Themed collection Exploring the conformational heterogeneity of biomolecules: theory and experiments

This themed collection reports on recent progress in the investigation of the conformational variability of biomolecules (proteins and nucleic acids), both from an experimental and theoretical point of view.

We analyze the different approaches to obtain quantitative and accurate structural information from averaged data. We cluster them in two groups: those satisfying the maximum entropy principle and those recovering ensembles composed of a restricted number of conformations. Information of different types are recovered in the two cases.

Enhanced sampling simulations of N-terminally acetylated human α-synuclein suggest that the post-translational modification leads to the formation of a transient amphipathic α-helix altering protein dynamics at the N-terminal and intramolecular interactions.

The structural variability of HET-s(218–289) loops is restricted by the β-sheet core.

Paramagnetic data show that the average structure of T4-lysozyme in solution is more open than its crystal structure.

Intrinsically disordered proteins (IDPs) and proteins with intrinsically disordered regions (IDRs) are known to play important roles in regulatory and signaling pathways.

SREFLEX employs normal mode analysis for the flexible refinement of atomic models of biological macromolecules against solution scattering data, providing insight into conformational transitions.

A probabilistic method infers ensembles of intrinsically disordered proteins (IDPs) by combining SAXS data with a force field.

The conformational landscape of HIV-1 protease can be characterized by double electron–electron resonance (DEER) spin-labeling.

Syk high-affinity association with receptor ITAM is regulated by a phosphorylation-dependent allosteric mechanism. NMR titration-curve/line-shape analyses determined phosphorylation increases the energetic barrier for, but does not prevent, isomerization.

Alternative labeling sites using the ‘rigid’ Rx spin label on protein secondary structures are explored and high field orientation measurements are made.

Carr–Purcell–Meiboom–Gill (CPMG) relaxation dispersion measurements are a valuable tool for the characterization of structural transitions on the micro-millisecond timescale.

Ensemble analysis using NMR and SANS revealed conformational heterogeneity of polyubiquitin chains, suggesting unique as well as overlapping functions.

³ J _C′Hα couplings in disordered proteins allow quantitative evaluation of the fraction of time each residue adopts a positive ϕ backbone angle.

NMR-based paramagnetic relaxation interference (PRI) allows for direct observation of concerted motions and cooperatively folded sub-states in IDPs, via cross correlated relaxation.

Molecular dynamics simulations and maximum occurrence distribution identify the same most likely sampled conformations over the available conformational space.

The effect of spin label mobility on the accuracy of protein–protein docking calculations was investigated using inter- and intra-molecular PRE data.

A set of coupled differential equations is presented describing the evolution of magnetization due to an exchange reaction whereby a pair of identical monomers form an asymmetric dimer.