Structure-Based Engineering of Internal Cavities in Coiled-Coil Peptides<sup>,</sup>

Yadav, Maneesh K.; Redman, James E.; Leman, Luke J.; Alvarez-Gutiérrez, Julietta M.; Zhang, Yanming; Stout, C.D.; Ghadiri, Mojtaba

doi:10.1021/bi050742a

Cited by 41 publications

(37 citation statements)

References 46 publications

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“…b The crystallization and structure determination of this peptide has been reported previously (17). b The full-length sequence (residues 1-33), rather than a truncated sequence (residues 2-32), was used for simulation.…”

Section: Aba-r-mkqiedk-leeilsk-ghhicne-larikkl-mentioning

confidence: 99%

“…c This variant of GCN4-pLI, containing an amino acid substitution in the hydrophobic core, has previously been shown to crystallize in the parallel configuration (17). Table 3 Decomposition of total potential energies (in kcal/mol) from lowest temperature window (280 K) of lowestaverage-energy simulations of GCN4-pLI (1) and E20C (3).…”

Section: Aba-r-mkqiedk-leeilsk-ghhicne-larikkl-mentioning

confidence: 99%

See 1 more Smart Citation

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^,

et al. 2006

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A detailed understanding of the mechanisms by which particular amino acid sequences can give rise to more than one folded structure, such as for proteins that undergo large conformational changes or misfolding, is a long-standing objective of protein chemistry. Here we describe the crystal structures of a single coiled-coil peptide in distinct parallel and antiparallel tetrameric configurations and further describe the parallel or antiparallel crystal structures of several related peptide sequences; the antiparallel tetrameric assemblies represents the first crystal structures of GCN4-derived peptides exhibiting such a configuration. Intriguingly, substitution of a single solvent-exposed residue enabled the parallel coiled-coil tetramer GCN4-pLI to populate the antiparallel configuration, suggesting that the two configurations are close enough in energy for subtle sequence changes to have important structural consequences. We present a structural analysis of the small changes to helix register and side chain conformations that accommodate the two configurations, and have supplemented these results using solution studies and a molecular dynamics energetic analysis using a replica exchange methodology. Considering the previous examples of structural nonspecificity in coiled-coil peptides, the findings reported here not only emphasize the predisposition of the coiled-coil motif to adopt multiple configurations, but also call attention to the associated risk that observed crytstal structures may not represent the only (or even the major) species present in solution.The diverse functional prowess of proteins derives in large part from their ability to adopt unique tertiary and quaternary structures, and a major goal of protein chemistry is thus to understand in detail how primary amino acid sequences specify three-dimensional structures. Conformational changes and protein misfolding are critical events in biological processes and diseases in which a given polypeptide sequence gives rise to more than one folded structure, but detailed structural analyses of such processes are often difficult because multiple † We thank the Skaggs Institute for Chemical Biology for financial support, and NSF for a predoctoral fellowship (L.J.L.). § Coordinates have been deposited in the RCSB Protein Data Bank: peptide 2, 1W5K; E20C (peptide 3), 2CCN; E20S (peptide 4), 2CCE, 2CCF; ABA-pLI (peptide 5), 1W5I; peptide 6, 1W5J; E20C Y17H (peptide 7), 1W5H; E20C Ak (peptide 8), 1W5G.* Address correspondence to this author. (858) 784-2700 (phone); (858) 784-2798 (fax); ghadiri@scripps.edu (e-mail).. ‡ These authors contributed equally to this study.Supporting Information Available. Additional figures, CD wavelength scans, thermal denaturation curves, crystallization statistics. This material is available free of charge via the Internet at http://pubs.acs.org. 1 Abbreviations: ABA, acetamidobenzoic acid; CD, circular dichroism; Cys, cysteine, Glu, glutamic acid; HPLC, high-performance liquid chromatography; Lys, lysine; MALDI-TOF, matr...

