Rapid refolding of a proline-rich all-beta-sheet fibronectin type III module

Side-chain effects on peptidyl-prolyl cis/trans isomerisation

Peptidyl-prolyl cis/trans isomerisation has been frequently found as a rate limiting step in the folding of proteins. In order to determine whether the nature of the amino acid preceding proline controls the probability of cis prolyl bonds in native proteins, systematic studies on the thermodynamics and kinetics of the prolyl isomerisation in the pentapeptide series Ac-Ala-Xaa-Pro-Ala-Lys-NH2 were performed. All proteinogenic amino acids were substituted in the position preceding proline. When measured by 1H-NMR and CD spectroscopy both isomers proved to be devoid of ordered structure in the whole series of the oligopeptides in aqueous solution. Thus, isomerization rates and cis/trans ratios calculated from solvent jump and 1H-NMR magnetisation transfer experiments exclusively reflect the side-chain effects of the Xaa position in the peptide series. There is a rough correlation between the cis content in the oligopeptides and the propensity of Xaa-Pro cis prolyl bonds in proteins. This correlation suggests that the prolyl bond conformation is mainly determined by local effects in proteins. The rate constants kc-->t of pentapeptides containing unionised amino acids preceding proline range from 3.2 x 10(-3) s-1 (Xaa = Ala) to 0.5 x 10(-3) s-1 (Xaa = Trp) at 4 degrees C. Proline clustering led to an isomerisation cycle indicating considerable influence on the isomerisation rates of the peptide bond conformations flanking the rotating bond. Both tyrosine and histidine specifically reduce isomerisation rates severalfold by deprotonation of their respective side-chains.

The molecular elasticity of the extracellular matrix protein tenascin

Extracellular matrix proteins are thought to provide a rigid mechanical anchor that supports and guides migrating and rolling cells. Here we examine the mechanical properties of the extracellular matrix protein tenascin by using atomic-force-microscopy techniques. Our results indicate that tenascin is an elastic protein. Single molecules of tenascin could be stretched to several times their resting length. Force-extension curves showed a saw-tooth pattern, with peaks of force at 137pN. These peaks were approximately 25 nm apart. Similar results have been obtained by study of titin. We also found similar results by studying recombinant tenascin fragments encompassing the 15 fibronectin type III domains of tenascin. This indicates that the extensibility of tenascin may be due to the stretch-induced unfolding of its fibronectin type III domains. Refolding of tenascin after stretching, observed when the force was reduced to near zero, showed a double-exponential recovery with time constants of 42 domains refolded per second and 0.5 domains per second. The former speed of refolding is more than twice as fast as any previously reported speed of refolding of a fibronectin type III domain. We suggest that the extensibility of the modular fibronectin type III region may be important in allowing tenascin-ligand bonds to persist over long extensions. These properties of fibronectin type III modules may be of widespread use in extracellular proteins containing such domain.

How evolution makes proteins fold quickly

Sequences of fast-folding model proteins (48 residues long on a cubic lattice) were generated by an evolution-like selection toward fast folding. We find that fast-folding proteins exhibit a specific folding mechanism in which all transition state conformations share a smaller subset of common contacts (folding nucleus). Acceleration of folding was accompanied by dramatic strengthening of interactions in the folding nucleus whereas average energy of nonnucleus interactions remained largely unchanged. Furthermore, the residues involved in the nucleus are the most conserved ones within families of evolved sequences. Our results imply that for each protein structure there is a small number of conserved positions that are key determinants of fast folding into that structure. This conjecture was tested on two protein superfamilies: the first having the classical monophosphate binding fold (CMBF; 98 families) and the second having type-III repeat fold (47 families). For each superfamily, we discovered a few positions that exhibit very strong and statistically significant "conservatism of conservatism"-amino acids in those positions are conserved within every family whereas the actual types of amino acids varied from family to family. Those amino acids are in spatial contact with each other. The experimental data of Serrano and coworkers [Lopez-Hernandez, E. & Serrano, L. (1996) Fold. Des. (London) 1, 43-55]. for one of the proteins of the CMBF superfamily (CheY) show that residues identified this way indeed belong to the folding nucleus. Further analysis revealed deep connections between nucleation in CMBF proteins and their function.

