Cellular Killing Mechanisms

Question 1

What is phagocytosis?

Answer 1

A form of receptor-mediated endocytosis, used by phagocytes to internalise pathogens.

Question 2

What is the main difference between phagocytosis and other forms of endocytosis?

Answer 2

Phagocytosis allows uptake of larger materials.

Question 3

Describe internalisation in endocytosis.

Answer 3

Membrane budding around the material to be internalised.

Question 4

Describe internalisation in phagocytosis.

Answer 4

Relies on the membrane moving out towards the target and engulfing the target. Dependent on the actin cytoskeleton.

Question 5

Give the two types of phagocytic receptors.

Answer 5

Opsonin receptors and microbe receptors.

Question 6

What do opsonin receptors recognise?

Answer 6

Host-derived molecules that have been deposited onto the microbe, i.e. antibodies/complement.

Question 7

Give examples of opsonin receptors.

Answer 7

FcR - binds antibodies.

CR3 - receptor for C3 complement protein.

Question 8

What is the role of microbe receptors?

Answer 8

Bind microbial proteins found on the pathogen cell surface. Some can have both phagocytic and signalling functions.

Question 9

Give examples of microbe receptors.

Answer 9

CD14 - binds LPS.

Dectin-1 - binds fungal glucans.

Question 10

What is the nascent phagosome?

Answer 10

a very brief stage between the phagocytic cup and the early phagosome, in which the phagocytic cup first closes.

Question 11

Give the stages of phagosome maturation.

Answer 11

Phagocytic cup, nascent phagosome, early phagosome, late phagosome, phagolysosome.

Question 12

Why is the phagosome progressively modified?

Answer 12

To give an increasingly hostile environment which the microbe cannot survive in.

Question 13

How is phagosome maturation achieved?

Answer 13

Through progressive fusion of the phagosome with other distinct intracellular vesicles.
NP fuses with EE -> EP which fuses with LE -> LP which fuses with lysosomes -> phagolysosome.

Question 14

Describe the conditions of the phagolysosome.

Answer 14

pH 4.5, contains hydrolases, proteases, lipases and DNases, contains ROS-producing enzymes. High levels of v-ATPase activity.

Question 15

What gives vesicle identity?

Answer 15

Different vesicle surface proteins and phosphatidylinositides.

Question 16

What family of proteins are involved in vesicle identity?

Answer 16

Rab GTPases.

Question 17

How many Rab GTPases are encoded in the human genome?

Answer 17

35

Question 18

What is the partial vesicle code?

Answer 18

Different vesicle types are labelled by different Rab proteins - different Rabs are also found in different regions of the Golgi.

Question 19

Describe the phagocytic cup/nascent phagosome.

Answer 19

Derived strictly from the plasma membrane.
pH 7.4 - same as extracellular fluid.
High levels of PI(3,4,5)P3 in membrane.

Question 20

Describe the early phagosome.

Answer 20

Derived from fusion with early endosomes.
Has EEA1, Rab5 and PI3P.
Some v-ATPase present in membrane.
pH 6-6.5

Question 21

What is the role of EEA1?

Answer 21

Allows recruitment of Rab5 to early endosomes.

Question 22

What is the role of Rab5?

Answer 22

Recruitment of downstream maturation markers, and recruitment of Vps34.

Question 23

Why does the early phagosome have PI3P rather than PI(3,4,5)P3?

Answer 23

Rab5 recruits Vps34 lipid phosphatase - removes phosphate groups from inositol head group.

Question 24

What is the role of v-ATPase?

Answer 24

Uses ATP to move the proton gradient - decreasing the pH inside the phagosome.

Question 25

What are recycling endosomes?

Answer 25

Endosomes that remove the transferrin receptor from the early phagosome, and carry it back to the plasma membrane.

Question 26

Why must the transferrin receptor be removed from the early phagosome?

Answer 26

Transferrin receptor would allow transferrin and therefore iron uptake into the vesicle - removal of this from the phagosome deprives microbes of iron, causing microbe death.

Question 27

Give an example of a bacterium that has evolved not to use iron.

Answer 27

Borrelia burgdorferi - the bacterium that causes lyme disease.

Question 28

Describe the late phagosome.

Answer 28

Derived from fusion with late endosomes. 
Has Rab7 (replaced Rab5), LAMP1, M6PR and Lysobisphospatidic acid. 
Increased v-ATPase activity - pH lowered to 5-6.

Question 29

What markers is the phagolysosome positive for?

Answer 29

Rab7 and LAMP1.

Question 30

What is the outcome of phagosome maturation?

Answer 30

Progressive acidification and deposition of acid hydrolases - this is sufficient to kill most non-pathogenic bacteria.

Question 31

Why have we evolved to use cytokines to alter the phagolysosome conditions?

Answer 31

Some pathogenic bacteria are resistant to the normal conditions of the lysosome. Therefore, we evolved tp use cytokines to make the phagolysosome more efficient at bacterial killing.

Question 32

What are the signals that drive macrophages to adopt the M1 phagocytic programme?

Answer 32

TLR activation and IFNy released by T cells.

Question 33

What are the signals that drive macrophages to adopt the M2 phagocytic programme?

Answer 33

IL-4 and IL-13, released by T cells.

Question 34

What is the main biochemical difference between M1 and M2 macrophages?

Answer 34

M1 generate higher levels of ROS in their phagolysosome.

