Ligand-modulated interactions between charged monolayer-protected Au144(SR)60 gold nanoparticles in physiological saline.

In order to determine how functionalized gold nanoparticles (AuNPs) interact in a near-physiological environment, we performed all-atom molecular dynamics simulations on the icosahedral Au144 nanoparticles each coated with a homogeneous set of 60 thiolates selected from one of these five (5) types: 11-mercapto-1-undecanesulfonate -SC11H22(SO3(-)), 5-mercapto-1-pentanesulfonate -SC5H10(SO3(-)), 5-mercapto-1-pentaneamine -SC5H10(NH3(+)), 4-mercapto-benzoate -SPh(COO(-)), or 4-mercapto-benzamide -SPh(CONH3(+)). These thiolates were selected to elucidate how the aggregation behavior of AuNPs depends on ligand parameters, including the charge of the terminal group (anionic vs. cationic), and its length and conformational flexibility. For this purpose, each functionalized AuNP was paired with a copy of itself, placed in an aqueous cell, neutralized by 120 Na(+)/Cl(-) counter-ions and salinated with a 150 mM concentration of NaCl, to form five (5) systems of like-charged AuNPs pairs in a saline. We computed the potential of mean force (the reversible work of separation) as a function of the intra-pair distance and, based on which, the aggregation affinities. We found that the AuNPs coated with negatively charged, short ligands have very high affinities. Structurally, a significant number of Na(+) counter-ions reside on a plane between the AuNPs, mediating the interaction. Each such ion forms a "salt bridge" (or "ionic bonds") to both of the AuNPs when they are separated by its diameter plus 0.2-0.3 nm. The positively charged AuNPs have much weaker affinities, as Cl(-) counter-ions form fewer and weaker salt bridges between the AuNPs. In the case of Au144(SC11H22(SO3(-)))60 pair, the flexible ligands fluctuate much more than the other four cases. The large fluctuations disfavor the forming of salt bridges between two AuNPs, but enable hydrophobic contact between the exposed hydrocarbon chains of the two AuNPs, which are subject to an effective attraction at a separation much greater than the AuNP diameter and involve a higher concentration of counter ions in the inter-pair space.

[1]  I. Vattulainen,et al.  Atomistic simulations of anionic Au144(SR)60 nanoparticles interacting with asymmetric model lipid membranes. , 2014, Biochimica et biophysica acta.

[2]  Liao Y. Chen,et al.  Interaction between functionalized gold nanoparticles in physiological saline. , 2014, Physical chemistry chemical physics : PCCP.

[3]  R. Whetten,et al.  Structure & bonding of the gold-subhalide cluster I-Au144Cl60[z]. , 2013, Physical chemistry chemical physics : PCCP.

[4]  Otto L Muskens,et al.  Manipulation of in vitro angiogenesis using peptide-coated gold nanoparticles. , 2013, ACS nano.

[5]  Feng-hua Wang,et al.  Calculating potential of mean force between like-charged nanoparticles: A comprehensive study on salt effects , 2013, 1305.2079.

[6]  U. Landman,et al.  STEM Electron Diffraction and High Resolution Images Used in the Determination of the Crystal Structure of Au144(SR)60 Cluster. , 2013, The journal of physical chemistry letters.

[7]  C. Rambo,et al.  Nanoparticle translocation through a lipid bilayer tuned by surface chemistry. , 2013, Physical chemistry chemical physics : PCCP.

[8]  Konstantin V Sokolov,et al.  Equilibrium gold nanoclusters quenched with biodegradable polymers. , 2013, ACS nano.

[9]  F. Biscarini,et al.  Anti-amyloidogenic activity of glutathione-covered gold nanoparticles , 2012 .

[10]  Liao Y. Chen Glycerol modulates water permeation through Escherichia coli aquaglyceroporin GlpF. , 2012, Biochimica et biophysica acta.

[11]  S. Safran,et al.  Effect of charge inhomogeneity and mobility on colloid aggregation. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[12]  I. Vattulainen,et al.  Atomistic Simulations of Functional Au144(SR)60 Gold Nanoparticles in Aqueous Environment , 2012 .

[13]  Clemens Burda,et al.  The unique role of nanoparticles in nanomedicine: imaging, drug delivery and therapy. , 2012, Chemical Society reviews.

[14]  M. Turesson,et al.  Coarse-graining intermolecular interactions in dispersions of highly charged colloids. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[15]  Keith E Maier,et al.  Growth inhibition of Staphylococcus aureus by mixed monolayer gold nanoparticles. , 2011, Small.

