Oncogenesis and tumour suppressor genes

Question 1

What are the major functional changes in cancer?

Answer 1

1. Increased growth
   • Loss of growth regulation, stimulation of environment promoting growth e.g. angiogenesis)
2. Failure to undergo apoptosis/senescence
3. Loss of differentiation
   ○ Including alterations in cell migration and adhesion
4. Failure to repair DNA damage
   -Including chromosomal instability

Question 2

What are oncogenes normally components of?

Answer 2

Many oncogenes are normally components of growth factor signalling pathways

Question 3

What happens when oncogenes are mutated?

Answer 3

When mutated produce products in higher quantities or whose altered products have increased activity and therefore act in a dominant manner

Question 4

What do tumour suppressor gene products act as?

Answer 4

Many tumour suppressor gene products act as a stop signal to uncontrolled growth, may inhibit the cell cycle or trigger apoptosis

Question 5

What is the normal job of oncogenes?

Answer 5

• Normal job: make cells divide, driving cell division forward

Question 6

What happens in cancer to oncogenes?

Answer 6

In cancer:Pick up mutations that mean they are permanently active

Question 7

What does a mutation cause to oncogenes?

Answer 7

Mutation causes gain of function

Question 8

What has to occur in order to completely knock out tumour suppressor function?

Answer 8

In order to completely knock out tumour suppressor function, must have mutations in both alleles – two hit hypothesis

Question 9

What does a mutation cause to tumour suppressor gene?

Answer 9

Mutation causes loss of function

Question 10

How can viral oncogene be transmitted?

Answer 10

Viral oncogenes can be transmitted by either DNA or RNA viruses

Question 11

What can DNA viruses cause?

Answer 11

• 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

Question 12

What do DNA viruses encode?

Answer 12

○ Encode various proteins along with environmental factors can initiate and maintain tumours

Question 13

What do RNA viruses integrate and induce?

Answer 13

○ Integrate DNA copies of their genomes into the genome of the host cell and as these contain transforming oncogenesthey induce cancerous transformation of the host

Question 14

What causes activation of oncogenes?

Answer 14

○ Mutations
○ Insertion
○ Amplifications
○ Translocations

Question 15

What does activation of oncogenes do?

Answer 15

○ Loss of response to growth regulatory factors

○ One allele needs to be altered

Question 16

What are the 4 types of proteins involved in the transduction of growth signals?

Answer 16

1. Growth factors
2. Growth factor receptors
3. Intracellular signal transducers
4. Nuclear transcription factors

Question 17

What do the majority of oncogene proteins function as?

Answer 17

○ 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 18

What do oncogene proteins act as?

Answer 18

Oncogene proteins act as growth factors (e.g.EGF), growth factor receptors (e.g. ErbB) and intracellular signalling molecules (Ras and Raf)

Question 19

What pathway do Ras and Raf activate and what does this lead to?

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

What are RAS proteins?

Answer 20

○ RAS proteins are small GTPases that are normally bound to GDP in a neutral state

Question 21

What percentage of cancers is oncogenic activation of Ras seen in?

Answer 21

○ Oncogenic activation of ras is seen in about 30% of human cancer

Question 22

What is the most commonly mutated oncogene?

Answer 22

Ras gene

Question 23

Where do the point mutations for Ras occur?

Answer 23

In codons12, 13, 61

Question 24

What does a mutation from glycine to valine in Ras cause?

Answer 24

Glycine to valine - bladder carcinoma

Question 25

What does a mutation from glycine to cysteine in Ras cause?

Answer 25

Glycine to cysteine - lung cancer

Question 26

What are the steps involved in activating Ras and what do these activated Ras do?

Answer 26

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

Question 27

How is Ras inactivated?

Answer 27

1. Ras hydrolyzes GTP to GDP fairly quickly, turning itself “off”

Question 28

What does mutations in the codons of Ras result in?

Answer 28

• Mutation in codons results in hyperactive Ras protein
○ Always switched on
Cells are continually dividing
– leads to tumorigenesis

Question 29

What does the MYC oncogene family consist of and what do they encode?

Answer 29

○ The MYC oncogene family consists of 3 members, C-MYC, MYCN, and MYCL, which encode c-Myc, N-Myc, and L-Myc, respectively

Question 30

What family does the MYC oncoproteins belong to?

Answer 30

○ The MYC oncoproteins belong to a family of transcription factors that regulate the transcription of at least 15% of the entire genome

Question 31

What are the main downstream effectors of MYC include?

Answer 31

○ 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

Question 32

In what is MYC oncogene overexpressed?

Answer 32

○ The MYC oncogene is overexpressed in the majority of human cancers and contributes to the cause of at least 40% of tumours

Question 33

What does MYC oncogene encode and what does it dimerize?

Answer 33

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

Question 34

When is MYC generally activated and what does this lead to?

Answer 34

○ Generally MYC is activated when it comes under the control of foreign transcriptional promoters. This leads to a deregulation of the oncogene that drives relentless proliferation.

Question 35

What is activation of MYC a result of?

