Cancer and stem cells

Question 1

Where are all the precursors of the cell types of the body?

Answer 1

In the 3 germ layers

Question 2

When do the pluripotent cells start differentiating?

Answer 2

During gastrulation

Question 3

What happens to the stem cells when they leave the niche?

Answer 3

They begin to differentiate and give rise to more specialised cell types

Under the influence of pro-differentiation signals

Question 4

What development does the cell cycle drive?

Answer 4

BOTH embryonic and postnatal development

Question 5

What genes disrupt the cell cycle?

Answer 5

• Oncogenes: capable of transforming a normal cell –> cancer cell when ACTIVE
• TSG: restrict proliferation when active (mutations inactivate)

Question 6

What are carcinogenic factors?

Answer 6

1) Chemical:
- Smoking

2) Parasites

3) Radiation:
- UV
- Ionising

4) Viruses:
- HPV
- HBV

Question 7

What are carcinogenic factors capable of?

Answer 7

Activating oncogenes

Inhibiting TSGs

Question 8

Describe the appearance of tumours

What does this mean?

Answer 8

Heterogeneous

Cells in the SAME tumour exhibit DIFFERENCES in terms of:

• Differentiation rate
• Proliferation rate
• Migratory and invasive capacity
• Size
• Therapeutic response
• Tumourgenicity

Question 9

What is ‘intra-tumour heterogeneity’

Answer 9

Differences between cells in the same tumour

Question 10

What is ‘inter-tumour heterogeneity’?

Answer 10

Differences between DIFFERENT tumours

Question 11

How is the heterogeneity between tumours explained?

Answer 11

2 different models:
1) Stochastic

2) Cancer stem cell model

Question 12

What is the stochastic model for cancer?

Answer 12

States that ALL tumour cells are EQUIPOTENT and can either differentiate or self-renew

Cells have unlimited proliferative capacity

ALL the cells of a tumour are tumour-initiating

All tumour cells are EQUALLY SUSCEPTIBLE to treatment (all have the same proliferative potential, all can be targeted by anti-proliferative drugs)

Question 13

What does equipotent mean?

Answer 13

Equal capacity to differentiate

Question 14

What are the problems with the stochastic model for cancer?

Answer 14

Tumours tend to RECUR after treatment, indicating:

• Not all cells are EQUALLY vulnerable to anti-proliferative treatments (some are differentially resistant to the drugs)

Question 15

What is the cancer stem cell model for cancer?

Answer 15

States that only a SUBSET of tumour cells have the ability for long-term self renewal and therefore cancer formation

These cells give rise to COMMITTED progenitors with LIMITED proliferative potential that will eventually terminally differentiate

Question 16

What does the cancer stem cell model form?

Answer 16

A hierarchy of differentiation:

• Tumour stays heterogenous
• Small reservoir os slowly proliferating CSCs

Question 17

What are the therapeutic implications of the cancer stem cell model of cancer?

Answer 17

1) CSCs represent a very SMALL fraction of the cells in the tumour
2) If treat the cancer with drug that kills mainly proliferating cells - CSCs ESCAPE treatment

Question 18

Why do CSCs escape the drug treatment that kills mainly proliferating cells?

Answer 18

CSCs are slowly proliferating/dormant

Resistant to the treatment

Question 19

How can normal stem cells be functionally tested?

Answer 19

Ability for functional reconstruction

Question 20

How can cancer stem cells be functionally tested?

Answer 20

Ability to initiate a tumour

Question 21

What is the difference between the need for self-renewal in normal stem cells and cancer stem cells?

Answer 21

Normal - needed in order to maintain HOMEOSTASIS

Cancer - serves as a tool for TUMOUR GROWTH

Question 22

What is the difference/similarities between the regulation of normal stem cells and cancer stem cells?

Answer 22

Similarities: Same signalling pathways (eg. Wnt)

Differences: Cancer - ELEVATED signalling

Question 23

What are the different possibilities for a cancer cell to arise?

Answer 23

1) REPROGRAMMING event:
- One or more genetic/epigenetic transformation events that drive specialised cells (differentiated from stem cells) BACK into cancer stem cell entity
- Gives the cells capacity for self-renewal and differentiation
2) ONCOGENIC transformation:
- Normal stem cell transformed into a CSC that fuels tumour growth
- Through number of genetic/epigenetic transformations

Question 24

Are the 2 mechanisms that can cause cancer mutually exclusive?

Answer 24

NO - they can happen in the SAME tumour

BUT, different cancers can be driven by one more than the other

Question 25

What 2 features allow cancer stem cells to be characterised?

Answer 25

1) In VITRO potential (Establish cell lines that can self-renew and differentiate)
2) In VIVO potential (Ability to give rise to cancer following transplantation into animals)

Question 26

What is acute myeloid leukaemia?

Answer 26

Blood cancer affecting the myeloid lineage

Question 27

What do haemopotetic stem cells give rise to?

Answer 27

ALL blood cells

Question 28

Where is the niche for haemopotetic stem cells?

Answer 28

In the bone marrow

Question 29

How are haemopotetic stem cells characterised?

Answer 29

By the POSITIVE expression of CD34

By the NEGATIVE expression of CD38

Question 30

What assay for testing HSCs ability?

Answer 30

• Take mice lacking the immune system and sub-lethally radiate the mouse to wipe of the HPC system
• -> eventually the mice DIE

BUT
- If transplant a SINGLE HSC into the mouse - can rescue the ENTIRE haematopoietic system

Question 31

What happens to the Haemopoietic cell in leukemia?