[16]  M. Quesada-Pérez,et al.  Influence of monovalent ion size on colloidal forces probed by Monte Carlo simulations. , 2011, Physical chemistry chemical physics : PCCP.

[17]  V. Dahirel,et al.  Effective interaction between charged nanoparticles and DNA. , 2011, Physical chemistry chemical physics : PCCP.

[18]  Zhen Chen,et al.  A simulation study on nanoscale holes generated by gold nanoparticles on negative lipid bilayers. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[19]  P. Saramito,et al.  Understanding and predicting viscous, elastic, plastic flows , 2011, The European physical journal. E, Soft matter.

[20]  Jiaqi Lin,et al.  Penetration of lipid membranes by gold nanoparticles: insights into cellular uptake, cytotoxicity, and their relationship. , 2010, ACS nano.

[21]  Sarit S. Agasti,et al.  Recognition-Mediated Activation of Therapeutic Gold Nanoparticles Inside Living Cells , 2010, Nature chemistry.

[22]  V. Dahirel,et al.  Effective interactions between charged nanoparticles in water: What is left from the DLVO theory? , 2010 .

[23]  Younan Xia,et al.  The effects of size, shape, and surface functional group of gold nanostructures on their adsorption and internalization by cells. , 2010, Small.

[24]  G. Pollack,et al.  Mechanism of attraction between like-charged particles in aqueous solution , 2009 .

[25]  Jianpeng Ma,et al.  CHARMM: The biomolecular simulation program , 2009, J. Comput. Chem..

[26]  Alexander D. MacKerell,et al.  CHARMM general force field: A force field for drug‐like molecules compatible with the CHARMM all‐atom additive biological force fields , 2009, J. Comput. Chem..

[27]  Younan Xia,et al.  Understanding the role of surface charges in cellular adsorption versus internalization by selectively removing gold nanoparticles on the cell surface with a I2/KI etchant. , 2009, Nano letters.

[28]  Wolfgang J. Parak,et al.  Synthesis, characterization, and bioconjugation of fluorescent gold nanoclusters toward biological labeling applications. , 2009, ACS nano.

[29]  R. Whetten,et al.  Structure and Bonding in the Ubiquitous Icosahedral Metallic Gold Cluster Au144(SR)60 , 2009 .

[30]  L. Chen Nonequilibrium fluctuation-dissipation theorem of Brownian dynamics. , 2008, The Journal of chemical physics.

[31]  V. Dahirel,et al.  Ion-mediated interactions between charged and neutral nanoparticles. , 2008, Physical chemistry chemical physics : PCCP.

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

[33]  Christian Melander,et al.  Inhibition of HIV fusion with multivalent gold nanoparticles. , 2008, Journal of the American Chemical Society.

[34]  Kristen N. Duthie,et al.  Wide varieties of cationic nanoparticles induce defects in supported lipid bilayers. , 2008, Nano letters.

[35]  M. C. Valsakumar,et al.  Bound pairs: Direct evidence for long-range attraction between like-charged colloids , 2007, 0711.2883.

[36]  Toby W Allen,et al.  Molecular dynamics - potential of mean force calculations as a tool for understanding ion permeation and selectivity in narrow channels. , 2006, Biophysical chemistry.

[37]  Jianzhong Wu,et al.  Density functional theory for chemical engineering: From capillarity to soft materials , 2006 .

[38]  Laxmikant V. Kalé,et al.  Scalable molecular dynamics with NAMD , 2005, J. Comput. Chem..

[39]  J. Hainfeld,et al.  Ni-NTA-gold clusters target His-tagged proteins. , 1999, Journal of structural biology.

[40]  H. Orland,et al.  Beyond Poisson-Boltzmann: Fluctuation effects and correlation functions , 1999, cond-mat/9902085.

[41]  J M Prausnitz,et al.  Interaction between like-charged colloidal spheres in electrolyte solutions. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[42]  K Schulten,et al.  VMD: visual molecular dynamics. , 1996, Journal of molecular graphics.

[43]  B. Roux The calculation of the potential of mean force using computer simulations , 1995 .

[44]  G. Hummer,et al.  Ion pair potentials-of-mean-force in water , 1994, chem-ph/9404001.

[45]  Michael L. Klein,et al.  Simulation of a monolayer of alkyl thiol chains , 1989 .

[46]  Roger Impey,et al.  Hydration and mobility of ions in solution , 1983 .

[47]  W. L. Jorgensen,et al.  Comparison of simple potential functions for simulating liquid water , 1983 .

[48]  David Chandler,et al.  Statistical mechanics of isomerization dynamics in liquids and the transition state approximation , 1978 .

[49]  J. Kirkwood Statistical Mechanics of Fluid Mixtures , 1935 .