U1T2 - Enzymes

Question 1

What makes up your metabolism?

Answer 1

Chemical reactions which take place within our bodies.

Question 2

What are the properties of enzymes?

Answer 2

Highly substrate specific, globular proteins, soluble, spherical, tertiary structure, fast acting. Affected by temp + pH.

Question 3

What do enzymes have which allows them to catalyse reactions?

Answer 3

Highly substrate specific active site (substrate receptor site) which is complementary to a particular substrate.

Question 4

When enzymes react and combine with the substrate, what do they form? What happens when the reaction is over?

Answer 4

Enzyme/substrate complex. Products are released and enzyme is left unchanged.

Question 5

Enzymes are fast acting, what does this mean?

Answer 5

High turnover number. Convert many molecules of substrate per unit time.

Question 6

What can enzymes build up and break down and how?

Answer 6

Molecules (carbs, proteins, lipids) hydrolysed by digestive enzymes. (starch + glycogen) built up from monomers for storage.

Question 7

What type of protein are most enzymes? e.g. fibrous/conjugated etc.

Answer 7

Conjugated protein.

Question 8

What is the non-protein part of a conjugated protein known as? What are the 2 types?

Answer 8

Cofactor. Prosthetic + coenzymes.

Question 9

Give some examples of cofactors.

Answer 9

Metal ions (Mg2+, Ca2+, Fe2+).

Question 10

How do cofactors work?

Answer 10

Form attachments to enzyme + change shape of active site, enabling a reaction to take place.

Question 11

Give an example of a cofactor, its enzyme, and how it works.

Answer 11

Chloride ions for salivary amylase. Bind with amylase, change shape of active site slightly + makes it easier for enzyme-substrate complex to form.

Question 12

Give examples of prosthetic groups.

Give examples of coenzymes.

Answer 12

Metal ions (zinc, iron, copper, haem group in catalase)
Vitamins (NAD from vitamin B)

Question 13

What do some coenzymes do?

Answer 13

Transfer chemical groups, atoms or electrons from one enzyme to another.

Question 14

How is the activation energy overcome in many chemical reactions?

Answer 14

Heating of reactants, not possible for living organisms so we use enzymes instead.

Question 15

As molecules react, what do they form? For how long? What is this known as?

Answer 15

High energy intermediates, momentarily (enzyme-substrate complex, ES) Transition state.

Question 16

What is formed after the transition state? Why is it released?

Answer 16

Enzyme-product complex (EP) No longer fits active site.

Question 17

How is activation energy lowered? What can do this?

Answer 17

Bringing substrate into correct orientation to facilitate bonding (breaking + making bonds) to form a product. Enzymes can do this.

Question 18

Finish the equation…

E + S ->

Answer 18

ES -> EP -> E + P

Question 19

What is the theory of enzyme action?

Answer 19

A molecules react they form enzyme-substrate complexes during the transition state which only happens if they have enough activation energy which is lowered by enzymes. An enzyme-product complex is then formed and because the products no longer fit the active site they are released

Question 20

What environmental factors affect the rate of reaction of enzymes?

Answer 20

Temperature, pH, substrate concentration + enzyme concentration.

Question 21

Describe how temperature affects the rate of reaction of enzymes up until the optimum temperature.

Answer 21

Increasing temp increases kinetic energy, meaning the molecules move around quicker and there are more collisions, resulting in more enzyme-substrate complexes being formed.

Question 22

Describe how temperature affects the rate of reaction of enzymes above the optimum temperature.

Answer 22

An increase in temp will denature the enzyme. (60c) which is permanent + irreversible.
DO NOT MENTION TIME.

Question 23

Describe how pH affects the rate of reaction of enzymes.

Answer 23

Each enzyme has an optimum pH where it works best. Changes in pH reduce enzyme activity. This is because the changes break ionic bonds to denature the enzyme eventually but this effect is reversible.

Question 24

Describe how substrate concentration affects the rate of reaction of enzymes.

Answer 24

If enzyme conc is constant and substrate conc is increased, enzyme activity will gradually increase until a point as there are more substrates to fill the active sites. It will level off because all the active sites will become occupied so the enzyme concentration becomes the limiting factor.

Question 25

Describe how enzyme concentration affects the rate of reaction of enzymes.

Answer 25

If substrate conc is constant + enzyme conc is increased, enzyme activity will gradually increase until a point as there are more active sites than there are substrate molecules so they become limiting. However, in living systems there is seldom substrate limiting.

Question 26

Describe how product can affect the rate of reaction of enzymes.

Answer 26

Too much product can interfere with the active sites so blocking substrate from binding and reducing the reaction rate.

Question 27

Give an example of non competitive inhibitor.

Answer 27

Cyanide non-reversible inhibitor of respiratory enzyme cytochrome oxidase.

Question 28

How might you reduce the damage on someone who has had antifreeze?

