scholarly journals Tight and specific lanthanide binding in a de novo TIM barrel with a large internal cavity designed by symmetric domain fusion

2020 ◽  
Vol 117 (48) ◽  
pp. 30362-30369
Author(s):  
Shane J. Caldwell ◽  
Ian C. Haydon ◽  
Nikoletta Piperidou ◽  
Po-Ssu Huang ◽  
Matthew J. Bick ◽  
...  
Keyword(s):  
Protein Design ◽  
Metal Binding ◽  
De Novo ◽  
Enzymatic Reaction ◽  
Symmetric Domain ◽  
Lanthanide Ions ◽  
Internal Cavity ◽  
Tim Barrel ◽  
Reaction Chambers ◽  
Modular Platform

De novo protein design has succeeded in generating a large variety of globular proteins, but the construction of protein scaffolds with cavities that could accommodate large signaling molecules, cofactors, and substrates remains an outstanding challenge. The long, often flexible loops that form such cavities in many natural proteins are difficult to precisely program and thus challenging for computational protein design. Here we describe an alternative approach to this problem. We fused two stable proteins with C2 symmetry—a de novo designed dimeric ferredoxin fold and a de novo designed TIM barrel—such that their symmetry axes are aligned to create scaffolds with large cavities that can serve as binding pockets or enzymatic reaction chambers. The crystal structures of two such designs confirm the presence of a 420 cubic Ångström chamber defined by the top of the designed TIM barrel and the bottom of the ferredoxin dimer. We functionalized the scaffold by installing a metal-binding site consisting of four glutamate residues close to the symmetry axis. The protein binds lanthanide ions with very high affinity as demonstrated by tryptophan-enhanced terbium luminescence. This approach can be extended to other metals and cofactors, making this scaffold a modular platform for the design of binding proteins and biocatalysts.

scholarly journals Epistasis on the stability landscape of de novo TIM barrels explored by a modular design approach

2020 ◽  
Author(s):  
Sergio Romero-Romero ◽  
Miguel Costas ◽  
Daniel-Adriano Silva Manzano ◽  
Sina Kordes ◽  
Erendira Rojas-Ortega ◽  
...  
Keyword(s):  
Protein Stability ◽  
Protein Design ◽  
Modular Design ◽  
De Novo ◽  
Conformational Stability ◽  
Modular Approach ◽  
Structure And Stability ◽  
Custom Made ◽  
Tim Barrel ◽  
The Stability

AbstractThe design of stable proteins with custom-made functions is a major goal in biochemistry with practical relevance for our environment and society. High conformational stability lowers protein sensitivity to mutations and changes in the environment; thus, understanding and manipulating protein stability will expand the applications of de novo proteins. Since the (β/α)8-barrel or TIM-barrel fold is one of the most common functional scaffolds, in this work we designed a collection of stable de novo TIM barrels (NovoTIMs), using a computational fixed-backbone and modular approach based on improved hydrophobic packing of sTIM11, the first validated de novo TIM barrel. NovoTIMs navigate a region of the stability landscape previously uncharted by natural TIM barrels, with variations spanning 60 degrees in melting temperature and 25 kcal per mol in conformational stability throughout the designs. Significant non-additive or epistatic effects were observed when stabilizing mutations from different regions of the barrel were combined. The molecular basis of epistasis in NovoTIMs appears to be related to the extension of the hydrophobic cores. This study is an important step towards the fine-tuned modulation of protein stability by design.Significance StatementDe novo protein design expands our knowledge about protein structure and stability. The TIM barrel is a highly relevant fold used in nature to host a rich variety of catalytic functions. Here, we follow a modular approach to design and characterize a collection of de novo TIM barrels and subjected them to a thorough folding analysis. Non-additive effects modulate the increase in stability when different regions of the barrel are mutated, showing a wide variety of thermodynamic properties that allow them to navigate an unexplored region of the stability landscape found in natural TIM barrels. The design of stable proteins increases the applications of de novo proteins and provides more information on the molecular determinants that modulate structure and stability.

