IMM: Immune Defects and Infection

Question 1

• What is the purpose of the innate immune system?
• Name the four general categories of the innate immune system.
• Give an example of an organ with lots of innate immunity.

Answer 1

PURPOSE

• Senses pathogens in our system.
• Prepares adaptive system, and assesses the damage.

Rapid, non-specific response system. It responds the same way each time a foreign substance is encountered.

GENERAL ​CATEGORIES

• Physical barriers
  
  • Skin and mucous membranes.
• Soluble proteins
  
  • Complement molecules.
  • Acute phase reactants (CRP).
• Cellular components
  
  • Neutrophils, macrophages, NK cells.
• Cytokines = how cells communicate.
  
  • IFN-gamma, TNFa, interleukins.
• The liver.

Question 2

What are the four steps of innate recognition of pathogens?

Answer 2

1. Innate immunity senses nonself.

• Conserved structures.
• Genetically fixed in pathogens, but not in us.

2. Cytokines are produced.
   * Communication.
3. Acute phase reactants produced locally + by liver.

• CRP and complement.
• Highlighter molecules → maximises efficiency of phagocytosis and cell destruction.

4. Measures to localise spread of infection and enhance systemic resistance.

Question 3

• What is the purpose of the pattern recognition receptors?
• What is the name of the patterns that they recognise?
  
  • What are some examples?

Answer 3

• Detect the conserved structures
  
  • Altered cells
  • Oxidised cells
  • Oxidised membrane structures
• Pattern on a pathogen → pathogen associated molecular patterns = PAMPs.
  
  • LPS.
  • Flagellin.
  • dsRNA.
  • Unmethylated CpG DNA.

Question 4

What are PAMPs?

Answer 4

Tissue damage can release normally sequestered molecules from inside cells – damage-associated molecular patterns (DAMPs).

Question 5

• Where are toll-like receptors located?
• The TLRs that recognise the bacteria components, where are they?
• What do TLRs activate? Give an example.
  
  • What do the things activated by TLRs do?

Answer 5

• Located on the cell surface and in the walls of intracellular vesicles.
• Extracellular membrane.
• TLRs activate transcription factors, e.g. NFkB.
  
  • NFkB induces pro-inflammatory cytokines and chemotactic factors.
• TLRs also activate IRF to induce antiviral type I interferons (IFNa and IFNb).

Question 6

• Where are the three TLRs that recognise viral components?
  
  • Where are they?
• TLR-4 recognises what structure present on bacterial cell walls?

Answer 6

• TLR-3, 7, 9.
  
  • Sit within the cytosol of the cell.
  • Associated with damaged DNA.
• TLR-4 recognises LPS (lipopolysaccharide) from bacterial cell wall.
  
  • Located on outside of cell wall.

Question 7

• What are NOD-like receptors?
  
  • Give an example.
    
    • What do they do? (+ clinical diagnosis if this NLR is altered).​
• Give an example of where NLRs are found?

Answer 7

• Floating, non-membrane bound intracellular sensor of infection and other molecules.
  
  • NLR example = Cryopyrin = NALP3.
    • Induces fever → Hereditary periodic fever syndrome.
  • Particularly epithelial cells in the gut.

Question 8

• Describe the structure (3 individual components) and discuss the function of an inflammasome.

Answer 8

• Structure:
  
  • Pro-caspase-1, NLRP3 (NALP3) and ASC.
• Function:
  
  • Components that come together with the end result of cleaving pro-cytokines to release their active form, eg IL-1b, Il-18.
  • Inflammasome creates caspase-1, which converts inactive cytokines eg prIL-1b and IL-18

Contains NLRP3.

Trigger = oxidative damage or potassium efflux.

Inflammasome activates pro-caspase 1 to caspase 1 (slide 8/41).

Caspase 1 cleaves pro-cytokines.

Examples = IL-1B and IL-18.

Clin example: Muckel-Wells

Treatment: anti-IL-1b antibody → no fever.

Untreated: amyloidosis and subsequent death.

Question 9

• Describe the role of C3, referring to C3a and C3b.
  
  • What uniquely happens to C3b in the alternative complement pathway?
    
    • What three factors stabilise this?
    • What do factors H and I do?
• What do all three arms of the complement system converge on? (Hint: Sesame Street)
• Is elevated C3 pathogenic?
• Discuss the mechanisms of C3 depletion.

Answer 9

• C3a is a chemoattractant.
• C3b is an opsonin; marks the pathogen for phagocytosis.
  
  • C3b is deposited directly on the microbe.
    
    • Factors B, D and P stabilise this complex.
    • Prevent C3b from binding to other things (together they displace and inactivate C3 convertase on host cells).
• C3b.
• No, as it is often apart of the acute phase response.
• C3 depletion.
  
