Computational Reconstruction of Atomistic Protein Structures from Coarse-grained Models

Overview

Journal Comput Struct Biotechnol J

Specialty Biotechnology

Date 2020 Jan 24

PMID 31969975

Citations 20

Authors

Aleksandra E Badaczewska-Dawid

Andrzej Kolinski

Sebastian Kmiecik

Affiliations

Soon will be listed here.

Abstract

Three-dimensional protein structures, whether determined experimentally or theoretically, are often too low resolution. In this mini-review, we outline the computational methods for protein structure reconstruction from incomplete coarse-grained to all atomistic models. Typical reconstruction schemes can be divided into four major steps. Usually, the first step is reconstruction of the protein backbone chain starting from the C-alpha trace. This is followed by side-chains rebuilding based on protein backbone geometry. Subsequently, hydrogen atoms can be reconstructed. Finally, the resulting all-atom models may require structure optimization. Many methods are available to perform each of these tasks. We discuss the available tools and their potential applications in integrative modeling pipelines that can transfer coarse-grained information from computational predictions, or experiment, to all atomistic structures.

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