Disease and the Immune System

Question 1

Name 4 groups of pathogen that can cause communicable diseases.

Answer 1

● bacteria
● fungi
● protoctista ● viruses

Question 2

How does Mycobacterium tuberculosis cause disease?

Answer 2

1. Triggers inflammatory response by infecting phagocytes in lungs.
2. Infected phagocytes are sealed in waxy-coated tubercles so bacteria remain dormant. First infection has no symptoms.
3. If another factor weakens immune system, bacteria become active & destroy lung tissue.

Question 3

How does HIV result in the symptoms of AIDS?

Answer 3

1. Attachment proteins bind to complementary CD4 receptor on TH cells.
2. HIV particles replicate inside TH cells, killing or damaging them.
3. AIDS develops when there are too few TH cells for the immune system to function.
4. Individuals cannot destroy other pathogens & suffer from secondary diseases/ infections. May cause death.

Question 4

How does the tobacco mosaic virus cause disease?

Answer 4

Affects plants. Mainly transmitted via infected sap.
Contains ssRNA, which is directly transcribed by host cell to assemble new virions.
Virions enter other cells via plasmodesmata then enter xylem & phloem.
Causes stunted growth & mottled leaves.

Question 5

How does the influenza virus cause disease?

Answer 5

Transmitted via: droplet infection, contact with mucus containing virus, zoonotic infection, contact with fomites.
Injects viral RNA into ciliated epithelial cells of throat & lungs. Viral RNA hijacks cell biochemistry to produce new virions. Cell lysis releases virions.
5-7 days of headache, coughing, sneezing, sore throat,
vomiting, fever, muscular/joint pain.

Question 6

What causes malaria?

Answer 6

Female Anopheles mosquito acts as vector for Plasmodium spp. protoctista when it transfers saliva to another organism during feeding.
Parasite reproduces asexually in red blood cells in liver, causing lysis

Question 7

What causes potato/ tomato late blight? What causes ring rot of potatoes?

Answer 7

Blight: The protoctista Phytophthora infestans behaves similarly to a fungus. Mainly transmitted via spores.
Ring rot: Sepedonicus subspecies of the bacterium Clavibacter michiganensis. Mainly transmitted by planting infected seeds/ contact with fomites. Plant-to-plant transmission is rare.

Question 8

What causes bacterial meningitis?

Answer 8

Often meningococcal bacteria A, B, C, W, X, Y, Z. Also caused by pneumococcal bacteria & Haemophilus influenzae type b (Hib) bacteria. Affects meninges (protective membranes around brain).
Transmitted by droplet infection & direct contact with saliva e.g. kissing. Usually spread by carriers of the bacteria who are not ill & occasionally by individuals with meningitis.

Question 9

Describe 3 fungal infections.

Answer 9

The sac fungus Mycosphaerella fijiensislack causes the leaf-spot disease black sigatoka in banana plants.
About 40 types of fungi cause ringworm. Transmitted by contact with fomites, zoonotic infection, direct contact with infected individuals. Particularly affects cattle.
Athlete’s foot in humans (tinea pedis) is caused by a range of fungi which can also affect hands or nails.

Question 10

How are communicable pathogens transmitted directly?

Answer 10

● Inhalation (droplet infection).
● Skin-to-skin contact or exchange of fluids.
● Penetrate skin actively using enzymes or
passively through wounds, hair follicles or sweat glands.

Question 11

How are communicable pathogens transmitted indirectly?

Answer 11

● Consumption of contaminated food & drink.
● Via a vector e.g. mosquitoes transmit Plasmodium parasite.
● Spores

Question 12

How do living conditions affect disease transmission?

Answer 12

Overcrowding increases direct transmission.
Climate determines which organisms can survive e.g. malaria is more prevalent in tropical countries, where mosquitoes (the vector) can breed.
Social factors influence how quickly people are treated, which can increase/ decrease direct transmission.

Question 13

Name 4 physical barriers to pathogen entry in plants.

Answer 13

● cellulose cell walls
● lignified layer
● waxy upper cuticle
● old vascular tissue is blocked to prevent
pathogens from spreading inside the plant

Question 14

Describe 2 mechanical responses to infection in plants.

Answer 14

Guard cells close stomata.
The thick polysaccharide callose is produced & deposited between the cell wall & plasma membrane to increase entry distance/ limit spread.

