We compare the folding of representative members of a protein superfamily by experiment and simulation to investigate common features in folding mechanisms. The homeodomain superfamily of three-helical, single-domain proteins exhibits a spectrum of folding processes that spans the complete transition from concurrent secondary and tertiary structure formation (nucleation-condensation mechanism) to sequential secondary and tertiary formation (framework mechanism). The unifying factor in their mechanisms is that the transition state for (un)folding is expanded and very native-like, with the proportion and degree of formation of secondary and tertiary interactions varying. There is a transition, or slide, from the framework to nucleation-condensation mechanism with decreasing stability of the secondary structure. Thus, framework and nucleation-condensation are different manifestations of an underlying common mechanism.two-state ͉ three-state ͉ framework ͉ nucleation ͉ homeodomain A Holy Grail of protein folding is to find a single mechanism. Given the diversity of protein structure and the evolutionary pressure on function and not on folding rates, a unique mechanism for folding would seem unlikely. If there are simplifying features, then small, single-domain proteins may be the most likely to exhibit them. But such proteins seem to fold by two distinct mechanisms. The 6-85 repressor fragment (1) and the engrailed homeodomain (En-HD; ref.2) seem to fold by a classical diffusion-collision mechanism (3-5) whereby secondary structural elements form independently and then dock to form the tertiary structure. Chymotrypsin inhibitor 2, on the other hand, folds by nucleation-condensation, which is characterized by concerted consolidation of secondary and tertiary interactions as the whole domain collapses around an extended nucleus (6). It has been argued on general grounds that nucleation-condensation and diffusion-collision are different manifestations of a common mechanism in which secondary structure and tertiary structure form in parallel (7,8). Nucleationcondensation reflects the situation when secondary structure is inherently unstable in the absence of tertiary interactions whereas diffusion-collision becomes more probable with increasing stability of secondary structure.Studies of the folding of point mutants of a prototype protein are essential for discovering atomic level details of folding mechanisms and kinetics. Single-point mutants may even cause gross changes in the kinetics of folding, such as the transition from three-state to two-state folding (9). But, to extrapolate a general understanding of folding mechanisms, studies on members of the same fold family (different homologues sharing the same overall topology but with different primary structures) can be useful in finding correlations between amino acid sequences and three-dimensional structures (10-16). Although there can be different folding routes through different transition states for some proteins (17), it seems that mechanisms of folding are oft...
Several hundred clinical trials currently explore the role of circulating tumor cell (CTC) analysis for therapy decisions, but assays are lacking for comprehensive molecular characterization of CTCs with diagnostic precision. We therefore combined a workflow for enrichment and isolation of pure CTCs with a non-random whole genome amplification method for single cells and applied it to 510 single CTCs and 189 leukocytes of 66 CTC-positive breast cancer patients. We defined a genome integrity index (GII) to identify single cells suited for molecular characterization by different molecular assays, such as diagnostic profiling of point mutations, gene amplifications and whole genomes of single cells. The reliability of > 90% for successful molecular analysis of high-quality clinical samples selected by the GII enabled assessing the molecular heterogeneity of single CTCs of metastatic breast cancer patients. We readily identified genomic disparity of potentially high relevance between primary tumors and CTCs. Microheterogeneity analysis among individual CTCs uncovered pre-existing cells resistant to ERBB2-targeted therapies suggesting ongoing microevolution at late-stage disease whose exploration may provide essential information for personalized treatment decisions and shed light into mechanisms of acquired drug resistance.
Understanding the basis of communication within protein domains is a major challenge in structural biology. We present structural and dynamical evidence for allosteric effects in a PDZ domain, PDZ2 from the tyrosine phosphatase PTP-BL, upon binding to a target peptide. The NMR structures of its free and peptide-bound states differ in the orientation of helix alpha2 with respect to the remainder of the molecule, concomitant with a readjustment of the hydrophobic core. Using an ultrafast mixing instrument, we detected a deviation from simple bimolecular kinetics for the association with peptide that is consistent with a rate-limiting conformational change in the protein (k(obs) approximately 7 x 10(3) s(-1)) and an induced-fit model. Furthermore, the binding kinetics of 15 mutants revealed that binding is regulated by long-range interactions, which can be correlated with the structural rearrangements resulting from peptide binding. The homologous protein PSD-95 PDZ3 did not display a similar ligand-induced conformational change.