  • Consumption.
  • Deficiency.
    
    • Genetic.
    • Not produced eg liver disease.
  • Loss.

Question 10

Discuss C5, and the role it plays in making the membrane attack complex.

Answer 10

• C5 breaks into C5a, an attractant, and C5b.
• C5b binds to C6, and then C7 binds to this complex, etc etc.
• Forms the MAC.
• MAC forms a pore into the cell, and lyses the cell.

Question 11

• Name two of the complement proteins specific to the classical pathway.
• Classical complement deficiency leads to what two phenomena?

Answer 11

• C2 and C4.
  
  • C4b and C2a come together to make C3 convertase, which cleaves the C3 molecule.
• SLE and pyogenic infections.

Question 12

Which group is the MBL pathway important in?

Answer 12

• Childhood (6-24 months).
• May be a factor in patients with other concurrent immunodeficiencies but alone in adults, not usually significant.

Question 13

• Describe the role C3 nephritic factor plays in the alternative pathway.

Answer 13

• C3neF is an autoantibody that stabilizes the alternative pathway C3 convertase (C3bBb).
  
  • Remember: C3 convertase is what cleaves C3 into active forms that lead to the formation of the MAC.

Question 14

CD59 (protectin) and DAF deficiency are rare complement disorders. Describe (briefly) their pathology and clinical signs.

Answer 14

• X-linked deficiency in PIG-A gene, causes lack of GPI tails on proteins.
• Complement “think” erythrocytes are bacteria, leading to red cell lysis.
• Paroxysmal = A sudden recurrence or intensification of symptoms.
• Dark urine overnight.

Question 15

Name three immune cells capable of phagocytosis.

Answer 15

• Macrophages.
• Dendritic cells.
• Granulocytes (polymorphonuclear leukocytes).

Question 16

Describe the roll and adhere mechanism of neutrophils and discuss the proteins that mediate this process.

Answer 16

• Neutrophils roll along endothelium.
• Endothelium expresses adhesion molecules.
  
  • Inflammatory cytokines such as TNF-a are required for expression of adhesion molecules such as ICAM-1 and ICAM-2.
• Receptor on leukocytes = integrin.
  
  • Chemokines (eg. CXCL8) upregulate the adhesion molecule ligands on neutrophil surfaces, called integrins, such as LFA-1.

Question 17

Name the four cell groups of innate immunity, and the two of adaptive immunity.

Answer 17

INNATE

• Phagocytosis.
• Dendritic cells.
• Complement proteins.
• NK cells.

ADAPTIVE

• B lymphocytes.
• T lymphocytes.
  
  • CD+ = T helper cells.
  • CD8+ = cytotoxic cells.

Question 18

T helper cells fall under the subsets of T_H1, T_H2, T_H17, and T_reg cells. What are the associated cytokines, what type of pathogens do they protect against, and what clinical relevance do they have?

Answer 18

T_H1

• IFN gamma.
• Intracellular pathogens (bacteria and viruses).
• Autoimmune conditions and delayed hypersensitivity.

T_H2

• IL-4,5,13.
• Parasites (+worms) and bacteria.
• Allergy and asthma.

T_H17

• IL-17,21,22.
• Mainly fungi, and bacteria.
• Autoimmunity.

T_reg

• TGF-B, IL-10.
• Regulate other adaptive immune cells.
• Immunosuppression.
• Can suppress effector T cells in periphery.

Question 19

• What is one feature that distinguishes innate immunity from adaptive?

Answer 19

• Adaptive has memory.
  
  • Memory B cells.

Question 20

• Describe the evolution of a B cell.
• How can B cells be measured in periphery?
• B cells can be broken down into two categories: T cell dependent and independent.
  
  • Describe the plasma cells they produce.
  • Give an example of each.
• T independent B cells are produce in the ____ and recognise ______ ______ as bacteria. They mostly produce ___ antibodies.

Answer 20

• Stem cell → Pro B cell → Pre B cell → Immature B cell → Migrates from bone marrow and matures in the periphery → Evolves some more steps → Memory B cell → Plasma blast cell → Plasma cell (which produces antibodies).
• Using flow cytometry.
• T cell dependent and T cell independent; T cells assist the B cell in the production of antibodies.
  
  • DEP’T: Long-lived plasma cells; Follicular B cells.
  • INDEP’T: Short-lived plasma cells; Marginal zone B cells.
• T independent B cells are produce in the spleen and recognise sugar moieties as bacteria. They mostly produce IgM antibodies.

Question 21

Describe the role antibodies play in the formation of vaccines.

Answer 21

• Antibodies are used as therapeutic agents and induced in vaccines.
• Inject person with inactive form of pathogen leads to formation of antibodies so when it experiences the ACTIVE form of pathogen, it can attack it.