4 a and b pleaseeee curve for tyrosine, labeling the buffer regions and equivalence points. circle the region on your titration curve where half the R groups are ionized.What is the isoelectric point for lysine? Indicate it on your titration curve with "pl"is the approximate net charge of tyrosine at pH 7?What iWhat2. You wish to make 1 L of a 100 mM Phosphate buffer at pH=7.0. You have each of the forms ofphosphate available: phosphoric acid (98 g/mol), monosodium phosphate (120 g/mol) and disodiumhydrogen phosphate (142 g/mol). The pK, values for phosphate are 2.12, 7.21, 12.67).3. Biomolecules come in all shapes and sizes and need to interact with one another,. Discuss the possiblechemical properties of the exterior of a protein that favorably interact with the following molecules. What arethe forces that are driving the interaction?a. A protein interacting with:OHH₂C-C-CH3O-CH3b. A protein interacting with the surface of a surface of a lipid bilayer, which is composed ofhydrocarbons in the interior and charged, polar head groups on the exterior.c. A protein interacting with lipids (such as the inside of a membrane)4. An enzyme catalyzed reaction was initiated in 1.0 mL of 0.06 M HEPES buffer, pH 7.55. During thecourse of the reaction 3.0 μmol of H* was produced.What was the final pH of the reaction mixture, assuming the enzyme and reaction metabolitesother than H+ did not influence it? The pKa for HEPES is 7.55.b. What would the pH be in the absence of buffer (If the reaction occurred in water)?

The Henderson Hasselbalch equation describes the mathematical relationship between the pH and pKa of…

Answered: 4. An enzyme catalyzed reaction was…

Biochemistry

9th Edition

ISBN:9781319114671

Author:Lubert Stryer, Jeremy M. Berg, John L. Tymoczko, Gregory J. Gatto Jr.

Publisher:Lubert Stryer, Jeremy M. Berg, John L. Tymoczko, Gregory J. Gatto Jr.