Answer 31

• Undergoes ONE or MORE transformation events under the influence of genetic drivers

–> TRANSFORMED into a leukemic stem cell that has the ability to self-renew and differentiate
(With a biast differentiation to the myeloid lineage)

Question 32

What happens if transplant a leukemic stem cell into an immunocompromised mouse with no HP system?

Answer 32

Generate BLOOD CANCERS in the mouse

Question 33

What is glioblastoma?

Answer 33

An aggressive and invasive BRAIN CANCER

Question 34

What is the treatment for glioblastoma?

Answer 34

• Surgical resection
• Radition
• Chemotherapy

Question 35

As glioblastomas are heterogenous, what idea did this bring forward?

Answer 35

That they are driven by stem cells (cancer stem cell model)

In the stochastic model - all the cells are EQUAL (not driven by CSCs)

Question 36

How can multi potent stem cells be captured in vitro?

Answer 36

• Dissociate the cells from a brain

- Plate the cells of laminin in the presence of cytokines: FGF2 and EGF

Question 37

What are the undifferentiated markers for NS cells?

What are these cells negative for?

Answer 37

RC2

Negative for differentiation markers: GFAP (glia) and TUJ1 (neurons)

Question 38

Can we isolate glioblastoma stem cells using the same methods as isolating NSCs?

Why?

Answer 38

Yes

As glioblastoma is driven by NS cells - NS cells are transformed into CSCs

Question 39

Describe the glioblastoma stem cells are isolated

What does this produce?

Answer 39

Dissociate the cells from the glioblastoma and CULTURE them under the SAME conditions as the NSCs
(On laminin, in the presence of cytokines)

Produces self-renewing GBM colonies that express undifferentiated markers - Indicating the self-renewal stage

Question 40

What are the undifferentiated markers of GBM colonies?

Answer 40

Nestin/Sox2

Question 41

What happens if remove the self-renewal factors from the GBM colonies?

Answer 41

Forces the GBM stem cells to DIFFERENTIATE

Question 42

What do the GBM glial cells express?

Answer 42

GFAP

Question 43

What do the GBM neural precursors express?

Answer 43

Dcx

Question 44

What is the difference between GBM cells and normal NSCs?

Answer 44

DIFFERENT tumours give rise to DIFFERENT GBM stem cell lines with DIFFERENT capacities for differentiation

Question 45

What does the injection of undifferentiated GBM stem cells into the brain of mice cause?

Answer 45

GBM-like tumour

Question 46

What can in vitro cancer cell systems be used for?

Example?

Answer 46

Drug screens - to identify suitable drugs to treat the tumours:
- Identify molecules that create/block a certain phenotype

Example:
- GBM and normal foetal NS cells - look similar when untreated

• Treat with INDATRALINE: selectively kills the GB cells through growth arrest, with a less severe effect on the NS cells

Question 47

What are the 3 main approaches to study cancer?

Answer 47

1) Xenograft models - Inject tumour cells into a permissive environment (eg. kidney)
2) Cancer cell lines in the petri dish - form tumours
3) Genetically modified animals - Manipulated to over express oncogenes or TSG mutations

Question 48

What are the limitations of using cell lines and animal models to study cancer?

What can be a solution to these problems?

Answer 48

• Failure to capture the TRANSITION from a normal to a tumourgenic phenotype in:
  A traceable manner
  In human context
• Lack of mechanistic insight (mechanism that drives the process)

Solution:
- iPS cells

Question 49

How can iPS be used to study cancer?

Answer 49

1) iPS from patients that carry the tumour
- iPS represents the early emrbyonic stem cells of these patients
2) Can introduce oncogenic mutation into the human pluripotent stem cell

These cells differentiate into the cell origin of the tumour:
- Can examine the phenotype and look for the hallmarks of cancer

Question 50

What are the hallmarks of cancer?

Answer 50

• Sustained proliferation
• Impaired differentiation
• Formation of a cancer if transplant into a permissive environment

Question 51

What is neuroblastoma?

Answer 51

Common solid tumour in infants/young children

Above the kidney, in the adrenal gland
Or
Around the spinal cord

Question 52

Where does neuroblastoma originate from?

Answer 52

The neural crest

Question 53

What do aggressive neuroblastomas express?

What is this?

Answer 53

High levels of the transcription factor MYCN

An oncogene

Question 54

What does ectopic expression of MYCN in normal neural crest cells in the mouse cause?

Answer 54

Neuroblastoma-like tumours

Question 55

Where do the neural crest cells come from?

Answer 55

The ECTODERM

Question 56

What is the main marker of neural crest cells?

Answer 56

Sox10

Question 57

How can the production of neural crest cells be mimicked using iPS cells in vitro?

Why do we want to do this?

Answer 57

Capture iPS cells in conditions that promote neural crest emergence in the neural tube (Wnt, BMP)

Want to do this in order to study neuroblastoma:
- Want to see what happens during the transformation from a neural crest into a neuroblast

• BUT, this can’t be seen in vitro
• May be able to instead, differentiate iPS cells –> neural crest and over express MYCN to get the neuroblastoma phenotype

Question 58

What does the capture of iPS cells in conditions that promote neural crest emergence in the neural tube (Wnt, BMP) generate?

What happens if over express MYCN in these cells?

Answer 58

Cells that represent the neural crest and express Sox10

If over express MYCN:
- Higher colonic efficiency

• Differentiate faster compared to control
• If graft into a mouse –> form a tumour that represents human neuroblastoma

Question 59

What method could be used to found the mechanism from the neural crest to transformed neuroblastoma cells?

Answer 59

• Differentiate iPS cells –> neural crest

- Over express MYCN –> get the neuroblastoma phenotype

Question 60

What is ‘colonic efficiency’?

Answer 60

If take cells and re plate them - give rise to more colonies