Computational redesign of thioredoxin is hypersensitive towards minor conformational changes in the backbone template

Kristoffer Enøe Johansson; Nicolai Tidemand Johansen; Signe Christensen; Scott Horowitz; James C. A.  Bardwell; Johan Gotthardt Olsen; Martin Willemoës; Kresten Lindorff-Larsen; Jesper Ferkinghoff-Borg; Thomas Wim Hamelryck; Jakob R. Winther

doi:10.1016/j.jmb.2016.09.013

Computational redesign of thioredoxin is hypersensitive towards minor conformational changes in the backbone template

Kristoffer Enøe Johansson, Nicolai Tidemand Johansen, Signe Christensen, Scott Horowitz, James C. A. Bardwell, Johan Gotthardt Olsen, Martin Willemoës, Kresten Lindorff-Larsen, Jesper Ferkinghoff-Borg, Thomas Wim Hamelryck, Jakob R. Winther

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Abstract

Despite the development of powerful computational tools, the full-sequence design of proteins still remains a challenging task. To investigate the limits and capabilities of computational tools, we conducted a study of the ability of the program Rosetta to predict sequences that recreate the authentic fold of thioredoxin. Focusing on the influence of conformational details in the template structures, we based our study on 8 experimentally determined template structures and generated 120 designs from each. For experimental evaluation, we chose six sequences from each of the eight templates by objective criteria. The 48 selected sequences were evaluated based on their progressive ability to (1) produce soluble protein in Escherichia coli and (2) yield stable monomeric protein, and (3) on the ability of the stable, soluble proteins to adopt the target fold. Of the 48 designs, we were able to synthesize 32, 20 of which resulted in soluble protein. Of these, only two were sufficiently stable to be purified. An X-ray crystal structure was solved for one of the designs, revealing a close resemblance to the target structure. We found a significant difference among the eight template structures to realize the above three criteria despite their high structural similarity. Thus, in order to improve the success rate of computational full-sequence design methods, we recommend that multiple template structures are used. Furthermore, this study shows that special care should be taken when optimizing the geometry of a structure prior to computational design when using a method that is based on rigid conformations.

Originalsprog	Engelsk
Tidsskrift	Journal of Molecular Biology
Vol/bind	428
Udgave nummer	21
Sider (fra-til)	4361-4377
Antal sider	17
ISSN	0022-2836
DOI	https://doi.org/10.1016/j.jmb.2016.09.013
Status	Udgivet - 23 okt. 2016

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10.1016/j.jmb.2016.09.013

1-s2.0-S0022283616303783-mainAccepteret manuskript, 2,09 MB

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Johansson, K. E., Johansen, N. T., Christensen, S., Horowitz, S., Bardwell, J. C. A., Olsen, J. G., Willemoës, M., Lindorff-Larsen, K., Ferkinghoff-Borg, J., Hamelryck, T. W., & Winther, J. R. (2016). Computational redesign of thioredoxin is hypersensitive towards minor conformational changes in the backbone template. Journal of Molecular Biology, 428(21), 4361-4377. https://doi.org/10.1016/j.jmb.2016.09.013

Johansson, KE , Johansen, NT, Christensen, S, Horowitz, S, Bardwell, JCA, Olsen, JG , Willemoës, M , Lindorff-Larsen, K, Ferkinghoff-Borg, J, Hamelryck, TW & Winther, JR 2016, 'Computational redesign of thioredoxin is hypersensitive towards minor conformational changes in the backbone template', Journal of Molecular Biology, bind 428, nr. 21, s. 4361-4377. https://doi.org/10.1016/j.jmb.2016.09.013

