Enzymes (Chapter 3)

Question 1

Define an enzyme

Answer 1

A globular protein that catalyses metabolic reactions

Question 2

What is a catalyst?

Answer 2

A molecule which speeds up a chemical reaction but remains unchanged at the end of the reaction

Question 3

What is an enzyme?

Answer 3

A biological catalyst made of protein with a specific tertiary structure and active site

Question 4

Why are enzymes essential for life?

Answer 4

Because virtually every metabolic reaction in a living organism is catalysed by an enzyme

Question 5

What is the name ending for most enzymes?

Answer 5

-ase

Question 6

What are intracellular enzymes?

Answer 6

Enzymes that operate within cells

Question 7

What are extracellular enzymes?

Answer 7

Enzymes that are secreted by cells and that catalyse reactions outside cells
- some organisms secrete enzymes outside their bodies

Question 8

Describe the structure of enzymes as globular proteins

Answer 8

Enzyme molecules are coiled into a precise, 3D shape, with hydrophilic R groups (side-chains) on the outside of the molecule

Question 9

What make enzymes soluble?

Answer 9

The hydrophilic R groups on the outside of the molecule

Question 10

What is the active site?

Answer 10

A region of the enzyme, usually a cleft or depression, to which another molecule (substrate) or molecules can bind

Question 11

Describe the lock and key hypothesis

Answer 11

The idea that the enzyme has a particular shape, into which the substrate fits exactly

• the substrate is held in place by temporary bonds which form between the substrate and some of the R groups of the enzyme’s amino acids
• this combined structure is called the enzyme-substrate complex

Question 12

How is the enzyme specific for a substrate?

Answer 12

Each type of enzyme will usually act on only one type of substate molecule because the shape of the active site will only allow one shape of molecule to fit

Question 13

What does catabolic mean?

Answer 13

Breaking down

Question 14

What does anabolic mean?

Answer 14

Building up

Question 15

Describe the induced fit hypothesis for enzyme action

Answer 15

It is mostly the same as lock and key but it adds the idea that the enzyme, and sometimes the substrate, can change shape slightly as the substrate molecule enters the enzyme, in order to ensure a perfect fit
- makes the catalysis even more efficient

Question 16

What is formed briefly before the release of the product?

Answer 16

An enzyme-product complex

Question 17

How do enzymes work?

Answer 17

1) Enzymes may catalyse the breakdown of a molecule as the interactions between the R groups of the enzyme and the atoms of the substrate can break bonds in the substrate molecule
2) Enzymes may catalyse the joining together of 2 molecules as the interactions can encourage formation of bonds in the substrate molecule

Question 18

How fast is enzyme catalysis?

Answer 18

Very rapid e.g. breakdown of H2O2 into H2O and O2

Question 19

What is the activation energy?

Answer 19

The energy temporarily given to a substrate to convert it to the product in a chemical reaction

Question 20

How do enzymes affect the activation energy?

Answer 20

Enzymes decrease the activation energy of the reaction which they catalyse, making it easier to turn substrate into product

• they do this by holding the substrate(s) in such a way that their molecules react more easily and their bonds become weaker
• reactions catalysed by enzymes will take place rapidly at a much lower temp then they otherwise would

Question 21

Why are enzymes needed when one way of increasing the rate of metabolic reactions is to increase the energy of the reactants is by heating them?

Answer 21

It is not enough to give most substrates the activation energy which they need to change into products

Question 22

Describe what happens during the course of the reaction of the breakdown of H2O2 by catalase

Answer 22

1) The reaction begins very swiftly - bubbles of O2 are released quickly and a large vol of O2 is collected in the first minute
2) But as the reaction continues, the rate at which O2 is released gradually slows down
3) The reaction gets slower and slower until it eventually stops completely

Question 23

Explain why the breakdown of H2O2 by catalase begins very swiftly

Answer 23

• When the enzyme + substrate are first mixed, there are a large number of substrate molecules - at any moment, virtually every enzyme molecule has a substrate molecule at its active site

Question 24

What does the rate at which the breakdown of H2O2 depend on?

Answer 24

How many enzyme molecules there are and the speed at which the enzyme can convert substrate to product, release it and bind with another substrate molecule

Question 25

What happens as the breakdown of H2O2 continues?

Answer 25

As more and more substrate is converted into product, there are fewer and fewer substrate molecules to bind with enzymes
- therefore, the reaction gets slower and slower until it stops

Question 26

Describe the graph for the rate of an enzyme controlled reaction

Answer 26

The graph is always steepest at the beginning (the initial rate of reaction) and then increases as a curve until it flattens out

Question 27

How can you measure the initial rate of reaction by the release of O2?

Answer 27

Measure the amount of O2 given off in the first 30s and then convert to cm3/min or just work out gradient

Question 28

What are the factors that affect enzyme action?

