05-10-21 - Introduction to Enzymes

Question 1

Enzymes that are biological catalysts
•	How are they chemically altered in reactions?
•	What is their function?
•	How do they do this
•	What conditions do they work in?        
•	How do they work? 
        What are they specific to? 
•	Properties

Answer 1

• Enzymes in any reaction are not chemically altered in a reaction.
• Their function is to increase the rate of reaction by providing a pathway of lower activation energy to get reactants to products
• They do this by stabilising the transition state.
• They operate under physiological conditions (around 37°, neutral, low substrate concentrations, aqueous environment
• Biological catalysts work by forming complexes with their substrate (binding), thus providing a unique microenvironment for the reaction to process
• Enzymes contain an active site where the substrate binds to.
• Enzymes have very high specificity for both the reaction catalysed and substrate used
• The activities of some enzymes are regulated in the body.

Question 2

What is rate enhancement of a catalyst?

How is it calculated?

Answer 2

• Rate enhancement of a catalyst is the factor by which the catalyst increases the rate of reaction
• Rate enhancement = catalysed rate/uncatalyzed rate.

Question 3

How are enzymes linked to different areas of medicine?
•	Disease
•	Diagnosis
•	Drug therapy
•	Basic research

Answer 3

• Disease – enzyme deficiencies caused by inborn errors cause disease e.g phenylketonuria – lack of phenylalanine hydroxylase
• Diagnosis – To diagnose myocardial infraction (heart attack) or indigestion, the activity and concentration of many enzymes must be measured.
• Drug therapy – many enzymes act as inhibitors, so can be prescribed as medicine
• Basic research – there are many unclassified enzymes which we don’t know the function of.

Question 4

What is an example of a biological catalyst?

What does it do?

How does it work?

Answer 4

• Lysozyme catalyses the cutting of polysaccharide chains
• It binds to polysaccharide chains, catalyses the cleavage of the specific covalent bonds, and released the cleaves products
• It remains unchanged at the end of the reaction.

Question 5

What are the 4 reasons why the accumulation of products is not linear on a graph?

What is the initial reaction velocity (Vo)?

What is it used for?

Answer 5

• Product accumulation is not linear because:
• Substrate concentration falls
• Products may inhibit the enzyme
• Enzyme might denature
• Reverse reactions may become more favourable
• The initial reaction velocity (Vo) is the initial rate of reaction before any of the factors that slow the rate of reaction become significant.
• Initial rate is what we measure when trying to calculate enzyme activity, and is the only valid parameter.

Question 6

What is the activity of an enzyme dependent on?

How is enzyme activity (Vo) measured?

Why do we do it this way?

Answer 6

• The activity of an enzyme depends on how rapidly it can process a substrate.
• Enzyme activity (Vo) is measured by increasing the substrate concentration and measuring the accumulation of products over time.
• This is so the reaction rate is not limited by decreasing substrate concentration.

Question 7

How is rate of reaction linked with substrate concentration?

What is V max of an enzyme?

How can it be calculated?

Answer 7

• The rate of reaction increases as the substrate concentration increases, until a maximum is reached (Vmax)
• Vmax is the maximum reaction velocity of an enzyme
• The Vmax of an enzyme is difficult to reach, so it can be calculated by plotting a Lineweaver-Burke plot (double reciprocal of the data)
• This produces a straight line, where the y intercept on the graph is equal to 1/Vmax (reciprocal of y-intercept = Vmax)

Question 8

What is Km? How is the Michaelis-Menten constant (Km) calculated?

What is it used for?

What is the equation for initial reaction velocity?

Answer 8

• Km is the substrate concentration required for half maximum reaction velocity (Vmax)
• The Michaelis-Menten constant is used in conjunction with Vmax to measure the activity of an enzyme using the Michaelis-Menten equation.

Question 9

What is the biological significance of Km in terms of hexokinase and glucokinase?

Answer 9

• Hexokinase and Glucokinase both catalyse the phosphorylation of glucose, but they have different Km values
• Hexokinase has lower Km and phosphorylates glucose at low concentrations of glucose
• It is found in all tissues and is required for energy production in cells
• A low Km ensures the utilisation of glucose, even at very low concentrations
• Glucokinase has a higher Km.
• It is found in the liver
• Glucokinase will only phosphorylate glucose when blood glucose concentrations are high, this allows for the production of glycogen, which can be stored
• A high Km ensures glucose is not removed from the blood for storage at low concentrations.

Question 10

How is Km determined?

Answer 10

• Km is determined by using a Lineweaver-Burke plot and dividing the Vmax by 2. The X intercept is also equivalent to -1/Km. If we take the reciprocal of the X intercept, we will have the Km value.

Question 11

What are enzyme inhibitors?

What are the 2 types of enzymes inhibitors?

