Understanding small biomolecule‐biomaterial interactions: A review of fundamental theoretical and experimental approaches for biomolecule interactions with inorganic surfaces

Costa, Dominique; Garrain, Pierre-Alain; Baaden, Marc

doi:10.1002/jbm.a.34416

Cited by 68 publications

(127 citation statements)

References 170 publications

(183 reference statements)

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“…Several of these provide a general overview of the adsorption of proteins at solid surfaces (Cohavi et al 2010;Costa et al 2013;Horbett & Brash, 1995;Rabe et al 2011;Qu et al 2013), whereas others focus on more specific aspects such as the determination of the adsorption kinetics of protein-surface binding by weakly bound mobile precursor states (Garland et al 2012), and adsorption on various different surface types, such as metallic surfaces (Tomba et al 2009;Vallee et al 2010), polymer surfaces (Hahm, 2014;Wei et al 2014) and protein repellent surfaces (Szott & Horbett, 2011). The physicochemical properties of nanomaterials, and their applications in medicine, biology and biotechnology, have also been reviewed in several papers (see, e.g.…”

Section: Introductionmentioning

confidence: 99%

Modeling and simulation of protein–surface interactions: achievements and challenges

Ozboyaci

Kokh

Corni

et al. 2016

Quart. Rev. Biophys.

192

199

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Abstract. Understanding protein-inorganic surface interactions is central to the rational design of new tools in biomaterial sciences, nanobiotechnology and nanomedicine. Although a significant amount of experimental research on protein adsorption onto solid substrates has been reported, many aspects of the recognition and interaction mechanisms of biomolecules and inorganic surfaces are still unclear. Theoretical modeling and simulations provide complementary approaches for experimental studies, and they have been applied for exploring protein-surface binding mechanisms, the determinants of binding specificity towards different surfaces, as well as the thermodynamics and kinetics of adsorption. Although the general computational approaches employed to study the dynamics of proteins and materials are similar, the models and force-fields (FFs) used for describing the physical properties and interactions of material surfaces and biological molecules differ. In particular, FF and water models designed for use in biomolecular simulations are often not directly transferable to surface simulations and vice versa. The adsorption events span a wide range of time-and length-scales that vary from nanoseconds to days, and from nanometers to micrometers, respectively, rendering the use of multi-scale approaches unavoidable. Further, changes in the atomic structure of material surfaces that can lead to surface reconstruction, and in the structure of proteins that can result in complete denaturation of the adsorbed molecules, can create many intermediate structural and energetic states that complicate sampling. In this review, we address the challenges posed to theoretical and computational methods in achieving accurate descriptions of the physical, chemical and mechanical properties of protein-surface systems. In this context, we discuss the applicability of different modeling and simulation techniques ranging from quantum mechanics through all-atom molecular mechanics to coarse-grained approaches. We examine uses of different sampling methods, as well as free energy calculations. Furthermore, we review computational studies of protein-surface interactions and discuss the successes and limitations of current approaches.

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Section: Introductionmentioning

confidence: 99%

Modeling and simulation of protein–surface interactions: achievements and challenges

Ozboyaci

Kokh

Corni

et al. 2016

Quart. Rev. Biophys.

192

199

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“…5,17 Therefore, the investigation of entire peptide chains in contact with inorganic surfaces is a critical component in advancing our understanding. 26 The tripeptide motif RGD and its interaction with titania surfaces has been of particular interest, [27][28][29][30][31][32][33] while others have sought to isolate and identify TiO2-binding peptides using biocombinatorial techniques to gain a deeper understanding of which peptide characteristics can confer strong titania-binding affinity. 32,[34][35][36][37] A crucial next step in advancing our understanding is the careful characterization of the adsorption of materials-binding peptides at aqueous titania interfaces.…”

Section: Introductionmentioning

confidence: 99%

Aqueous Peptide–TiO₂ Interfaces: Isoenergetic Binding via Either Entropically or Enthalpically Driven Mechanisms