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Section: Aba-r-mkqiedk-leeilsk-ghhicne-larikkl-mentioning

confidence: 99%

Section: Aba-r-mkqiedk-leeilsk-ghhicne-larikkl-mentioning

confidence: 99%

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^,

et al. 2006

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“…5C) using the cyclic hydrocarbon benzene. Benzene binds efficiently to cellular membranes (45), interacts with hydrophobic protein patches and/or cores, and modulates the arrangement of hydrophobic protein interfaces (19,20). Benzene does not affect the cholesterol-binding properties of digitonin (23), but it specifically targets leucine zippers containing central small residues (19,20) (see Fig.…”

Section: Resultsmentioning

confidence: 99%

“…In contrast, three highly conserved arginine and aspartate residues located within or directly adjacent to these TMs are not required. Moreover, we demonstrate that the cyclic hydrocarbon benzene known to interfere with the structure and formation of leucine zippers (19,20) specifically disrupts the physical interaction between TAP and TPN even under stabilizing detergent conditions. Based on our data, we conclude that TM1 and TM2 of TAP2 are essential for the functional interaction with TPN/MHC I.…”

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confidence: 89%

Hydrophobic Interactions Are Key To Drive the Association of Tapasin with Peptide Transporter Subunit TAP2

Rufer

Kägebein

Leonhardt

et al. 2015

The Journal of Immunology

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The transporter associated with Ag processing (TAP) translocates proteasomally derived cytosolic peptides into the endoplasmic reticulum. TAP is a central component of the peptide-loading complex (PLC), to which tapasin (TPN) recruits MHC class I (MHC I) and accessory chaperones. The PLC functions to facilitate and optimize MHC I–mediated Ag presentation. The heterodimeric peptide transporter consists of two homologous subunits, TAP1 and TAP2, each of which contains an N-terminal domain (N-domain) in addition to a conserved transmembrane (TM) core segment. Each N-domain binds to the TM region of a single TPN molecule, which recruits one MHC I molecule to TAP1 and/or TAP2. Although both N-domains act as TPN-docking sites, various studies suggest a functional asymmetry within the PLC resulting in greater significance of the TAP2/TPN interaction for MHC loading. In this study, we demonstrate that the leucine-rich hydrophobic sequence stretches (with the central leucine residues L20 and L66) in the first and second TM helix of TAP2 form a functional unit acting as a docking site for optimal TPN/MHC I recruitment, whereas three distinct highly conserved arginine and/or aspartate residues inside or flanking these TM helices are dispensable. Moreover, we show that the physical interaction between TAP2 and TPN is disrupted by benzene, a compound known to interfere with hydrophobic interactions, such as those between pairing leucine zippers. No such effects were observed for the TAP1/TAP2 interaction or the complex formation between TPN and MHC I. We propose that TAP/TPN complex formation is driven by hydrophobic interactions via leucine zipper–like motifs.

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“…Large hydrophobic cavities are known from various studies to destabilize the folded state. 32 The energetic penalty for introducing a cavity into a 4 tbA 6 can be estimated using the generally accepted value of 24 cal mol À1 Å À3 for the hydrophobic effect in proteins. 33 The calculated reduction in stability is $4.8 kcal mol À1 , which is in reasonable agreement with the observed decrease in stability compared to fluorinated proteins with similar hydrophobic surface areas.…”

Section: Structures Of a 4 F 3 D And A 4 F 3 (6-13)mentioning

confidence: 99%

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

et al. 2012

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Highly fluorinated analogs of hydrophobic amino acids are well known to increase the stability of proteins toward thermal unfolding and chemical denaturation, but there is very little data on the structural consequences of fluorination. We have determined the structures and folding energies of three variants of a de novo designed 4-helix bundle protein whose hydrophobic cores contain either hexafluoroleucine (hFLeu) or t-butylalanine (tBAla). Although the buried hydrophobic surface area is the same for all three proteins, the incorporation of tBAla causes a rearrangement of the core packing, resulting in the formation of a destabilizing hydrophobic cavity at the center of the protein. In contrast, incorporation of hFLeu, causes no changes in core packing with respect to the structure of the nonfluorinated parent protein which contains only leucine in the core. These results support the idea that fluorinated residues are especially effective at stabilizing proteins because they closely mimic the shape of the natural residues they replace while increasing buried hydrophobic surface area.

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

Cited by 41 publications

References 46 publications

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^,

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^,

Hydrophobic Interactions Are Key To Drive the Association of Tapasin with Peptide Transporter Subunit TAP2

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

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

Cited by 41 publications

References 46 publications

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,

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,

Hydrophobic Interactions Are Key To Drive the Association of Tapasin with Peptide Transporter Subunit TAP2

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

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

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^,

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^,