Question 15

What is necrosis?

Answer 15

Injury activates intracellular enzymes in plants that kill cells near the site of infection to prevent pathogen from spreading.
Necrosis of woody tissue is known as canker.

Question 16

Describe the chemical defences plants use against pathogens.

Answer 16

● Terpenoids (essential oils) e.g. menthols act as antibacterials.
● Phenols e.g. tannin inhibit insects from attacking by interfering
with digestion.
● Alkaloids e.g. caffeine & morphins deter herbivores from
feeding because they taste bitter.
● Defensins (cysteine-rich proteins) inhibit transport channels.
● Hydrolytic enzymes e.g. chitinases break down cell wall of
invading organisms.

Question 17

Name 5 barriers to infection in animal

Answer 17

● Skin is tough keratin layer.
● Blood clotting prevents pathogens from entering through
skin lesions.
● Hydrochloric acid in stomach kills bacteria.
● Harmless bacteria in gut & on skin surface increase
interspecific competition with pathogens.
● Mucous membranes trap pathogens and may secrete
antimicrobial enzymes.

Question 18

What are expulsive reflexes?

Answer 18

Body attempts to force foreign substances out:
● Irritation of mucous membranes in nostrils causes sneezing.
● Irritation of ciliated epithelium in respiratory tract causes coughing.

Question 19

Name 4 ways the nonspecific immune system responds to infection.

Answer 19

● inflammation
● phagocytosis
● digestive action of lysozymes
● production of interferon (antiviral agent)

Question 20

Outline the process of inflammation.

Answer 20

1. Damaged vessels release histamines, causing vasodilation.
2. Blood flow & permeability of blood vessels increase.
3. White blood cells & plasma move into the
   infected tissue.

Question 21

How does blood clotting occur?

Answer 21

1. Blood platelets form plug & release chemicals that enhance clotting e.g. thromboplastin.
2. Prothrombin changes into thrombin, its active form.
3. Fibrinogen changes into insoluble fibrin which covers wound.

Question 22

Name the 2 types of white blood cell involved in phagocytosis.

Answer 22

Neutrophils

Macrophages (can become antigen-presenting cells)

Question 23

How does phagocytosis destroy pathogens?

Answer 23

1. Phagocyte moves towards pathogen which may have been marked by opsonins via chemotaxis.
2. Phagocyte engulfs pathogen via endocytosis to form a phagosome.
3. Phagosome fuses with lysosome (phagolysosome).
4. Lysozymes digest pathogen.
5. Phagocyte absorbs the products from pathogen
   hydrolysis.

Question 24

Explain the role of antigen-presenting cells (APCs).

Answer 24

Macrophage displays antigen from pathogen on its surface (after hydrolysis in phagocytosis).
Enhances recognition by TH cells, which cannot directly interface with pathogens/ antigens in body fluid.
Secrete cytokines that are involved in stimulating specific immune response.

Question 25

What are lysozymes?

Answer 25

Digestive enzymes. Found in lysosomes as well as many secretions e.g. tears & mucus. Damage bacterial cell walls, causing osmotic lysis.

Question 26

Outline how to prepare blood to be observed under a microscope.

Answer 26

1. Smear a drop of blood onto a slide using a spreader held at 45°.
2. Add leishman stain then a buffer. Rinse.

Question 27

Name the 2 types of specific immune response.

Answer 27

● cell-mediated ● humoral

Question 28

Outline the process of the cell-mediated response.

Answer 28

1. Complementary TH lymphocytes bind to foreign antigen on APC.
2. Cell signalling via secretion of interleukins stimulates:
   a. clonal expansion of complementary TH cells (rapid
   mitosis): become memory cells or trigger humoral
   response.
   b. clonal expansion of cytotoxic T cells (TC): secrete
   enzyme perforin to destroy infected cells.

Question 29

Outline the process of the humoral response.

Answer 29

1. Complementary TH lymphocytes bind to foreign antigen on antigen-presenting T cells.
2. Release cytokines that stimulate clonal expansion (rapid mitosis) of complementary B lymphocytes.
3. B cells differentiate into plasma cells.
4. Plasma cells secrete antibodies with
   complementary variable region to antigen.

Question 30

Describe the structure and function of B and T lymphocytes.