Answer 28

1) Enzyme concentration
2) Substrate concentration
3) Temperature
4) pH

Question 29

Describe the effect of enzyme concentration on enzyme action

Answer 29

• Higher enzyme conc, faster reaction
• Overall, same amount of product will be formed eventually regardless of different enzyme conc because the substrate conc is the same

Question 30

How would you compare the effect of different enzyme concentrations on reaction rate and why?

Answer 30

• Plot enzymes concentration against initial rate of reaction - it should increase linearly and be directly proportional
• You use the initial rate of reaction because once the reaction is under way, the amount of substrate in each reaction begins to vary because substrate is converted into product at different rates - this ensures that the difference in reaction rate is only caused by the difference in enzyme concentration

Question 31

Explain the effect of enzyme concentration on enzyme action

Answer 31

• The more enzyme present, the more active sites will be available for the substrate
• As long as there is plenty of substrate available, the initial rate of reaction increases linearly with enzyme conc

Question 32

Describe the effect of substrate concentration on enzyme action

Answer 32

As substrate concentration increases, the initial rate of reaction also increases

Question 33

Explain the effect of substrate concentration on enzyme action

Answer 33

The more substrate molecules there are, the more often an enzyme’s active site can bind with one

Question 34

Why is there a limit on the initial rate of reaction in relation to substrate concentration?

Answer 34

• Because if substrate conc keeps increasing but enzyme conc remains constant, there comes a point where every enzyme active site is working continuously
• If more substrate is added, the enzyme simply cannot work faster - substrate molecules are effectively ‘queuing up’ for an active site to become vacant
• The enzyme is working at its maximum possible rate, know as Vmax

Question 35

Describe the effect of temperature on the rate of reaction

Answer 35

• At low temperatures the reaction takes place very slowly
• As the temp rises, the rate of reaction begins to increase significantly
• However above a certain temperature (the optimum temp), the molecule begins to denature and the rate of reaction falls until it completely denatures

Question 36

Why does the enzyme catalysed reaction take place slowly at low temperatures?

Answer 36

• Molecules are moving relatively slowly
• Substrate molecules will not collide often with active sites, and so binding between substrate and enzyme is a rare event (less enzyme-substrate complexes)

Question 37

Why does the rate of reaction increase as temperature increases?

Answer 37

• As temp rises, the enzyme and substrate molecules move faster as they have more kinetic energy
• Collisions happen more frequently, so that substrate molecules enter the active site more often (more enzyme-substrate complexes)
• When they collide, they also do so with more force, making it easier for bonds to be formed or broken so that the reaction can occur

Question 38

Why does the rate of reaction fall after a certain temperature?

Answer 38

• Above a certain temp, the structure of the enzyme molecule vibrates so energetically that some of the bonds (esp H-bonds) holding the enzyme molecules in its precise shape begin to break up
• The enzyme molecules begins to lose its shape and activity and is said to be denatured (often irreversible)
• At first, the substate molecule fits less well into the active site of the enzyme, so the rate of reaction begins to slow down
• Eventually, the substrate no longer fits at all, or can no longer be held in the correct position for the reaction to occur

Question 39

What is the optimum temperature?

Answer 39

The temperature at which an enzyme catalyses a reaction at the maximum rate

Question 40

What is the optimum temperature of most human enzymes?

Answer 40

Roughly 40 degrees

Question 41

What are we ensuring by keeping our bodies at roughly 37 degrees?

Answer 41

That enzyme-catalysed reactions occur at close to their maximum rate

Question 42

Describe the effect of pH on the rate of reaction?

Answer 42

The rate of reaction rises until the optimum pH and then falls as the pH increases

Question 43

What is the optimum pH of most enzymes?

Answer 43

7

Question 44

What is pH?

Answer 44

A measure of the conc of H+ ions in a solution

Question 45

How does pH affect the enzyme and therefore the rate of reaction?

Answer 45

• H+ ions (or OH- ions) can interact with the R groups of amino acids e.g. by affecting ionisation of the group
• This affects the ionic bonding between the groups, which in turn affects the 3D arrangement of the enzyme molecule
• The shape of the active site may change and reduce the chances of the substrate molecule fitting into it
• The ions can also block up the active site
• A pH which very different from the optimum pH can cause denaturation of an enzyme

Question 46

What can use when investigating pH?

Answer 46

Buffer solutions - these have a particular pH and maintain it even if the reaction taking place would otherwise cause the pH to change
- you add a measured volume of buffer to your reacting mixture

Question 47

How could a competitive inhibitor inhibit an enzyme’s function?

Answer 47

• If it is very similar in shape to the substrate and there is a higher conc of inhibitor than substrate, it becomes less likely that the substrate will collide with an empty site
• Therefore, the rate of enzyme activity decreases
• This is known as competitive inhibition e.g. ethanol is a competitive inhibitor to ethylene glycol

Question 48

How is competitive inhibition reversible (not permanent)?

Answer 48

Because it can be reversed by increasing substrate concentration

Question 49

What does there has to be for a competitive inhibitor to inhibit enzyme function?

