Protein-nanoparticle interactions: the effects of surface compositional and structural heterogeneity are scale dependent.

Nanoparticles (NPs) in the biological environment are exposed to a large variety and concentration of proteins. Proteins are known to adsorb in a 'corona' like structure on the surface of NPs. In this study, we focus on the effects of surface compositional and structural heterogeneity on protein adsorption by examining the interaction of self-assembled monolayer coated gold NPs (AuNPs) with two types of proteins: ubiquitin and fibrinogen. This work was designed to systematically investigate the role of surface heterogeneity in nanoparticle-protein interaction. We have chosen the particles as well as the proteins to provide different types (in distribution and length-scale) of heterogeneity. The goal was to unveil the role of heterogeneity and of its length-scale in the particle-protein interaction. Dynamic light scattering and circular dichroism spectroscopy were used to reveal different interactions at pH above and below the isoelectric points of the proteins, which is related to the charge heterogeneity on the protein surface. At pH 7.4, there was only a monolayer of proteins adsorbed onto the NPs and the secondary structure of proteins remained intact. At pH 4.0, large aggregates of nanoparticle-protein complexes were formed and the secondary structures of the proteins were significantly disrupted. In terms of interaction thermodynamics, results from isothermal titration calorimetry showed that ubiquitin adsorbed differently onto (1) AuNPs with charged and nonpolar terminals organized into nano-scale structure (66-34 OT), (2) AuNPs with randomly distributed terminals (66-34 brOT), and (3) AuNPs with homogeneously charged terminals (MUS). This difference in adsorption behavior was not observed when AuNPs interacted with fibrinogen. The results suggested that the interaction between the proteins and AuNPs was influenced by the surface heterogeneity on the AuNPs, and this influence depends on the scale of surface heterogeneity and the size of the proteins.

[1]  V. Uversky Use of fast protein size-exclusion liquid chromatography to study the unfolding of proteins which denature through the molten globule. , 1993, Biochemistry.

[2]  B. Ninham,et al.  Specific ion effects: why DLVO theory fails for biology and colloid systems. , 2001, Physical review letters.

[3]  George M. Whitesides,et al.  Contact Angles for Liquid Drops at a Model Heterogeneous Surface Consisting of Alternating and Parallel Hydrophobic/Hydrophilic Strips , 1996 .

[4]  Francesco Stellacci,et al.  Surface-structure-regulated cell-membrane penetration by monolayer-protected nanoparticles. , 2008, Nature materials.

[5]  T. C. Ta,et al.  Mapping interfacial chemistry induced variations in protein adsorption with scanning force microscopy. , 2000, Analytical chemistry.

[6]  Lauren A Austin,et al.  Dynamic light scattering as a powerful tool for gold nanoparticle bioconjugation and biomolecular binding studies. , 2009, Analytical chemistry.

[7]  Francesco Stellacci,et al.  From homoligand- to mixed-ligand- monolayer-protected metal nanoparticles: a scanning tunneling microscopy investigation. , 2006, Journal of the American Chemical Society.

[8]  V. Hlady,et al.  Relating material surface heterogeneity to protein adsorption: the effect of annealing of micro-contact-printed OTS patterns , 2005, Journal of adhesion science and technology.

[9]  T. Xia,et al.  Understanding biophysicochemical interactions at the nano-bio interface. , 2009, Nature materials.

[10]  Molly M. Stevens,et al.  Amphiphilic amino acids: a key to adsorbing proteins to nanopatterned surfaces? , 2013 .

[11]  Irene Yarovsky,et al.  Ordering surfaces on the nanoscale: implications for protein adsorption. , 2011, Journal of the American Chemical Society.

[12]  S. Glotzer,et al.  The effect of nanometre-scale structure on interfacial energy. , 2009, Nature materials.

[13]  A. Zille,et al.  Complexity of cyanobacterial exopolysaccharides: composition, structures, inducing factors and putative genes involved in their biosynthesis and assembly. , 2009, FEMS microbiology reviews.

