Is based on the assumption that a transition state is formed in the enzyme active site.

Is based on the assumption that an enzyme catalysed reaction is mediated at the active site of an enzyme.

Is based on the assumption that a biochemical reaction is at equilibrium.

Is based on the assumption that a biochemical reaction occurs at a steady state.

Is associated with the maximum enzyme activity observed when the all active
sites in an enzyme are saturated with substrate.

Is associated with the number of substrate molecules reacted on by an enzyme
molecule per unit time.

Is associated with the affinity of an enzyme for a specific substrate.

Is associated with the selectivity of an enzyme for different substrates.

Is a measure of the rate of acceleration carried out by the enzyme.

For a given enzyme is independent of the substrate used.

Has units of concentration.

Gives an idea of the enzymes catalytic efficiency.

Is associated with the maximum enzyme activity observed when the all active sites in
an enzyme are saturated with substrate.

Is associated with the number of substrate molecules reacted on by an enzyme
molecule per unit time.

Is associated with the affinity of an enzyme for a specific substrate.

Is associated with the selectivity of an enzyme for different substrates.

A catalytic strategy facilitating transition state formation through covalent bond formation between the substrate and enzyme active site.

A catalytic strategy facilitating transition state formation through hydrogen bond formation and electrostatic bond formation between the substrate and enzyme active site.

A catalytic strategy facilitating transition state formation through interaction involving metal ions and substrate in the enzyme active site.

A catalytic strategy facilitating transition state formation through direct transfer of a proton to or from the substrate in the enzyme active site.

Half of Vmax

Two thirds of Vmax

Double Vmax

Three times Vmax

May explain why enzymes have particular substrate specificity.

May explain why enzymes are able to catalyse chemical reactions that cannot be facilitated in any other way

May explain why enzymes increase the rate of a reaction by reduction of the activation energy change for the reaction

May explain why enzymes can effectively reduce the loss of energy from a chemical reaction as heat

are chemically altered at the end of their reaction

are involved in changing the equilibrium constant of the reaction that they
catalyse

bind their substrates at their active site(s)

increase the activation energy of the reaction they catalyse

Is a measure of the rate acceleration caused by the enzyme

For a given enzyme is independent of the substrate used

Has units of concentration

Gives an idea of the enzyme’s catalytic efficiency

Is altered when a competitive inhibitor is present

Can be determined from the intercept on the x-axis of a Lineweaver-Burk plot

Is the maximum rate at which the enzyme can convert substrate into product

Has units of concentration

Is controlled by serine protease enzymes.

Is a key part of the control mechanism in the eukaryote cell cycle

Is a key part of the control mechanism in the prokaryote cell cycle

Is controlled by ubiquinone activating enzymes.

Is completely located in the mitochondrial matrix.

Facilitates transport of ammonia produced in the liver to the muscles where it can be used in anabolic processes - preventing the exposure of free ammonium to other components of eukaryote tissues.

Facilitates transport of ammonia produced in the muscles to the liver where it can be effectively removed from the body - preventing the exposure of free ammonium to other components of eukaryote tissues.

Is located in the cell membrane of muscle cells.

Describes the way the substrate interacts with the enzyme.

Descibes the protein tertiary structure when the enzyme substrate is converted to a product.

Describes the form the substrate takes that facilitates the formation of a low energy intermediate during the catalytic cycle.

Describes an intermediate in the catalytic cycle that is produced in order to minimise the activation energy for the reaction.

15 mM

30 mM

45 mM

60 mM

Will always be negative if an enzyme catalysed reaction proceeds spontaneously.

Will always be positive if an enzyme catalysed reaction proceeds spontaneously.

Will always be equal to the ΔG value for a reaction where both the reactants and products have an equal concentration.

Will only apply to a reaction occurring if the pH = 7.0 in aqueous solution.

An enzyme that is protein-engineered to work like an antibody.

An antibody that is protein-engineered to work like an enzyme.

An enzyme that has high affinity for a transition state analogue.

An antibody that has high affinity for a transition state analogue.

A region of the enzyme active site that facilitates binding of positively charged substrates through their association with oxygen-containing amino-acid side chains in the enzyme.

A region of the enzyme active site that facilitates binding of negatively charged substrates through their association with oxygen-containing amino- acid side chains in the enzyme.

A region of the active site that facilitates binding of positively charged oxygen- containing groups present in a substrate.

