Showing papers on "Bradford protein assay published in 2004"

Spectrophotometric Determination of Protein Concentration

Abstract: This unit describes spectrophotometric and colorimetric methods for measuring the concentration of a sample protein in solution. Absorbance measured at 280 nm (A(280)) is used to calculate protein concentration by comparison with a standard curve or published absorptivity values for that protein (a(280)). Alternatively, absorbance measured at 205 nm (A(205)) is used to calculate the protein concentration. The A(280) and A(205) methods can be used to quantify total protein in crude lysates and purified or partially purified protein. A spectrofluorometer or a filter fluorometer can be used to measure the intrinsic fluorescence emission of a sample solution; this value is compared with the emissions from standard solutions to determine the sample concentration. The fluorescence emission method is used to quantify purified protein. This simple method is useful for dilute protein samples and can be completed in a short amount of time. There are two colorimetric methods: the Bradford colorimetric method, based upon binding of the dye Coomassie brilliant blue to the protein of interest, and the Lowry method, which measures colorimetric reaction of tyrosyl residues in the protein sample.

A rapid solid-phase fluorescence-based protein assay for quantitation of protein electrophoresis samples containing detergents, chaotropes, dyes, and reducing agents.

Abstract: A new solid-phase, fluorescence-based protein assay was developed that quantifies proteins in the presence of detergents, urea and reducing agents (one-dimensional sodium dodecyl sulfate (1-D SDS) lysis buffers and urea isoelectric focusing (IEF) buffers). A specially designed 96-well microplate facilitates application of protein samples to the assay paper and allows easy quantitation of samples using fluorescence microplate readers (top or bottom reading format). Alternatively, stained membranes may be directly scanned using a variety of different laser or charge-coupled device (CCD)-based imaging devices with UV or visible imaging capabilities. Since protein is specifically bound to the membrane, contaminants are readily washed away, avoiding interference with the protein measurement. The protein assay has a dynamic range extending from 10 ng to 5 microg of protein per microliter and requires only 1 microL of sample, which is ideal for samples destined for electrophoresis. The protein-to-protein variability of staining of ten different proteins was determined to be comparable with that of the bicinchoninic acid (BCA) and Lowry assays (16%). Additionally, the quality of the assay according to Z-factor analyses is excellent.

Stress protein assay for the evaluation of cytotoxicity of dental amalgam.

Abstract: To evaluate the cytotoxicity of mercury in dental amalgams, a stress protein assay was performed and the results were compared with the cytotoxicity evaluated by a neutral red uptake assay. The induction of a major stress protein, hsp70, was analyzed at levels of mRNA, synthesis and accumulation in human HeLa cells treated with extracts from amalgam, metal mercury and mercuric chloride. Mercuric chloride induced an increase in the synthesis of hsp70 at concentrations of mercury half those used for the neutral red uptake assay. The extracts from dental amalgam and metal mercury induced an increase in hsp70 mRNA at concentrations of mercury half those causing the inhibition of neutral red uptake into cells. Furthermore, the extracts from dental amalgam or metal mercury increased the synthesis of hsp70 and inhibited the uptake of dye at concentrations of mercury 1/10–1/50 lower than those at which mercuric chloride acted. These results suggest that the stress protein assay is more sensitive than the conventional neutral red assay for the evaluation of the cytotoxicity of mercury in dental amalgams and that the methods used in the preparation of metal solutions seem to be critical to the evaluation of cytotoxicity of dental materials.

Micro-Determination of Protein Containing SH– and –S–S– Groups Based on the Polarographic wave of an Electroactive Derivative

Abstract: This paper presents a new simple and sensitive method for the micro-determination of protein containing SH– and –S–S– groups based on the single sweep polarographic wave of an electroactive derivative. In 0.04 mol L−1 Na3PO4 and 0.2% ascorbic acid solution, protein is heated in a boiling water bath for 15 min, the reaction product giving a sensitive reduction wave at −0.70 V (vs. SCE). The wave height is linearly proportional to the concentration of protein. The calibration curves of bovine serum albumin (BSA), human serum albumin (HSA), ovalbumin (OVA) and lysozyme (Lyso) are constructed under the optimal conditions. For BSA and HSA, the linear ranges and detection limits are 0.05–24 mg L−1 and 0.02 mg L−1, respectively. The method has been applied to the determination of protein in human serum samples with satisfactory results. The mechanism of the polarographic wave was also studied, and the results show that S2− ion is released from the protein molecule during the derivatization reaction, the wave being attributed to the reduction of HgS.

A new approach to protein phosphorylation modification analysis for neuron

Abstract: Objective To develop a new method for analysis of protein phosphorylation modification in cultured neuron. Methods Cultured neurons were pre-incubated in DMEM without sodium phosphate for 15 min to deplete the metabolic pools. Neurons were then labeled with [32P] orthophosphate (2.78 x 10(6) Bq/ml) for 1.5 h and stimulated by either insulin (100 nmol/L), EGF (20 nm/L) or saline for 0, 5, 20, 60, 120 min. Reactions were terminated by freezing neurons in liquid nitrogen prior to the solubilizing of them in a lysis buffer containing 8 mol/L urea, 4% CHAPS, 2% Bio-lyte, pH 3-10, 2 mmol/L TBP. Protein concentrations were determined with Bio-Rad DC Protein Assay kit. The 32P-labled lysates isoelectrically focused on IPG Drystrip pH 3-10 or pH 4-7 Linear gels were subsequently separated in second-dimensional SDS-PAGE. The dried gel was autoradiographed for 5 days at -70 degrees C with an intensifying screen. Alternatively, the separated proteins were visualized by Coomassie Brilliant Blue (CBB) R250 straining. Results Autoradiography of the 2-DE-separated 32P-laebled neuron lysates revealed around 100 phosphoproteins. This phosphoprotein pattern was stable at 1.5 h after radiolabelling and did not vary significantly for up to 4 h further incubation in the absence of hormone. Most of the major proteins which are phosphorylated in response to insulin or EGF migrated with pH 4.6-6.5 and MW 20000-130000. Insulin and EGF induced similar but not identical patterns of protein phosphoryltion in neurons. Only a few phosphoproteins were abundant enough to be visualized by CBB straining, suggesting that abundance of these phosphoproteins is extremely low. Responses to both isulin and EGF are marked by more increased labeling of the constitutive phosphoproteins, compared with the appearance of new phosphoproteins. Conclusion This approach co-application of 32P-labeled with 2-DE separation and autoradiography has proven to be specific and sensitive in phosphoprotein analysis for neuron. It was valuable in functional proteomic analysis for protein phosphorylation modification during cellular signal transduction.

Typ-PepT1-Protein-Assay Type PepT1 protein assay

Abstract: Die Erfindung betrifft einen Typ-PepT1-Protein-Assay und insbesondere ein Verfahren zum Identifizieren eines Substrats und/oder eines Modulators des PepT1-Proteins. The invention relates to a PepT1-type protein assay and in particular to a method for identifying a substrate and / or a modulator of the PepT1 protein.