tackled this problem by integration of MS, NMR, and IM-MS data [74] to characterize αB-crystallin, a small heat shock protein
(Fig. 4). MS data indicated that this system exists in a dynamic equilibrium of differently sized oligomers. NMR spectra revealed that each monomer exists in a symmetrical environment. A range of candidate structures was constructed formed by either series of regular polyhedra or rings. Computed collision cross-sections (CCS) of these models were compared to those obtained experimentally. Enzalutamide datasheet Using the observed trends in CCS, consistent models of the dominant αB-crystallin 24-, 26- and 28-mer oligomers were identified as polyhedral architectures. These arrangements provide a structural rationale for the interconversion of these oligomers via loss and addition of a subunit. In a similar integrated approach atomic structures of 24-mer αB-crystallin complexes have been derived [75] and [76]. Lack of symmetry in a check details complex also means a significant loss of information to drive the modeling. Thus studies on non-symmetrical complexes are typically limited to dock two subunits together, of which one may be a known, multi-subunit complex itself. Recent work of the Kay lab
focused on the interaction between the 70 kDa DnaK and the 580 kDa hexameric ClpB in protein disaggregation [77]. Using an impressive, and pragmatic, combination of backbone and methyl-group based TROSY and complexes with hexameric and monomeric
variants of ClpB, the authors could define the binding surfaces on both proteins from CSP measurements and identify a 1:6 stoichiometry of the DnaK:ClpB complex. PRE measurements were performed on complexes of ILVM-labeled DnaK nucleotide binding domain bound to monomeric ClpB, labeled with MTSL at five different positions. The resulting 29 distance restraints were combined with CSP-derived Calpain ambiguous interaction restraints to dock the DnaK-NBD to a ClpB monomer (Fig. 5). The models were validated by mutagenesis and used to devise functional test of ClpB–DnaK function in protein disaggregation, revealing that the DnaK–ClpB interaction stimulates ClpB activity on the substrate. A nice example of how different types of NMR data can be used comes from the docking of a nuclear export signal (NES) peptide to the 150 kDa exportin CRM1/RanGTP complex [42] and [78]. Using an intricate combination of 13C-direct detection, CRINEPT-TROSY, several ambiguous and unambiguous intermolecular NOEs and solvent PREs, the peptide was docked precisely and in a well-defined conformation to its binding site. The resulting structures were consistent with the crystal structure of the complex based on a NES-fusion protein and explained structural basis of NES recognition. As a large DNA–protein complex, nucleosomes present an additional challenge in modeling of their complexes with other chromatin factors.