Pathways for Gold Nucleation and Growth over Protein Cages (original) (raw)
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Time-dependent, protein-directed growth of gold nanoparticles within a single crystal of lysozyme
Nature Nanotechnology, 2011
Gold nanoparticles are useful in biomedical applications due to their distinct optical properties and high chemical stability 1-5 . Reports of the biogenic formation of gold colloids from gold complexes has also led to an increased level of interest in the biomineralization of gold 6-13 . However, the mechanism responsible for biomolecule-directed gold nanoparticle formation remains unclear due to the lack of structural information about biological systems and the fast kinetics of biomimetic chemical systems in solution. Here we show that intact single crystals of lysozyme can be used to study the time-dependent, protein-directed growth of gold nanoparticles. The protein crystals slow down the growth of the gold nanoparticles, allowing detailed kinetic studies to be carried out, and permit a three-dimensional structural characterization that would be difficult to achieve in solution. Furthermore, we show that additional chemical species can be used to fine-tune the growth rate of the gold nanoparticles.
Emerging applications that exploit the properties of nanoparticles for biotechnology require that the nanoparticles be biocompatible or support biological recognition. These types of particles can be produced through syntheses that involve biologically relevant molecules (proteins or natural extracts, for example). Many of the protocols that rely on these molecules are performed without a clear understanding of the mechanism by which the materials are produced. We describe a single-pot reaction in which protein-templated gold nanoparticles (AuNPs) are produced as either solution-suspended colloids or as colloids formed within a solid, fibrous protein structure. We have investigated the mechanism for this process by detailing the reaction kinetics and outcomes through the use of 7 different proteins over a range of concentrations and temperatures. The key factor that controls the synthetic outcome (colloid or fiber) is the concentration of the protein relative to the gold concentrati...
Gold nanoparticles induce protein crystallization
Crystal Research and Technology, 2008
Nucleation of protein crystals by gold nanoparticles was observed. Lysozyme and ferritin were used as model proteins. The effect was established with uncoated gold nanoparticles and with gold nanoparticles coated by 16-mercaptodecanoic acid.
Use of Gold Nanoparticles as Additives in Protein Crystallization
Crystal Growth & Design, 2014
Gold nanoparticles (AuNPs) exhibit unique properties that have made them a very attractive material for application in biological assays. Given the potentially interesting interactions between AuNPs and biological macromolecules, we investigated AuNPs-induced protein crystal growth. Differently functionalized AuNPs were tested as additives in cocrystallization studies with model proteins (hen egg white lysozyme (HEWL), ribonuclease A (RNase A), and proteinase K) as well as with case studies where there were problems in obtaining well-diffracting crystals. Trials were performed considering different crystallization drawbacks, from total absence of crystals to improvement of crystal morphology, size, twinning, and number of crystals per drop. Improvement of some of these factors was observed in the cases of HEWL, RNase A, phenylalanine hydroxylase (PAH), myoglobin, native aldehyde oxidase (AOH), and human albumin. In these proteins, the presence of the AuNPs promoted an increase in the size and/or better crystal morphology. From the systematic trials and subsequent observations, it can be concluded that the introduction of AuNPs should definitely be considered in crystal optimization trials to improve previously determined crystallization conditions.
Gold Nanoparticle-Induced Formation of Artificial Protein Capsids
Nano Letters, 2012
Gold nanoparticles are generally considered to be biologically inactive. However, in this study we show that the addition of 1.4 nm diameter gold nanoparticle induces the remodeling of the ring-shaped protein TRAP into a hollow, capsid-like configuration. This structural remodeling is dependent upon the presence of cysteine residues on the TRAP surface as well as the specific type of gold nanoparticle. The results reveal an apparent novel catalytic role of gold nanoparticles.
Generally applicable procedure for in situ formation of fluorescent protein-gold nanoconstructs
RSC Advances, 2012
ABSTRACT Small noble metal nanoclusters can be formed in situ by direct reduction and stabilization of a metal precursor by biomolecules such as proteins. Considering the diversity in amino acid composition of proteins, and hence their reductive ability, a general method for synthesis of gold nanoclusters using proteins is presented here. A range of proteins (bovine serum albumin, fibrinogen, α-lactalbumin, lysozyme, cytochrome c, myoglobin, β-lactoglobulin and α-chymotrypsin) have been studied, based on size, isoelectric point, flexibility and 3-dimensional structure. Results show protein-gold nanoconstructs with complex protein-specific photophysical properties. The effect on the 3-dimensional conformation of the proteins upon formation of gold nanoclusters and/or nanoparticles within the protein structure is also shown to be highly protein-dependent. A general mechanism for the formation of protein-gold nanoconstructs is proposed, based on charge density matching, yielding a high local concentration of the metal precursor on the protein structure which in turn can nucleate, grow and be stabilized by amino acid residues in the protein.
