not true about the Michaelis-Menten equation?The equation that gives the rate, v, of anthe substrate concentration [S] is the Michaelis-Menten equation= Vmax[S]/(Km + [S]), where V,enzyme-catalyzed reaction for all values ofmax and Km are constants. Which of the following isa)for [S] << Km, V = Vmaxapplies to most enzymes, but allosteric enzymes have different kineticswhen [S] = Km, then v =Vmax/2gives the rate when the enzyme concentration, temperature, pH, and ionicstrength are constantfor very high values of [S], v approaches Vmaxe)Which is correct about the constant Km in the Michaelis-Menten equation?also called the catalytic constant or turnover numberequal to the number of product molecules produced per unit time when theenzyme is saturated with substrateit is the constant in the first order rate equation v = k[A]it is the constant in the second order rate equation v =equal to the substrate concentration at which the velocity or rate of a reaction is½ the maximum rate (2 Vmax)a)b)c)d)k[A][B]

Enzymes are biocatalysts which accelerate the rate of a biochemical reaction. Enzymes catalyze a…

Answered: The equation that gives the rate, v, of…

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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molecule A Plot of velocity versus substrate B Lineweaver-Burk plot 1/v Km 1 Vmax (S) Vmx 1 V max 1/2Vmax 1/Vmax -1/Km Km [S] 1/[S] fppt.com molecule Exercise The following data describe an enzyme-catalyzed reaction. Plot these results using the Lineweaver-Burk method, and determine values for KM and Vinax- The symbol mM represents millimoles per liter; 1 mM = 1 × 10 3 mol L. (The concentration of the enzyme is the same in all experiments.) Velocity (mM sec-) Substrate Concentration (тм) 2.5 0.024 5.0 0.036 10.0 0.053 15.0 0.060 20.0 0.061 fppt.com
. Recall your study of equilibria and kinetics from general chemistry. You used equations with upper case Kand lower case k during the study of equilibria and kinetics respectively. What do the upper and lower case letters refer to?
The Michaelis-Menten equation models the hyperbolic relationship between [S] and the initial reaction rate Vo for an enzyme-catalyzed, single-substrate reaction E + S ES → E + P. The model can be more readily understood when comparing three conditions: [S] > Km- Match each statement with the condition that it describes. Note that "rate" refers to initial velocity Vo where steady state conditions are assumed. [Etotal] refers to the total enzyme concentration and [Efree] refers to the concentration of free enzyme. [S] > Km Not true for any of these conditions Almost all active sites will [ES] is much lower than [Efree]. be filled. The rate is directly proportional to Increasing [Etotal] will increase [S]. Km: Adding more S will not increase [Efree] is equal to [ES]. the rate.
Many enzyme -catalyzed reactions are consistent with a modified version of the Michaelis -Menten mechanism in which the second step is also reversible. For this mechanism obtain an expression for the rate of formation of product and find its limiting behavior for large and small concentrations of substrate using steady state approximation
Compare and contrast Bound Fraction equation in ligand binding and Michaelis-Menten equation in enzyme kinetics, including their double-reciprocal forms. Discuss what Km is important for and what Vmax (or kcat) is important for? Under what (substrate) conditions is Km more important than Vmax, and under what (substrate) conditions is Vmax more important than Km? Based on the discussions in question 2, explain what type of inhibitors works best under (a) high substrate concentration and (b) low substrate concentration.
For an enzyme that displays Michaelis-Menton kinetics, what is thereaction velocity, V (as a percentage of V max , observed at the followingvalues?[S] = K M[S] = 0.5K M[S] = 0.1K M[S] = 2K M[S] = 10K M
Imagine a typical enzyme kinetic curve of [S] vs. V. The maximum [S] is about four times the Km. Lines are drawn at [S] = Km and V = Vmax. The asymptote is drawn at [S] = 0. 1. What effect does altering Km have on Vmax? Explain. 2. What effect does altering [E] have on Km? Vmax? Explain. 3. At what concentration of [S] is the initial velocity proportional to [E]? Explain.
The Michaelis-Menten equation models the hyperbolic relationship between [S] and the initial reaction rate V% for an enzyme-catalyzed, single-substrate reaction E + S=ES → E + P. The model can be more readily understood when comparing three conditions: [S] > Km- Match each statement with the condition that it describes. Note that "rate" refers to initial velocity Vo where steady state conditions are assumed. [Etotal] refers to the total enzyme concentration and [Efree] refers to the concentration of free enzyme. [S] > Km Not true for any of these conditions [ES] is much lower than [Efree]. Reaction rate is independent of Increasing [Etotal] will lower Almost all active sites will Km- be filled. [S). [Efree] is about equal to [Etotal]. Show All W- 5179933 (3).docx 5179933 (4).docx PCR-MINI RES....docx MacBook Pro
The protein catalase catalyzes the reaction 2H,O,(aq) — 2H,O(l) + O,(g) and has a Michaelis-Menten constant of KM = 25 mM and a turnover number of 4.0 × 107 s¯¹. The total enzyme concentration is 0.010 µM and the initial substrate concentration is 4.83 µM. Catalase has a single active site. Calculate the value of Rmax (often written as Vmax) for this enzyme. Rmax Calculate the initial rate, R (often written as V), of this reaction. R = ×10 mM.s-1 mM-s-1
The KMof the enzyme for the substrate adenosine is 3 × 10ꟷ5M. The product inosine acts as an inhibitor of the reaction, with an inhibition constant (KI, the dissociation constant for enzyme-inhibitor binding) of 3 × 10ꟷ4M. However, a transition state analog,Inhibits the reaction with KIof 1.5 × 10ꟷ13M. Explain why 1,6-dihydroinosine serves as a better inhibitor of adenosine deaminase than inosine. Elaborate on your answe
An enzyme that follows simple Michaelis–Menten kinetics has an initial reaction velocity of 10 µmol⋅min−110 µmol⋅min−1 when the substrate concentration is five times greater than the ?M.KM. What is the ?maxVmax of this enzyme?
6-25 substrate-band enzyme concentrations. The the turnover number is equal to umax- b) V=Umax •57(Km+S) anstont For an enzyme that displays Michaelis-Menten kinetics, what is the reaction velocity, V (as a percentage of Vmax), observed at the following values? a) [S] = KM C) d) e) [S] = 0.5KM [S] = = 0.1KM [S] = 2KM [S] = 10KM w reactores -maximumrate of reaction boteles conc. Would you expect the structure of a competitive inhibitor of a given enzyme to be similar to that of its substrate?

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