Sultan

Westcott

Hughes

et al. 2016

ACS Appl. Mater. Interfaces

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A major barrier to the systematic improvement of biomimetic peptide-mediated strategies for the controlled growth of inorganic nanomaterials in environmentally benign conditions lies in the lack of clear conceptual connections between the sequence of the peptide and its surface binding affinity, with binding being facilitated by non-covalent interactions. Peptide conformation, both in the adsorbed and non-adsorbed state, is the key relationship that connects peptide-materials binding with peptide sequence. Here, we combine experimental peptide-titania binding characterization with state-of-the-art conformational sampling via molecular simulations to elucidate these structure/binding relationships for two very different titania-binding peptide sequences. The two sequences (Ti-1: QPYLFATDSLIK and Ti-2:GHTHYHAVRTQT) differ in their overall hydropathy, yet via quartz-crystal microbalance measurements and predictions from molecular simulations, we show these sequences both support very similar, strong titania-binding affinities. Our molecular simulations reveal that the two sequences exhibit profoundly different modes of surface binding, with Ti-1 acting as an entropically-driven binder while Ti-2 behaves as an enthalpically-driven binder. The integrated approach presented here provides a rational basis for peptide sequence engineering to achieve the in-situ growth and organization of titania nanostructures in aqueous media and for the design of sequences suitable for a range of technological applications that involve the interface between titania and biomolecules.3

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Section: Introductionmentioning

confidence: 99%

“…This phenomenon is a very common one and has a great impact on biomedical and biotechnical applications of silicone materials [2][3][4]. Many undesired events such as blood coagulation, thrombosis, immune reactions leading to diseases are caused by protein adsorption [2,5]. On the other hand, the protein adsorption is used to bioactivate synthetic materials.…”

Section: Introductionmentioning

confidence: 99%

“…Adsorption of proteins on these surfaces occurs instantly whenever silicones are exposed to biological medium [1,2]. This phenomenon is a very common one and has a great impact on biomedical and biotechnical applications of silicone materials [2][3][4]. Many undesired events such as blood coagulation, thrombosis, immune reactions leading to diseases are caused by protein adsorption [2,5].…”

Section: Introductionmentioning

confidence: 99%

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Gamma Globulins Adsorption on Carbofunctional Polysiloxane Microspheres

Mizerska

Fortuniak

Pośpiech

et al. 2015

J Inorg Organomet Polym

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Polysiloxane microspheres containing a large number of silanol groups were functionalized by reactions of these groups with organic alkoxy or chlorosilanes having chloro, amine or imidazole functions in their organic parts. The obtained imidazole groups on the microspheres were ionized by the reaction with n-octyl iodide and with methyl iodide while the chloro functions were used for quaternization of a tertiary amine. Adsorption of gamma globulins on these functionalized microspheres was studied in aqueous suspension at pH 5.2, 7.4 and 9.2. Hydrophilichydrophobic properties of these microspheres were examined by measuring adsorption of a hydrophobic dye, Rose Bengal. The functionalized microspheres showed higher adsorption of globulins and higher hydrophobicity than the not functionalized ones rich in silanol groups. In the case of microspheres with ionic functional groups the electrostatic forces also contribute to attractive interactions between proteins and microspheres.

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Understanding small biomolecule‐biomaterial interactions: A review of fundamental theoretical and experimental approaches for biomolecule interactions with inorganic surfaces

Cited by 68 publications

References 170 publications

Modeling and simulation of protein–surface interactions: achievements and challenges

Modeling and simulation of protein–surface interactions: achievements and challenges

Aqueous Peptide–TiO₂ Interfaces: Isoenergetic Binding via Either Entropically or Enthalpically Driven Mechanisms

Gamma Globulins Adsorption on Carbofunctional Polysiloxane Microspheres

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Understanding small biomolecule‐biomaterial interactions: A review of fundamental theoretical and experimental approaches for biomolecule interactions with inorganic surfaces

Cited by 68 publications

References 170 publications

Modeling and simulation of protein–surface interactions: achievements and challenges

Modeling and simulation of protein–surface interactions: achievements and challenges

Aqueous Peptide–TiO2 Interfaces: Isoenergetic Binding via Either Entropically or Enthalpically Driven Mechanisms

Gamma Globulins Adsorption on Carbofunctional Polysiloxane Microspheres

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Aqueous Peptide–TiO₂ Interfaces: Isoenergetic Binding via Either Entropically or Enthalpically Driven Mechanisms