A protein assay based on colloidal gold conjugates with trypsin

The standard sol particle immunoassay (SPIA) is based on a biospecific aggregation of gold nanoparticle conjugates, followed by conventional spectrophotometry. Here we propose a novel SPIA format that uses microtitration immunological plates and an enzyme-linked immunosorbent assay reader. The novel and standard assays are exemplified by determination of immunoglobulin G by using 15-nm colloidal gold-protein A conjugates. We also describe a novel sol particle-trypsin assay using conjugates of gold nanoparticles with trypsin. The method is based on measuring spectral extinction changes caused by the addition of protein to a conjugate solution. The changes in the extinction spectra are presumed to be related to aggregation of gold nanoparticles caused by polyvalent binding of protein molecules to the trypsin molecules of the conjugates.     

Labelling of colloidal gold with protein A. A quantitative study

Colloidal gold complexes with protein A are extensively used in immunocytochemistry as secondary reagents for the localization of antigens. However detailed information on the process and extent of adsorption of protein A onto gold particles, the optimal condition of preparation and the stability of such complexes are lacking. The adsorption isotherm of 125I-protein A onto gold particles (11.2 nm in diameter) was studied quantitatively with gold sols buffered at pH 4-7. At low coverage of the particles, the isotherm was independent of pH. However in the presence of a large excess of protein A, the highest coverage was obtained with a gold sol buffered at pH 5.1, the isoelectric point of the protein. The association constant was decreased at high coverage of the particles. Maximum binding of the complex to immobilized IgG occurred with particles labelled with at least 9 molecules of protein A. The complex was stable under storage with up to 12 molecules adsorbed per particle. At high coverage (26 molecules per particle), a progressive loss of protein A was observed. The optimum condition for preparing the complex are reported.     

Preparation of protein colloidal gold complexes in the presence of commonly used buffers

In the presence of various commonly used buffers, phosphate-buffered saline (PBS), tris-buffered saline (TBS), Na-cacodylate, bovine serum albumin and a wide range of cytochemically active proteins (monoclonal and polyclonal IgG, concanavalin A, Ricinus communis lectin I, Helix pomatia lectin, protein A) were complexed to colloidal gold of different particle sizes (6 nm, 9 nm, 22 nm). The resulting complexes were active in cytochemical labelling. Complex-formation in the presence of electrolyte opens the possibilities of: maintenance of ionic environment during complexing of proteins sensitive to low ionic strength, pH control by addition of buffers to the protein solution or to the gold sol, direct coupling of protein supplied in PBS or saline avoiding dialysis against low ionic strength buffers. Using the electron microscope to estimate the protein amounts needed for stabilization provided a sensitive and economical method to obtain aggregate-free protein-gold complexes.     

An 8- to 10-fold enhancement in sensitivity for quantitation of proteins by modified application of colloidal gold

We have modified the highly sensitive protein assay of C. M. Stoscheck (1987, Anal. Biochem. 160, 301-305), resulting in a further 8- to 10-fold enhancement of sensitivity. This assay, responding to protein quantities with a detection limit of 1 ng, involves the single step of addition of colloidal gold solution, as now commonly used in histochemistry and protein blotting, to the protein sample, followed by simple measurement of the change in absorbance at 590 nm within minutes. By increasing the concentration of the colloidal gold, by using gold sol that has been stabilized with 0.01% polyethylene glycol and adjusted to pH 3.8, and by adapting the assay to microtiter plates, this type of assay can be applied to reliably determine proteins in the complete nanogram range. This assay therefore compares favorably to other assay procedures in terms of rapidity, sensitivity, expense, and lack of interference by many laboratory reagents, although like the others it suffers from the drawback of differences in response of different proteins, which is inherent in dye-binding assays.     

Solid core liposomes with encapsulated colloidal gold particles

Solid core liposomes with encapsulated colloidal gold particles were prepared through four major steps: Preparation of prevesicles with encapsulated solid cores of agarose-gelatin by emulsification of agarose-gelatin sol in organic solvent containing emulsifiers followed by cooling. Extraction of lipophilic components from prevesicles to obtain microspherules of agarose-gelatin. Introducing colloidal gold particles into microspherules and coating with protein molecules. Encapsulation of colloidal gold-bearing microspherules with the modified organic solvent spherule evaporation method for preparation of liposomes (Kim et al. (1983) Biochim. Biophys. Acta 728, 339-348 and Kim et al. (1984) Biochim. Biophys. Acta 812, 793-801). Electron micrographs showed that if liposomes were prepared by using a lipid mixture containing dioleoylphosphatidylcholine/cholesterol/dioleoylphosphatidylglycerol/tri olein (molar ratio 4.5:4.5:1:1), there was only a single continuous bilayer membrane for each solid core liposome. However, if no triolein was added to the lipid mixture, it would cause the formation of multilamellar liposomes. In both cases, there were hundreds to thousands of colloidal gold particles within each solid core liposome.     