Answer 11

• Enzyme inhibitors are chemicals that interfere with enzyme reactions.
• There are irreversible and reversible inhibitors
• Irreversible inhibitors include inactivators
• Reversible inhibitors include competitive and allosteric (Non-competitive)
• Competitive inhibitors compete with the enzyme’s substrate for access to the active site
• Allosteric enzymes bind to another part of the enzyme which is not the active site.

Question 12

How does irreversible inhibitors work?

What is an example of irreversible inhibition?

Answer 12

• Irreversible inhibitors react with the enzyme and form a covalent adduct with the protein
• This inactivation is irreversible
• DIPF is an organophosphate pesticide, which inhibits AChE
• AChE is an enzyme that degrades neurotransmitter Ach into choline and acetic acid
• Organophosphates inactivate AChE by phosphorylated the serine hydroxyl group located at the active site of AChE
• This inactivation causes ACh accumulation throughout the nervous system, resulting in overstimulation of receptors, which is fatal to pests.

Question 13

What is aspirin?

How does aspirin work as an irreversible inhibitor?

Answer 13

• Aspirin is an antipyretic (reduces fever), anti-inflammatory, and analgesic (painkiller)
• It works by irreversible inhibiting COX-1
• COX-1 catalyses the conversion of AA (arachidonic acid) to Prostaglandin H2 (precursor for synthesis of inflammatory mediators)
• Aspirin reacts with a serine residue close to the active site of COX-1, preventing the substrate AA from binding

Question 14

How does competitive (reversible) inhibition work?

How are competitive inhibitors structured?

How is the action of an enzyme affected by competitive inhibitors?

Answer 14

• A competitive drug can compete with the substrate for the active site of an enzyme
• The drug will occupy the active sit and then leave it unchanged
• Competitive inhibitors have a similar structure to the substrate of the enzyme
• The action of an enzyme is slowed down by the presence of competitive inhibitors.

Question 15

How do competitive inhibitors affect Vmax and Km of an enzyme? How do competitive inhibitors affect graphs and Lineweaver-burke plots?

Answer 15

• A higher concentration of substrate is needed to reach Vmax, as more substrate is needed to outcompete the competitive inhibitor
• This leads to Vmax being unchanged, but an increase in Km, as Km is the substrate concentration needed to reach half of Vmax
• On graphs, the curve is extended to the right, as a higher substrate concentration is needed to reach Vmax
• On line-weaver burke plots, the y-intercept is the same, as the Vmax is the same, but the gradient is steeper, as a higher substrate concentration is needed to reach Vmax.

Question 16

When can allosteric inhibitors bind to enzymes?

What do allosteric inhibitors to do enzyme?

What won’t help reactivate the enzyme?

What happens to Vmax and Km values due to allosteric inhibitors?

Answer 16

• Allosteric inhibitors can bind to the enzyme at the same time as the substrate, because they never bind to the active site.
• Allosteric enzymes bind to the enzyme, and alter its active site, so the substrate can no longer fit inside it.
• This makes the enzyme inactive
• Increasing substrate concentration cannot drive away the allosteric inhibitor from the enzyme, so this does not help increase the rate of reaction (in contrast to competitive inhibition)
• Vmax decreases
• Km often (but now always) increases

Question 17

What are the 2 types of allosteric inhibition?

What effects do they have on Vm and Km?

Answer 17

• Non-competitive inhibition – inhibitor binds equally well to the enzyme, whether it has already bound the substrate or not
• V max is reduced by non-competitive inhibition
• Km is unchanged (along with substrate affinity)
• Mixed inhibition – inhibitor that can bind allosterically, whether the substrate has been bound or not, but has a greater affinity for one state or the other. (Mix of competitive and uncompetitive inhibition)
• (Uncompetitive inhibition – inhibitor only binds to enzyme-substrate complex)
• Vmax decreases due to mixed inhibition
• Km is increased, as substrate affinity is reduced.

Question 18

What is an example of allosteric inhibition?

How is this also an example of feedback inhibition?

Answer 18

• The enzyme PFK catalyses the transfer of phosphate to fructose-6-phosphate
• This is an important step in glycolysis (process that produces positive net ATP)
• PFK binds ATP at two sites (an allosteric inhibitory site and the active site)
• In the presence of high ATP levels, ATP binds to the inhibitory site, which prevents the fructose-6-phosphate from binding
• This prevents glycolysis from proceeding when ATP is not needed.
• This is known as feedback inhibition, where a product of the pathway acts as an inhibitor to prevent the process from continuing.

Question 19

How is enzyme kinetics used to treat anti-freeze poisoning?

Answer 19

• The toxin responsible for anti-freeze poisoning is oxalate, which is produced when ethylene glycol from the anti-freeze is broken down by alcohol dehydrogenase
• By administering a near-intoxicating dose of ethanol to the patient, this allows ethanol to act as a competitive inhibitor against ethylene glycol, which prevents oxalate from getting made.