Cell death/repair & acute inflammation

Question 1

Discuss different forms of cell death

Answer 1

Apoptosis → programmed and normally silent to limit damage spread
Necrosis → injurious and can initiate inflammation due to the uncoordinated and unconfined nature of death

Question 2

What is irreversible injury characterised by?

Answer 2

• extensive cell swelling and resultant blebbing which eventually causes the cell to burst
• protein aggregation
• ER lysis
• spillage of the enzymatic contents into the cytoplasm for autolysis
• further mitochondrial swelling

Question 3

What does irreversible injury lead to?

Answer 3

necrotic lysis and release of cell contents into the EC space → further damage to other cells and inflammation

Question 4

Why is there an increase in Ca2+ in necrosis? What can this Ca2+ do?

Answer 4

• loss of membrane function

- can activate enzymes (proteases and phospholipases) which further break down the membrane and there is a vicious cycle

Question 5

Roles of apoptosis

Answer 5

Normal tissue homeostasis
Embryonic morphogenesis (digits)
Deletion of self-reactive lymphocytes (during T cell development)

Question 6

What cytokines are release in necrosis and apoptosis?

Answer 6

Apoptosis → TGFB (promote repair)

Necrosis → TNF, IL-1, IL-8 (inflammation)

Question 7

What are the 5 cardinal signs of inflammation?

Answer 7

1 - Heat (brought about in the tissue by vasodilation and blood flow through peripheral vessels)
2 - Redness (vasodilation)
3 - Swelling (caused by formation of an inflammatory exudate - oedema, resulting from increased capillary permeability)
4 - Pain (released chemical mediators acting on nociceptve fibres)
5 - Loss of function (caused by the inflammation itself and not the processes which it brings about)

Question 8

How long does acute inflammation last?

Answer 8

Minutes-days

Question 9

What is the general function of acute inflammation?

Answer 9

To facilitate recruitment of neutrophils to sites of pyogenic bacterial infection and enable them to phagocytose and kill the organisms

Question 10

Describe the histology of acute inflammation

Answer 10

• vasodilation
• oedema
• adhesion of PMN to venule walls
• cellular infilatration by PMN and macrophages
• Formation of pus

Question 11

What are the key players for acute inflammation?

Answer 11

Neutrophils and mast cells

Question 12

What are the key players in chronic inflammation?

Answer 12

Macrophages and lymphocytes

Question 13

What three classes of mediator are important in acute inflammation?

Answer 13

Cytokines
Peptides and proteinase cascades
Lipids

Question 14

What are the major proinflammatory cytokines? What do they do?

Answer 14

TNF alpha - leads to activation of vascular endothelial cells and increased vascular permeability, as well as increased blood clotting locally

Interleukin 1B - activates vascular endothelial cells and lymphocytes, results in local tissue destruction

IL-6 - endothelial cell activation

Question 15

Describe the cascades there are of plasma protein

Answer 15

1. Coagulation system - clotting cascade
2. Fibrinolysis system - acts to counterbalance clotting
3. kinin system - generates porteins capable of sustaining vasodilation and other inflammatory effects (bradykinin)
4. Complement system - promotes chemotaxis, opsonisation and formation of the MAC

Question 16

Describe opsonisation. What is an opsonin?

Answer 16

An opsonin is any molecule that enhances phagocytosis by marking an antigen for an immune response or my marking dead cells for recycling

When antigen is coated with opsonins, binding to immune cells is greatly enhanced

Question 17

How may lipids be important in acute inflammation?

Answer 17

Membrane phospholipids (e.g. in platelets and leukocytes) provide the substrate (arachidonate) for prostaglandin, thromboxane and leukotriene protein but the COX and lipo-oxygenase pathways respectively

Question 18

Describe the main roles of the inflammatory mediators? Which mediators have what effects?

Answer 18

Vasodilatation – Histamine and prostaglandins

Vascular leakage – Histamine, Leukotriene C4 (LTC4), LTD4 and C5a

Endothelial cell activation – IL-1, TNF-a, IL-6 and LPS

Chemotaxis – LTB4, C5a, PAF (Platelet Activating Factor) and chemokines

Pain – Bradykinin and prostaglandins

Tissue damage – Free radicals and leukocyte enzymes

Question 19

What is the process of leukocyte movement from the blood to the tissue called?

Answer 19

Extravasion

Question 20

What steps does extravasion consist of?

Answer 20

Margination
Leukocyte rolling 
Leukocyte actication
Leukocyte tight adhesion 
Diapedesis (leukocyte extravasion)
Chemotaxis

Question 21

Describe margination

Answer 21

It is movement along the endothelium
Occurs due to stasis - condition characterised by enlarged vessels packed with cells - allows leukocytes to move to the endothelium

Question 22

Describe leukocyte rolling

Answer 22

• Normal physiological process
• Mediated by low-affinity interactions between L-selectins on the leukocytes and their carbohydrate counter-ligands on the endothelium
• the marginal affinity causes the leukocytes to slow down and begin rolling along the inner surface of the vessel
• during rolling, transitory beongs are formed between selectins and their ligands

Question 23

What serves to increase rolling during inflammation?

