Comparison of colorimetric methods for the quantification of model proteins in aqueous two-phase systems

In the current study, the quantification of different model proteins in the presence of typical aqueous two-phase system components was investigated by using the Bradford and bicinchoninic acid (BCA) assays. Each phase-forming component above 1 and 5 wt% had considerable effects on the protein quantification in both assays, respectively, resulting in diminished protein recoveries/absorption values by increasing poly(ethylene glycol) (PEG)/salt concentration and PEG molecular weight. Therefore, a convenient dilution of both components (up to 1 and 5 wt%) before protein quantification is recommended in both assays, respectively, where the BCA assay is favored in comparison with the Bradford assay.     

Interferences of suspended clay fraction in protein quantitation by several determination methods

Seven current methods of protein quantitation, Bradford (standard, micro, and 590/450 nm ratio), Lowry, bicinchoninic acid (BCA), UV spectrophotometry at 280 nm, and Quant-iT fluorescence-based determination, were compared with regard to their susceptibility to interferences due to the presence of suspended and not easily detectable clay particles. Bovine serum albumin (BSA) and Na-Wyoming montmorillonite were selected as model protein and reference clay, respectively. Protein-clay suspension mixtures were freshly prepared for each assay to simulate supernatants not completely centrifuged in batch sorption/kinetic experiments. Seven fixed increasing levels of clay (0.0, 0.00725, 0.0145, 0.029, 0.058, 0.145, 0.435 mg ml⁻¹) were mixed with different levels of BSA in an appropriate range for each assay. To ascertain the interfering effect of different levels of clay, the theoretical concentrations of BSA were plotted against the estimated BSA concentrations of the samples, as obtained from the calibration curve of each method. A correct quantitation of the BSA concentration not influenced by clay would be described by a regression line with slope (b) not significantly different from 1 and an intercept (a) not significantly different from zero. At the lowest clay levels (0.00725 mg ml⁻¹) a significant interference was evident for Bradford micro, Bradford 590/450, UV, and fluorescence. The three methods (Bradford standard, Lowry, and BCA) that seemed to show the better performances in the presence of clay after this first screening step also underwent an ANCOVA analysis, with the measured BSA concentrations as dependent variable and the clay concentrations as covariate. The Bradford standard and BCA methods were affected by a clay-dependent interference on BSA quantitation. The Lowry assay was the only method that gave correct estimates of BSA concentrations in the presence of any of the clay levels tested.     

Rapid method for protein quantitation by Bradford assay after elimination of the interference of polysorbate 80

Bradford assay is one of the most common methods for measuring protein concentrations. However, some pharmaceutical excipients, such as detergents, interfere with Bradford assay even at low concentrations. Protein precipitation can be used to overcome sample incompatibility with protein quantitation. But the rate of protein recovery caused by acetone precipitation is only about 70%. In this study, we found that sucrose not only could increase the rate of protein recovery after 1 h acetone precipitation, but also did not interfere with Bradford assay. So we developed a method for rapid protein quantitation in protein drugs even if they contained interfering substances.     

Development of a fluorescent and colorimetric detection methods-based protein microarray for serodiagnosis of TORCH infections

We developed a protein microarray methodology that has the ability of serodiagnosis of IgM antibodies directed against TORCH pathogens. Six chemical surface modifications were validated by a dimension atomic force microscope (AFM) and contact angle measurement, agarose modified surface of which offered an appropriate platform for detecting IgM antibody. Further, signal amplification sensitivities on agarose modified microarrays were detected by Cy3-labeled biotin-streptavidin and immunogold-based assays. The detection limits of IgM antibody on the microarrays were 0.48 and 0.24mug/ml, quantitatively equal to 0.25 and 12.5pg, respectively, on each spot as ascertained by the two assays. Satisfactory linear correlations between the signal intensity and the logarithm of the IgM concentration were obtained. Finally, 60 serum samples characterized by a commercial ELISA were evaluated by the protein microarray. There were good concordances between the results of the protein microarray and ELISA assay for sorting of the TORCH infected sera (95.0% by fluorescence-based assay and 96.7% by immunogold-based assay). Clearly, the potential application of this protein microarray format facilitates clinical detection of not only the antibodies directed against TORCH pathogens but also other autoimmune diseases.     