Question 35

Describe M1 macrophages.

Answer 35

Rapid ROS production due to rapid activation of NOX2 upon internalisation. Weaker v-ATPase activity.

Question 36

Describe M2 macrophages.

Answer 36

Lower activation of NOX2 (only acquired from plasma membrane), lower levels of ROS production, stronger v-ATPase activity. Still sufficient to kill many microbes.

Question 37

When are M1 macrophages used?

Answer 37

During serious infection.

Question 38

What is the cost of using M1 macrophages?

Answer 38

Increased tissue damage due to increased ROS production.

Question 39

When are M2 macrophages used?

Answer 39

During tissue repair.

Question 40

Why must NOX2 be rendered inactive across the plasma membrane?

Answer 40

Prevents oxidative stress.

Question 41

How and when is NOX2 activated?

Answer 41

By PI3P - only activated in the early phagosome.

Question 42

Describe the structure of NOX2.

Answer 42

gp91 catalytic subunit containing 2 b-type cytochromes, and the p22 subunit containing FAD. Requires accessory proteins -p40, p47 and p67 - for NADPH binding.

Question 43

What is the function of NOX2?

Answer 43

Reduces oxygen to superoxide, using NADPH as an electron donor.

Question 44

How are the accessory proteins recruited to NOX2?

Answer 44

p47 is phosphorylated during phagocytosis, exposing its SH3 domains to allow assembly with gp91/p22. Further level of control of NOX2 activity, where NOX2 can only bind NADPH upon phagocytosis.

Question 45

How can mitochondria synergise with the phagosome?

Answer 45

If TLRs 1, 2 or 4 are activated, mitochondria migrate to the phagosome, increasing ROS production in the phagosome of M1 macrophages.

Question 46

What do secretory granules provide the phagolysosome with?

Answer 46

Pore forming proteins and MPO.

Question 47

How are neutrophils recruited to the site of infection?

Answer 47

IL-8, released by macrophages.

Question 48

What are the killing mechanisms used by neutrophils?

Answer 48

Phagocytosis (similar to M1, with high NOX2 activity), and production of NETs.

Question 49

What do NETs consist of?

Answer 49

Nuclear DNA, histones, and toxic proteins from secretory granules.

Question 50

Are histones antimicrobial?

Answer 50

Yes - H2B and H4 are components of surfaceous gland secretion on the skin.

Question 51

Is extracellular DNA toxic?

Answer 51

Yes - it is a good chelator of cations and leads to disruption of the bacterial cell membrane, causing bacterial cell lysis.

Question 52

How long does it take neutrophils to release NETs?

Answer 52

2-3 hours.

Question 53

Why is NETosis thought to be a last resort action for neutrophils to take?

Answer 53

Neutrophils die in the process.

Question 54

Why is there controversy over whether or not neutrophils die during NETosis?

Answer 54

It has been claimed that neutrophils can release NETs in a non-lytic way, and remain viable and phagocytic (without a nucleus).

Question 55

What is the role of elastase in NET release?

Answer 55

Thought to be important in the decision to phagocytose or release NETs. Elastase is sequestered in the phagosome during phagocytosis, but triggers NET release if it translocates to the nucleus.

Question 56

Give examples of pathogens able to survive inside macrophages.

Answer 56

Legionella pneumophila and mycobacterium tuberculosis.

Question 57

Why have some pathogens evolved to live inside host cells?

Answer 57

Allows evasion of humoral immune defences and immune cells in circulation.

Question 58

How do pathogens manage to survive inside phagocytes?

Answer 58

Disruption of the vesicle maturation process.

Question 59

What is the main challenge faced by pathogens that escape vesicles altogether and live in the cytosol?

Answer 59

Inflammasome formation.

Question 60

How do some pathogens escape the phagosome to live in the cytosol?

Answer 60

By causing lysis of the phagosome.

Question 61

How can some pathogens induce phagocytosis in non-phagocytic cells?

Answer 61

By secreting effectors into epithelial cells that trigger the actin rearrangment that is required for internalisation.

Question 62

How does mycobacterium tuberculosis inhibit maturation at the early phagosome?

Answer 62

ManLAM - inhibits cytosolic Ca2+ fluctuations that are required for Vps34 activity.
SapM - dephosphorylates any PI3P produced, giving PI.

Question 63

How can macrophages still kill internalised mycobacterium tuberculosis, without further phagosome maturation?

Answer 63

If the macrophage is activated by IFNy, there will be enough ROS production to kill the bacterium in the early endosome.

Question 64

How does legionella pneumophila survive inside cells?

Answer 64

Lives in a modified vesicle (LCV) that acts like an element of the secretory pathway - 300 effectors secreted by dot/icm secretion system.

• RaIF recruits Arf1 (normally found on Golgi)
• LidA and DrrA recruit Rab1 (normally found on ERGIC)
• VipD binds Rab5, preventing EEA1 recruitment.

Question 65

How does listeria monocytogenes live inside non-phagocytic cells?

Answer 65

• lnlA and lnlB bind host cell surface proteins.
• LLO forms pores in the membrane, triggering membrane uptake for repair.
• PI-PLC degrades the vesicle once inside the cell.
• ActA recruits actin, allowing intracellular motility of listeria.

Question 66

Why do listeria recruit actin for intracellular motility?

Answer 66

Thought to allow evasion of the inflammasome. Also thought to allow spreading between cells - but it is unclear if this happens in vivo.