Oncogenes and tumour suppressor genes

Question 1

describe how the mutations oncogenes and tumour suppressor genes acquire have different effects but the same outcome

Answer 1

mutation in oncogenes make the gene permanently active

mutation in TSG make turn the gene off

these both result in the formation of a tumour

Question 2

describe how oncogenes gain function

Answer 2

alleles within the protooncogene gain ONE MUTATION = activation of oncogene

An oncogene will produce protein products in large quantities or with increased activity meaning they will act in a dominant manner = uncontrolled cell proliferation

Question 3

describe the discovery of rous sarcoma virus

Answer 3

• Frances Peyton Rous discovered Rous sarcoma virus (RSV)

• He took the sarcoma from the original chicken and injected it into a healthy chicken, a few weeks later the healthy chicken developed tumours (sarcoma)
• The filter he used excluded bacteria BUT was not small enough to exclude viruses, therefore he concluded that a virus must be responsible for the tumour formation (sarcoma)
• Therefore his discovery was that this sarcoma was transmissible through viruses
Thus = Rous Sarcoma Virus

Question 4

describe the discovery by Bishop and Varmus

oncogene hypothesis

Answer 4

oncogene hypothesis: an oncogene is any cellular gene that upon activation can transform cells

in their research they found that in the rous sarcoma infection:
• V-src = oncogene = cancer causing
• C-src = proto-oncogene was present in the genome of many species
• C-src gene was normally involved in the positive regulation of cell growth and cell division

HOWEVER following infection that the v-src oncogene was highly expressed, leading to:

• Uncontrolled host cell growth
• Unrestricted host cell division
• Cancer

Question 5

mechanism of rous sarcoma infection

Answer 5

• Reverse transcription of virus to form dsDNA provirus
• Provirus integrated into sequence adjacent to c-src (protooncogene)
• This is then packaged into v-src (oncogene) = responsible for causing cancer

Question 6

What did Bishop and Varmus discover about protooncogenes?

Answer 6

found that proto oncogenes are normal genes that can control cell growth

BUT

following exposure to carcinogens (chemicals, viruses, physical) they can become oncogenes = leading to uncontrolled growth and tumour formation

Question 7

how are viral oncogenes transmitted?

Answer 7

Viral oncogenes can be transmitted by either DNA or RNA viruses.

Question 8

what is the oncogene mechanism in Epstein-Barr virus?

Answer 8

Epstein-Barr virus can produce its own oncogene called LMP-1 which is ALWAYS switched on and feeds into survival pathways, therefore it promotes tumorigenesis

Question 9

what effect do DNA viruses have on the host cell

Answer 9

DNA viruses can cause lytic infection leading to the death of the cellular host
OR

can replicate their DNA along with that of the host and promote neoplastic transformation (tumour formation)

Question 10

difference between mechanism of DNA viruses and RNA viruses in oncogenesis

Answer 10

DNA VIRUSES:
- encode various proteins and (along with environmental factors) can initiate and maintain tumours

RNA VIRUSES:
- integrate DNA copies of their genomes into the genome of the host cell and as these contain transforming oncogenes they induce cancerous transformation of the host.

Question 11

what changes occur in proto oncogenes to become activated oncogenes

Answer 11

Different oncogenes have different mechanisms by which they are switched on

alteration to their sequence

· Mutations
Point mutation or deletion = alters structure or function of protein encoded by gene

· Insertions

· Amplifications
Gene duplication = increased synthesis of encoded protein

· Translocation
Increased synthesis of encoded protein

only ONE allele needs to be altered to activate the oncogene

Question 12

oncogene: L-myc

1. name the type of cancer
2. name the activation mechanism

Answer 12

lung cancer

amplification

Question 13

oncogene: PI3K

1. name the type of cancer
2. name the activation mechanism

Answer 13

Breast cancer

amplification

Question 14

oncogene: PML

1. name the type of cancer
2. name the activation mechanism

Answer 14

leukaemia

point mutation

Question 15

oncogene: B-raf

1. name the type of cancer
2. name the activation mechanism

Answer 15

melanoma

point mutation

Question 16

what do proto oncogenes encode and what is the function of the proteins they produce

Answer 16

Protooncogenes encode components (proteins) of the growth factor signal transduction pathway.

The majority of oncogene proteins function as elements of the signalling pathways that regulate cell proliferation and survival in response to growth factor stimulation.

Question 17

Protooncogenes encode components (proteins) of the growth factor signal transduction pathway. What are the four types of proteins involved in the transduction of growth signals?

