Cell Damage and Cell Death

Question 1

Outline the genetic causes of cell damage / death

Answer 1

Genetic

• Abnormal number chromosomes (aneuploidy)
• Abnormal chromosomes (deletions/translocations)
• Increased fragility (Fanconi’s anaemia)
• Failure of repair (Xeroderma pigmentosa)
• Inborn errors (Storage disorders ie. Tay Sachs disease)

Question 2

Give examples of traumatic damage that can cause cell death and damage

Answer 2

Traumatic Damage

• Interruption of blood supply
• Direct rupture of cells
• Entry of foreign agents

Question 3

What physical factors can cause cell death and damage?

Answer 3

Physical

• Irradiation
• Heat
• Cold
• Barotrauma

Question 4

Which chemicals cause cell damage?

Answer 4

Chemical

• Acids/corrosives
• Specific actions e.g. enzymes
• Interference with metabolism e.g. alcohol

Question 5

How can inflammation lead to cell death and damage?

Answer 5

Inflammation

• Trauma
• Thrombo-embolism
• Atherosclerosis
• Vasculitis

Question 6

Outline how infection can induce cell death and damage

Answer 6

Infection
- Toxic agents 
- Competition for nutrients 
- Intracellular replication 
  > viruses/mycobacteria provoking an immune response

Question 7

What mechanism is responsible for cell death?

Answer 7

Cell death is caused by three basic mechanisms:

1. Necrosis
2. Apoptosis
3. Autophagic cell death

Question 8

What is necrosis?

Answer 8

Necrosis: most common cause of cell death

Occurs after stresses such as ischemia, trauma, chemical injury

Question 9

What is apoptosis?

Answer 9

programmed cell death
Designed to eliminate unwanted host cells through activation of a co-ordinated, internally programmed series of events affected by a dedicated set of gene products

Question 10

What is autophagic cell death?

Answer 10

Autophagy is responsible for degradation of normal proteins involved in cellular remodeling found during metamorphosis, aging and differentiation

Also used for digestion and removal of abnormal proteins that can accumulate following toxin exposure, cancer, or disease

Question 11

Give an example of autophagy

Answer 11

An example is the death of breast cancer cells induced by Tamoxifen.

Question 12

What are the causes of necrosis?

Answer 12

Usually caused by lack of blood supply to cells or tissues, e.g.

• injury
• infection
• cancer
• infarction
• inflammation

Question 13

Explain how lack of blood flow can induce necrosis

Answer 13

pH and po2 levels decrease the further from a vessel - dagerous for cells

Question 14

Which cells are affected by necrosis?

Answer 14

Whole groups of cells are affected following an injurious agent or event

Question 15

Outline the process of necrosis

Answer 15

Reversible events proceed irreversible.

1. Energy deprivation causes changes. (e.g. cells unable to produce ATP because of oxygen deprivation)
2. Cells swell due to influx of water (ATP is required for ion pumps to work).
3. Haphazard destruction of organelles and nuclear material by enzymes from ruptured lysosomes.
4. Cellular debris stimulates an inflammatory cell response

Question 16

What are the types of microscopic changes in cell appearance associated with necrosis?

Answer 16

• nuclear changes
• cytoplasmic changes
• biochemical changes

Question 17

Describe the nuclear changes that occur in cells during necrosis

Answer 17

1. Chromatin condensation/shrinkage.
2. Fragmentation of nucleus.
3. Dissolution of the chromatin by DNAse

Question 18

What changes occur to cell cytoplasm during necrosis?

Answer 18

1. Opacification: denaturation of proteins with aggregation.
2. Complete digestion of cells by enzymes causing cell to
   liquify (liquefactive necrosis).

Question 19

What are the biochemical changes seen in necrotic cells?

Answer 19

1. Release of enzymes such as creatine kinase or lactate dehydrogenase
2. Release of proteins such as myoglobin

Question 20

What is the significance of the biochemical changes that occur during necrosis?

Answer 20

These biochemical changes are useful in the clinic to measure the extent of tissue damage

Question 21

What is astrocytoma?

Answer 21

Frequent brain tumour: highly progressive and diagnosis is low

Question 22

How do astrocytomic cells appear?

Answer 22

Can see the opacification of necrotic tissue due to denaturation of proteins causing a darker appearance

The tumour is evading the normal histology of the brain cells

Question 23

Describe the differences seen in stained glomeruli of normal and necrotic kidneys

Answer 23

Normal glomeruli; can see dark staining where cell nuclei are present

Necrotic glomerul; doesn’t stain as well as DNA is degraded

Question 24

What are the functions of necrosis?

Answer 24

Removes damaged cells from an organism

Failure to do so may lead to chronic inflammation

Question 25

What are the functions of apoptosis?

Answer 25

Selective process for the deletion of superfluous, infected or transformed cells

Question 26

What other processes is apoptosis heavily involved in?

Answer 26

• Embryogenesis
• Metamorphosis
• Normal tissue turnover
• Endocrine-dependent tissue atrophy
• A variety of pathological conditions

Question 27

What is the purpose of apoptosis in embryonic hands?