Structure and mechanistic insights into novel iron-mediated moonlighting functions of human J-protein cochaperone, Dph4

J-proteins are obligate cochaperones of Hsp70s and stimulate their ATPase activity via the J-domain. Although the functions of J-proteins have been well understood in the context of Hsp70s, their additional co-evolved "physiological functions" are still elusive. We report here the solution structure and mechanism of novel iron-mediated functional roles of human Dph4, a type III J-protein playing a vital role in diphthamide biosynthesis and normal development. The NMR structure of Dph4 reveals two domains: a conserved J-domain and a CSL-domain connected via a flexible linker-helix. The linker-helix modulates the conformational flexibility between the two domains, regulating thereby the protein function. Dph4 exhibits a unique ability to bind iron in tetrahedral coordination geometry through cysteines of its CSL-domain. The oxidized Fe-Dph4 shows characteristic UV-visible and electron paramagnetic resonance spectral properties similar to rubredoxins. Iron-bound Dph4 (Fe-Dph4) also undergoes oligomerization, thus potentially functioning as a transient "iron storage protein," thereby regulating the intracellular iron homeostasis. Remarkably, Fe-Dph4 exhibits vital redox and electron carrier activity, which is critical for important metabolic reactions, including diphthamide biosynthesis. Further, we observed that Fe-Dph4 is conformationally better poised to perform Hsp70-dependent functions, thus underlining the significance of iron binding in Dph4. Yeast Jjj3, a functional ortholog of human Dph4 also shows a similar iron-binding property, indicating the conserved nature of iron sequestration across species. Taken together, our findings provide invaluable evidence in favor of additional co-evolved specialized functions of J-proteins, previously not well appreciated.     

New fluorescent probes for ligand-binding assays of odorant-binding proteins

Fluorescence-linked binding assays allow determination of dissociation constants at equilibrium and have recently become increasingly popular, thanks to their ease of operation. Currently used probes, such as 1-aminoanthracene and N-phenyl-1-naphthylamine, are excited and emit in the ultraviolet region, but alternative ligands operating in the visible spectrum would be highly desirable for applications in biosensing devices. Based on the two above structures, we have designed and synthesised six new fluorescent probes to be used in ligand-binding assays. The compounds are derivatives of naphatalene, anthracene and fluoranthene and present two aromatic moieties linked by an amine nitrogen. We have measured the emission spectra of the new probes and their binding to three odorant-binding proteins. The probes bind the tested proteins with different affinities, generally with dissociation constants about one order of magnitude lower than the parent compounds. The extended aromatic systems present in the new compounds produced a shift of both excitation and emission peaks at higher wavelength, close or within the visible spectrum, thus facilitating measurements in biosensors for odorants and small organic molecules using optical devices.     

Interference of N-hydroxysuccinimide with bicinchoninic acid protein assay

We report here substantial interference from N-hydroxysuccinimide (NHS) in the bicinchoninic acid (BCA) protein assay. NHS is one of the most commonly used crosslinking agents in bioanalytical sciences, which can lead to serious potential errors in the BCA protein assay based protein estimation if it is present in the protein analyte solution. It was identified to be a reducing substance, which interferes with the BCA protein assay by reducing Cu²⁺ in the BCA working reagent. The absorbance peak and absorbance signal of NHS were very similar to those of bovine serum albumin (BSA), thereby indicating a similar BCA reaction mechanism for NHS and protein. However, the combined absorbance of NHS and BSA was not additive. The time–response measurements of the BCA protein assay showed consistent single-phase kinetics for NHS and gradually decreasing kinetics for BSA. The error in protein estimation due to the presence of NHS was counteracted effectively by plotting additional BCA standard curve for BSA with a fixed concentration of NHS. The difference between the absorbance values of BSA and BSA with a fixed NHS concentration provided the absorbance contributed by NHS, which was then subtracted from the total absorbance of analyte sample to determine the actual absorbance of protein in the analyte sample.     

Comparison of 5 microplate colorimetric assays forin vitro cytotoxicity testing and cell proliferation assays

This paper describes a critical comparative evaluation of 5 miniaturised colorimetric assays applicable to cytotoxicity testing of anti-tumour drugs (and other toxins)in vitro. Each assay shows a different linear range for optical density versus cell number, a different sensitivity to change in cell number and a different minimum detectable cell number; the values of these parameters vary with experimental conditions and with cell line used. All the methods gave good correlation with viable cell number (determined by colony forming efficiency) in toxicity assays after 3 or 4 days of treatment, but they underestimated cell death after 2 days. Toxicity levels for individual chemicals (in a standard 6-day assay) are similar for the different assays, irrespective of the mechanism of action of the chemical being tested. Two of the more recently developed assays (APNaOH and SRB) were found to be very sensitive under the conditions examined.     