Answer 17

1. Growth factors
2. Growth factor receptors
3. Intracellular signal transducers (eg- Ras oncogene family)
4. Nuclear transcription factors (eg-MYC oncogene family)

Question 18

what do oncogene proteins act as in the growth factor signal transduction pathway?

Answer 18

• growth factors (e.g.EGF)
• growth factor receptors (e.g. ErbB)
• intracellular signalling molecules (Ras and Raf)

Question 19

what is the function of Ras and Raf in the growth factor signal transduction pathway

Answer 19

Ras and Raf activate the ERK MAP kinase pathway, leading to the induction of additional genes (e.g. fos) that encode potentially oncogenic transcriptional regulatory proteins.

Question 20

How were Ras genes identified?

Answer 20

Identified from the studies of 2 cancer-causing viruses:

1. Harvey sarcoma virus
2. Kirsten sarcoma virus

These viruses were discovered originally in rats hence the name Rat sarcoma

Question 21

What are Ras proteins?

Answer 21

GTP binding protein that is normally bound to GDP in a neutral state (in its inactive form)

Ras-GDP = inactive 
Ras-GTP = active

Question 22

How are Ras proteins activated?

which codons are the mutations in? what does this alter? what type of cancer can each mutation lead to?

Answer 22

Oncogenic activation of Ras is seen in about 30% of human cancer

Most commonly activated by mutated oncogene
Point mutations in codons 12, 13 and 61

• Glycine –> valine = bladder carcinoma (valine instead of glycine)
• Glycine –> cysteine = lung cancer (cysteine instead of glycine)

Question 23

what is the NORMAL function of Ras in a cell

Answer 23

1. Binding of extracellular growth factor signal.
2. Promotes recruitment of RAS proteins to the receptor complex.
3. Recruitment promotes RAS to exchange GDP (inactive RAS) with GTP (active RAS).
4. Activated RAS then initiates the remainder of the signalling cascade (mitogen activated protein kinases).
5. These kinases ultimately phosphorylate targets, such as transcription factor to promote expression of genes important for growth and survival.

GTPase activity of RAS hydrolyses GTP to GDP fairly quickly, turning itself “off”.

Question 24

what happens to Ras function as a result of point mutation

Answer 24

Point mutation results in loss of GTPase activity of the Ras protein normally required to return active Ras —> inactive Ras.

This results in hyperactivity of Ras protein. Some specific mutations in the Ras gene are characteristics for specific cancers.

Question 25

what is the specific mutation in Ras gene that are characteristic for bladder cancer?

Answer 25

A point mutation in codon 12 that results in the substitution of valine INSTEAD of glycine. This is a characteristic of bladder cancer.

Question 26

what are the 3 members of the MYC oncogene family

and what are they all?

Answer 26

1. C-MYC (encodes c-Myc)
2. MYCN (encodes N-Myc)
3. MYCL (encodes L-Myc)

these are all transcription factors

Question 27

MYC oncogene family

where were they originally discovered

Answer 27

Avian myelocytomastosis virus (AMV)

Question 28

MYC oncogene family

MYC function?

Answer 28

Major downstream effectors of MYC include those involved in:
• ribosome biogenesis

• protein translation
• cell-cycle progression and metabolism
• orchestrating a broad range of biological functions, such as:

1. cell proliferation
2. Differentiation
3. Survival
4. immune surveillance

Question 29

MYC oncogene family

what does MYC encode?

MYC activation and involvement in cancer?

Answer 29

MYC oncogene overexpressed in the majority of human cancers

It encodes a helix-loop-helix leucine zipper transcription factor that dimerizes with its partner protein, Max, to transactivate gene expression.

MYC is activated by chromosomal translocation = overexpression of MYC gene

Question 30

what oncogenic activity is usually observed in Burkitt’s lymphoma? (which MYC oncogene family member?)

Answer 30

Oncogenic activity of c-myc is commonly observed in Burkitt’s lymphoma

Question 31

what virus is usually observed in Burkitts lymphoma?

