Circularization changes the folding transition state of the src SH3 domain.

Native state topology has been implicated as a major determinant of protein-folding mechanisms. Here, we test experimentally the robustness of the src SH3-domain folding transition state to changes in topology by covalently constraining regions of the protein with disulfide crosslinks and then performing kinetic analysis on point mutations in the context of these modified proteins. Circularization (crosslinking the N and C termini) of the src SH3 domain makes the protein topologically symmetric and causes delocalization of structure in the transition state ensemble suggesting a change in the folding mechanism. In contrast, crosslinking a single structural element (the distal beta-hairpin) which is an essential part of the transition state, results in a protein that folds 30 times faster, but does not change the distribution of structure in the transition state. As the transition states of distantly related SH3 domains were previously found to be very similar, we conclude that the free energy landscape of this protein family contains deep features which are relatively insensitive to sequence variations but can be altered by changes in topology.

Mechanisms of protein folding.

The strong correlation between protein folding rates and the contact order suggests that folding rates are largely determined by the topology of the native structure. However, for a given topology, there may be several possible low free energy paths to the native state and the path that is chosen (the lowest free energy path) may depend on differences in interaction energies and local free energies of ordering in different parts of the structure. For larger proteins whose folding is assisted by chaperones, such as the Escherichia coli chaperonin GroEL, advances have been made in understanding both the aspects of an unfolded protein that GroEL recognizes and the mode of binding to the chaperonin. The possibility that GroEL can remove non-native proteins from kinetic traps by unfolding them either during polypeptide binding to the chaperonin or during the subsequent ATP-dependent formation of folding-active complexes with the co-chaperonin GroES has also been explored.

Long-range order in the src SH3 folding transition state.

One of the outstanding questions in protein folding concerns the degree of heterogeneity in the folding transition state ensemble: does a protein fold via a large multitude of diverse "pathways," or are the elements of native structure assembled in a well defined order? Herein, we build on previous point mutagenesis studies of the src SH3 by directly investigating the association of structural elements and the loss of backbone conformational entropy during folding. Double-mutant analysis of polar residues in the distal beta-hairpin and the diverging turn indicates that the hydrogen bond network between these elements is largely formed in the folding transition state. A 10-glycine insertion in the n-src loop (which connects the distal hairpin and the diverging turn) and a disulfide crosslink at the base of the distal beta-hairpin exclusively affect the folding rate, showing that these structural elements are nearly as ordered in the folding transition state as in the native state. In contrast, crosslinking the base of the RT loop or the N and C termini dramatically slows down the unfolding rate, suggesting that dissociation of the termini and opening of the RT loop precede the rate-limiting step in unfolding. Taken together, these results suggest that essentially all conformations in the folding transition state ensemble have the central three-stranded beta-sheet formed, indicating that, for the src homology 3 domain, there is a discrete order to structure assembly during folding.

Experiment and theory highlight role of native state topology in SH3 folding.

We use a combination of experiments, computer simulations and simple model calculations to characterize, first, the folding transition state ensemble of the src SH3 domain, and second, the features of the protein that determine its folding mechanism. Kinetic analysis of mutations at 52 of the 57 residues in the src SH3 domain revealed that the transition state ensemble is even more polarized than suspected earlier: no single alanine substitution in the N-terminal 15 residues or the C-terminal 9 residues has more than a two-fold effect on the folding rate, while such substitutions at 15 sites in the central three-stranded beta-sheet cause significant decreases in the folding rate. Molecular dynamics (MD) unfolding simulations and ab initio folding simulations on the src SH3 domain exhibit a hierarchy of folding similar to that observed in the experiments. The similarity in folding mechanism of different SH3 domains and the similar hierarchy of structure formation observed in the experiments and the simulations can be largely accounted for by a simple native state topology-based model of protein folding energy landscapes.

Important role of hydrogen bonds in the structurally polarized transition state for folding of the src SH3 domain.

Experimental and theoretical studies on the folding of small proteins such as the chymotrypsin inhibitor 2 (CI-2) and the P22 Arc repressor suggest that the folding transition state is an expanded version of the native state with most interactions partially formed. Here we report that this picture does not hold generally: a hydrogen bond network involving two beta-turns and an adjacent hydrophobic cluster appear to be formed in the folding transition state of the src SH3 domain, while the remainder of the polypeptide chain is largely unstructured. Comparison with data on other small proteins suggests that this structural polarization is a consequence of the topology of the SH3 domain fold. The non-uniform distribution of structure in the folding transition state provides a challenging test for computational models of the folding process.