scholarly journals Extension of a de novo TIM barrel with a rationally designed secondary structure element

2020 ◽  
Author(s):  
Jonas Gregor Wiese ◽  
Sooruban Shanmugaratnam ◽  
Birte Höcker
Keyword(s):  
High Resolution ◽  
Secondary Structure ◽  
Protein Design ◽  
Building Block ◽  
Biochemical Characterization ◽  
De Novo ◽  
X Ray ◽  
Future Design ◽  
Catalytic Sites ◽  
Tim Barrel

SummaryThe ability to construct novel enzymes is a major aim in de novo protein design. A popular enzyme fold for design attempts is the TIM barrel. This fold is a common topology for enzymes and can harbor many diverse reactions. The recently published de novo design of a four-fold symmetric TIM barrel provides a well understood minimal scaffold for potential enzyme designs. Here we explore opportunities to extend and diversify this scaffold by adding a short de novo helix on top of the barrel. Due to the size of the protein we developed a design pipeline based on computational ab initio folding that solves a less complex sub-problem focused around the helix and its vicinity and adapt it to the entire protein. We provide biochemical characterization and a high-resolution X-ray structure for one variant and compare it to our design model. The successful extension of this robust TIM-barrel scaffold opens opportunities to diversify it towards more pocket like arrangements and as such can be considered a building block for future design of binding or catalytic sites.

scholarly journals Bottom-up de novo protein design

2021 ◽  
Vol 18 (3) ◽  
pp. 233-233
Author(s):  
Arunima Singh
Keyword(s):  
Protein Design ◽  
De Novo ◽  
Bottom Up ◽  
De Novo Protein Design

scholarly journals Extension of a de novo TIM barrel with a rationally designed secondary structure element

2021 ◽  
Vol 30 (5) ◽  
pp. 982-989
Author(s):  
Jonas Gregor Wiese ◽  
Sooruban Shanmugaratnam ◽  
Birte Höcker
Keyword(s):  
Secondary Structure ◽  
De Novo ◽  
Secondary Structure Element ◽  
Tim Barrel

scholarly journals Rational thermostabilisation of four-helix bundle dimeric de novo proteins

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Shin Irumagawa ◽  
Kaito Kobayashi ◽  
Yutaka Saito ◽  
Takeshi Miyata ◽  
Mitsuo Umetsu ◽  
...  
Keyword(s):  
Protein Design ◽  
De Novo ◽  
Protein Complexes ◽  
Salt Bridge ◽  
Dynamics Simulation ◽  
Saturation Mutagenesis ◽  
Helix Bundle ◽  
Stable Mutant ◽  
Four Helix Bundle ◽  
The Stability

AbstractThe stability of proteins is an important factor for industrial and medical applications. Improving protein stability is one of the main subjects in protein engineering. In a previous study, we improved the stability of a four-helix bundle dimeric de novo protein (WA20) by five mutations. The stabilised mutant (H26L/G28S/N34L/V71L/E78L, SUWA) showed an extremely high denaturation midpoint temperature (Tm). Although SUWA is a remarkably hyperstable protein, in protein design and engineering, it is an attractive challenge to rationally explore more stable mutants. In this study, we predicted stabilising mutations of WA20 by in silico saturation mutagenesis and molecular dynamics simulation, and experimentally confirmed three stabilising mutations of WA20 (N22A, N22E, and H86K). The stability of a double mutant (N22A/H86K, rationally optimised WA20, ROWA) was greatly improved compared with WA20 (ΔTm = 10.6 °C). The model structures suggested that N22A enhances the stability of the α-helices and N22E and H86K contribute to salt-bridge formation for protein stabilisation. These mutations were also added to SUWA and improved its Tm. Remarkably, the most stable mutant of SUWA (N22E/H86K, rationally optimised SUWA, ROSA) showed the highest Tm (129.0 °C). These new thermostable mutants will be useful as a component of protein nanobuilding blocks to construct supramolecular protein complexes.

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