<i>De novo</i> backbone scaffolds for protein design

MacDonald, James T.; Maksimiak, Katarzyna; Sadowski, Michael I.; Taylor, William R.

doi:10.1002/prot.22651

Cited by 39 publications

(45 citation statements)

References 46 publications

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“…The available methods that are able to reconstruct mainchain atoms while keeping the C a atom positions fixed were compared to the method described in this article. Some methods [5,18,27] are additionally able to refine C a positions but this aspect is not explored in this article.…”

Section: Introductionmentioning

confidence: 91%

“…The C a atoms were kept fixed in position during minimization with all other backbone atoms free to move. This was performed using a previously described simple backbone potential energy function [5] consisting of local structure molecular mechanics terms derived from the OPLS-UA force field (bond, torsion, improper torsion, 1-4 Lennard-Jones, 1-4 electrostatic, 1-5 LennardJones, and 1-5 electrostatic), a soft steric repulsive term for atom pairs separated by more than four bonds and statistical backbone hydrogen bonding potential terms. In fitting length six fragments to a C a trace, there is inevitably a problem at the beginning and end of each polypeptide chain, where there are insufficient C a atoms either side of the peptide bonds to anchor the fragment.…”

Section: Full Paper Wwwc-chemorgmentioning

confidence: 99%

“…[2] C a coarse-grained models have also been successfully used for protein structure prediction applications [3,4] and have the potential to be used in computational protein design. [5,6] In order for the multiscale modeling approach to be viable, a fast and accurate method of interconversion between coarse-and fine-grained models is required. Recent evidence has shown that at low resolutions, low crystallographic R-values are still achievable if the model is accurate, such as if it is restrained to a similar structure refined at high resolution.…”

Section: Introductionmentioning

confidence: 99%

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High–quality protein backbone reconstruction from alpha carbons using Gaussian mixture models

et al. 2013

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Coarse-grained protein structure models offer increased efficiency in structural modeling, but these must be coupled with fast and accurate methods to revert to a full-atom structure. Here, we present a novel algorithm to reconstruct mainchain models from C traces. This has been parameterized by fitting Gaussian mixture models (GMMs) to short backbone fragments centered on idealized peptide bonds. The method we have developed is statistically significantly more accurate than several competing methods, both in terms of RMSD values and dihedral angle differences. The method produced Ramachandran dihedral angle distributions that are closer to that observed in real proteins and better Phaser molecular replacement log-likelihood gains. Amino acid residue sidechain reconstruction accuracy using SCWRL4 was found to be statistically significantly correlated to backbone reconstruction accuracy. Finally, the PD2 method was found to produce significantly lower energy full-atom models using Rosetta which has implications for multiscale protein modeling using coarse-grained models. A webserver and C++ source code is freely available for noncommercial use from: http://www.sbg.bio.ic.ac.uk/phyre2/PD2_ca2main/.

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Section: Introductionmentioning

confidence: 91%

Section: Full Paper Wwwc-chemorgmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High–quality protein backbone reconstruction from alpha carbons using Gaussian mixture models

et al. 2013

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“…The incorporation of backbone flexibility in protein design has been recognized as a key challenge in computational protein design (30), with current methods typically reusing backbone fragments from other known protein structures (31,32). Recently, we have developed algorithms to sample loop conformations rapidly using a coarse-grained C α model (33) and to reconstruct proteins backbones accurately (34) as part of an approach that often gave subangstrom root-mean-square deviation (RMSD) loop predictions (35). In this paper, we have applied these techniques to de novo backbone design without using fragments from known protein structures while also explicitly considering alternative conformational states.…”

Section: Significancementioning

confidence: 99%

Synthetic beta-solenoid proteins with the fragment-free computational design of a beta-hairpin extension

MacDonald

Kabasakal

Godding

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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The ability to design and construct structures with atomic level precision is one of the key goals of nanotechnology. Proteins offer an attractive target for atomic design because they can be synthesized chemically or biologically and can self-assemble. However, the generalized protein folding and design problem is unsolved. One approach to simplifying the problem is to use a repetitive protein as a scaffold. Repeat proteins are intrinsically modular, and their folding and structures are better understood than large globular domains. Here, we have developed a class of synthetic repeat proteins based on the pentapeptide repeat family of beta-solenoid proteins. We have constructed length variants of the basic scaffold and computationally designed de novo loops projecting from the scaffold core. The experimentally solved 3.56-Å resolution crystal structure of one designed loop matches closely the designed hairpin structure, showing the computational design of a backbone extension onto a synthetic protein core without the use of backbone fragments from known structures. Two other loop designs were not clearly resolved in the crystal structures, and one loop appeared to be in an incorrect conformation. We have also shown that the repeat unit can accommodate whole-domain insertions by inserting a domain into one of the designed loops.computational protein design | synthetic repeat proteins | de novo backbone design | coarse-grained model D uring the course of evolution, natural proteins may be recruited to new unrelated functions conferring a selective advantage to the organism (1, 2). This accretion of new features and functions is likely to have left behind complex interlocking amino acid dependencies that can make reengineering natural proteins difficult and unpredictable (3). For this reason, we and others hypothesize that it is more desirable to design de novo proteins because these proteins provide a biologically neutral platform onto which functional elements can be grafted (4). Artificial proteins have been designed by decoding simple residue patterning rules that govern the packing of secondary structural elements, and this technique has been particularly successful for α-helical bundle proteins (5-7). An alternative approach is to assemble de novo folds from backbone fragments of known structures or idealized secondary structural elements and use computational protein design methods to design the sequence (4,(8)(9)(10). Both the computational and simpler rules-based design approaches have concentrated on designing proteins consisting of canonical secondary structure linked with loops of minimal length.A class of proteins that has attracted considerable interest is artificial proteins based on repeating structural motifs due to their intrinsic modularity and designability (11). Repeat proteins have applications that include their use as novel nanomaterials (12-14) and as scaffolds for molecular recognition (15, 16). These proteins may be designed using sequence consensus-based rules (17) or computational prot...

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“…The simplest way to find a backbone structure that is capable of being designed is to reuse experimentally solved backbone structures and/or local loop remodeling; however, there has been work on methods to design de novo backbone structures [17][18][19][20].…”

Section: Computational Designmentioning

confidence: 99%