Answer 35

○ Such activation is a result of chromosomal translocation

Question 36

What virus is associated with Burkitt’s lymphoma?

Answer 36

Epstein Barr virus is associated with Burkitt’s lymphoma

Question 37

What is burkitt’s lymphoma?

Answer 37

• BL is a high grade lymphoma that can effect children from the age of 2 to 16 years

Question 38

When does EBV infection usually happen and what happens if this infection is delayed to teenage years?

Answer 38

• Usually this infection happens in childhood but if it is delayed to teenage years, you get infection mononucleosis or glandular fever

Question 39

What is the main transmission of EBV?

Answer 39

Main transmission is through saliva

Question 40

What does EBC affect?

Answer 40

• Affects jawbone

-Highly aggressive, doubles every 24 hours

Question 41

What do all burkitt’s lymphoma cases carry and what does this therefore mean?

Answer 41

• All BL cases carry one of three characteristic chromosomal translocations that place the MYC gene under the regulation of the Ig heavy chain
-Therefore c-myc expression is deregulated

Question 42

What are the chromosomes involved in the translocations in burkitt’s lymphoma and what does each translocation fuse to?

Answer 42

• In BL three distinct, alternative chromosomal translocations involving chromosomes 2, 14 and 22
-In all three translocations a region form one of these three chromosomes is fused to a section of chromosome 8

Question 43

What percent of all leukemias does chronic myelogenous leukaemia account for?

Answer 43

• Chronic myelogenous leukaemia (CML) accounts for 15-20% of all leukaemias

Question 44

What do 95% of chronic myelogenous leukemia patients carry and what is this the product of?

Answer 44

• 95% of CML patients carry the Philadelphia chromosome, that is the product of the chromosomal translocation t(9;22)(q34;q11) generating the BCR-ABL fusion protein

Question 45

As a result of the translocation of the philadelphia chromosome, what happens?

Answer 45

• As a result of this translocation the tyrosine kinase activity of the oncogene ABL is constitutive leading to abnormal proliferation

Question 46

What are the therapeutic strategies for chronic myelogenous leukaemia?

Answer 46

• Therapeutic strategies for CML include Imatinib (Gleevac) a tyrosine kinase inhibitor-96% remission in early-stage patients

Question 47

What do tumour suppressor gene products act as and what are they usually the regulators of?

Answer 47

• Tumour suppressor gene products act as stop signs to uncontrolled growth, promote differentiation or trigger apoptosis
-Therefore they are usually regulators of cell cycle checkpoints (e.g. RB1), differentiation (e.g. APC) or DNA repair (e.g. BRCA1)

Question 48

What does loss of tumour suppressor gene function require?

Answer 48

• Loss of tumour suppressor gene function requires inactivation of both alleles of the gene

Question 49

What are tumour suppressor genes defined as?

Answer 49

• Tumour suppressor genes are defined as recessive genes

○ Sometimes referred to as ‘anti-oncogenes’

Question 50

What is retinoblastoma?

Answer 50

Retinoblastoma is a rare childhood cancer

Question 51

Why do retinoblastoma develop?

Answer 51

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

Question 52

What is leukocoria?

Answer 52

An abnormal white reflection from the retina of the eye when the eye contains a tumour

Question 53

What are the 2 forms of the retinoblastoma disease?

Answer 53

Two forms of the disease: familial (40%) and sporadic (60%)

Question 54

What is the hereditary mutation for retinoblastoma on?

Answer 54

○ The hereditary mutation is on chromosome 13 (13q14), the retinoblastoma 1 (Rb1) gene

Question 55

What is loss of heterozygosity often used to describe in retinoblastomas?

Answer 55

• “Loss of heterozygosity” often used to describe the process that leads to the inactivation of the second copy of a tumour suppressor gene

Question 56

What are mutations that inactivate tumour suppressor genes?

Answer 56

• Mutations that inactivate tumour suppressor genes, called loss-of-function mutations, are often point mutations or small deletions
○ Disrupt the function of the protein that is encoded by the gene

Question 57

What does the Rb gene family include?

Answer 57

• The Rb gene family includes three members: Rb/(p105/110), p107 and Rb2/p130

Question 58

What are the retinoblastoma genes collectively known as?

Answer 58

• Collectively known as pocket proteins

-Have large and small pockets

Question 59

What can large pocket areas interact with?

Answer 59

§ Through large pocket area they can interact with E2F transcription factor

Question 60

What is the retinoblastoma protein?

Answer 60

• A transcriptional co factor that can bind to transcription factors

Question 61

What does the retinoblastoma function in and how does it regulate these pathways?

Answer 61

• RB functions in diverse cellular pathways, such as apoptosis and the cell cycle
-RB regulates these pathway through the stimulation or inhibition of the activity of interacting proteins.

Question 62

What is the main binding partner of retinoblastoma?

Answer 62

• Main binding partner is the E2F transcription factor, interacting with the large pocket

Question 63

What is the main function of Rb?

Answer 63

Regulate the cell cycle by inhibiting the G1 to s phase transition

Question 64

What are the important proteins involved in the cell cycle?