Comparison of colloidal gold electrode fabrication methods: the preparation of a horseradish peroxidase enzyme electrode.

In order to prepare biosensing electrodes which respond to hydrogen peroxide, horseradish peroxidase has been adsorbed to colloidal gold sols and electrodes prepared by deposition of these enzyme-gold sols onto glassy carbon using three methods: evaporation, electrodeposition and electrolyte deposition. In the latter method the enzyme-gold sol is applied to the surface of a glassy carbon disk electrode followed by an equal volume of 2 mM CaCl2. The electrolyte causes the sol to precipitate on the electrode surface, producing an immobilized enzyme electrode. Satisfactory electrodes which gave an electrochemical response to hydrogen peroxide in the presence of the electron transfer mediator ferrocenecarboxylic acid were produced by all three methods. Evaporation of horseradish peroxidase-gold sols produced electrodes with the best reproducibility and the widest linear amperometric response range. These electrodes can also easily be stored in a dry state. Although not as good as evaporation, electrodeposition also produced satisfactory electrodes. Electro-deposition provides the added advantage that it lends itself to the preparation of multi-enzyme/multi-analyte electrodes by the adsorption of different enzymes to separate gold sols, followed by sequential electrodeposition onto discrete areas of a multichannel electrode.     

Simplified purification and testing of colloidal gold probes

A novel efficient method for purifying and testing colloidal gold probes has been developed. The method consists of concentrating colloidal gold particles conjugated to IgG or protein A in dialysis bags over silica gel and purifying them by gel chromatography on small columns of Sephacryl S-400. Fractions collected are tested by paper immunocytochemical models. Comparisons to gold probes purified by conventional ultracentrifugation documents that ultrastructural staining intensities and total yield of gold probes is the same, but that the chromatographically purified gold probes are less prone to aggregation or clumping. The method has been extensively used for preparing conjugates of 5, 10 or 15 nm gold particles with antirabbit immunoglobulins but has also been exploited for preparing streptavidin-gold conjugates, protein A-gold conjugates and antirabbit immunoglobulin-silver conjugates.     

Simplified purification and testing of colloidal gold probes

Summary A novel efficient method for purifying and testing colloidal gold probes has been developed. The method consists of concentrating colloidal gold particles conjugated to IgG or protein A in dialysis bags over silica gel and purifying them by gel chromatography on small columns of Sephacryl S-400. Fractions collected are tested by paper immunocytochemical models. Comparisons to gold probes purified by conventional ultracentrifugation documents that ultrastructural staining intensities and total yield of gold probes is the same, but that the chromatographically purified gold probes are less prone to aggregation or clumping. The method has been extensively used for preparing conjugates of 5, 10 or 15 nm gold particles with antirabbit immunoglobulins but has also been exploited for preparing streptavidin-gold conjugates, protein A-gold conjugates and antirabbit immunoglobulin-silver conjugates.     

Porous gold surfaces for biosensor applications

The sensitivity of optical biosensors where the detection takes place on a planar gold surface can be improved by making the surface porous. The porosity allows a larger number of ligands per surface area resulting in larger optical shifts when interacting with specifically binding analyte molecules. The porous gold was deposited as a thin layer on a planar gold surface by electrochemical deposition in a solution of tetrachloroaurate and lead acetate. A protein, streptavidin, was adsorbed into the formed porous layer and the time course of the adsorption was monitored by in-situ ellipsometry. When the porous layer was 500 nm in thickness a six-fold increase of the ellipsometric response was obtained compared with a planar gold surface. The dependency of porosity and layer thickness was explained with a mathematical model of the gold/porous gold/protein/solution system.     