An Obligatory Intermediate in the Folding Pathway of Cytochromec552 from Hydrogenobacterthermophilus
The folding mechanism of many proteins involves the population of partially organized structures en route to the native state. Identification and characterization of these intermediates is particularly difficult, as they are often only transiently populated and may play different mechanistic roles, being either on-pathway productive species or off-pathway kinetic traps. Following different spectroscopic probes, and employing state-of-the-art kinetic analysis, we present evidence that the folding mechanism of the thermostable cytochrome c 552 from Hydrogenobacter thermophilus does involve the presence of an elusive, yet compact, on-pathway intermediate. Characterization of the folding mechanism of this cytochrome c is particularly interesting for the purpose of comparative folding studies, because H. thermophilus cytochrome c 552 shares high sequence identity and structural homology with its homologue from the mesophilic bacterium Pseudomonas aeruginosa cytochrome c 551 , which refolds through a broad energy barrier without the accumulation of intermediates. Analysis of the folding kinetics and correlation with the three-dimensional structure add new evidence for the validity of a consensus folding mechanism in the cytochrome c family.
PostprintThis is the accepted version of a paper published in Biophysical Chemistry. This paper has been peerreviewed but does not include the final publisher proof-corrections or journal pagination.Citation for the original published paper (version of record):Gianni, S., Dogan, J., Jemth, P. (2014) Distinguishing induced fit from conformational selection.
It is controversial whether fast-folding proteins can form productive on-pathway intermediates that are more stable than the denatured state because noncovalent intermediates are usually evanescent. Here, we apply the classical criteria for the existence of intermediates: namely, the intermediates form and react rapidly enough to be on pathway and they can be isolated and characterized
A classical dogma of molecular biology dictates that the 3D structure of a protein is necessary for its function. However, a considerable fraction of the human proteome, although functional, does not adopt a defined folded state under physiological conditions. These intrinsically disordered proteins tend to fold upon binding to their partners with a molecular mechanism that is elusive to experimental characterization. Indeed, although many hypotheses have been put forward, the functional role (if any) of disorder in these intrinsically denatured systems is still shrouded in mystery. Here, we characterize the structure of the transition state of the binding-induced folding in the reaction between the KIX domain of the CREB-binding protein and the transactivation domain of c-Myb. The analysis, based on the characterization of a series of conservative site-directed mutants, reveals a very high content of native-like structure in the transition state and indicates that the recognition between KIX and c-Myb is geometrically precise. The implications of our results in the light of previous work on intrinsically unstructured systems are discussed.kinetics | mutagenesis | protein folding
PDZ domains are protein adapter modules present in a few hundred human proteins. They play important roles in scaffolding and signal transduction. PDZ domains usually bind to the C termini of their target proteins. To assess the binding mechanism of this interaction we have performed the first in-solution kinetic study for PDZ domains and peptides corresponding to target ligands. Both PDZ3 from postsynaptic density protein 95 and PDZ2 from protein tyrosine phosphatase L1 bind their respective target peptides through an apparent A ؉ B 3 A⅐B mechanism without rate-limiting conformational changes. But a mutant with a fluorescent probe (Trp) outside of the binding pocket suggests that slight changes in the structure take place upon binding in protein tyrosine phosphatase-L1 PDZ2. For PDZ3 from postsynaptic density protein 95 the pH dependence of the binding reaction is consistent with a one-step mechanism with one titratable group. The salt dependence of the interaction shows that the formation of electrostatic interactions is rate-limiting for the association reaction but not for dissociation of the complex. PDZ4 domains are found in a few hundred human proteins, either as a single domain or in arrays. These domains mediate binding to other proteins and in this way play important roles in scaffolding and signal transduction (1, 2). Structural studies have shown that the PDZ domains usually bind to the C terminus of their target proteins. A number of crystal and NMR structures of PDZ domains have been solved both with and without bound peptide (for example, Refs 3-6) ( Fig. 1). A wealth of data on different peptides binding to different PDZ domains has been obtained by screening (for example, Refs. 7 and 8) and selection (for example, Refs. 9 and 10). Such studies and those using the yeast twohybrid technique (for example, Ref. 11) provide important information on possible cellular targets for distinct PDZ domains as well as the specificity of the interaction. Moreover, theory and NMR experiments have suggested that the dynamics of PDZ domains and the residues outside of the binding pocket influence their interaction with ligands (12, 13). Despite considerable effort to clarify the structural basis for the PDZ-ligand interaction, only a handful of studies have assessed the binding energetics and specificity of PDZ-peptide interactions using proper equilibrium assays in solution (3, 11, 14 -24). Kinetics of chemical reactions not only provide "end point data" such as equilibrium constants but also yield microscopic rate constants and, more importantly, the possibility of elucidating the mechanisms of binding and probing the binding dynamics as well as the properties of the transition state of the reaction. To assess the binding mechanism, we have performed the first kinetic study of PDZ domains in solution using stopped-flow fluorimetry. The PDZ domains chosen were PDZ3 from human PSD-95, one of the most well studied PDZ domains, and the second PDZ domain from mouse protein tyrosine phosphatase-L1 (PTP-BL; also known...
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
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