Microbial Synthesis of Multi-Shaped Gold Nanostructures.
The development of methodologies for the synthesis of nanoparticles of well-defined size and shape is a challenging one and constitutes an important area of research in nanotechnology. This Full Paper describes the controlled synthesis of multishaped gold nanoparticles at room temperature utilizing a simple, green chemical method by the interaction of chloroauric acid (HAuCl4 · 3H20) and cell-free extract of the fungal strain Rhizopus oryzae. The cell-free extract functions as a reducing, shape-directing, as well as stabilizing, agent. Different shapes of gold nanocrystals, for example, triangular, hexagonal, pentagonal, spherical, spheroidal, urchinlike, two-dimensional nanowires, and nanorods, are generated by manipulating key growth parameters, such as gold ion concentration, solution pH, and reaction time. The synthesized nanostructures are characterized by UV/Vis and Fourier-transform infrared spectroscopy, transmission electron microscopy, and energy dispersive X-ray analysis studies. Electron diffraction patterns reveal the crystalline nature of the nanoparticles and a probable mechanism is proposed for the formation of the different structural entities.
DNA-controlled assembly of protein-modified gold nanocrystals
Journal of Physical Chemistry B, 2003
The controlled assembly in solution of gold nanocrystals modified by attachment of complementary protein-DNA conjugates is described. The size of the aggregates formed can be controlled by the addition of singlestranded DNA, which quickly terminates the assembly process. The rate of formation of the aggregates can also be controlled by varying the salt concentration. Consequently, two distinct regimes of aggregation kinetics are observed. At low salt concentrations, aggregation is shown to be dependent on the rate of duplex formation between the modified gold nanocrystals, i.e., reaction-limited. At higher salt concentrations, aggregation is shown to be dependent only on the rate of diffusion of the nanocrystals, i.e., diffusion-limited. The results presented provide important insights into the rates of formation of nanocrystal assemblies. Moreover, the approach adopted is modular, requiring only the relevant biotin linker chemistry to be developed for a given nanoparticle, while also precluding unfavorable interactions between the DNA and the streptavidin-coated nanoparticle. The ability to control the rate of formation and size of nanocrystal aggregates assembled is important new knowledge. Application of this knowledge will inform future studies of nanocrystal assembly in solution involving different types of nanocrystals, which is of increasing technological significance.
Gold Nanoparticles Can Induce the Formation of Protein-based Aggregates at Physiological pH
Nano Letters, 2009
Protein-nanoparticle interactions are of central importance in the biomedical applications of nanoparticles, as well as in the growing biosafety concerns of nanomaterials. We observe that gold nanoparticles initiate protein aggregation at physiological pH, resulting in the formation of extended, amorphous protein-nanoparticle assemblies, accompanied by large protein aggregates without embedded nanoparticles. Proteins at the Au nanoparticle surface are observed to be partially unfolded; these nanoparticle-induced misfolded proteins likely catalyze the observed aggregate formation and growth.
Small, 2007
In this work, single-crystalline gold nanoplates were produced by treating an aqueous solution of chloroauric acid with the extract of the unicellular green alga Chlorella vulgaris at room temperature. The results suggest proteins as the primary biomolecules involved in providing the dual function of Au III reduction and the size-and shape-controlled synthesis of the nanogold crystals. A protein with a molecular weight of approximately 28 kDa was isolated and purified by reversed-phase HPLC; this protein tested positive for the reduction of chloroauric acid in aqueous solution. The isolated protein (named gold shape-directing protein, or GSP for convenience) was then used to produce gold nanoplates with distinctive triangular and hexagonal shapes in high yields (% 90 %). The kinetics of the reduction reaction could be manipulated through changes in the GSP concentration to produce plates with lateral sizes ranging from nanometers to micrometers. The growth of gold nanoplates in the GSP solution with time was monitored by microscopic and spectroscopic techniques, thereby allowing the detection of several key intermediates in the growth process.