Efficient Structure-factor Modeling for Crystals with Multiple Components

Overview

Journal Acta Crystallogr A Found Adv

Specialty Chemistry

Date 2023 Jun 20

PMID 37338214

Authors

Pavel V Afonine

Paul D Adams

Alexandre G Urzhumtsev

Affiliations

Soon will be listed here.

Abstract

Diffraction intensities from a crystallographic experiment include contributions from the entire unit cell of the crystal: the macromolecule, the solvent around it and eventually other compounds. These contributions cannot typically be well described by an atomic model alone, i.e. using point scatterers. Indeed, entities such as disordered (bulk) solvent, semi-ordered solvent (e.g. lipid belts in membrane proteins, ligands, ion channels) and disordered polymer loops require other types of modeling than a collection of individual atoms. This results in the model structure factors containing multiple contributions. Most macromolecular applications assume two-component structure factors: one component arising from the atomic model and the second one describing the bulk solvent. A more accurate and detailed modeling of the disordered regions of the crystal will naturally require more than two components in the structure factors, which presents algorithmic and computational challenges. Here an efficient solution of this problem is proposed. All algorithms described in this work have been implemented in the computational crystallography toolbox (CCTBX) and are also available within Phenix software. These algorithms are rather general and do not use any assumptions about molecule type or size nor about those of its components.

Citing Articles

Accounting for nonuniformity of bulk-solvent: A mosaic model.

Afonine P, Adams P, Sobolev O, Urzhumtsev A Protein Sci. 2024; 33(3):e4909.

PMID: 38358136 PMC: 10868464. DOI: 10.1002/pro.4909.

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