Answer 31

Epstein Barr virus is associated with Burkitt’s lymphoma

Question 32

who is usually affected by Epstein Barr virus

Answer 32

Effects children age 2-16 yrs (aggressive tumour)

In central Africa children with chronic malarial infections = reduced resistance to Epstein Barr virus

Question 33

what translocations do people with Burkitts lymphoma usually carry

Answer 33

All Burkitt’s lymphoma cases carry 1 of 3 chromosomal translocations:

1. Chromosome 2
2. Chromosome 14
3. Chromosome 22

any of the above with Chromosomes 8

Question 34

describe the translocations that occur in Burkitts lymphoma and what effect this has on Myc

Answer 34

In ALL 3 translocations, a region from 1 of the 3 is fused to a section of chromosome 8
In these translocations, the myc gene is moved to be under the control of the Ig heavy chain
Movement from Chr2, 14 or 22 onto fusion with chromosome 8 = switches myc on constantly

Question 35

what chromosomes are found n nearly all chronic myelogenous leukaemia

Answer 35

Philadelphia chromosomes are found in nearly all CML patients

Question 36

chronic myelogenous leukaemia

What is the Philadelphia chromosomes?

Answer 36

Product of chromosomal translocation between ABL and BCR

This fusion results in enhances tyrosine kinase activity of the oncogene = abnormal proliferation

Question 37

chronic myelogenous leukaemia

Therapeutic strategies?

Answer 37

Tyrosine kinase inhibitors

Such as imatinib (Gleevac) = 95% remission in early stage patients

Question 38

Briefly describe the discovery of tumour suppressor genes

Answer 38

Fusion of normal cell with tumour cell forms a nontumorigenic hybrid cell.

Genes derived from the normal parent acted to inhibit or suppress tumour development

Therefore concluded that their must have been a factor in the normal cell that was transmitted to the tumour cell to suppress its tumorigenic activity.

Question 39

differences between oncogene and TSG

• consequence of mutation
• type of mutation

Answer 39

There are 2 major classifications of mutated genes that contribute to carcinogenesis:

1. Oncogenes
   Mutated gene whose protein product is produced in higher quantities or whose altered product has increased activity

Mutation in ONE allele is sufficient for above effect (dominant)

2. Tumour suppressor genes
   Gene in which the mutation has caused a loss of function = no suppression

Mutation in BOTH alleles required for above effect (recessive)

Question 40

oncogenes

• dominant or recessive?

Answer 40

dominant

BECAUSE
Mutation in ONE allele is sufficient for effect

Question 41

TSG

• dominant or recessive?

Answer 41

recessive

BECAUSE
Mutation in BOTH alleles required for effect

Question 42

What are tumour suppressor gene products?

and their function

Answer 42

• RB
• P53

Tumour suppressor gene products act as stop signs to uncontrolled growth and therefore may:

• Inhibit cell cycle
• Promote differentiation
• Trigger apoptosis

Question 43

What causes the loss of tumour suppressor gene function?

Answer 43

Inactivation of BOTH alleles of the gene (tumour suppressor genes are recessive genes)
Inactivation can be as a result of mutation OR deletion

Question 44

Explain the role of tumour suppressor gene products in the cell cycle (RB1)

Answer 44

• Retinoblastoma 1 (RB1) is a regulator of the cell cycle checkpoints

Question 45

RB-1 is involved in cell cycle regulation

When this protein (RB-1) is inactivated it can be found in different types of cancers. Name 3 of these cancers

Answer 45

retina

lung

breast

Question 46

What is retinoblastoma?

Answer 46

A rare childhood cancer that affects the retina

Develops when the immature retinoblasts continue to grow very fast and do NOT turn into mature retinal cells

Question 47

What causes retinoblastoma?

Which Chr is the mutation found on

Answer 47

RB1 (the tumour suppressor gene) causes retinoblastoma when BOTH COPIES are mutated
The hereditary mutation is on chromosome 13, the retinoblastoma 1 (RB1) gene

Question 48

How can you tell if a child has retinoblastoma? and what is the specific name for this presentation

Answer 48

An eye that contains a tumour cell will reflect light back in a white colour
This appearance is called leukocoria

Question 49

What are the 2 forms of retinoblastoma?

Answer 49

Familial (inherited) = (40% of cases)

Sporadic = (60% of cases)

Question 50

mutations in RB1 results in..

Answer 50

retinoblastoma

Question 51

mutations in BRCA2 results in..

Answer 51

Breast cancer

Question 52

mutations in CX26 results in..

Answer 52

autosomal recessive neurosensory deafness

Question 53

mutations in ATP7B results in..

Answer 53

Wilson disease

Question 54

2 HIT HYPOTHESIS
KNUDSON

describe what he found in hereditary patients

Answer 54

tumour formation requires a mutation in both alleles of the RB gene.

Hereditary (40% of cases) patients: the first mutations (HIT 1) in one of the alleles were inherited and the second mutation (HIT 2) in the other allele was acquired after birth = loss of heterozygosity = TUMOUR early in life

Question 55

2 HIT HYPOTHESIS
KNUDSON

describe what he found in sporadic patients

Answer 55

tumour formation requires a mutation in both alleles of the RB gene.