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title = "Computational redesign of thioredoxin is hypersensitive towards minor conformational changes in the backbone template",

abstract = "Despite the development of powerful computational tools, the full-sequence design of proteins still remains a challenging task. To investigate the limits and capabilities of computational tools, we conducted a study of the ability of the program Rosetta to predict sequences that recreate the authentic fold of thioredoxin. Focusing on the influence of conformational details in the template structures, we based our study on 8 experimentally determined template structures and generated 120 designs from each. For experimental evaluation, we chose six sequences from each of the eight templates by objective criteria. The 48 selected sequences were evaluated based on their progressive ability to (1) produce soluble protein in Escherichia coli and (2) yield stable monomeric protein, and (3) on the ability of the stable, soluble proteins to adopt the target fold. Of the 48 designs, we were able to synthesize 32, 20 of which resulted in soluble protein. Of these, only two were sufficiently stable to be purified. An X-ray crystal structure was solved for one of the designs, revealing a close resemblance to the target structure. We found a significant difference among the eight template structures to realize the above three criteria despite their high structural similarity. Thus, in order to improve the success rate of computational full-sequence design methods, we recommend that multiple template structures are used. Furthermore, this study shows that special care should be taken when optimizing the geometry of a structure prior to computational design when using a method that is based on rigid conformations.",

author = "Johansson, {Kristoffer En{\o}e} and Johansen, {Nicolai Tidemand} and Signe Christensen and Scott Horowitz and Bardwell, {James C. A.} and Olsen, {Johan Gotthardt} and Martin Willemo{\"e}s and Kresten Lindorff-Larsen and Jesper Ferkinghoff-Borg and Hamelryck, {Thomas Wim} and Winther, {Jakob R.}",

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AU - Bardwell, James C. A.

AU - Olsen, Johan Gotthardt

AU - Willemoës, Martin

AU - Lindorff-Larsen, Kresten

AU - Ferkinghoff-Borg, Jesper

AU - Hamelryck, Thomas Wim

AU - Winther, Jakob R.

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N2 - Despite the development of powerful computational tools, the full-sequence design of proteins still remains a challenging task. To investigate the limits and capabilities of computational tools, we conducted a study of the ability of the program Rosetta to predict sequences that recreate the authentic fold of thioredoxin. Focusing on the influence of conformational details in the template structures, we based our study on 8 experimentally determined template structures and generated 120 designs from each. For experimental evaluation, we chose six sequences from each of the eight templates by objective criteria. The 48 selected sequences were evaluated based on their progressive ability to (1) produce soluble protein in Escherichia coli and (2) yield stable monomeric protein, and (3) on the ability of the stable, soluble proteins to adopt the target fold. Of the 48 designs, we were able to synthesize 32, 20 of which resulted in soluble protein. Of these, only two were sufficiently stable to be purified. An X-ray crystal structure was solved for one of the designs, revealing a close resemblance to the target structure. We found a significant difference among the eight template structures to realize the above three criteria despite their high structural similarity. Thus, in order to improve the success rate of computational full-sequence design methods, we recommend that multiple template structures are used. Furthermore, this study shows that special care should be taken when optimizing the geometry of a structure prior to computational design when using a method that is based on rigid conformations.

AB - Despite the development of powerful computational tools, the full-sequence design of proteins still remains a challenging task. To investigate the limits and capabilities of computational tools, we conducted a study of the ability of the program Rosetta to predict sequences that recreate the authentic fold of thioredoxin. Focusing on the influence of conformational details in the template structures, we based our study on 8 experimentally determined template structures and generated 120 designs from each. For experimental evaluation, we chose six sequences from each of the eight templates by objective criteria. The 48 selected sequences were evaluated based on their progressive ability to (1) produce soluble protein in Escherichia coli and (2) yield stable monomeric protein, and (3) on the ability of the stable, soluble proteins to adopt the target fold. Of the 48 designs, we were able to synthesize 32, 20 of which resulted in soluble protein. Of these, only two were sufficiently stable to be purified. An X-ray crystal structure was solved for one of the designs, revealing a close resemblance to the target structure. We found a significant difference among the eight template structures to realize the above three criteria despite their high structural similarity. Thus, in order to improve the success rate of computational full-sequence design methods, we recommend that multiple template structures are used. Furthermore, this study shows that special care should be taken when optimizing the geometry of a structure prior to computational design when using a method that is based on rigid conformations.

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DO - 10.1016/j.jmb.2016.09.013

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Computational redesign of thioredoxin is hypersensitive towards minor conformational changes in the backbone template

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