Answer 28

Give them a massive dose of ethanol.

Question 29

Why can enzymes be used as biomarkers?

Answer 29

Some enzymes are only present/active during a particular disease process.

Question 30

Give an example of enzymes as biomarkers of disease. (respiratory)

Answer 30

White blood cells release elastase during respiratory infections. It hydrolyses elastin within alveolar walls leading to reduced lung function due to recoil function of lungs which is a part of exhalation. By detecting elastase in clinical sample (blood/urine/sputum) you can diagnose a respiratory infection which can then be treated.

Question 31

Give an example of enzymes as biomarkers of disease (cardiac)

Answer 31

Cardiac enzymes are released when irreversible damage has occurred during a heart attack to the myocardium causing a myocardial infarct. The level of these cardiac enzymes detected in a blood sample depends on the size of the infarct so can indicate levels of monitoring + treatment required by patient.

Question 32

How can inhibitors be used as therapeutic drugs?

Answer 32

Active site directed inhibitors to stop enzymes contributing to disease processes to treat symptoms.

Question 33

Give examples of how enzyme inhibitors can be used as therapeutic drugs.

Answer 33

ACE inhibitor treats hypertension.
MOI inhibitor treats depression by inhibiting monoamine oxidase enzyme which would decrease levels of noradrenalin + serotonin in brain which contribute to depression.
Sulfonamide antibiotic drugs inhibit enzyme DHPS in bacteria as it is essential for synthesis of vitamin necessary for reproduction.

Question 34

In the mid-1960s biological washing powders became widely available, what did they contain and what were the issues? What do we have now?

Answer 34

Contained protease in powdered for. Allergic reactions in workers + users leading to bad publicity. These were caused by the powdered enzyme coming into contact with the skin. They then made detergents to contain immobilised proteases which don’t react with the skin.

Question 35

What are the 4 main methods for immobilising enzymes?

Answer 35

Adsorption, entrapment, encapsulation/enmeshment + cross-linkage.

Question 36

What are the disadvantages of immobilisation? (4)

Answer 36

Material may reduce speed of diffusion between substrate + enzyme, enzyme may be held where active site is inaccessible to substrate, may damage active site + In adsorption, enzyme can be easily washed from material.

Question 37

What are the advantages of immobilisation? (5)

Answer 37

Thermostable enzymes, more resistant to pH, can be reused, can be continuous commercial process + doesn’t need to be purified due to lack of contamination of end product with enzyme.

Question 38

What 3 factors are controlled in a continuous flow column reactor to ensure maximum efficiency?

Answer 38

Flow rate, immobilisation method + environmental conditions.

Question 39

What might immobilised enzymes be placed in for maximum production?

Answer 39

Continuous flow column reactor

Question 40

Why can enzymes be used as biosensors?

Answer 40

They are specific + quantitative.

Question 41

Give 2 examples of biosensor tests.

Answer 41

Clinistix + digital blood glucose testing kit.

Question 42

How does the clinistix test work?

Answer 42

Test strips contain glucose oxidase + peroxidase + chromagen. Strip is dipped into a urine sample + if glucose is present, it is oxidised to gluconic acid + hydrogen peroxide. The 2nd enzyme catalyses reduction of hydrogen peroxide + oxidation of chromagen. Products produced are water + oxidised dye. More dye, more glucose. Colour is compared to a printed scale to indicate amount of glucose in urine.

Question 43

How does a digital blood glucose testing kit work?

Answer 43

Glucose reacts with immobilised enzyme + reaction that occurs produces colour change. Results are converted into an electrical signal. Kit includes blood testing meter, box of diagnostic test strips + lancing device.

Question 44

How does a pregnancy test work?

Answer 44

Detects the level of hCG by use of an antibody linked to an enzyme which causes a colour change In the test zone (blue line). It’s an example of ELISA.

Question 45

What sectors are enzyme inhibition based biosensors used in?

Answer 45

Pharmaceutical, healthcare, agrifood + environmental monitoring.

Question 46

How is lactose intolerance caused?

Answer 46

Cannot produce lactase, bacteria in gut ferment lactose, producing diarrhoea + gas.

Question 47

How is lactose free milk produced using enzymes?

Answer 47

Pour milk over immobilised lactase enzyme beads by continuous flow processing.

Question 48

____ + Water - (____) -> Glucose + ____

Answer 48

Lactose, lactase, galactose.

Question 49

What is lactose broken down into?

Answer 49

Glucose + galactose

Question 50

How might you test a soil water sample for the presence of heavy metal ions?

Answer 50

Enzymatic inhibition of heavy metal ions, often by urease and glucose oxidase.

Question 51

Give examples of heavy metal ions

Answer 51

Mercury, cadmium + chromium.

Question 52

In which respiratory conditions might you see a breakdown of elastin?

Answer 52

Cystic fibrosis, emphysema, COPD.