Answer 30

Many specific receptors & immunoglobulins on surface.
B cells differentiate into plasma cells to secrete antibodies.
3 types of T cell: T helper (secrete cytokines), T killer (secrete perforin), T regulator (suppress other immune cells to prevent autoimmune disease).

Question 31

What is an antibody? Describe its structure.

Answer 31

IMAGE 20

Question 32

How do antibodies lead to the destruction of a pathogen?

Answer 32

● Agglutinins form antigen-antibody complexes to enhance phagocytosis.
● Activation of complement.
● Opsonins mark microbes for phagocytes.
● Antitoxins make toxins insoluble via
precipitation/ neutralisation.

Question 33

What are memory cells?

Answer 33

Specialised TH/ B cells produced from primary immune response.
Remain in low levels in the blood.
Can divide very rapidly by mitosis if organism encounters the same pathogen again.

Question 34

Contrast the primary and secondary immune response.

Answer 34

secondary response:
● Faster rate of antibody production.
● Shorter time lag between exposure & antibody production.
● Higher concentration of antibodies.
● Antibody level remains higher after the secondary
response.
● Pathogen usually destroyed before any symptoms.

Question 35

Compare and contrast passive and active immunity.

Answer 35

Passive:
No memory cells and antibodies not replaced when broken down = short term
Immediate 
Antibodies from external source 
No direct contact with antigen necessary 
Active:
Memory cells produced = long term
Time lag
Lymphocytes produce antibodies 
Needs direct contact with antigen
Both:
Involve antibodies and can be natural or artificial

Question 36

Give examples of passive and active immunity.

Answer 36

Passive natural: antibodies in breast milk/ across placenta.
Passive artificial: anti-venom, needle stick injections.
Active natural: humoral response to infection. Active artificial: vaccination.

Question 37

Define ‘autoimmune disease’ and give examples.

Answer 37

Immune system produces antibodies against its own tissues.
Rheumatoid arthritis: immune system targets synovium lined joints, causing inflammation.
Lupus: results in inflammation throughout body.

Question 38

Explain the principles of vaccination.

Answer 38

1. Vaccine contains dead/ inactive form of a pathogen or antigen.
2. Triggers primary immune response.
3. Memory cells are produced and remain in the
   bloodstream, so secondary response is rapid &
   produces higher concentration of antibodies.
4. Pathogen is destroyed before it causes symptoms.

Question 39

Define endemic and epidemic.

Answer 39

Endemic: disease occurs routinely in a geographical area.
Epidemic: temporary rapid increase in incidence of disease in a geographical area.

Question 40

What role do vaccines play in preventing epidemics?

Answer 40

Routine vaccination of 80-90% of population reduces available carriers of pathogen, resulting in herd immunity. Limited by country’s resources.
Vaccinating close contacts of infected individual limits spread of pathogen, but raises issues of distributive justice.
Programs have changed to account for informed consent & maximum beneficence even during epidemic

Question 41

List some possible natural sources of medicines.

Answer 41

● microorganisms e.g. streptomycin, neomycin, chloramphenicol = various species of Streptomyces genus
● fungi e.g. penicillin
● plants e.g. Taxol for chemotherapy = yew, quinine for
malaria = cinchona, digoxin for heart arrhythmia = foxglove
Maintaining biodiversity means new natural treatments can
be discovered in the future.

Question 42

What is personalised medicine and synthetic biology?

Answer 42

Personalised medicine: genome sequencing has enabled scientists to predict an individual’s response to disease/ certain medicines so prescriptions can be targeted.
Synthetic biology: engineering that targets biochemical processes.

Question 43

What are the benefits of using antibiotics to treat bacterial infection?

Answer 43

Effectively reduce population of bacterial colony. Used widely since discovery of penicillin in mid-20th century.
Bacteriostatic antibiotics prevent protein synthesis/ inhibit formation of nucleic acids = inhibit growth.
Bactericidal antibiotics prevent formation of peptidoglycan cross-links in cell walls = osmotic lysis.

Question 44

What are the risks of using antibiotics to treat bacterial infection?

Answer 44

Overuse of antibiotics increases selection pressure for resistant strains of bacteria. Antibiotic-resistant infections e.g. caused by MRSA & Clostridium
difficile are difficult to treat.