Structure-Based Engineering of Internal Cavities in Coiled-Coil Peptides

Cavities and clefts are frequently important sites of interaction between natural enzymes or receptors and their corresponding substrate or ligand molecules and exemplify the types of molecular surfaces that would facilitate engineering of artificial catalysts and receptors. Even so, structural char...

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Bibliographic Details
Published in:Biochemistry (Easton) 2005-07, Vol.44 (28), p.9723-9732
Main Authors: Yadav, Maneesh K, Redman, James E, Leman, Luke J, Alvarez-Gutiérrez, Julietta M, Zhang, Yanming, Stout, C. David, Ghadiri, M. Reza
Format: Article
Language:English
Subjects:
Amino Acid Sequence
Binding Sites
Circular Dichroism
Crystallization
Crystallography, X-Ray
DNA-Binding Proteins - chemistry
Hydrophobic and Hydrophilic Interactions
Iodobenzenes - chemistry
Models, Chemical
Models, Molecular
Molecular Sequence Data
Peptides - chemistry
Protein Engineering - methods
Protein Kinases - chemistry
Protein Structure, Secondary
Saccharomyces cerevisiae Proteins - chemistry
Solutions
Structure-Activity Relationship
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Summary:Cavities and clefts are frequently important sites of interaction between natural enzymes or receptors and their corresponding substrate or ligand molecules and exemplify the types of molecular surfaces that would facilitate engineering of artificial catalysts and receptors. Even so, structural characterizations of designed cavities are rare. To address this issue, we performed a systematic study of the structural effects of single-amino acid substitutions within the hydrophobic cores of tetrameric coiled-coil peptides. Peptides containing single glycine, serine, alanine, or threonine amino acid substitutions at the buried L9, L16, L23, and I26 hydrophobic core positions of a GCN4-based sequence were synthesized and studied by solution-phase and crystallographic techniques. All peptides adopt the expected tetrameric state and contain tunnels or internal cavities ranging in size from 80 to 370 Å3. Two closely related sequences containing an L16G substitution, one of which adopts an antiparallel configuration and one of which adopts a parallel configuration, illustrate that cavities of different volumes and shapes can be engineered from identical core substitutions. Finally, we demonstrate that two of the peptides (L9G and L9A) bind the small molecule iodobenzene when present during crystallization, leaving the general peptide quaternary structure intact but altering the local peptide conformation and certain superhelical parameters. These high-resolution descriptions of varied molecular surfaces within solvent-occluded internal cavities illustrate the breadth of design space available in even closely related peptides and offer valuable models for the engineering of de novo helical proteins.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi050742a