Answer 27

Cell death in the embryonic hand forms individual fingers.

Question 28

What is the role of growth factor in apoptosis?

Answer 28

Apoptosis can be induced by growth factor deprivation e.g.(neuronal death from lack of NGF)

Question 29

Explain DNA damage-mediated apoptosis

Answer 29

If DNA is damaged due to radiation or chemo therapeutic agents, p53 (tumour suppressor gene product) accumulates.

This arrests the cell cycle enabling the cell repair the damage. If the repair process fails, p53 triggers apoptosis

Question 30

Give examples of pathologies that induce apoptosis?

Answer 30

Cell death in tumours causing regression.

Cell death in viral diseases (ie viral hepatitis).

Question 31

How does the immune system contribute to apoptosis?

Answer 31

Cell death induced by cytotoxic T cells (ie. Cellular immune rejection or graft vs. host disease).

Death of neutrophils during an acute inflammatory response.

Death of immune cells( both T and B lymphocytes) after depletion of cytokines as well of death of autoreactive T cells in the developing thymus..

Question 32

Which factors promote cell survival ?

Answer 32

• cell-cell and/or cell-matrix contacts
• growth factors
• cytokines

Question 33

Which factors promote apoptosis ?

Answer 33

• disruption of cell-cell and/or cell-matrix contacts
• lack of growth factors
• death domain ligands
• DNA damaging agents

Question 34

What are the 2 types of apoptosis?

Answer 34

• Intrinsic; triggered from within a cell

- Extrinsic; stems from outside the cell

Question 35

Outline the intrinsic causes of apoptosis

Answer 35

• DNA damage (p53 dependent pathway)
• Cell cycle interruption
• Protein synthesis inhibition
• viral infection
• change in redox state

Question 36

Outline the extrinsic causes of apoptosis

Answer 36

• Withdrawal of growth factors (e.g. IL-3)
• Extracellular signals (e,g, TNF)
• T-cell / NKs (e.g. Granzyme)

Question 37

What are caspases?

Answer 37

(Cysteine Aspartate-specific Proteases)

Caspases are Cysteine Proteases that play a central role in the initiation of apoptosis

Question 38

How are caspases synthesised?

Answer 38

Most proteases are synthesised as inactive precursors requiring activation (usually partial digestion by another protease).

Question 39

How is apoptosis regulated?

Answer 39

Apoptosis is mediated by an intracellular proteolytic cascade

Question 40

Outline how inactive Caspase precursors are activated

Answer 40

1. Inactive caspase Y is activated via cleavage at the
   amino and carboxyl terminals by active caspase X
2. Due to the cleavage there are 2 parts of now active
   caspase Y which form a dimer
3. The dimer can go on to degrade further substrates

Question 41

Describe the caspase cascade

Answer 41

Inside cells active initiator caspase (8/9) leads to procaspase Y activation which goes on to cleave further effector caspases (1,3,6,7)

Question 42

What are the caspase substrates involved in the apoptotic caspase cascade?

Answer 42

The caspase substrates are as following:

Procaspase Y start to cleave cytosolic proteins (actin filaments, microfilaments)

Effector caspases cleave nuclear lamin

Question 43

What is the result of caspase (8/9) activation?

Answer 43

Caspase activation leads to characteristic morphological changes of the cell such as shrinkage, chromatin condensation, DNA fragmentation and plasma membrane blebbing.

Question 44

Describe the morphological changes seen in cells undergoing apoptosis

Answer 44

Seen via TEM (transmission electron micrograph)
- Virtually lost all actin filaments and cells become
rounded blobs

Seen via SEM (scanning electron micrograph)
- Bulges form on cell surface containing intact organelles
(mitochondria etc.)
- Bulges bud off the cells and are recognised by
phagocytes and macrophages - will be engulfed and
removed

Question 45

What is the major difference in necrosis and apoptosis mechanisms?

Answer 45

Unlike necrosis there is no inflammatory response as budding off cells removed by macrophages

Question 46

How can DNA fragmentation via gel electrophoresis be used to see apoptotic and necrotic cells?

Answer 46

A population of healthy cells is obtained, and the genomic DNA is purified and treated with an apoptotic agent → DNA ladders form

Question 47

Describe what we see in DNA fragmentation of apoptotic cells?

Answer 47

During apoptosis we can see an orderly degradation of protein and compounds

Question 48

How do necrotic cells appear in DNA fragmentation?

Answer 48

In necrosis we see a DNA smear as opposed to a ladder - due to the fact in necrosis all the enzymes are released and degradation occurs at once; no nucleosome particles

Question 49

Which cells undergo apoptosis?

Answer 49

Single or few cells selected for programmed cell death.

Events are energy driven
Irreversible once initiated

Question 50

Outline the process of apoptosis

Answer 50

1. Cells shrink as the cytoskeleton is disassembled.
2. Orderly packaging of organelles and nuclear fragments
   in membrane bound vesicles.
3. New molecules expressed on vesicle membranes
   stimulate phagocytosis, no inflammatory response.

Question 51

How many substrates activate initiator caspase complexes to induce apoptosis?