Chapter1: Biochemistry: An Evolving Science

Section: Chapter Questions

Problem 1P

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Titration curve of an unknown amino acid The graph below shows a curve, which was obtained following titration of an unknown amino acid. Include a suitable descriptive title stating the identity of the unknown amino acid Use rectangles to precisely outline the regions in the graph where ionisable groups show buffering activity (base/acid ratio 1:10 to base/acid ratio 10:1); clearly associate the name of the ionisable group with the buffering regions; indicate within the graph all observable titration mid-points and all observable titration end-points and indicate estimates of the pKa of the three functional groups (do not provide pka values from the literature, you need to read the pka from the titration curve provided). Note that it is not possible to estimate the pka with more than one decimal precision due to limited resolution of the shown graph.
Size Size Crude Anion Cation 2) Exclusion Exclusion Lysate Exchange Exchange 1 2 Total Protein Concentration 15.2 6.6 2 3.75 4.7 (mg/mL) Final Sample Volume 60 30 20 4 3 (mL) Enzyme Specific Activity 0.43 1.7 7.25 18.3 12.5 (units/mgprotein) Based on your protein purification sample data, in which of the purification steps in your protocol did you effectively purify your enzyme? Select all that apply. a) anion exchange correct b) cation exchange correct c) size exclusion 1 correct d) size exclusion 2
amino glycine pka is 2.4, 9.8 Calculate the most effective buffering range. if there is two pka, since there are 2 buffer region, is the buffering range 1.4~3.4 and 8.8~10.8? i would like to know the correct answer and detailed solution/reason.
N-(2-hydroxyethyl)piperazine-N'-(2-ethanesulfonic acid) buffer at pH 7 with 400 mM NaCl. A A purified protein is in a Hepes dialysis membrane tube holds a 5.0 mL sample of the protein solution. The sample tube floats in a beaker containing 0.50 L of the same Hepes buffer, but with 0 mM NaCl, for dialysis. Small molecules and ions (such as Na*, CI", and Hepes) can to diffuse across the dialysis membrane, but the protein cannot. Assume there are no sample volume changes during the dialysis. Calculate the final concentration of NaCl in the protein sample once the dialysis has come to equilibrium. Calculate the final NaCl concentration in the 5.0 mL protein sample after dialysis in 300 mL of the same Hepes buffer, with 0 mM NaCl, twice in succession. [NaCl] after a single dialysis: [NaCl] after a double dialysis: mM mM
Diethylaminoethyl cellulose is a positively charged resin used in ion-exchange chromatography with a pKa is about 11. A negatively charged protein with an isoelectric point of 5.0 is applied to the column in a buffer at pH 7 and containing 0.1 M NaCl. Which of the following conditions is most likely to weaken the interaction between the protein and the resin? A Raising the pH to 8 and decreasing the NaCl to 0.05 M B Raising the pH to 8 and increasing the NaCl to 0.2 M C Lowering the pH to 6 and decreasing the NaCl to 0.05 M D Lowering the pH to 6 and increasing the NaCl to 0.2 M
10 tab of acetaminophen 500 mg molar absorptivity= 14520 @ 243nm. The total weight of the 10tab is 5278 mg. I take a sample equivalent to 100mg of tablet and I diluted it in 100mL, I took an aliquot of 10mL and I diluted it in 250mL, of these I took 25mL and I diluted them in 250mL. Calculate the weight per tablet. Absorbance = 0.944
at 257 nm) is dissolved in 2.5 mL of buffer. A 250 microliter aliquot is removed and placed in a 1.0 cm A sample of adenosine triphosphate (ATP) (MW 507, ɛ = 14,700 M'cm cuvette with sufficient buffer to give a total volume of 2.0 mL. The absorbance of the sample at 257 nm is 2.0. Calculate the weight of ATP in the original 2.5 mL sample. (Choose the correct value from the drop-down list provided. The values of weight are listed in units of milligrams.) Weight of ATP: v mg
Protein Solubility 3.5 5.5 5 5 0.068 0.028 Absorbance 0.098 Conc.(mg/ml) 0.195 0.130 0.044 0.9% 2.786% 9.429% 11.3: % solubility 4.179% The above table indicates the concentration of protein in the diluted supernatant and the supernatant before dilution at different pH. Dilution Factor 30 22.5 15 PH 7.5 1.5 4.5 5 0.027 3 0.042 Protein Solubility Versus pH 6.5 6 4.5 pH Value The above figure shows a plot of protein solubility versus pH. 50 7.5 7.5 50 0.032 0.053 8.5 50 0.054 0.100 21.429% 9 Please provide a brief discussion and explanation of the results. (using isoelectric point and net charge to explain)
Benzalkonium chloride (E=0.16) 1.5g qs 100 ml Distilled water 0.9% Nacl solution ad Make isotonic solution Questions: 1. How many ml of distilled water must be added to make the Benzalkonium chloride preparation isotonic? 2. How many ml of 0.9% NaCl must be added to make a 100ml solution?
Consider the following pH titration curve of a diprotic acid. What is the approximate values for pka 1 and pka 2? the curve is attached below.
Amino acid Cys has ionizable groups with pKa values 2.0, 8.0, and 10.0. Determine the charge on the Cys at the following pH. Be sure to write the charge in fraction with sign in front (for example, +1/2, -1/5, and +7/8). Charge when pH is at 1.0? _________ Charge when pH is at 9.0? _________ Charge when pH is at 8.0? _________ Charge when pH is at 10.0? _________
ok-Personal Microsoft Edge com/maildeeplink 021 pdt Download Print Save to OneDrive 1. Draw the structure of the pentapeptide Gln-Trp-His-Glu-Tyr that would predominate in aqueous solution at pH3D10.3. (Relevant pka values are: 2.2 4.3, 6.0, 9.8, and 10.1) Acp is adiusted to

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