“Thiocyanate gold”: small (2–3 nm) colloidal gold for affinity cytochemical labeling in electron microscopy

Summary Reduction of HAuCl₄ by NaSCN or KSCN produces colloidal gold particles of 2.6 nm in diameter and homogeneous in size (coefficient of variation 15%). The Au_SCN sol forms protein-gold complexes. The amount of protein required to form an Au_SCN-protein complex is best determined in the electron microscope, where serial dilutions of protein with gold sol are inspected for the presence of aggregates.By immuno-electron microscopy SCN-gold complexed to protein A is active and visible as is shown by revealing -amylase in rat pancreatic acinar cells.     

Ultrastructural localisation of oestrogen receptor in breast cancer cell nuclei

A method of localising oestrogen receptor in nuclei of breast cancer cells by the protein A-gold technique is described. Mast cell granules were found to take up uncoated particles of the gold sol selectively.     

Ultrastructural localisation of oestrogen receptor in breast cancer cell nuclei

Summary A method of localising oestrogen receptor in nuclei of breast cancer cells by the protein A-gold technique is described. Mast cell granules were found to take up uncoated particles of the gold sol selectively.     

Nature of immobilized antibody layers linked to thioctic acid treated gold surfaces

Utilization of 125I-labeled IgG enables an investigation of protein immobilized to gold electrodes sputter deposited on microporous nylon membranes, including the precise nature of the surface-protein bond (i.e. covalent or non-specific adsorption), physical location of the immobilized protein (i.e. on the surface of the gold electrode or within the pores of the membrane), and the amount of protein immobilized. This is accomplished by comparing the mass of protein immobilized to gold surfaces that have been treated in several different fashions, as well as, deposition of the gold on nylon membranes that have been treated differently. It is shown that these microporous gold electrodes, proposed previously for conducting novel non-separation electrochemical enzyme immunoassays, consist of multiple protein layers non-specifically adsorbed. Approximately, half of the total adsorbed protein is immobilized to the gold surface with the remaining protein bound within the pores on the nylon membrane.     

Stable self-assembly of a protein engineering scaffold on gold surfaces

The outer membrane protein OmpF from Escherichia coli is a member of a large family of beta-barrel membrane proteins. Some, like OmpF, are pore-forming proteins whilse others are active transporters or enzymes. We have previously shown that the receptor-binding domain (R-domain) of the toxin colicin N binds with high affinity to OmpF reconstituted into tethered lipid bilayers on gold electrodes. The binding can be measured by surface plasmon resonance (SPR) and ion channel blockage (impedance spectroscopy, IS). In this paper we report the use of a mutant OmpF-E183C in which a single cysteine had been introduced on a short periplasmic turn. OmpF-E183C binds directly to gold surfaces and creates high-density protein layers by self-assembly from detergent solution. When the gold surface is pretreated with beta-mercaptoethanol and thiolipids are added after the protein immobilisation step, the protein is shown, by Fourier transform infrared spectroscopy (FTIR), to retain its beta-rich structure. Furthermore, we could also measure R-domain binding by SPR and IS, confirming the functional reconstitution of a self-assembled membrane protein monolayer at the gold surface. Because these beta-barrel proteins are recognized protein engineering scaffolds, the method provides a generic method for the simple self-assembly of protein interfaces from aqueous solution.     

Secondary structure analyses of protein films on gold surfaces by circular dichroism

In order to analyze the secondary structures of protein molecules adsorbed on gold surfaces, circular dichroism (CD) spectra were measured and the secondary structure contents of protein ultra-thin films were estimated quantitatively. A disulfide group was introduced to cytochrome b(562) (cyt.b562), which is a water-soluble b-type heme protein. The cyt.b562 molecules self-assembled to form an ultra-thin protein film both on a gold substrate modified with 2,2(')-dithiodiacetic acid and on a bare gold surface. CD measurements were carried out both in solution and in air, and these results were compared. The protein denaturation was partially prevented, not only in solution but also in air, by both the modification of the substrate and the introduction of the anchor group to the protein molecule. The secondary structure contents of ultra-thin protein films on flat gold surfaces were observed for the first time both in solution and in air by CD spectra.     