Answer 49

A higher concentration of inhibitor than substrate

Question 50

What is non-competitive inhibition?

Answer 50

When a molecule binds to another part of the enzyme, rather than the active site, but still affects the enzyme’s function

Question 51

How does non-competitive reversible inhibition inhibit an enzyme’s function?

Answer 51

• When the inhibitor is bound to the enzyme it can seriously disrupt the normal arrangement of H-bonds and hydrophobic interactions holding the enzyme in its 3D shape
• The resulting distortion ripples across the molecule to the active site, making the enzyme unsuitable for the substrate
• Therefore, enzyme activity rapidly decreases
• While the inhibitor is attached to the enzyme, the enzyme’s function is blocked no matter how much substrate is present

Question 52

Although inhibition of enzyme function can be lethal, how can it be essential?

Answer 52

It can control metabolic reactions so that they don’t ‘run wild’

Question 53

How can metabolic reactions be controlled?

Answer 53

• By using the end-product of a chain of reactions as a non-competitive inhibitor (end-product inhibition)
• As the enzyme converts substrate to product, it is slowed down because the end-product binds to another part of the enzyme and prevents more substrate binding
• The end-product can then lose its attachment to the enzyme and be used elsewhere, allowing the enzyme to reform to it active state
• As product levels fall, the enzyme is able to top them up again

Question 54

What is the turnover number/second (rate)?

Answer 54

The number of molecules of substrate that one molecule of enzyme converts into product in one second (related to Vmax) e.g. average enzyme = 1000

Question 55

What are the two different ways of comparing the efficiency of different enzymes?

Answer 55

1) To measure the theoretical maximum rate (velocity) -Vmax - of the reaction it catalyses
2) Km

Question 56

What happens at Vmax?

Answer 56

All the enzyme molecules are bound to substrate molecules - the enzyme is saturated with substrate

Question 57

What happens to the rate of reaction as substrate concentration increases?

Answer 57

The rate of reaction increases until the reaction reaches Vmax

Question 58

Why can’t you accurately read off Vmax from a substrate concentration graph?

Answer 58

• The curve is asymptotic
• Therefore, in practice, the curve never flattens out
• In theory, it does at an infinite conc, but this is impossible to measure

Question 59

How can you find Vmax using a graph?

Answer 59

• Plot 1/S (substrate concentration) against 1/V (velocity, i.e. rate)
• This plot is called a double reciprocal plot
• You can then plot the infinite substrate concentration because 1/infinity = 0 which can be plotted (the graph is a straight line)
• Therefore Vmax can be found accurately (y-intercept = 1/Vmax)

Question 60

What is the Michaelis-Menten constant (Km)?

Answer 60

The substrate concentration at which an enzymes works at half its max rate (1/2 of Vmax)

Question 61

What happens at Km and what does this mean?

Answer 61

• At Km, 1/2 of the active sites of the enzyme are occupied by the substrate
• The higher the affinity of the enzyme for the substrate, the lower substrate concentration is needed for this to happen
• Therefore, Km is a measure for the affinity of an enzyme for its substrate
• The higher the affinity, the lower the Km and the quicker the reaction will proceed to Vmax (although it is not directly affected)

Question 62

What is a way to think about Vmax and Km?

Answer 62

Vmax = max speed of car
Km = acceleration

Question 63

What does Vmax give information about?

Answer 63

The maximum rate of reaction that is possible (but not necessarily under cell conditions)

Question 64

What does Km measure?

Answer 64

The affinity of the enzyme for the substrate
- the higher the affinity, the more likely that the product will be formed when a substrate molecule enters the active site, rather than the substrate simply leaving the active site again before a reaction takes place

Question 65

How do you find Km from a double reciprocal plot?

Answer 65

-1/Km (x-intercept) - in negative region of x-axis

Question 66

What are two significances of Vmax and Km?

Answer 66

1) For a commercially important enzyme, the performance of different enzymes can be compared
2) An enzyme’s preference for different substrates can be compared quantitively

Question 67

What are some commercial applications of enzymes?

Answer 67

Medicine, food technology

Question 68

Why do people use immobilised enzymes?

Answer 68

They keep costs down as they can be reused/recycled

Question 69

How is the enzyme lactase immobilised?

Answer 69

Using alginate beads (enzyme is inside beads)

• Milk is then allowed to run through the column of beads
• Lactase hydrolyses the lactose in milk into glucose and galactose
• Therefore, the milk is lactose-free

Question 70

What are the advantages of using immobilised lactase?

Answer 70

• W/o it, you would not be able to get the enzyme back and the milk would be contaminated with enzyme
• You can keep and re-use the enzyme and the milk is enzyme-free
• Immobilised enzymes are also more tolerant of temp and pH changes than enzymes in solution (bc held more firmly in shape and less exposed)

Question 71

What is an inhibitor?

Answer 71

A substance that slows down the rate of an enzyme-catalysed reaction