TY - JOUR
T1 - Mis-translation of a Computationally Designed Protein Yields an Exceptionally Stable Homodimer
T2 - Implications for Protein Engineering and Evolution
AU - Dantas, Gautam
AU - Watters, Alexander L.
AU - Lunde, Bradley M.
AU - Eletr, Ziad M.
AU - Isern, Nancy G.
AU - Roseman, Toby
AU - Lipfert, Jan
AU - Doniach, Sebastian
AU - Tompa, Martin
AU - Kuhlman, Brian
AU - Stoddard, Barry L.
AU - Varani, Gabriele
AU - Baker, David
N1 - Funding Information:
We acknowledge the expert assistance of Steve Reichow, Tom Leeper, and Kate Godin in NMR data collection and processing, and modelling and refinement of the CFr structure; Priti Deka for help with NMR dynamics analysis of CFr; Juan Pizarro and Django Sussman for help with crystallographic data collection and processing; Soenke Seifert for help with SAXS data collection; Mark DePristo for insightful comments about mechanisms of protein evolution; the facilities at NMRFAM (Madison, WI, supported by NIH) and PNNL (Richland, WA, supported by DOE) for access to NMR instrumentation, and the facilities at the Advanced Light Source (Berkeley, CA, supported by DOE); and the Advanced Photon Source (Argonne, IL, supported by DOE) for access to their synchrotron-source X-ray beamlines. This work is supported in part by grants from NIH-NIGMS (to G.V.) and NIH and HHMI (to D.B.).
PY - 2006/10/6
Y1 - 2006/10/6
N2 - We recently used computational protein design to create an extremely stable, globular protein, Top7, with a sequence and fold not observed previously in nature. Since Top7 was created in the absence of genetic selection, it provides a rare opportunity to investigate aspects of the cellular protein production and surveillance machinery that are subject to natural selection. Here we show that a portion of the Top7 protein corresponding to the final 49 C-terminal residues is efficiently mis-translated and accumulates at high levels in Escherichia coli. We used circular dichroism, size-exclusion chromatography, small-angle X-ray scattering, analytical ultra-centrifugation, and NMR spectroscopy to show that the resulting C-terminal fragment (CFr) protein adopts a compact, extremely stable, homo-dimeric structure. Based on the solution structure, we engineered an even more stable variant of CFr by disulfide-induced covalent circularisation that should be an excellent platform for design of novel functions. The accumulation of high levels of CFr exposes the high error rate of the protein translation machinery. The rarity of correspondingly stable fragments in natural proteins coupled with the observation that high quality ribosome binding sites are found to occur within E. coli protein-coding regions significantly less often than expected by random chance implies a stringent evolutionary pressure against protein sub-fragments that can independently fold into stable structures. The symmetric self-association between two identical mis-translated CFr sub-domains to generate an extremely stable structure parallels a mechanism for natural protein-fold evolution by modular recombination of protein sub-structures.
AB - We recently used computational protein design to create an extremely stable, globular protein, Top7, with a sequence and fold not observed previously in nature. Since Top7 was created in the absence of genetic selection, it provides a rare opportunity to investigate aspects of the cellular protein production and surveillance machinery that are subject to natural selection. Here we show that a portion of the Top7 protein corresponding to the final 49 C-terminal residues is efficiently mis-translated and accumulates at high levels in Escherichia coli. We used circular dichroism, size-exclusion chromatography, small-angle X-ray scattering, analytical ultra-centrifugation, and NMR spectroscopy to show that the resulting C-terminal fragment (CFr) protein adopts a compact, extremely stable, homo-dimeric structure. Based on the solution structure, we engineered an even more stable variant of CFr by disulfide-induced covalent circularisation that should be an excellent platform for design of novel functions. The accumulation of high levels of CFr exposes the high error rate of the protein translation machinery. The rarity of correspondingly stable fragments in natural proteins coupled with the observation that high quality ribosome binding sites are found to occur within E. coli protein-coding regions significantly less often than expected by random chance implies a stringent evolutionary pressure against protein sub-fragments that can independently fold into stable structures. The symmetric self-association between two identical mis-translated CFr sub-domains to generate an extremely stable structure parallels a mechanism for natural protein-fold evolution by modular recombination of protein sub-structures.
KW - NMR structure
KW - mistranslation
KW - protein engineering
KW - protein sub-fragments
KW - protein-fold evolution
UR - http://www.scopus.com/inward/record.url?scp=33748474370&partnerID=8YFLogxK
U2 - 10.1016/j.jmb.2006.07.092
DO - 10.1016/j.jmb.2006.07.092
M3 - Article
C2 - 16949611
AN - SCOPUS:33748474370
SN - 0022-2836
VL - 362
SP - 1004
EP - 1024
JO - Journal of Molecular Biology
JF - Journal of Molecular Biology
IS - 5
ER -