Kinetic studies of beta-sheet protein folding

New studies have shown that folding of beta-sheet proteins can occur with and without intermediates, with fast to slow refolding rates and late to very late transition states. These experiments demonstrate that, despite early speculation to the contrary, beta-sheet protein folding does not appear to be fundamentally different from that of helical and mixed alpha, beta proteins.

Folding and stability of a fibronectin type III domain of human tenascin

The folding of an isolated fibronectin type III domain of human tenascin, a large extra-cellular matrix protein, has been characterised. The isolated module, which has no disulphide bonds, can be reversibly unfolded by chemical denaturant and temperature. Equilibrium unfolding, measured using a number of different probes, fits to a two-state transition, with consistent measures of DeltaGH2OD-N. Folding and refolding rate constants have been determined over a range of denaturant concentrations. The refolding kinetics are bi-phasic, and in the transition region the slow phase dominates refolding kinetics. Outside the transition region the folding of the fast-folding species fits to a two-state model. There is no evidence for significant accumulation of partially folded intermediates.

A comparison of the folding kinetics and thermodynamics of two homologous fibronectin type III modules

The homologous ninth and tenth type III modules of human fibronectin share identical topologies and nearly identical core structures. Despite these structural similarities, the refolding characteristics of the two modules, which have a sequence identity of less than 30 %, are very different; in the absence of denaturant the ninth module folds several hundred times more slowly than the tenth and, although both modules contain numerous proline residues, only the ninth exhibits a slow, proline isomerization-limited folding phase. The different folding kinetics of the two modules coincide with a large difference in their thermodynamic stability, with the folding free energy of the tenth being approximately five fold greater than that of the ninth. This may be the reason why the ninth module, unlike the rapidly folding tenth module, is apparently unable to overcome characteristics of the fibronectin type III modules that can slow the folding process. The non-proline-limited folding kinetics are, however, very similar for the two modules when compared under conditions where their overall stabilities are similar. The significance of this finding is discussed in terms of possible determinants of the kinetics of protein folding.

Elasticity and unfolding of single molecules of the giant muscle protein titin

The giant muscle protein titin, also called connectin, is responsible for the elasticity of relaxed striated muscle, as well as acting as the molecular scaffold for thick-filament formation. The titin molecule consists largely of tandem domains of the immunoglobulin and fibronectin-III types, together with specialized binding regions and a putative elastic region, the PEVK domain. We have done mechanical experiments on single molecules of titin to determine their visco-elastic properties, using an optical-tweezers technique. On a fast (0.1s) timescale titin is elastic and force-extension data can be fitted with standard random-coil polymer models, showing that there are two main sources of elasticity: one deriving from the entropy of straightening the molecule; the other consistent with extension of the polypeptide chain in the PEVK region. On a slower timescale and above a certain force threshold, the molecule displays stress-relaxation, which occurs in rapid steps of a few piconewtons, corresponding to yielding of internal structures by about 20 nm. This stress-relaxation probably derives from unfolding of immunoglobulin and fibronectin domains.

Time-resolved biophysical methods in the study of protein folding

Many of the biophysical techniques developed to characterize native proteins at equilibrium have now been adapted to the structural and thermodynamic characterization of transient intermediate populations during protein folding. Recent advances in these techniques, the use of novel methods of initiating refolding, and a convergence of theoretical and experimental approaches are leading to a detailed understanding of many aspects of the folding process.

Linguistic analysis of protein folding

Folding of nascent chains resembles the decoding of spoken language in that information is emitted as a unidirectional, one-dimensional string of elements, with higher structures and long-distance interactions emerging with time. Applying a "pseudolinguistic' analysis of structure to a set of all 36 possible six-stranded antiparallel beta-sandwich topologies reveals new order principles and reduces the complexity of this family significantly. The simple connectivity diagrams ("linguistic trees') proposed here allow predictions of the speed and cooperativity of beta-sheet folding and help understanding the cotranslational folding from the N-terminus.