Simplified proteins: minimalist solutions to the 'protein folding problem'.

Recent research has suggested that stable, native proteins may be encoded by simple sequences of fewer than the full set of 20 proteogenic amino acids. Studies of the ability of simple amino acid sequences to encode stable, topologically complex, native conformations and to fold to these conformations in a biologically relevant time frame have provided insights into the sequence determinants of protein structure and folding kinetics. They may also have important implications for protein design and for theories of the origins of protein synthesis itself.

Functional rapidly folding proteins from simplified amino acid sequences.

Early protein synthesis is thought to have involved a reduced amino acid alphabet. What is the minimum number of amino acids that would have been needed to encode complex protein folds similar to those found in nature today? Here we show that a small beta-sheet protein, the SH3 domain, can be largely encoded by a five letter amino acid alphabet but not by a three letter alphabet. Furthermore, despite the dramatic changes in sequence, the folding rates of the reduced alphabet proteins are very close to that of the naturally occurring SH3 domain. This finding suggests that despite the vast size of the search space, the rapid folding of biological sequences to their native states is not the result of extensive evolutionary optimization. Instead, the results support the idea that the interactions which stabilize the native state induce a funnel shape to the free energy landscape sufficient to guide the folding polypeptide chain to the proper structure.

Folding dynamics of the src SH3 domain.

The thermodynamics and kinetics of folding of the chicken src SH3 domain were characterized using equilibrium and stopped-flow fluorescence, circular dichroism (CD), and nuclear magnetic resonance (NMR) hydrogen exchange experiments. As found for other SH3 domains, guanidinium chloride (GdmCl) denaturation melts followed by both fluorescence and circular dichroism were nearly superimposable, indicating the concerted formation of secondary and tertiary structure. Kinetic studies confirmed the two-state character of the folding reaction. Except for a very slow refolding phase due to proline isomerization, both folding and unfolding traces fit well to single exponentials over a wide range of GdmCl concentrations, and no burst phase in amplitude was observed during the dead time of the stopped-flow instrument. The entropy, enthalpy, and heat capacity changes upon unfolding were determined by global fitting of temperature melts at varying GdmCl concentrations (0.4-3.7 M). Estimates of the free energy of unfolding, DeltaGUH2O, from guanidine denaturation, thermal denaturation, and kinetic experiments were in good agreement. To complement these data on the global characteristics of src SH3 folding, individual hydrogen-deuterium (HD) exchange rates were measured for approximately half of the backbone amides in 0 and 0.7 M GdmCl. The calculated free energies of the opening reaction leading to exchange (DeltaGHD) indicated that unfolding is highly cooperative--slowly exchanging protons were distributed throughout the core of the protein. The slowly exchanging protons exhibited DeltaGHD values higher than the global DeltaGUH2O by approximately 1 kcal/mol, suggesting that the denatured state might be somewhat compact under native conditions. Comparison of the src SH3 with homologous SH3 domains as well as with other small well-characterized beta-sheet proteins provides insights into the determinants of folding kinetics and protein stability.

Modifying the helical structure of DNA by design: recruitment of an architecture-specific protein to an enforced DNA bend.

BACKGROUND: Proteins can force DNA to adopt distorted helical structures that are rarely if ever observed in naked DNA. The ability to synthesize DNA that contains defined helical aberrations would offer a new avenue for exploring the structural and energetic plasticity of DNA. Here we report a strategy for the enforcement of non-canonical helical structures through disulfide cross-linking; this approach is exemplified by the design and synthesis of an oligonucleotide containing a pronounced bend. RESULTS: A localized bend was site-specifically introduced into DNA by the formation of a disulfide cross-link between the 5' adenines of a 5'-AATT-3' region in complementary strands of DNA. The DNA bend was characterized by high-resolution NMR structure determination of a cross-linked dodecamer and electrophoretic mobility assays on phased multimers, which together indicate that the cross-linked tetranucleotide induces a helical bend of approximately 30 degrees and a modest degree of unwinding. The enforced bend was found to stimulate dramatically the binding of an architecture-specific protein, HMG-D, to the DNA. DNase I foot-printing analysis revealed that the protein is recruited to the section of DNA that is bent. CONCLUSIONS: The present study reports a novel approach for the investigation of non-canonical DNA structures and their recognition by architecture-specific proteins. The mode of DNA bending induced by disulfide cross-linking resembles that observed in structures of protein-DNA complexes. The results reveal common elements in the DNA-binding mode employed by sequence-specific and architecture-specific HMG proteins.