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. 2009 May 19;25(10):5637-46.
doi: 10.1021/la8042186.

Benchmark experimental data set and assessment of adsorption free energy for peptide-surface interactions

Yang Wei  1 Robert A Latour
Affiliations

Benchmark experimental data set and assessment of adsorption free energy for peptide-surface interactions

Yang Wei et al. Langmuir. .

Abstract

With the increasing interest in protein adsorption in fields ranging from bionanotechnology to biomedical engineering, there is a growing need to understand protein-surface interactions at a fundamental level, such as the interaction between individual amino acid residues of a protein and functional groups presented by a surface. However, relatively little data are available that experimentally provide a quantitative, comparative measure of these types of interactions. To address this deficiency, the objective of this study was to generate a database of experimentally measured standard state adsorption free energy (DeltaGoads) values for a wide variety of amino acid residue-surface interactions using a host-guest peptide and alkanethiol self-assembled monolayers (SAMs) with polymer-like functionality as the model system. The host-guest amino acid sequence was synthesized in the form of TGTG-X-GTGT, where G and T are glycine and threonine amino acid residues and X represents a variable residue. In this paper, we report DeltaGoads values for the adsorption of 12 different types of the host-guest peptides on a set of nine different SAM surfaces, for a total of 108 peptide-surface systems. The DeltaGoads values for these 108 peptide-surface combinations show clear trends in adsorption behavior that are dependent on both peptide composition and surface chemistry. These data provide a benchmark experimental data set from which fundamental interactions that govern peptide and protein adsorption behavior can be better understood and compared.

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Figures

Figure 1
Figure 1
Response curves (SPR signal (RU) vs. time for TGTG-L-GTGT on (A) SAM-CH3 and (B) SAM-OH surface. (Not all of the concentration curves are listed for clarity sake because some of the low concentration curves overlap one another and are thus not separately distinguishable).
Figure 2
Figure 2
Corresponding adsorption isotherm for TGTG-L-GTGT on both of SAM-OH solid line SAM-CH3 surfaces (dotted line). Note that the adsorption response plotted on the y-axis includes bulk-shift effects, which are linearly related to solution concentration. (Error bar represents 95% C.I., N = 6.)
Figure 3
Figure 3
ΔGoads (kcal/mol) vs. cosine (contact angle) for TGTG-X-GTGT on SAM surfaces with various functionalities. The ΔGoads values represent the average value of all of the host-guest peptides that exhibited reversible adsorption behavior on each SAM surface (i.e., peptides with X = A, F, and V, which tended to adsorb irreversibly, were excluded from these average values). The blue line shows the linear regression for the non-charged SAM surfaces with r2=0.95. (The error bar represents the 95% C.I. with N = 9.)
Figure 4
Figure 4
Comparisons of ΔGoads for each peptide on the hydrophobic surfaces (water contact angle > 65°): SAM–CH3, SAM–OCH2CF3 and SAM–OC6H5 surfaces. The amino acid label across the top of each set of columns designates the X residue of the TGTG-X-GTGT peptide. Peptides are ordered by a standard hydrophobicity scale from the most-to-least degree of hydrophobicity. (An asterisks (*) indicates that adsorption was irreversible. The error bars represent the 95% C.I. with N = 6.)
Figure 5
Figure 5
Comparisons of ΔGoads for each peptide on neutrally charged relatively hydrophilic surfaces (water contact angle < 65°): SAM–COOCH3, SAM–NHCOCH3, and SAM–EG3OH surfaces. The amino acid label across the top of each set of columns designates the X residue of the TGTG-X-GTGT peptide. The SAM-OH surface is not included in this plot because ΔGoads = 0.0 for each reversibly adsorbed peptide on this surface. (An asterisks (*) indicates that adsorption was irreversible. The error bar represent the 95% C.I. with N = 6.)
Figure 6
Figure 6
Comparisons of ΔGoads for each peptide on the charged surfaces: SAM–COOH and SAM–NH2 surfaces. The amino acid label across the top of each set of columns designates the X residue of the TGTG-X-GTGT peptide. An asterisks (*) indicates that adsorption was irreversible. The error bar represent the 95% CI. with N = 6.)
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References

    1. Hruby VJ, Matsunaga TO. Applications of Synthetic Peptides. In: Grant GA, editor. Synthetic peptides: a user's guide. 2nd ed. Oxford; New York: Oxford University Press; 2002. pp. 292–376.
    1. Zhang W, Laursen RA. Artificial antifreeze polypeptides: alpha-helical peptides with KAAK motifs have antifreeze and ice crystal morphology modifying properties. FEBS Lett. 1999;455(3):372–376. - PubMed
    1. Corradin G, Spertini F, Verdini A. Medicinal application of long synthetic peptide technology. Expert Opinion on Biological Therapy. 2004;4(10):1629–1639. - PubMed
    1. Srivastava AK, Castillo G, Wergedal JE, Mohan S, Baylink DJ. Development and Application of a Synthetic Peptide-Based Osteocalcin Assay for the Measurement of Bone Formation in Mouse Serum. Calcified Tissue International. 2000;67(3):255. - PubMed
    1. Shen Z, Yan H, Zhang Y, Mernaugh RL, Zeng X. Engineering peptide linkers for scFv immunosensors. Anal Chem. 2008;80(6):1910–1917. - PMC - PubMed

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