AI Article Synopsis
- Advances in protein expression and handling techniques have improved the ability to study complex biomolecules like disordered and membrane proteins using small-angle scattering (SAXS) experiments.
- A new modeling scheme combines classical form factor modeling with spherical harmonics to accurately calculate scattering profiles from these intricate samples, allowing for better structural analysis.
- The efficacy of the modeling is illustrated with the growth hormone receptor in a phospholipid bilayer nanodisc, demonstrating how varying scattering contrasts influence the structural information obtained from the data.
Article Abstract
Recent advances in protein expression protocols, sample handling, and experimental set up of small-angle scattering experiments have allowed users of the technique to structurally investigate biomolecules of growing complexity and structural disorder. Notable examples include intrinsically disordered proteins, multi-domain proteins and membrane proteins in suitable carrier systems. Here, we outline a modeling scheme for calculating the scattering profiles from such complex samples. This kind of modeling is necessary for structural information to be refined from the corresponding data. The scheme bases itself on a hybrid of classical form factor based modeling and the well-known spherical harmonics-based formulation of small-angle scattering amplitudes. Our framework can account for flexible domains alongside other structurally elaborate components of the molecular system in question. We demonstrate the utility of this modeling scheme through a recent example of a structural model of the growth hormone receptor membrane protein in a phospholipid bilayer nanodisc which is refined against experimental SAXS data. Additionally we investigate how the scattering profiles from the complex would appear under different scattering contrasts. For each contrast situation we discuss what structural information is contained and the related consequences for modeling of the data.
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| http://dx.doi.org/10.1016/j.jcis.2022.12.024 | DOI Listing |
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