NMR analysis of apomyoglobin N-terminal fragments of increasing length, taken as models for different stages of protein biosynthesis, in the absence and presence of the substrate binding domain of Escherichia coli Hsp70, DnaK-β. The incomplete polypeptides misfold and self-associate under refolding conditions. In the presence of DnaK-β, however, formation of the original selfassociated species is completely or partially prevented. Chaperone interaction with incomplete protein chains promotes a globally unfolded dynamic DnaK-β-bound state, which becomes foldingcompetent only upon incorporation of the residues corresponding to the C-terminal H helix. The chaperone does not bind the full-length protein at equilibrium. However, its presence strongly disfavors the kinetic accessibility of misfolding side-routes available to the full-length chain. This work supports the role of DnaK as a "holder" for incomplete N-terminal polypeptides. However, as the chain approaches its full-length status, the tendency to intramolecularly bury non-polar surface efficiently out-competes chaperone binding. Under these conditions, DnaK serves as a "folding enhancer" by supporting folding of a population of otherwise folding-incompetent full-length protein chains.

show abstract

Cooperative fluctuations of unliganded and substrate‐bound HIV‐1 protease: A structure‐based analysis on a variety of conformations from crystallography and molecular dynamics simulations

Kurt

Scott²,

Schiffer

et al. 2003

Proteins

View full text Add to dashboard Cite

The dynamics of HIV-1 protease, both in unliganded and substrate-bound forms have been analyzed by using an analytical method, Gaussian network model (GNM). The method is applied to different conformations accessible to the protein backbone in the native state, observed in crystal structures and snapshots from fully atomistic molecular dynamics (MD) simulation trajectories. The modes of motion obtained from GNM on different conformations of HIV-1 protease are conserved throughout the MD simulations. The flaps and 40's loop of the unliganded HIV-1 protease structure are identified as the most mobile regions. However, in the liganded structure these flaps lose mobility, and terminal regions of the monomers become more flexible. Analysis of the fast modes shows that residues important for stability are in the same regions of all the structures examined. Among these, Gly86 appears to be a key residue for stability. The contribution of residues in the active site region and flaps to the stability is more pronounced in the substrate-bound form than in the unliganded form. The convergence of modes in GNM to similar regions of HIV-1 protease, regardless of the conformation of the protein, supports the robustness of GNM as a potentially useful and predictive tool.

show abstract

Secondary Structure Mapping of DnaK-Bound Protein Fragments: Chain Helicity and Local Helix Unwinding at the Binding Site

et al. 2006

View full text Add to dashboard Cite

Little is known about polypeptide conformation and folding in the presence of molecular chaperones participating in protein biosynthesis. In vitro studies on chaperone-substrate complexes have been mostly carried out with small peptide ligands. However, the technical challenges associated with either competing aggregation or spectroscopically unfavorable size and exchange rates have typically prevented analysis of larger substrates. Here, we report the high-resolution secondary structure of relatively large N-terminal protein fragments bound to the substrate-binding domain of the cotranslationally active chaperone DnaK. The all-alpha-helical protein apomyoglobin (apoMb), bearing the ubiquitous globin fold, has been chosen as a model substrate. On the basis of NMR secondary chemical shift analysis, we identify, for the first time, weak helical content (similar to that found in the chemically unfolded full-length protein) for the assigned residues of the chaperone-bound chain away from the chaperone binding sites. In contrast, we found that the residues corresponding to the strongest specific binding site for DnaK, examined via a short 13-mer apoMb peptide fragment matching the binding site sequence, display highly reduced helical content in their chaperone-bound form. Given that the free state of the peptide is weakly helical in isolation, we conclude that the substrate residues corresponding to the chaperone binding site undergo helix unwinding upon chaperone binding.

show abstract

The Burial of Solvent-Accessible Surface Area is a Predictor of Polypeptide Folding and Misfolding as a Function of Chain Elongation

Kurt

Cavagnero

2005

J. Am. Chem. Soc.

View full text Add to dashboard Cite

The hydrophobic effect is a major driving force in all chemical and biological events involving chain collapse in aqueous solution. Here, we show that the burial of nonpolar solvent-accessible surface area (NSASA) is a powerful criterion to predict the folding and misfolding behavior of small single-domain proteins as a function of chain elongation. This bears fundamental implications for co- and post-translational protein folding in the cell and for understanding the interplay between noncovalent interactions and formation of native-like structure and topology. Comparison between the fraction of NSASA in fully unfolded and folded elongating chains shows that efficient burial of nonpolar surface area is preferentially achieved only when the polypeptide chain is almost complete. This effect has no preferential vectorial character in that it is present upon elongation from both the N and C termini. For incomplete chains that do not have the ability to fold and bury nonpolar surface intramolecularly, the overall hydrophobic nature of the polypeptide chain (expressed as FBA, i.e., fractional buried surface area per residue) dictates the tendency toward misfolding and self-association. N-terminal chains characterized by FBA exceeding 0.73 are likely to misfold and aggregate, if unable to fold intramolecularly.

show abstract

Structural Characterization of Apomyoglobin Self-Associated Species in Aqueous Buffer and Urea Solution

Chow

Kurt

Murphy

et al. 2006

Biophysical Journal

View full text Add to dashboard Cite

The biophysical characterization of nonfunctional protein aggregates at physiologically relevant temperatures is much needed to gain deeper insights into the kinetic and thermodynamic relationships between protein folding and misfolding. Dynamic and static laser light scattering have been employed for the detection and detailed characterization of apomyoglobin (apoMb) soluble aggregates populated at room temperature upon dissolving the purified protein in buffer at pH 6.0, both in the presence and absence of high concentrations of urea. Unlike the beta-sheet self-associated aggregates previously reported for this protein at high temperatures, the soluble aggregates detected here have either alpha-helical or random coil secondary structure, depending on solvent and solution conditions. Hydrodynamic diameters range from 80 to 130 nm, with semiflexible chain-like morphology. The combined use of low pH and high urea concentration leads to structural unfolding and complete elimination of the large aggregates. Even upon starting from this virtually monomeric unfolded state, however, protein refolding leads to the formation of severely self-associated species with native-like secondary structure. Under these conditions, kinetic apoMb refolding proceeds via two parallel routes: one leading to native monomer, and the other leading to a misfolded and heavily self-associated state bearing native-like secondary structure.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Neşe Kurt

Effect of Hsp70 Chaperone on the Folding and Misfolding of Polypeptides Modeling an Elongating Protein Chain

Cooperative fluctuations of unliganded and substrate‐bound HIV‐1 protease: A structure‐based analysis on a variety of conformations from crystallography and molecular dynamics simulations

Secondary Structure Mapping of DnaK-Bound Protein Fragments: Chain Helicity and Local Helix Unwinding at the Binding Site

The Burial of Solvent-Accessible Surface Area is a Predictor of Polypeptide Folding and Misfolding as a Function of Chain Elongation

Structural Characterization of Apomyoglobin Self-Associated Species in Aqueous Buffer and Urea Solution

Contact Info

Product

Resources

About