Which of the following plot(s) is(are) CORRECT for an enzyme that obeysMichaelis-Menten kinetics, assuming [𝑆] ≪ 𝐾௠?[𝑆] is the concentration of the substrate, 𝐾௠ is the Michaelis constant, and v0 isthe initial reaction velocity.

The following data were obtained in a study of an enzyme known to follow Michaelis-Menten kinetics: Velocity Substrate Added (mM)1.3 12.6 24.1 45.1 65.2 10The Vmax for this enzyme is approximately:

Use the Michaelis-Menten equation to complete the enzyme kinetic data set shown below (fill in the blanks), when Vmax is known to have a value of 100 nM/min. Answer with three significant digits.Substrate concentration (µM) Reaction rate (nM/min)4.00 50.05.00 10.0 20.0

Which statement is correct about the enzyme kinetics shown below?Group of answer choicesalpha = 4; alpha' = 3alpha = 2.5; alpha' = 5alpha = 1.5; alpha' = 3alpha = 3; alpha' = 4alpha = 5; alpha' = 2.5alpha = 3; alpha' = 1.5

Which of the following statements is/are correct in enzyme kinetics, if S represents the substrate?Group of answer choicesAt very low substrate concentration, the rate of enzyme reaction is zero order with respect to [S].At all substrate concentrations, the rate of enzyme reaction is first order with respect to [S].At very high substrate concentration, the rate of enzyme reaction is first order with respect to [S].At very high substrate concentration, the rate of enzyme reaction is zero order with respect to [S].At all substrate concentrations, the rate of enzyme reaction is zero order with respect to [S].

According to the Michaelis-Menton kinetics theory, when a reaction is performed in zero-order kinetics:Please select the single best answer The substrate concentration is very low and the reaction rate is dependent on the substrate concentration The substrate concentration is in excess and the reaction rate is dependent on the enzyme concentration The enzyme concentration is in excess and the reaction rate is dependent on the substrate concentration The substrate concentration is equal to Km and the reaction rate is dependent on the enzyme concentration