Structure and activity of apoferritin-stabilized gold nanoparticles

A simple method for synthesizing gold nanoparticles stabilized by horse spleen apoferritin (HSAF) is reported using NaBH(4) or 3-(N-morpholino)propanesulfonic acid (MOPS) as the reducing agent. AuCl(4)(-) reduction by NaBH(4) was complete within a few seconds, whereas reduction by MOPS was much slower; in all cases, protein was required during reduction to keep the gold particles in aqueous solution. Transmission electron microscopy (TEM) showed that the gold nanoparticles were associated with the outer surface of the protein. The average particle diameters were 3.6 and 15.4 nm for NaBH(4)-reduced and MOPS-reduced Au-HSAF, respectively. A 5-nm difference in the UV-Vis absorption maximum was observed for NaBH(4)-reduced (530 nm) and MOPS-reduced Au-HSAF (535 nm), which was attributed to the greater size and aggregation of the MOPS-reduced gold sample. NaBH(4)-reduced Au-HSAF was much more effective than MOPS-reduced Au-HSAF in catalyzing the reduction of 4-nitrophenol by NaBH(4), based on the greater accessibility of the NaBH(4)-reduced gold particle to the substrate. Rapid reduction of AuCl(4)(-) by NaBH(4) was determined to result in less surface passivation by the protein. Methods for studying ferritin-gold nanoparticle assemblies may be readily applied to other protein-metal colloid systems.     

Use of colloidal gold in diagnostic surgical pathology

Colloidal gold immuno-electron microscopy is a powerful tool for defining antigenicity at the subcellular level. Such studies permit correlation with cell fractionation studies. They also allow one to assess the specificity of a particular antibody. The most useful reagent for immuno-electron microscopy is colloidal gold stabilized by a binding protein, either staphylococcal protein A or immunoglobulin. This method permits highly discrete labeling, and the system is useful for most antibodies used in diagnostic pathology.     

A nanogram-level colloidal gold single reagent quantitative protein assay

We have developed a nanogram-level quantitative protein assay based on the binding of colloidal gold to proteins adhered to nitrocellulose paper. The protein–gold complex produces a purple color proportional to the amount of protein present, and the intensity of the stain is quantified by densitometry. Typical assays require minimal starting material (10–20 μl) containing 1 to 5 μg protein. A small volume (2 μl) of protein solution is applied to nitrocellulose paper in a grid array and dried. The nitrocellulose is incubated in colloidal gold suspension with gentle agitation (2–16 h), rinsed with water, and scanned. Densitometric analysis of the scanned images allows quantitation of the unknown sample protein concentration by comparison with protein standards placed on the same nitrocellulose grid. The assay requires significantly less sample than do conventional protein assays. In this report, the Golddots assay is calibrated against weighed protein samples and compared with the Pierce Micro BCA Protein Assay Kit. In addition, the Golddots assay is evaluated with several known proteins with different physical properties.     

Analysis of colloidal gold methods for labelling proteins

Summary The relationship between unbound and bound proteins prepared during labelling with colloidal gold (Au) was investigated. For this aim, labelled ¹²⁵I-bovine serum albumin and ¹²⁵I-rabbit immunoglobulin were employed. The procedures associated with the washing of the Au labelled proteins (i.e. albumin) had a marked influence on the dissociation of the bound ligand. This was most evident when the concentration of albumin that was used for labelling was too high (0.1 or 1.0 mg/ml Au sol). We suggest that purification of labelled proteins be conducted shortly before use so as to avoid a significant amount of dissociation during the time when the solution is coming to equilibrium.     

A model of protein-colloidal gold interactions

We prepared homogeneous populations of colloidal gold particles of various sizes. These were analyzed for size distribution and number of particles per unit volume. On exposure to increasing concentrations of insulin, myoglobin, protein A, peroxidase, serum albumin, galactosylated serum albumin, lactoferrin, transferrin, catalase, low-density lipoprotein, ferritin, and polymeric IgA, protein binding was a saturable process. Using serum albumin, we verified that a reversible equilibrium was reached within 15 minutes. Scatchard analysis of the interactions between all of these proteins and the gold particles resulted in a single component, linear relation. For a given particle size, the number of binding sites for various proteins was inversely proportional to their molecular weight. Conversely, when the size of particles was varied, the number of binding sites was directly proportional to the average area of each gold particle. All results are compatible with a monomolecular shell of protein surrounding the particle at saturation, the binding capacity being inversely proportional to the projection area of the protein. We present direct morphological evidence for this model. The affinity of the various proteins for the colloid also increased with molecular weight, and was not related to the protein isoelectric point. For globular proteins, the monomolecular shell model makes possible prediction of the number of molecules that will saturate a gold particle, if the average diameter of the gold particles and the molecular weight of the protein are known.