Sporadic (60% of cases) patients: no inherited mutation, both mutations were acquired after birth. These patients presented at a much later age.

Question 56

what mutation is required in order to prevent the expression of RB protein

Answer 56

2 separate mutations, one in each of the 2 retinoblastoma alleles are needed to inactivate the 2 copies of the Rb allele and prevent expression of the RB protein

Question 57

what are the 3 members of the Rb gene family

Answer 57

1. Rb/(p105/110)
2. p107
3. Rb2/p130

Question 58

1. Rb/(p105/110)
2. p107
3. Rb2/p130

what are these proteins collectively known as

Answer 58

pocket proteins

Question 59

pRB (protein retinoblastoma) is the product of which gene?

Answer 59

retinoblastoma tumour suppressor gene

Question 60

what is the function of pRB

Answer 60

pRB is a multifunctional protein

bind to transcription factors to either inhibit and induce transcription factor activity.

acts to regulate apoptosis and the cell cycle

Question 61

pRB is considered a transcriptional cofactor. What can this then go on to do?

Answer 61

It is considered as a transcriptional co factor that can bind to transcription factors to either inhibit and induce transcription factor activity.

Question 62

protein-protein interactions facilitate the function of pRB. what proteins interact with pRB?

Answer 62

Its main binding partner is E2F transcription factor, pRB binds to E2F via its large pocket

Other viral oncoproteins can also bind to pRB

Question 63

regulation of pRB activity

Answer 63

When RB is DEPHOSPHORYLATED/HYPOPHOSPHORYLATED it is ACTIVE and remains bound to E2F

When RB is active it can inhibit cell proliferation by blocking the progression of the cell to S phase

Cyclin D/CDK4/6 and Cyclin E/CDK2 both phosphorylate the RB = RB unbinds from E2F = inactive RB + E2F can induce transcription of genes required for cell cycle progression

Therefore, RB activity is regulated by phosphorylation via CDK/cyclin complexes

Question 64

role of RB in terms of E2F activity

Answer 64

Regulates the activity of the E2F transcription factor crucial for the expression of genes required for protein products needed in S phase (eg- thymidine kinase)

Question 65

What is the role of pRB in the cell cycle?

Answer 65

Main function of pRB is to regulate the cell cycle by inhibiting the G1 —> S phase

Remember: Cyclin E-CDK2 = progression from G1 —> S phase

Question 66

Passage of a cell through the cell cycle is regulated via cyclins and their associated CDK (cyclin dependent kinase)

what is the first cyclin to be synthesised and what is its role

Answer 66

Cyclin D (along with CDK4/6) is the first cyclin to be synthesised and drives progression through G1

Question 67

what happens at the G1 checkpoint

Answer 67

The G1 checkpoint leads to cell cycle arrest in response to any DNA damage

Question 68

what is a key substrate for cyclin D and what is its role?

Answer 68

A key substrate for cyclin D is the pRB
Cyclin D and E families (along with their CDKs) can hyperphosphorylate RB = inactive RB = E2F migrates to the nucleus and can induce transcription of genes required for cell cycle progression from G1 —> S phase (eg- transcription of genes required to produce S phase proteins such as DNA polymerase, thymidine kinase and PCNA)

Question 69

what are the 3 ways in which pRB can be inactivated

Answer 69

genetic mutation

viral oncoprotein binding

phosphorylation (this is reversible-normal process)

Question 70

3 ways in which pRB can be inactivated

describe genetic mutation

Answer 70

pRB is functionally inactivated by mutations of partial deletions

Question 71

3 ways in which pRB can be inactivated

describe viral oncoprotein binding

Answer 71

Viral inactivation found in small DNA tumour viruses mainly by disrupting E2F binding OR destabilisation of RB

• Adenovirus- E1A
• Papilloma- E7
• Polyoma- large T antigen

Question 72

Describe what happens to RB function in cancer cells

Answer 72

In cancer cells RB phosphorylation is deregulated throughout the cell cycle
As a direct consequence E2F transcription factors can induce the deregulation of the cell cycle

Without RB on watch, cells can move through G1 into S phase and are not checked for things such as DNA damage

Question 73

Describe how P53 can induce apoptosis

Answer 73

In response to DNA damage (if the cells are unable to repair the DNA) P53 can induce apoptosis
P53 is a transcription factor that can activate the expression of genes
A target gene for P53 is the Bax gene
• DNA damage that cannot be repaired = intracellular stress
• Activation of P53
• P53 acts as a transcription factor and activates the expression of Bax gene = more Bax protein
• This means there will be more Bax molecules present in the mitochondrial membrane
• More pores on the mitochondrial membrane = more cytochrome C can move into the cytosol
• More cytochrome c can act on APAF-1 to activate caspase 9 = inducing apoptosis

Question 74

why are many cancers treated with DNA damaging drugs

Answer 74

DNA damaging drugs

The aim of this is to damage DNA of cancer and therefore activate P53 to induce apoptosis of the cancerous DNA/cells.

