Kaspar Feldmeier scite author profile

Despite efforts for over 25 years, de novo protein design has not succeeded in achieving the TIM-barrel fold. Here we describe the computational design of 4-fold symmetrical (β/α)8-barrels guided by geometrical and chemical principles. Experimental characterization of 33 designs revealed the importance of sidechain-backbone hydrogen bonding for defining the strand register between repeat units. The X-ray crystal structure of a designed thermostable 184-residue protein is nearly identical with the designed TIM-barrel model. PSI-BLAST searches do not identify sequence similarities to known TIM-barrel proteins, and sensitive profile-profile searches indicate that the design sequence is distant from other naturally occurring TIM-barrel superfamilies, suggesting that Nature has only sampled a subset of the sequence space available to the TIM-barrel fold. The ability to de novo design TIM-barrels opens new possibilities for custom-made enzymes.

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Computational protein design of ligand binding and catalysis

Feldmeier

Höcker

2013

Current Opinion in Chemical Biology

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Identification of Protein Scaffolds for Enzyme Design Using Scaffold Selection

Stiel

Feldmeier

Höcker

2014

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The identification of suitable protein structures that can serve as scaffolds for the introduction of catalytic residues is crucial for the design of new enzymes. Here we describe how the automated and rapid scaffold search program ScaffoldSelection can be used to find the best starting points, namely protein structures that are most likely to tolerate the introduction and promote the proper formation of a specific catalytic motif.

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Crystal structure of a de novo designed TIM-barrel

Feldmeier¹,

Höcker²

2015

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Quantile-Quantile Plots: An Approach for the Inter-Species Comparison of Promoter Architecture in Eukaryotes

Feldmeier¹,

Kilian²,

Harter³

et al. 2011

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