Answer 64

1. Cyclins

2. CDKs

Question 65

What is cyclin D

Answer 65

Cyclin D is the first cyclin to be synthesised and drive progression through G1 together with cdks4/6

Question 66

What does the G1 checkpoint lead to and in response to what?

Answer 66

• The G1 checkpoint leads to the arrest of the cell cycle in response to DNA damage

Question 67

What is a key substrate for cyclin D?

Answer 67

• A key substrate for cyclin D is RB protein

Question 68

What do cyclins D and E families and their CDKs do?

Answer 68

• Cyclin D and E families and their cdks phosphorylate RB

Question 69

What do Rb protein regulate the activity of?

Answer 69

• Rb protein regulates the activity of the E2F transcription factor which crucial for the expression of genes required for S phase

Question 70

What is Rb activity regulated by?

Answer 70

Rb activity is regulated by phosphorylation

Question 71

What form does Rb exist in?

Answer 71

Rb exists in hypophosphorylated form

Question 72

When Rb is bound to E2F, what does it prevent?

Answer 72

When bound to E2F, it prevents progression into S phase so triggers cell cycle death

Question 73

What can the Rb tumour suppressor do when active?

Answer 73

• When the Rb tumour suppressor is active it can inhibit cell proliferation

Question 74

What state is Rb active in and remains bound to E2F?

Answer 74

• When Rb is dephosphorylated/hypophosphorylated it is active and remains bound to E2F

Question 75

What state is Rb inactive in?

Answer 75

• When Rb is hyperphosphorylated in response to extracellular physiological signals, it is inactive

Question 76

What happens upon the phosphorylation of Rb?

Answer 76

• Upon phosphorylation of RB, E2F is released and migrates to the nucleus to induce transcription

Question 77

What progression occurs when Rb is inactive?

Answer 77

• When RB is inactive cell cycle progression from G1 to S occurs

Question 78

In retinoblastoma, what is pRb functionally inactivated by?

Answer 78

• In retinoblastoma, pRb is functionally inactivated by mutations or partial deletions

Question 79

What happens to Rb phosphorylation in cancer cells and what happens as a direct consequence?

Answer 79

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

Question 80

What is the p53 gene involved in?

Answer 80

• It is involved in sensing DNA damage and regulating cell death/apoptosis as well as other pathways

Question 81

What does frequent mutation of p53 in tumour cell genomes suggest?

Answer 81

• Frequent mutation of p53 in tumour cell genomes suggests that tumour cells try to eliminate p53 function before they can thrive

Question 82

What is the structure of p53?

Answer 82

• Protein has an amino transactivation domain, a central DNA binding domain, a tetramerization domain and a carboxyl regulatory domain

Question 83

How many gene promoter regions can p53 bind to?

Answer 83

• Can bind to around 300 different gene promoter regions-main role as a transcription factor

Question 84

What is MDM2 and what does it regulate?

Answer 84

Is a ubiquitin ligase and regulates p53

Question 85

What does MDM2 do?

Answer 85

○ Adds ubiquitin to lycine residues of molecule so is targeted to proteasome for proteolytic degradation

Question 86

What keeps p53 levels low?

Answer 86

○ These levels are kept low by MDM2 protein, a ubiquitin ligase (also an oncogene)

Question 87

How does MDM2 regulate p53 levels?

Answer 87

○ MDM2 binds p535 to form a complex in the nucleus where MDM modifies the carboxyl terminus of p53 andtargets it for degradation by the proteasome

Question 88

Half life of WT p53?

Answer 88

○ WT p53 has a short 20 min half life

Question 89

What signals activate p53?

Answer 89

Stress signals are able to activate p53

Question 90

What are stress signals sensed by?

Answer 90

• Signals are sensed by mainly kinases that then phosphorylate p53

Question 91

What does phosphorylation of p53 disrupt?

Answer 91

• Phosphorylation of p53 disrupts the interaction between it and MDM2

Question 92

What can p53 regulate?

Answer 92

• P53 can thus regulate genes involved in DNA damage repair, apoptosis and cell cycle arrest

Question 93

What is the most common molecular mechanism behind the dysfunction of p53?

Answer 93

• Mutational inactivation is considered to be one of the most common molecular mechanisms behind the dysfunction of p53

Question 94

What are the therapeutic strategies for p53 mutations?

Answer 94

• Correcting p53 mutation and restoring wild-type p53 function by targeting its regulators

Question 95

How does retrovirus as a therapeutic strategy for p53 mutation work?

Answer 95

• Retroviruses integrate in a stable form into the genome of infected cells. It has been demonstrated thatretrovirus-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 96

How are inhibitors used in p53 mutations?

Answer 96

○ Inhibitors can be used in two ways:
1. Refold mutant p53 by modifying the thiol groups in the core domain of the protein e.g. PRIMA 1
2. Regulate the regulators of p53
• i.e. MDM2; the half life would therefore be greater so more ability to function as a tumour suppressor
-Nutlin (MDM2 inhibitor) prevents the ubiquitination of the molecule