A method for concentrating organic dyes: colorimetric measurements of nitric oxides and sialic acids

A new method for extraction and concentration of organic dyes that uses a reagent composed of a nonionic detergent mixed with an alcohol is described. We have observed that water-soluble organic dyes are also soluble in nonionic detergents and can be extracted by adding salt, which separates the dye–detergent component from the aqueous phase. We have also found that mixing nonionic detergents with alcohols markedly reduces their viscosity and produces stable, free-flowing, and effective reagents for color extraction. On the basis of these observations, we used a mixture of Triton X-100 and 1-butanol and observed that water-soluble natural and synthetic chromophores, as well as dyes generated in biochemical reactions, can be extracted, concentrated, and analyzed spectrophotometrically. Trypan blue and phenol red are used as examples of synthetic dyes, and red wine is used as an example of phenolic plant pigments. Applications for quantification of nitric oxides and sialic acids are described in more detail and show that as little as 0.15 nmol of nitric oxide and 0.20 nmol of sialic acid can be detected. A major advantage of this method is its ability to concentrate chromophores from dye-containing solutions that otherwise cannot be measured because of their low concentrations.     

New methods for measuring macromolecular interactions in solution via static light scattering: basic methodology and application to nonassociating and self-associating proteins

A method for rapid detection and characterization of reversible associations of macromolecules in solution is presented. A programmable dual-syringe infusion pump is used to introduce a solution of time-varying composition into parallel flow cells for concurrent measurement of laser light scattering at multiple angles and ultraviolet-visible absorbance. An experiment lasting less than 15 min produces a large and information-rich set of data, consisting of several thousand values of the Rayleigh ratio as a function of solute concentration(s) and scattering angle. Using a novel treatment of the data, the entire data set may be equally rapidly analyzed in the context of models for self-association. Validation experiments conducted on previously characterized nonassociating and self-associating proteins yielded robust values for molecular weights in the range 10-330 kDa and equilibrium association constants for dimer formation in the range 2 x 10(3)-6 x 10(5) M(-1).     

A tracking marker for the first dimension of the two-dimensional gel electrophoresis of ribosomal proteins

Protein content of different subcellular fractions from chick brain is compared by using Lowry, TCA—Lowry and Bradford assay methods. Caution is urged in application of Bradford's method to general assay for protein concentration in subcellular fractions.     

Applications of cytotoxicity assays and pre-lethal mechanistic assays for assessment of human hepatotoxicity potential

While drug toxicity (especially hepatotoxicity) is the most frequent reason cited for withdrawal of an approved drug, no simple solution exists to adequately predict such adverse events. Simple cytotoxicity assays in HepG2 cells are relatively insensitive to human hepatotoxic drugs in a retrospective analysis of marketed pharmaceuticals. In comparison, a panel of pre-lethal mechanistic cellular assays hold the promise to deliver a more sensitive approach to detect endpoint-specific drug toxicities. The panel of assays covered by this review includes steatosis, cholestasis, phospholipidosis, reactive intermediates, mitochondria membrane function, oxidative stress, and drug interactions. In addition, the use of metabolically competent cells or the introduction of major human hepatocytes in these in vitro studies allow a more complete picture of potential drug side effect. Since inter-individual therapeutic index (TI) may differ from patient to patient, the rational use of one or more of these cellular assay and targeted in vivo exposure data may allow pharmaceutical scientists to select drug candidates with a higher TI potential in the drug discovery phase.     

Evaluation of fluorescence-based thermal shift assays for hit identification in drug discovery

The fluorescence-based thermal shift assay is a general method for identification of inhibitors of target proteins from compound libraries. Using an environmentally sensitive fluorescent dye to monitor protein thermal unfolding, the ligand-binding affinity can be assessed from the shift of the unfolding temperature (Delta Tm) obtained in the presence of ligands relative to that obtained in the absence of ligands. In this article, we report that the thermal shift assay can be conducted in an inexpensive, commercially available device for temperature control and fluorescence detection. The binding affinities obtained from thermal shift assays are compared with the binding affinities measured by isothermal titration calorimetry and with the IC(50) values from enzymatic assays. The potential pitfalls in the data analysis of thermal shift assays are also discussed.     