Answer 23

• Endothelial cells have P-selectin and E-selectin which interact with P-selectin ligands and PMN carbohydrates on the leukocyte respectively
• P selectins are released from storage granules of the endothelial cells in response to histamine or thrombin
• E selectin is upregulated by TNF-alpha, IL-1 and LPS

Question 24

Describe leukocyte activation and tight adhesion

Answer 24

• activation = rapid, occuring in a number of seconds via various GPCRs (chemokine, C5a, fMLP, LTB4 and PAF receptors)
• Activation = increase beta2 integrins which for tight interactions
• these can bind to endothelial cell receptors (e.g. ICLAM)
• this halts rolling

Question 25

Describe diapedesis

Answer 25

• leukocytes arrested on endothelial surface
• integrins promotes spreading of leukocytes across the endothelial surface
• they extent pseudopodia and migrate through vessel wall
• This migration is driven by chemokines
• After passing through, leukocytes secrete collagenase (macrophages) and elastase (neutrophils) that enables them to pass through the vascular basement membrane

Question 26

Describe chemotaxis. What substances can be chemotactic? What are these mediators produced in response to?

Answer 26

Bacterial products, particularly peptides with N-formyl-methionine termini

Cytokines, especially those of the chemokine family – E.g. Il-8

Components of the complement system, particularly C5a

Products of the lipoxygenase pathway of arachidonic acid metabolism, particularly LTB4

They are produced in response to infections and tissue damage

Question 27

How do leukocytes move?

Answer 27

By extending pseudopods that anchor to the ECM and then pull in the direction of the extension

Question 28

How may leukocytes lead to tissue damage?

Answer 28

• bystander tissues may be damaged in normal defensive reaction
• may be damaged in an attempt to clear dead and damaged tissues
• autoimmunity

Question 29

Describe the systemic effects of acute inflammation

Answer 29

Fever – Through the action of cytokines such as TNF and IL-1 at the hypothalamus

Chills/rigor

Other CNS – Loss of appetite and fatigue

Cardiovascular system – Tachycardia, increased cardiac output and increased endothelial permeability leading to hypotension

Metabolic – Hepatocytes secrete acute phase proteins, such as C-reactive protein, fibrinogen and complement proteins

Endocrine – Stress response is triggered leading to the secretion of corticosteroids and thyroxin

Leukocytosis – Cytokines stimulate production of leukocytes from precursors in the bone marrow

Plasma cascades – Intravascular coagulation and complement consumption

Long term – Wasting/cachexia

Question 30

Describe endotoxic shock

Answer 30

The LPS (endotoxin) present on the Gram-negative bacteria binds to the monocyte CD14 receptor, triggering signaling via TLR4 to produce the inflammatory mediators TNF-a, IL-1, IL-6 and IL-8 systemically. The systemic presence of these cytokines leads to a number of systemic effects, including fever, endothelial damage, capillary leakage, hypotension and systemic activation of the coagulation cascade leading to disseminated intravascular coagulation. As a result, there is hypoperfusion of many of the major organs systems, resulting in multiorgan system failure and potentially death.

Question 31

Describe some inhibitors of proteinases

Answer 31

The main local and systemic defences against PMN-inflicted proteolytic injury include a range of inhibitors of proteinases, such as a2-macroglobulin, a1-antitrypsin and a2-antiplasmin

Question 32

Role of C3a

Answer 32

Produces anaphylotoxic which activates mast cells and basophils to release histamine

Question 33

Role of C5a

Answer 33

Chemotaxis

Question 34

What may macrophages be activated by?

Answer 34

1. Endotoxin, IFN-gamma, IL-4, IL-3
2. Proinflammatory cytokines (TNF-a, IL-1, IL-6)
3. Other cytokines (IL-10, IL-12)

Question 35

Give an example of non-oxygen dependent tkilling mechanisms employed by neutrophils

Answer 35

Antimicrobial peptides, e.g. LL-37 found in lysosomes

Destroys the lipoprotein membranes of microbes enveloped in phagosome after fusion with lysosomes in macrophages

Question 36

Describe chronic granulomatous disease

Answer 36

Occurs where cells of the immune system (neutrophils and macrophages) cant form reactive oxygen compounds (most importantly, the superoxide radical due to defective NADPH oxidase)
No respiratory burst
This leads to the formation of granulomas in certain organs

Question 37

Which components of complement are opsonins?

Answer 37

C3b and C4b

Question 38

How may the complement cascade interact with the coagulation cascade?

Answer 38

FXa and FXIa also cleave C3 and C5 into C3a and C5a

Question 39

How does complement interact with the kinin cascade?

Answer 39

They have a common contrl mechanism

the inactivator of C5a and C3a anaphylotoxins is identical to a major plasma bradykinin inactivator