2. A 500µl reaction containing 0.5 pmol of an enzyme following Michaelis -Menten kineticswith saturating substrate concentration is studied. For this enzyme kl = 1 x 10° M-1 s', k-1 =2 x 10's', and k2 = 1 x 10° s'.a. What is the Vmax for the enzyme considering that it has only one substrate bindingsite?b. What are the values of Km and Ks? Is this a rapid equilibrium enzyme or does it followsteady state kinetics? Explain why.c. What is the substrate concentration needed to achieve half maximal velocity? Explain thebasis for your answer.d. If the substrate concentration in part e is doubled, how many fold will the initialvelocity increase?e. What is the Km is the concentration of the enzyme is doubled?f. What is the efficiency of this enzyme?g. Would this enzyme be considered a perfect enzyme? Explain.h. If 0.25 pmol of an irreversible or classic non-competitive inhibitor is added before startingthe reaction. What is the resulting Km for the enzyme?i. A reversible inhibitor with Ki = 1 x 10* M is added to the reaction la. The observedVmax remained unchanged but Km was shifted to an increased value.What type of inhibitor is this? Explain.j. If the concentration of this inhibitor is 1 x 10“M, which will be the resulting apparentfinal Km Value?

Enzyme increases the rate of the reaction without altering the equilibrium of the reaction. Enzymes…

2. A 500ul reaction containing 0.5 pmol of an enzyme following Michaelis –-Menten kineties with saturating substrate concentration is studied. For this enzyme kl = 1 x 10° M-1 s', k-1 = 2 x 10's", and k2 = lx 10ʻ s". a. What is the Vmax for the enzyme considering that it has only one substrate binding site? b. What are the values of Km and Ks? Is this a rapid equilibrium enzyme or does it follow steady state kineties? Explain why. c. What is the substrate concentration needed to achieve half maximal velocity? Explain the basis for your answer. d. If the substrate concentration in part e is doubled, how many fold will the initial velocity increase?

2. A 500ul reaction containing 0.5 pmol of an enzyme following Michaelis –-Menten kineties with saturating substrate concentration is studied. For this enzyme kl = 1 x 10° M-1 s', k-1 = 2 x 10's", and k2 = lx 10ʻ s". a. What is the Vmax for the enzyme considering that it has only one substrate binding site? b. What are the values of Km and Ks? Is this a rapid equilibrium enzyme or does it follow steady state kineties? Explain why. c. What is the substrate concentration needed to achieve half maximal velocity? Explain the basis for your answer. d. If the substrate concentration in part e is doubled, how many fold will the initial velocity increase?

Biology: The Dynamic Science (MindTap Course List)

4th Edition

ISBN:9781305389892

Author:Peter J. Russell, Paul E. Hertz, Beverly McMillan

Publisher:Peter J. Russell, Paul E. Hertz, Beverly McMillan

Chapter6: Energy, Enzymes, And Biological Reactions

Section: Chapter Questions

Problem 9TYK: Which of the following statements about inhibition is true? a. Allosteric inhibitors and allosteric...

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1. Make a Lineweaver-Burk plot and use the plot to complete the information in the table and the following questions. a. Is it possible for the enzyme to overcome the effect of the inhibitor in question from the chart. Explain. b. What prevents this enzyme from being an even more catalytically efficient enzyme? c. What do single molecule data indicate about the validity of ensemble data?d. What is the reason that humans are insensitive to sulfa drugs?
1) what is the Vmax of the enzyme WITHOUT inhibitor 2) What is the Km of the enzyme WITHOUT the inhibitor 3) The specificity constant for enzyme X is (8*10^7) /(M*seconds); what is the kcat of the enzyme WITHOUT the inhibitor? 4) what was the concentration of the enzyme used for measuring the kinetics of enzyme X without inhibitor? 5) the dashed line represents enzyme with inhibitor. The concentration of the inhibitor is 5 micromolar. Calculate the equilibrium constant for the inhibitor Please show work and units
1 what is does the induced -fit model account for? 2 why are most enzyme inactive at higher temperature ( greater than 37degree Celsius) 3 Does this happen to all enzymes in all species? 4 What are the formulas for the reduced form of the coenzymes?
An enzyme is found that catalyzes the reaction X ⇌ Y. Researchers find that the Km for the substrate X is 4 μM, and the kcat is 20 min−1.(a) In an experiment, [X] = 6 mM, and V0 = 480 nM min−1. What was the [Et] used in the experiment?(b) In another experiment, [Et] = 0.5 μM, and the measured V0 = 5 μM min−1. What was the [X] used in the experiment?(c) The compound Z is found to be a very strong competitive inhibitor of the enzyme, with an α of 10. In an experiment with the same [Et] as in (a), but a different [X], an amount of Z is added that reduces V0 to 240 nM min−1. What is the [X] in this experiment?(d) Based on the kinetic parameters given above, has this enzyme evolved to achieve catalytic perfection? Explain your answer briefly, using the kinetic parameter(s) that define catalytic perfection.
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1. What is the difference between the lock and key model in the induced fit model enzyme-substrate binding? 1a. What factors affect an enzymes catalytic function?
1. Provided in the Table below kinetic data for an enzymatic reaction that was carried out in the presence (last two columns) and absence (second column = control) of enzyme inhibitor. Both inhibitors were added in eachreaction at a concentration of 2 mM. The enzyme concentration was similar in all and was approximately 0.001 µM. a. Calculate both Vmax and KM for the control using Lineweaver-Burk curve. b. Provide the type of inhibition for both? c. Find, KI, for the inhibitor binding to the enzyme, for experiments (2) and (3). d. Calculate the reaction Kcat for the Control in experiment (1). e. Draw a velocity versus [S] showing Michaelis-Menten curve for the Control. Clearly show Vmax and KMfor the enzyme.
1. Provided in the Table below kinetic data for an enzymatic reaction that was carried out in the presence (last two columns) and absence (second column = control) of enzyme inhibitor. Both inhibitors were added in eachreaction at a concentration of 2 mM. The enzyme concentration was similar in all and was approximately 0.001 µM. a. Calculate both Vmax and KM for the control using Lineweaver-Burk curve. b. Provide the type of inhibition for both? c. Find, KI, for the inhibitor binding to the enzyme, for experiments (2) and (3). d. Calculate the reaction Kcat for the Control in experiment (1). e. Draw a velocity versus [S] showing Michaelis-Menten curve for the Control. Clearly show Vmax and KM for the enzyme.