A rapid method for determining dynamic binding capacity of resins for the purification of proteins

Biolayer interferometry is a novel method for quantifying macromolecules, such as proteins, in solution. The presence of other, non-binding molecules does not interfere with quantification, which allows one to measure the concentration of the molecule of interest in a crude mixture. Here we apply this method to determining the dynamic binding capacity of affinity resins.     

Simplified 2,4-dinitrophenylhydrazine spectrophotometric assay for quantification of carbonyls in oxidized proteins

This work proposes a modification of the 2,4-dinitrophenylhydrazine (DNPH) spectrophotometric assay commonly used to evaluate the concentration of carbonyl groups in oxidized proteins. In this approach NaOH is added to the protein solution after the addition of DNPH, shifting the maximum absorbance wavelength of the derivatized protein from 370 to 450 nm. This reduces the interference of DNPH and allows the direct quantification in the sample solution without the need for the precipitation, washing, and resuspension steps that are carried out in the traditional DNPH method. The two methods were compared under various conditions and are statistically equivalent.     

Free and bound amino acids and proteins in developing grains of rice with enhanced lysine/proteins

 Free amino acids were determined in developing seed of a rice mutant with enhanced grain lysine. This phenotype frequently has enhanced protein. Some free amino acids of developing seed are inversely related to the level of total amino acids in proteins of the mature grain. Amino acids that were enhanced in protein, including aspartic acid, threonine, methionine and lysine, were notably lower in the free amino-acid pool. Our conclusion is that mutant-developing grains process aspartate amino acids more rapidly than the controls. Conversely, arginine, valine and glutamic acid/glutamine accumulate as free amino acids with mutant/control ratios of 1.39, 1.29 and 1.12, respectively. Glutamic acid/glutamine in proteins of mature seeds is lower in the mutant than the control. ³H-lysine incorporation showed enhanced isotope incorporation into at least four proteins. One mutant protein was less actively labelled than analogous controls. The ³Hlysine pattern indicates processing modifications in this useful rice mutant. Received: 14 October 1996/Accepted: 8 November 1996     

Modification of the Lowry assay to measure proteins and phenols in covalently bound complexes

It is well established that phenols interfere with many routine protein assays and a number of protocols have been developed to overcome this. One such method is based on the differences in response obtained with the Lowry assay in the presence and absence of copper. This assumes that the phenol response with the Lowry assay is not affected by copper. However ortho-diphenols such as catechol, methylcatechol, caffeic acid, chlorogenic acid, and phaselic acid show decreased responses in the presence of copper. Three methods of estimating protein were compared for their accuracy in measuring proteins in the presence of covalently bound ortho-diphenols; the Lowry assay, the modified Lowry assay, and a new method including a calculation to take into account differences in ortho-diphenol response in the presence and absence of copper. The ortho-diphenols were caffeic acid and phaselic acid, which were bound to bovine serum albumin and red clover protein either chemically or enzymatically. For all assays, the new method gave values within 4 to 8% of control values for protein (without bound phenols) as determined by the modified Lowry method. Values for the Lowry and modified Lowry methods varied by 20-50% from control protein values. The new method also gave a good approximation of protein-bound phenol content.     

Amino Acid Biases in the N- and C-termini of Proteins are Evolutionarily Conserved and are Conserved Between Functionally Related Proteins

Analysis of the Arabidopsis thaliana, Saccharomyces cerevisiae, Mus musculus, Escherichia coli, Bacillus subtilis, Thermoplasma acidophilum, and Sulfolobus tokodaii genomes demonstrate that many amino acid biases occur at the N- and C-termini of proteins, a statistically significant number of these biases are evolutionarily conserved, and these biases occur in amino acids beyond the first and last five amino acids. Analyses designed to shed light on the mechanism causing amino acid biases suggest that in at least some cases the bias is caused by forces acting at the nucleic acid level. It is also demonstrated that in E. coli functionally related proteins show similar biases at the N- and C-termini suggesting that the mechanisms causing the biases are complex and in some cases are related to function.