Answer 51

Apoptosis = “Death by a thousand cuts”

• Hundreds of substrates for activated caspases
• Substrates fall into most classes of important genes

Question 52

What activates caspases to induce apoptosis?

Answer 52

Initiator caspases are activated by induced proximity

Question 53

How are caspases brought in close proximity of one another to induce apoptosis?

Answer 53

Extrinsic
- In response to receptor dimerisation upon ligand binding

or

Intrinsic
- Cytochrome C release from the mitochondria.

Question 54

Outline the substrates involved in the extrinsic ligand-induced dimerisation of caspases

Answer 54

Transmembrane receptor has 2 domains:

1. Ligand binding domain on extracellular surface
2. Death domain located intracellularly

The Death adaptor protein also has 2 domains:

1. death domain
2. death effector domain

Cells express all of these components but the system is not functioning until they receive TNF (Tumour necrosis factor)

Question 55

Outline the mechanism of action of ligand-induced dimerisation

Answer 55

1. TNF released
2. The transmembrane receptor death domain forms a
   dimer with a death adaptor protein
3. The death effector domain binds to the protease
   domain of the initiator caspase (e.g. procaspase 8)
4. Autoproteolysis of procapsase into caspase 8

Question 56

What is the role of TNF in the extrinsic pathway of caspase activation?

Answer 56

TNF induces the formation of a death-inducing signalling complex = DISC

TNF allows dimerisation of the ligands to bring adaptor proteins and caspases together.

Question 57

What is the result of cells being exposed to TNF?

Answer 57

As a result of the caspases being brought in close proximity, autoproteolysis occurs forming active caspase 8 → induces caspase cascade

Question 58

What is cytochrome c?

Answer 58

Mitochondrial matrix protein that also induces apoptosis

Question 59

How is cytochrome C released?

Answer 59

Known for many years to be released in response to oxidative stress by a “permeability transition”

Any inducers of the permeability transition also eventually induce apoptosis

Question 60

What are the substrates for the intrinsic apoptosis pathway?

Answer 60

Cytochrome C from mt. matrix

APAF protein in cell cytoplasm has 3 domains:

1. Cytochrome C binding site
2. APAF domain
3. Caspase recruitment domain (CARD)

Question 61

Outline the intrinsic apoptosis pathway

Answer 61

1. CARD binds procaspase 9 molecules
2. Cytochrome c released from mitochondria induces the
   formation of a death-inducing complex
3. Causes dimerization of 2 APAF molecules allowing
   procaspase 9 molecules to be in very close proximity
4. Procaspase 9 molecules in close proximity induce
   autoproteolysis and cleave each other to produce active
   procaspase 9

Question 62

What is Procaspase 9?

Answer 62

Procaspase 9 is a precursor expressed in cells; not yet active

Question 63

How is cytochrome C release regulated?

Answer 63

Cytochrome C release form mitochondria is regulated by a family of bcl-2 proteins

Question 64

What is bcl-2?

Answer 64

bcl-2 is a member of a 7 multi-gene family in mammals

The bcl-2 family members form dimers
Homodimers with themselves or heterodimers with other family members

Question 65

What is the role of bcl-2 proteins?

Answer 65

Mainly form dimers with anti-apoptotic proteins favouring life in the cells

When pro-apoptotic dimers form cells undergo apoptosis

Or can have a balance between anti-apoptotic and pro-apoptotic

Question 66

How do bcl-2 family proteins mediate cytochrome c release?

Answer 66

Within cell cytoplasm (cytochrome C in mitochondrial lumen)

1. Bax protein forms homodimers on mitochondrial
   membrane with pores in the middle
2. Pore is large enough to allow cytochrome C
   transportation from lumen to cytoplasm to activate
   APAF/Caspase 9 inducing apoptosis
3. Bcl-2 (anti-apoptotic protein) forms a dimer with pro-
   apoptotic Bax protein => forms a lid on the pore
4. Cytochrome C isn’t able to pass through so is
   maintained in mitochondria

Question 67

What is cell survival dependent upon?

Answer 67

Cell survival is dependent on cells receiving the correct survival signals in the right environment

Question 68

What is the result of correct cell signalling?

Answer 68

If correct signalling is occurring, an intracellular survival signal Akt/PKB is activated to phosphorylate the Bad protein rendering it inactive => cell survives

Question 69

What is the consequence of incorrect cell signalling?

Answer 69

If survival signals aren’t received, PKB no longer works, Bad is dephosphorylated and is able to dimerise with other family members => apoptosis

Question 70

How is cell signalling induced apoptosis regulated?

Answer 70

There are equal numbers of pro-apoptotic and antiapoptotic proteins = there is competition between them

Question 71

Explain how dimeristaion of certain bcl-2 family proteins due to cell signalling can induce apoptosis

Answer 71

Bad can bind to bcl-2; removes lid allowing cytochrome C to pass and activate caspase-9
⇒ apoptosis

Question 72

What is the significance of P53?

Answer 72

Mutations in the p53 gene are the most common mutations in cancer.

Some mutations destroy the ability of p53 to induce apoptosis.