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Transcript
5 Quantitative Determination of Proteins Objectives: A) To prepare a standard curve for the Bio-Rad assay and B) to determine and compare the unknown concentration of a solution of a protein from this curve. Introduction: There are many methods for determining protein concentration. Some of these methods depend on the reactions of reagents with peptide bonds or amino acid side chains of the protein; others depend on the binding of a reagent (dye) to the protein. The Biuret Method In this method, the reagent, a dilute copper sulfate solution at alkaline pH, reacts with peptides or proteins. This complex undergoes a blue to violet color transformation that requires five minutes to complete. The protein is quantitated at 540 nm. This method requires relatively large quantities of protein (1 - 20 mg protein / mL) for detection. Additionally, it is sensitive to a variety of nitrogen-containing substances that could be in the protein solution, thereby increasing the likelihood of erroneous results. The Lowry Test The Lowry test is the most sensitive quantitative colorimetric assay for protein detection. This test requires only 0.005 to 0.3 mg protein per mL for detection. It is a modification of the biuret method. The intense blue-green color formed in the Lowry test comes from the reaction of the phosphomolybdotungstate in the Lowry reagent with the W and Y residues in the protein. This assay method, however, can give low values if the protein under examination does not have a significant number of W and Y residues. The Bradford (Bio-Rad) Method This method employs a dye that binds to the protein to form a blue complex. It can detect from 0.2 to 1.4 mg of protein per mL. The Bradford method uses the negatively charged dye Coomasie Brilliant Blue G-250, which binds to positive chains of the protein, to give the blue complex. The red form of this dye predominates in solution before a protein is added. The color changes into the blue form upon complexing to the protein – the more concentrated the protein, the more intense the blue color. This method is more rapid and less susceptible to interfering substances than either of the above methods. The color develops within 2 - 5 minutes and is stable up to 24 hours. It is for these reasons that it is the most popular method of protein quantitation. Consequently, it is the method we will use in today’s experiment. The Protein The protein we will analyze is bovine serum albumin (BSA). Albumin is a serum protein that transports fatty acids and is important in maintaining plasma pH. In protein quantitation assays, BSA serves as a reference protein that is used to construct protein standard curves. Other proteins can be used depending on the physical/chemical properties of your protein of interest. Procedures for the Bio-Rad Protein Assay: Procedures for the Bio-Rad Protein Assay: I. Prepare a standard curve You will be given a stock solution of 0.8 mg/mL bovine serum albumin (BSA) You will need to make 6 standards. Make 1 mL of each of the following concentrations: 10 µg/mL 20 µg/mL 40 µg/mL 60 µg/mL 80 µg/mL 100 µg/mL I have not given you the exact procedure to follow because you should be able to calculate the volumes required to make these standards. Review the handout from the first day of class. II. Prepare the plate To wells A4 – A6 add 160 µL water (this is the blank)* To wells B4 – B6 add 160 µL of 10 µg/mL standard To wells C4 – C6 add 160 µL of 20 µg/mL standard To wells D4 – D6 add 160 µL of 40 µg/mL standard To wells E4 – E6 add 160 µL of 60 µg/mL standard To wells F4 – F6 add 160 µL of 80 µg/mL standard To wells G4 – G6 add 160 µL of 100 µg/mL standard To wells H4 – H6 add 80 µL of the protein sample of unknown concentration and 80 µL water Add 40 µL of Stock BioRad reagent to each well MIX WELL WITH THE PIPETTE TIP, last year the groups that mixed well got good results those who did not had very poor results. WAIT AT LEAST 5 MINUTES BEFORE READING • III. The plate reader will average the “blank” absorbance values and subtract this average from every other well. You will also use this as one of the points on your standard curve. Read the plate Open protocol “proteinquant#” where # is your section number Click on Icon that reads “Read” Fill in the information: Section Name Experiment Click on button that reads “Start Reading” A window will open that reads “Insert plate and press ok” Insert the plate and then press ok Save data as before, and e-mail the data to yourself. You may wish to consult the lab manual for the Riboflavin experiment. IV. Analyze the data Check for outlying data points (this assay can give rather varied results) Use Microsoft Excel to construct a standard curve of A595 vs. µg protein. Remember to do the linear regression analysis. Use the equation from the linear regression to determine the amount of protein in wells H1, H2, and H3. Then calculate the protein concentration of your unknown BY THAT I MEAN THE CONCENTRATION IN THE TUBE WITH THE NUMBER, recall that you diluted it when placing it in the plate. Express the answer in µg/mL. Make sure to include the number of the unknown. Why isn’t water used to blank the spectrophotometer in this experiment? Quantitative Determination of Proteins STUDY GUIDE 1. In this experiment, the “blank” was different from that used in the riboflavin experiment. How does one know what should be in the “blank”? 2. Suppose you used 0.1 mL of your BSA solution of unknown concentration in the Bio-Rad assay. If the assay tube had a total volume of 5.1 mL, and the absorbance indicated a concentration of 10µg protein per tube, what is the concentration of the unknown BSA solution in µg/mL? 3. Give examples of nitrogen-containing molecules that might be present in a protein solution. 4. Describe how the Lowry test is a modification of the biuret test. Compare the sensitivities of these two tests for proteins. 5. There are advantages and disadvantages associated with all of the quantitation methods discussed in this week’s experiment. When might it be more advantageous to use the Lowry rather than the Bio-Rad assay? Why? 6. Should there be any concerns associated with the disposal of any of these reagents? Which one(s)? Why? 7. The molar extinction coefficient of Substance A is 18,550 M-1cm-1 at pH 8.5 and 650 nm. You have 250 mL of Solution A of unknown concentration. When 4 mL of your Solution A is poured into a cuvette 1 cm wide, 1 cm long, and 4 cm high, and placed in a spectrophotometer, an absorbance of 0.358 is obtained at pH 8.5 and 650 nm. a. What is the molar concentration of your Solution A? b. How many moles do you have in 250 mL of solution? c. If your 250 mL of Substance A was prepared by dissolving 2.58 x 10-3 grams of Substance A in 250 mL of solution, what is the molecular weight of Substance A?
