1uo2 Citations

Structure-based engineering of internal cavities in coiled-coil peptides.

Yadav MK, Redman JE, Leman LJ, Alvarez-Gutiérrez JM, Zhang Y, Stout CD, Ghadiri MR
Biochemistry 44 9723-32 (2005)
Related entries: 1unt, 1unu, 1unv, 1unw, 1unx, 1uny, 1unz, 1uo0, 1uo1, 1uo3, 1uo4, 1uo5, 1w5g, 1w5i, 2bni

Cited: 25 times
EuropePMC logo PMID: 16008357

Abstract

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 A(3). 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.

Articles - 1uo2 mentioned but not cited (2)

  1. Coiled coils at the edge of configurational heterogeneity. Structural analyses of parallel and antiparallel homotetrameric coiled coils reveal configurational sensitivity to a single solvent-exposed amino acid substitution. Yadav MK, Leman LJ, Price DJ, Brooks CL, Stout CD, Ghadiri MR. Biochemistry 45 4463-4473 (2006)
  2. Structure-based engineering of internal cavities in coiled-coil peptides. Yadav MK, Redman JE, Leman LJ, Alvarez-Gutiérrez JM, Zhang Y, Stout CD, Ghadiri MR. Biochemistry 44 9723-9732 (2005)


Reviews citing this publication (2)

  1. Molecular recognition with designed peptides and proteins. Cooper WJ, Waters ML. Curr Opin Chem Biol 9 627-631 (2005)
  2. Design of catalytic polypeptides and proteins. Gutte B, Klauser S. Protein Eng Des Sel 31 457-470 (2018)

Articles citing this publication (21)

  1. The HAMP domain structure implies helix rotation in transmembrane signaling. Hulko M, Berndt F, Gruber M, Linder JU, Truffault V, Schultz A, Martin J, Schultz JE, Lupas AN, Coles M. Cell 126 929-940 (2006)
  2. Synthetic foldamers. Guichard G, Huc I. Chem. Commun. (Camb.) 47 5933-5941 (2011)
  3. Structural basis for the assembly of the mitotic motor Kinesin-5 into bipolar tetramers. Scholey JE, Nithianantham S, Scholey JM, Al-Bassam J. Elife 3 e02217 (2014)
  4. Shaping quaternary assemblies of water-soluble non-peptide helical foldamers by sequence manipulation. Collie GW, Pulka-Ziach K, Lombardo CM, Fremaux J, Rosu F, Decossas M, Mauran L, Lambert O, Gabelica V, Mackereth CD, Guichard G. Nat Chem 7 871-878 (2015)
  5. The homo-oligomerisation of both Sas-6 and Ana2 is required for efficient centriole assembly in flies. Cottee MA, Muschalik N, Johnson S, Leveson J, Raff JW, Lea SM. Elife 4 e07236 (2015)
  6. Structural plasticity of the phage P22 tail needle gp26 probed with xenon gas. Olia AS, Casjens S, Cingolani G. Protein Sci. 18 537-548 (2009)
  7. Conformational transition between four and five-stranded phenylalanine zippers determined by a local packing interaction. Liu J, Zheng Q, Deng Y, Kallenbach NR, Lu M. J. Mol. Biol. 361 168-179 (2006)
  8. Fluorogenically active leucine zipper peptides as tag-probe pairs for protein imaging in living cells. Tsutsumi H, Nomura W, Abe S, Mino T, Masuda A, Ohashi N, Tanaka T, Ohba K, Yamamoto N, Akiyoshi K, Tamamura H. Angew. Chem. Int. Ed. Engl. 48 9164-9166 (2009)
  9. Biomimetic catalysis of intermodular aminoacyl transfer. Wilcoxen KM, Leman LJ, Weinberger DA, Huang ZZ, Ghadiri MR. J. Am. Chem. Soc. 129 748-749 (2007)
  10. Switching the chirality of the metal environment alters the coordination mode in designed peptides. Peacock AF, Stuckey JA, Pecoraro VL. Angew. Chem. Int. Ed. Engl. 48 7371-7374 (2009)
  11. Functional and mechanistic analyses of biomimetic aminoacyl transfer reactions in de novo designed coiled coil peptides via rational active site engineering. Leman LJ, Weinberger DA, Huang ZZ, Wilcoxen KM, Ghadiri MR. J. Am. Chem. Soc. 129 2959-2966 (2007)
  12. Molecular dynamics guided study of salt bridge length dependence in both fluorinated and non-fluorinated parallel dimeric coiled-coils. Pendley SS, Yu YB, Cheatham TE. Proteins 74 612-629 (2009)
  13. Competition between Coiled-Coil Structures and the Impact on Myosin-10 Bundle Selection. Vavra KC, Xia Y, Rock RS. Biophys. J. 110 2517-2527 (2016)
  14. Development of crosslink-type tag-probe pairs for fluorescent imaging of proteins. Nomura W, Mino T, Narumi T, Ohashi N, Masuda A, Hashimoto C, Tsutsumi H, Tamamura H. Biopolymers 94 843-852 (2010)
  15. A systematic study of fundamentals in α-helical coiled coil mimicry by alternating sequences of β- and γ-amino acids. Rezaei Araghi R, Baldauf C, Gerling UI, Cadicamo CD, Koksch B. Amino Acids 41 733-742 (2011)
  16. Comparison of the structures and stabilities of coiled-coil proteins containing hexafluoroleucine and t-butylalanine provides insight into the stabilizing effects of highly fluorinated amino acid side-chains. Buer BC, Meagher JL, Stuckey JA, Marsh EN. Protein Sci. 21 1705-1715 (2012)
  17. A possible degree of motional freedom in bacterial chemoreceptor cytoplasmic domains and its potential role in signal transduction. Hu W. Int J Biochem Mol Biol 2 99-110 (2011)
  18. Biomimetic catalysis of diketopiperazine and dipeptide syntheses. Huang ZZ, Leman LJ, Ghadiri MR. Angew. Chem. Int. Ed. Engl. 47 1758-1761 (2008)
  19. Intrinsically unstructured proteins by design-electrostatic interactions can control binding, folding, and function of a helix-loop-helix heterodimer. Rydberg J, Baltzer L, Sarojini V. J. Pept. Sci. 19 461-469 (2013)
  20. From peptides to proteins: coiled-coil tetramers to single-chain 4-helix bundles. Naudin EA, Albanese KI, Smith AJ, Mylemans B, Baker EG, Weiner OD, Andrews DM, Tigue N, Savery NJ, Woolfson DN. Chem Sci 13 11330-11340 (2022)
  21. Organic ligand binding by a hydrophobic cavity in a designed tetrameric coiled-coil protein. Mizuno T, Hasegawa C, Tanabe Y, Hamajima K, Muto T, Nishi Y, Oda M, Kobayashi Y, Tanaka T. Chemistry 15 1491-1498 (2009)


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