Characterisation of the BRCT domains of the breast cancer susceptibility gene product BRCA1.

The breast cancer susceptibility gene product BRCA1 is a tumour suppressor but the biochemical and biological functions that underlie its role in carcinogenesis remain to be determined. Here, we characterise the solution properties of the highly conserved C terminus of BRCA1, consisting of a tandem repeat of the BRCT domain (BRCT-tan), that plays a critical role in BRCA1-mediated tumour suppression. The overall free energy of unfolding of BRCT-tan is high (14.2 kcal mol(-1) at 20 degrees C in water) but unfolding occurs via an aggregation-prone, partly folded intermediate. A representative set of cancer-associated sequence variants was constructed and the effects on protein stability were measured. All of the mutations were highly destabilising and they would be expected to cause loss of function for this reason. Over half could not be purified in a soluble form, indicating that these residues are critical for maintaining structural integrity. The remaining mutants exhibited much greater aggregation propensities than the wild-type, which is most likely a consequence of their reduced thermodynamic stability relative to the partly folded intermediate. The mutations characterised here are located at different sites in the BRCT-tan structure that do not explain fully their effects on the protein's stability. Thus, the results indicate an important role for biophysical studies in assessing the significance of sequence variants and in determining how they cause disease.

Observation of signal transduction in three-dimensional domain swapping.

p13suc1 (suc1) has two native states, a monomer and a domain-swapped dimer. The structure of each subunit in the dimer is identical to that of the monomer, except for the hinge loop that connects the exchanging domains. Here we find that single point mutations at sites throughout the protein and ligand binding both shift the position of the equilibrium between monomer and dimer. The hinge loop was shown previously to act as a loaded molecular spring that releases tension present in the monomer by adopting an alternative conformation in the dimer. The results here indicate that the release of strain propagates throughout the entire protein and alters the energetics of regions remote from the hinge. Our data illustrate how the signal conferred by the conformational change of a protein loop, elicited by domain swapping, ligand binding or mutation, can be sensed by a distant active site. This work highlights the potential role of strained loops in proteins: the energy they store can be used for both signal transduction and allostery, and they could steer the evolution of protein function. Finally, a structural mechanism for the role of suc1 as an adapter molecule is proposed.

Three-dimensional domain swapping in p13suc1 occurs in the unfolded state and is controlled by conserved proline residues.

p13suc1 has two native states, a monomer and a domain-swapped dimer. We show that their folding pathways are connected by the denatured state, which introduces a kinetic barrier between monomer and dimer under native conditions. The barrier is lowered under conditions that speed up unfolding, thereby allowing, to our knowledge for the first time, a quantitative dissection of the energetics of domain swapping. The monomer-dimer equilibrium is controlled by two conserved prolines in the hinge loop that connects the exchanging domains. These two residues exploit backbone strain to specifically direct dimer formation while preventing higher-order oligomerization. Thus, the loop acts as a loaded molecular spring that releases tension in the monomer by adopting its alternative conformation in the dimer. There is an excellent correlation between domain swapping and aggregation, suggesting they share a common mechanism. These insights have allowed us to redesign the domain-swapping propensity of suc1 from a fully monomeric to a fully dimeric protein.

Sequence conservation provides the best prediction of the role of proline residues in p13suc1.

The unique nature of the proline side-chain imposes severe constraints on the polypeptide backbone, and thus it seems likely that it plays a special structural or functional role in the architecture of proteins. We have investigated the role of proline residues in suc1, a member of the cyclin-dependent kinase (cks) family of proteins, whose known function is to bind to and regulate the activity of the major mitotic cdk. The effect on stability of mutation to alanine of all but two of the eight proline residues is correlated with their conservation within the family. The remaining two proline residues are located in the hinge loop between two beta-strands that mediates a domain-swapping process involving exchange of a beta-strand between two monomers to form a dimer pair. Mutation of these proline residues to alanine stabilises the protein. cdk binding is unaffected by these mutations, but dimerisation is altered. We propose, therefore, that the double-proline motif is conserved for the purpose of domain swapping, which suggests that this phenomenon plays a role in the function of cks proteins. Thus, the conservation of the proline residues is a good indicator of their roles in suc1, either in the stabilisation of the native state or in performing functions that are as yet unknown. In addition, the strain resulting from two of the proline residues was relieved successfully by mutation of the preceeding residue to glycine, suggesting a general method for designing more stable proteins.

The folding pathway of the cell-cycle regulatory protein p13suc1: clues for the mechanism of domain swapping.

BACKGROUND: The 113-residue alpha+beta protein suc1 is a member of the cyclin-dependent kinase subunit (cks) family of proteins that are involved in regulation of the eukaryotic cell cycle. In vitro, suc1 undergoes domain swapping to form a dimer by the exchange of a C-terminal beta strand. We have analysed the folding pathway of suc1 in order to determine the atomic details of how strand-exchange occurs in vitro and thereby obtain clues as to the possible mechanism and functional role of dimerisation in vivo. RESULTS: The structures of the rate-determining transition state for the folding/unfolding of suc1 and of the intermediate that is populated during refolding were probed using phi values determined for 57 mutants with substitutions at 43 sites throughout the protein. The majority of phi values are fractional in the intermediate and transition state, indicating that interactions build up in a concerted manner during folding. In the transition state, phi values of greater than 0.5 are clustered around the inner strands beta2 and beta4 of the beta sheet. This part of the structure constitutes the nucleus for folding according to a nucleation-condensation mechanism. Molecular dynamics simulations of unfolding of suc1, performed independently in a blind manner, are in excellent agreement with experiment (proceeding paper). CONCLUSIONS: Strand beta4 is the exchanging strand in the dimer and yet it forms an integral part of the folding nucleus. This suggests that association is an early event in the folding reaction of the dimer. Therefore, interchange between the monomer and dimer must occur via an unfolded state, a process that may be facilitated in vivo by accessory proteins.

Stability and folding of the cell cycle regulatory protein, p13(suc1).

p13(suc1) (suc1) is a member of the CDC28 kinase specific family of cell cycle regulatory proteins that bind to the cyclin-dependent kinase CDK2 and regulate its activity. suc1 has two distinct conformational and assembly states, a compact globular monomer and a beta strand-exchanged dimer. The dimerisation is an example of domain-swapping, and is mediated by a molecular hinge mechanism that is conserved across the entire CKS family. It has been proposed that the function of suc1 may be modulated by the dimerisation process with monomer-dimer switching occurring in response to a change in the cell environment. We have investigated the stability and folding of suc1 as a first step in determining the mechanism and functional role of the strand exchange. Suc1 unfolds reversibly at equilibrium in a two-state manner with a free energy of unfolding of 7.2 kcal mol-1. The kinetics of folding and unfolding are complex, and double-jump stopped-flow methods revealed that there are at least three parallel folding pathways arising from distinct unfolded and partly folded, intermediate states. The major population of unfolded species fold rapidly according to a three-state mechanism, D1->I1->N, with a rate constant for the formation of native species, N, from the intermediate, I1, of 65 s-1 in water. Two minor populations of unfolded molecules fold more slowly. Folding of one population is limited by proline isomerisation in a partly folded state, and some expansion of the protein is required for isomerisation to occur. The other population could be assigned to rate-limiting isomerisation of the peptidyl-proline bond of residue 90, which is located in the molecular hinge. A minor, fast phase was detected in the unfolding kinetics that corresponds to unfolding of a small population of a distinct native-like form. Heterogeneity was removed upon mutation of Pro90 to Ala. The unfolding kinetics of the strand-exchanged dimer were also investigated and showed that the dimer unfolds at the same rate as the monomer.