[14]  Francesco Stellacci,et al.  Water-soluble amphiphilic gold nanoparticles with structured ligand shells. , 2008, Chemical communications.

[15]  E. Tombácz,et al.  Surface charge heterogeneity of kaolinite in aqueous suspension in comparison with montmorillonite , 2006 .

[16]  J. Palmaz,et al.  Fibrinogen: structure, function, and surface interactions. , 2001, Journal of vascular and interventional radiology : JVIR.

[17]  Kenneth A. Dawson,et al.  Nanoparticle size and surface properties determine the protein corona with possible implications for biological impacts , 2008, Proceedings of the National Academy of Sciences.

[18]  Francesco Stellacci,et al.  Determination of monolayer-protected gold nanoparticle ligand–shell morphology using NMR , 2012, Nature Communications.

[19]  Rodney F. Minchin,et al.  Molecular interaction of poly(acrylic acid) gold nanoparticles with human fibrinogen. , 2012, ACS nano.

[20]  P. Chakrabarti,et al.  Contrasting effect of gold nanoparticles and nanorods with different surface modifications on the structure and activity of bovine serum albumin. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[21]  A. Rowe Probing hydration and the stability of protein solutions--a colloid science approach. , 2001, Biophysical chemistry.

[22]  M. Zembala Electrokinetics of heterogeneous interfaces. , 2004, Advances in colloid and interface science.

[23]  C. Bugg,et al.  Structure of ubiquitin refined at 1.8 A resolution. , 1987, Journal of molecular biology.

[24]  De-Hao Tsai,et al.  Adsorption and conformation of serum albumin protein on gold nanoparticles investigated using dimensional measurements and in situ spectroscopic methods. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[25]  J. Walz The effect of surface heterogeneities on colloidal forces , 1998 .

[26]  Sara Linse,et al.  Understanding the nanoparticle–protein corona using methods to quantify exchange rates and affinities of proteins for nanoparticles , 2007, Proceedings of the National Academy of Sciences.

[27]  Jeffrey M. Davis,et al.  The impact of nanoscale chemical features on micron-scale adhesion: crossover from heterogeneity-dominated to mean-field behavior. , 2009, Journal of colloid and interface science.

[28]  A. Jackson,et al.  The role of nanostructure in the wetting behavior of mixed-monolayer-protected metal nanoparticles , 2008, Proceedings of the National Academy of Sciences.

[29]  B. Jachimska,et al.  Structure of fibrinogen in electrolyte solutions derived from dynamic light scattering (DLS) and viscosity measurements. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[30]  K. Dawson,et al.  Systematic investigation of the thermodynamics of HSA adsorption to N-iso-propylacrylamide/N-tert-butylacrylamide copolymer nanoparticles. Effects of particle size and hydrophobicity. , 2007, Nano letters.

[31]  Jack F Douglas,et al.  Interaction of gold nanoparticles with common human blood proteins. , 2010, ACS nano.

[32]  D C Carter,et al.  Structure of serum albumin. , 1994, Advances in protein chemistry.

[33]  Lutz Mädler,et al.  Protein adsorption on colloidal alumina particles functionalized with amino, carboxyl, sulfonate and phosphate groups. , 2012, Acta biomaterialia.

[34]  Shaojun Dong,et al.  pH-dependent protein conformational changes in albumin:gold nanoparticle bioconjugates: a spectroscopic study. , 2007, Langmuir : the ACS journal of surfaces and colloids.

[35]  Luigi Calzolai,et al.  Protein--nanoparticle interaction: identification of the ubiquitin--gold nanoparticle interaction site. , 2010, Nano letters.

[36]  B. Dahlbäck,et al.  Structural changes in apolipoproteins bound to nanoparticles. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[37]  V. Rotello,et al.  Biomimetic interactions of proteins with functionalized nanoparticles: a thermodynamic study. , 2007, Journal of the American Chemical Society.