Enumeration and comprehensive in-silico modeling of three-helix bundle structures composed of typical αα-hairpins
| Autor: | Shintaro Minami, Koya Sakuma |
|---|---|
| Jazyk: | angličtina |
| Rok vydání: | 2021 |
| Předmět: |
Protein Conformation
alpha-Helical Fragment assembly Protein Conformation Computer science QH301-705.5 Protein design Computer applications to medicine. Medical informatics Structure (category theory) R858-859.7 α-Helical protein Topology Biochemistry Protein Structure Secondary Set (abstract data type) Protein structure Structural Biology Simple (abstract algebra) Amino Acid Sequence Biology (General) Molecular Biology Helix bundle Research Applied Mathematics Proteins Construct (python library) Helical bundle αα-Hairpins Computer Science Applications Bundle |
| Zdroj: | BMC Bioinformatics, Vol 22, Iss 1, Pp 1-15 (2021) BMC Bioinformatics |
| ISSN: | 1471-2105 |
| Popis: | Background The design of protein structures from scratch requires special attention to the combination of the types and lengths of the secondary structures and the loops required to build highly designable backbone structure models. However, it is difficult to predict the combinations that result in globular and protein-like conformations without simulations. In this study, we used single-chain three-helix bundles as simple models of protein tertiary structures and sought to thoroughly investigate the conditions required to construct them, starting from the identification of the typical αα-hairpin motifs. Results First, by statistical analysis of naturally occurring protein structures, we identified three αα-hairpins motifs that were specifically related to the left- and right-handedness of helix-helix packing. Second, specifying these αα-hairpins motifs as junctions, we performed sequence-independent backbone-building simulations to comparatively build single-chain three-helix bundle structures and identified the promising combinations of the length of the α-helix and αα-hairpins types that results in tight packing between the first and third α-helices. Third, using those single-chain three-helix bundle backbone structures as template structures, we designed amino acid sequences that were predicted to fold into the target topologies, which supports that the compact single-chain three-helix bundles structures that we sampled show sufficient quality to allow amino-acid sequence design. Conclusion The enumeration of the dominant subsets of possible backbone structures for small single-chain three-helical bundle topologies revealed that the compact foldable structures are discontinuously and sparsely distributed in the conformational space. Additionally, although the designs have not been experimentally validated in the present research, the comprehensive set of computational structural models generated also offers protein designers the opportunity to skip building similar structures by themselves and enables them to quickly focus on building specialized designs using the prebuilt structure models. The backbone and best design models in this study are publicly accessible from the following URL: https://doi.org/10.5281/zenodo.4321632. |
| Databáze: | OpenAIRE |
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