A region of the active site that facilitates binding of negatively charged oxygen-containing groups present in a substrate.

Approximation.

Acid-base catalysis.

Metal-ion catalysis.

Covalent catalysis.

Is completely located in the mitochondrial matrix – preventing the exposure of free ammonium to other components of the eukaryote cell.

Allows free ammonia obtained directly from deamination of glutamate to be converted to urea – preventing the exposure of free ammonium to other components of the eukaryote cell.

Allows free ammonia obtained directly from deamination of tryptophan to be converted to urea – preventing the exposure of free ammonium to other components of the eukaryote cell.

Is completely located in the cytoplasm of the cell – preventing the exposure of free ammonium to other components of the eukaryote cell.

Active site

Activation site

Allosteric site

Transitional site

Are proteases that hydrolyse polypeptides with serine in the F1 position

Are proteases that are found in the cytoplasm of all cells

Utilise a serine residue at the active site to facilitate substrate binding

Utilise a serine residue at the active site to facilitate cleavage of peptide bonds

An acidic- or basic- amino acid in the active site of an enzyme facilitates transition state formation by hydrogen abstraction from an appropriate substrate.

An acid- or basic- substrate in the active site of an enzyme facilitates transition state formation by hydrogen abstraction from a catalytic amino acid in the active site.

Both are correct.

Neither are correct.

Can be covalently linked to proteins via the N-terminus glycine residue.

Is a polypeptide.

Is an essential component of eukaryote respiratory chains.

Can be covalently linked to proteins via isopeptide bond formation.

The reaction will proceed fast with the formation of the explosive products.

The reaction will not occur spontaneously.

The reaction will never reach equilibrium.

The reaction will proceed spontaneously from left to right.

Is a key concept that helps to explain how enzymes reduce activation energy for chemical reactions.

Is a key concept that helps to explain how enzymes can reduce the Gibb’s free energy for a chemical reaction.

Is a key concept that helps to explain how enzymes can exhibit diverse substrate specificity.

Is a key concept that helps to explain how enzymes may exhibit Michaelis-Menton kinetics.

Is a term used to describe the amount of randomness or disorder that results as the reaction proceeds

Is a term used to describe the amount of ‘free energy’ change that results as the reaction proceeds

Is a term used to describe the amount of heat that is produced or consumed as the reaction proceeds

Is always determined at room temperature (25oC)

Facilitate substrate binding

Facilitate transition state formation

Facilitate stabilisation of the tertiary structure

Facilitate conformational changes in the protein during the catalytic cycle

Reduce the entropy associated with chemical reactions

Reduce the enthalpy associated with chemical reactions

Reduce the Gibb’s free energy associated with chemical reactions

Reduce the activation energy associated with chemical reactions

Reaction 1

Reaction 2

They both occur at much the same rate

It is not possible to know this from the data provided

Can be described by the ratio: kCAT/KM

Can be described by the ratio: KM/kCAT

Can be described by the ratio: Vmax/kCAT

Can be described by the ratio: kCAT/Vmax

Hydrogen bonding with at least one amino acid side chain at the active site to facilitate formation of the transition state.

Hydrogen bonding between the carbonyl and amide groups of peptide bonds to facilitate formation of the transition state.

Hydrogen bonding between a water molecule and the substrate to facilitate formation of the transition state.

Hydrogen bonding with an oxidised metal ion prosthetic group in the active site to facilitate formation of the transition state.

The reaction will stop

The reaction will proceed spontaneously from B to A

The reaction will proceed spontaneously from A to B

The reaction will not occur spontaneously

This reaction can only occur in a cell in which NADH is converted to NAD+ by the respiratory chain

This reaction can only occur in a cell if it is coupled to another reaction for which ΔG°' is large and negative

This reaction may occur in cells at some concentrations of substrate and product

This reaction is energy-releasing

Is always the rate limiting step in an enzyme catalysed reaction

Is never the rate limiting step in an enzyme catalysed reaction

Is always a necessary pre-requisite to formation of the transition state and therefore product turnover

Is never a necessary pre-requisite to formation of the transition state and therefore product turnover

alter the Vmax of the reaction

show irreversible binding to their target enzyme

resemble the structure of the natural substrate/product molecule

bind at a site distant from the active site

Inhibits proteosome-mediated protein degradation

Is essential for proteosome-mediated protein degradation

Enhances proteosome-mediated protein degradation

Has nothing to do with proteosome-mediated protein degradation