Question 53

Give an example of enzymes as biomarkers of disease.

Tubular enzymes

Answer 53

Enzymes in urine which are normally found on brush border of epithelial cells of proximal convoluted tubule of kidney nephron. These tubular enzymes can lead into urine due to cell damage and can indicate acute kidney injury.

Question 54

Treating disease through enzyme inhibition:

Heart disease

Answer 54

ACE (angiotensin converting enzyme) converts angiotensin 1 to angiotensin 2 which contributes to vasoconstriction of arteries, increasing blood pressure and is a normal part of blood pressure regulating mechanism. Treated with ACE inhibitor.

Question 55

Treating disease through enzyme inhibition:

High cholesterol

Answer 55

HMG-CoA reductase is involved in production of cholesterol and treated with statins (HMG-CoA reductase inhibitors) which are the most commonly prescribed medication in the UK.

Question 56

Treating disease through enzyme inhibition:

Headache/toothache

Answer 56

Cyclooxygenase is involved in production of prostaglandins which bring about inflammation. Treated with paracetamol + other non-opioid analgesics.

Question 57

Treating disease through enzyme inhibition:

Type 2 diabetes

Answer 57

DPP-4 (Dipeptidyl peptidase 4) destroys gastrointestinal hormone incretin which helps body produce insulin when necessary. It is a T-cell activator and has several other metabolic roles. Treated with DPP-4 inhibitor.

Question 58

Treating disease through enzyme inhibition:

HIV (Protease)

Answer 58

Protease, following synthesis of large viral proteins, cuts them into functional molecules so that virus particles can be assembled. Treated by a protease inhibitor.

Question 59

Treating disease through enzyme inhibition:

HIV (Reverse Transcriptase)

Answer 59

Reverse Transcriptase catalyses the formation of a DNA copy of the viral RNA genome. It is treated with nucleotide reverse transcriptase inhibitors which involve faulty versions of DNA nucleotides so viral DNA is produced incorrectly and can’t be incorporated into host cell DNA.

Question 60

Treating disease through enzyme inhibition:

HIV (Integrase)

Answer 60

Integrase inserts viral DNA into the host cell DNA. It can be treated by Integrase inhibitor.

Question 61

Treating disease through enzyme inhibition:

Various Mental Health Disorders

Answer 61

Monoamine oxidases break down various neurotransmitters including seratonin, adrenaline, melatonin + dopamine. Treated with monoamine oxidase inhibitors which are the first class of antidepressants to be developed and are now used for depression, schizophrenia + other conditions like Parkinson’s Disease.

Question 62

Treating disease through enzyme inhibition:

Respiratory Disease

Answer 62

Elastase hydrolyses elastin in alveolar walls. It is produced by white blood cells and helps them move through tissues to the site of infection. It is treated with elastase inhibitors (alpha-1 antitrypsin) which is in clinical development.

Question 63

How might you ensure the pH of a solution stays the same?

Answer 63

Use a buffer or continuously test it.

Question 64

Why might it not be better to cut lettuce with a knife rather than tearing it with your hands?

Answer 64

The knife may rupture the cells whilst tearing will break along cell walls.

Question 65

How does a synthesis reaction work?

Answer 65

Substrates are oriented to facilitate bonding.

Question 66

If there are 2 peaks for enzyme activity depending on temperature in a biological washing powder graph, what’s going on?

Answer 66

There are 2 different enzymes with different optimum temperatures, allowing enzyme activity to happen over a broader range of temperatures.

Question 67

Why does a high temperature break bonds in enzymes?

Answer 67

They vibrate.

Question 68

Soybean lipase works at a Lower temperature than mammalian lipase, why is this advantageous?

Answer 68

Environmental temperatures will be low and this allows them to germinate in Springtime as they should.

Question 69

Why might an enzyme be extracted in a buffered solution?

Answer 69

Ensures pH stays optimum + prevents pH fluctuation to prevent it being denatured.

Question 70

Why might an experiment show a different optimum temp for an enzyme which should have a different optimum temp?

Answer 70

The enzyme has been immobilised.

Question 71

Why might an enzyme and suspension be incubated separately before mixing in an experiment to determine the optimum temp?

Answer 71

To allow the enzyme + substrate to reach the reaction temp before being mixed.

Question 72

Why should a pH be maintained at the optimum pH level for an enzyme?

Answer 72

Active site is most complementary and at other pHs the active site is less complementary.

Question 73

Why would a blue filter be chosen in a colorimeter when measuring intensity of orange colouration of a solution?

Answer 73

Solution reflects orange and absorbs blue light.

Question 74

Explain how cyanide affects cell function.

Answer 74

Inhibits respiration and therefore ATP production.

Question 75

In normal circumstances, why might respiration rate decrease for a mitochondrion?

Answer 75

Limiting factor of substrate availability.