Question 75

what is the most common mutation in cancer and what does this mean for the therapy method

Answer 75

Mutations in the P53 gene are the most common mutations in cancer

Some mutations destroy the ability of P53 to induce apoptosis
This means that the damaged DNA can go on to replicate and multiply
(this means that these cancers will be resistant to DNA damaging drugs)

Question 76

describe the role of the P53 tumour suppressor gene

Answer 76

P53 protein is aka the ‘guardian of the genome’
It is involved in sensing DNA damage and regulating cell death/apoptosis as well as other pathways
P53 is specialised in preventing the appearance of abnormal cells

Question 77

what happens to p53 in 30-50% of cancers and what does this suggest about why cancer cells do this?

Answer 77

P53 is mutated in 30-50% of human cancers

This suggests that tumour cells try to eliminate p53 function so that they can grow and survive

Question 78

Describe the structure of p53 tumour suppressor

4 domains

Answer 78

• P53 is a transcription factor (because p53 central binding domain has the ability to bind to DNA)
• Protein has an amino transactivation domain, a central binding domain, a tetramerization domain and a carboxyl regulatory domain

Question 79

Describe the regulation of P53 in normal cells

what is an MDM2 protein?

Answer 79

P53 levels are kept low in cells by MDM2 protein (a ubiquitin ligase and oncogene)
P53 should have a short half life (20 mins)

MDM2 will add a ubiquitin tag onto the lysine residues of p53 protein and this will then target the tagged p53 protein to the lysosome for degradation

Question 80

Describe the activation of p53 tumour suppressor protein

Answer 80

• DNA damage that cannot be repaired = intracellular stress
• Stress signals are mainly sensed by kinases
• These kinases then phosphorylate P53 = disrupts the interaction between P53 and MDM2
• P53 can therefore regulate genes involved in DNA damage repair, apoptosis and cell cycle arrest

Question 81

effect of ionising radiation on p53 tumour suppressor protein

Answer 81

Ionising radiation signals through 2 kinases ATM/ATR

activates oncogenes such as Ras to induce activity of p14arf responsible for sequestering MDM2

prevent degradation of p53 by disrupting the interaction between p53&MDM2

Question 82

Outline what the research on p53 discovered and how this is useful in therapeutic strategies

Answer 82

Mutational inactivation = dysfunction of p53

active p53 = vital role in tumorigenesis suppression

Therapeutic strategies:
Aimed at correcting p53 mutation and restoring wild type p53 function by targeting regulators

Question 83

explain gene therapy as a therapeutic strategy for cancer (based on p53 function)

Answer 83

retrovirus-mediated gene transfer of the wild-type TP53 gene into both human lung tumour cell lines and xenograft models could lead to the inhibition of tumour cell growth.

Question 84

what are the alternative therapeutic strategies for cancer

Answer 84

Alternative strategies include the use of inhibitors.

Example of the use of inhibitors:

• PRIMA-1
• Nutlin
• RITA
• Inhibitors of CRM1

Question 85

Describe personalised medicine’s role in cancer treatment

Answer 85

Uses the understanding of the individual patients tumour (as oppose to where it is located in the body). Even if 2 patients have the same tumour type, their tumour genetics will be very different. Understanding the differences will help to personalise their therapy in a more specific way so it works better for them. This also prevents exposure of treatments to patients that will not work/not work as well as other treatments.

Question 86

therapeutic strategies for cancer based on p53 function

what is PRIMA-1

Answer 86

restores mutant p53 by modifying the thiol groups in the core domain of the protein

Question 87

therapeutic strategies for cancer based on p53 function

what is Nutlin

Answer 87

is a potent MDM2 antagonist

Question 88

therapeutic strategies for cancer based on p53 function

what is RITA

Answer 88

binds to p53 and can restore mutp53 activity

Question 89

therapeutic strategies for cancer based on p53 function

what are CRM1 inhibitors

Answer 89

Inhibitors of CRM1 result in nuclear accumulation of p53