Genetics - Cancer Genetics

Question 1

When do we get a compromising of a cell function?

Answer 1

When a functional or regulating region of DNA is damaged/mutated

Question 2

What are cancer genes?

Answer 2

Critical gene DNA sequence that will compromise cell function

Question 3

What types of cancer genes do we have?

Answer 3

Tumour suppressor genes which are silenced

Proto oncogenes which are over expressed

Question 4

What factors can lead to cancer?

Answer 4

Environment
Exogenous factors
Hereditary

Question 5

What are benign tumours?

Answer 5

Well differentiated
Slow growth
Capsulated
Non invasive

Question 6

What are malignant tumours?

Answer 6

Poorly differentiated
Fast growth
Invade local tissue
Integrated

Question 7

What are the 6 hallmarks of cancer needed for successful cancer?

Answer 7

Self sufficiency in growth signals 
Insensitivity to anti growth signals 
Evading apoptosis
Limitless replicative potential 
Sustained angiogenesis 
Tissue invasion/metastasis

Question 8

What 2 hallmarks have recently been added to the classic 6

Answer 8

Genome instability

Evading immune destruction.

Question 9

Give an example of evading immune destruction

Answer 9

PD1 protein found on normal cells and tumour cells

Question 10

What does the lifetime risk of developing cancer correlate with?

Answer 10

How often stem cells in that tissue divide

Question 11

What are germline cells?

Answer 11

Cells which produce our gametes - undergo meiosis and mitosis.

Question 12

What do germline mutations lead to?

Answer 12

Heritable cancer

Question 13

What are somatic cell mutations?

Answer 13

Mutations occurring in any non-germline cell

Question 14

Are somatic cell mutations heritable?

Answer 14

no

Question 15

How do we get cancer families?

Answer 15

Cancer predisposing mutation may occur in germline so is inherited

Question 16

What increases the risk of breast cancer by 80%?

Answer 16

Abnormal BRCA-1/BRCA-2 gene

Question 17

What increases the risk of ovarian cancer by 55%?

Answer 17

Abnormal BRCA-1 gene

Question 18

How do germline mutations compare to somatic?

Answer 18

Smaller and indistinguishable

Question 19

What is a silent mutation?

Answer 19

Mutations has no effect as same amino acid is produced

Question 20

What is a mis sense mutation?

Answer 20

Codons code for a completely different amino acid

Question 21

What is a non sense mutation?

Answer 21

Mutation leads to premature stop codon

Question 22

How do somatic cell mutations compare in size?

Answer 22

Can be much larger

Question 23

What is chromosome instability?

Answer 23

Higher rate of chromosome mis segregation can lead to alterations in chromosome number

Question 24

How do we get chromosome instability?

Answer 24

Defective cell cycle control

Question 25

What does the loss of a repair system lead to?

Answer 25

Loss of amplification and rearrangement of chromosome segments

Question 26

What does the loss of a repair system cause in the long term?

Answer 26

loss in the cell’s ability to induce cell cycle apoptosis when there are defective or incorrect chromosome

Question 27

What are the 3 stages of carcinogenesis?

Answer 27

initiation promotion and progression

Question 28

What are passenger mutations?

Answer 28

many mutations can be tolerated by somatic cells (often in heterozygote state) - don’t confer growth advantage however are present in the ancestor of cancer cells when the cell acquires one of the driver mutations

Question 29

What are drivers mutations?

Answer 29

few mutations can confer a selective growth advantage and are recurrently found (in homozygote state) - they confer clonal expansion

Question 30

What are candidate driver genes?

Answer 30

genes mutated in a greater proportion of cancer samples than would be expected from the background mutation rate.

Question 31

How do we identify candidate driver genes?

Answer 31

cell is more likely to become cancerous than they would have been without mutation of that gene, and thus that the gene is a candidate driver.

Question 32

What happens once we identify a candidate driver gene?

Answer 32

somatic mutations in that gene that have a consistent predicted effect on the gene’s activity, can be considered as candidate driver mutations

Question 33

How may we distinguish candidate driver genes from passenger genes?

Answer 33

Candidate driver mutations may also be distinguished from passengers by their tendency to have a greater impact on protein function than passenger mutations do.

Question 34

How may we base the assessment of the functional impact of a mutation?

Answer 34

• evolutionary conservation (if the protein has close homologs)
• secondary and tertiary structural features
• biochemical similarity of the previously existing amino acid to its replacement
placement of side chains in the three-dimensional protein structure

Question 35

What are oncogenes?

Answer 35

Oncogenes are genes which have to potential to cause cancer

Question 36

How do oncogenes normally operate?

Answer 36

Normally operate via chromosome rearrangement, gene amplification or mutation

Question 37

How many dominant oncogene mutations do we need for cancer?

Answer 37

1

Question 38

What are RAS proteins?

Answer 38

RAS proteins belong to the large family of small GTPases, which are activated in response to various extracellular stimuli.
Ras proteins function as binary molecular switches that control intracellular signaling networks.

Question 39

When RAS proteins function normally, what does it control?

Answer 39

RAS proteins control cellular signaling pathways responsible for growth, migration, adhesion, cytoskeletal integrity, survival and differentiation.
When it functions normally, it controls cell proliferation.

Question 40

When RAS is mutated, what is disrupted?

Answer 40

When it is mutated, negative signalling is disrupted

Question 41

What are the 3 methods of oncogene activation?

Answer 41

Mutation in proto-oncogene or regulatory protein
Increase protein expression
Increase mRNA stability

Question 42

What is KRAS?

Answer 42

Gene that acts as an on/off switch for cell signalling

It is called KRAS because it was first identified as an oncogene in Kirsten RAt Sarcoma virus

Question 43

How many recessive tumour suppressing mutations are needed for cancer development?

Answer 43

2

Question 44

What are the functions of tumour suppressing genes?

Answer 44

gene that regulates a cell during cell division and replication. If the cell grows uncontrollably, it will result in cancer.

Question 45

What is the significance of a bilateral retinoblastoma?

Answer 45

It’s always inherited

Question 46

What is the significance of a unilateral retinoblastoma?

Answer 46

Not heritable

Question 47

What was observed concerning the onset of retinoblastoma?

Answer 47

the age of onset distribution of bilateral cases (much earlier) was consistent with a the presence of a single mutation, whereas sporadic unilateral cases followed a two-hit kinetics (came later in life).

Question 48

What was suggested about the inheritance of retinoblastoma?

Answer 48

all retinoblastoma derived from two mutations but that in the familial cases one hit is inherited.

Question 49

Why is a second mutation required in familial retinoblastoma?

Answer 49

In the first event in the two-hit model is an inherited mutation, however inheriting one germline copy of a damaged gene present in every cell in the body is not sufficient to enable this cancer to develop.
A second hit (or loss) to the good copy in the gene pair could occur somatically, producing cancer.

Question 50

Why are familial retinoblastoma cancers easier to get than a purely somatic retinoblastoma?

Answer 50

It is more likely for someone with the first hit to get the second somatic mutation than for someone to get two somatic mutations

Question 51

What is p53?

Answer 51

tumor-suppressor protein encoded by the TP53 gene.

Question 52

What are the functions of p53?

Answer 52

DNA repair, inducing apoptosis, transcription, and regulating the cell cycle.

Question 53

When do we see abnormalities of p53?

Answer 53

Li-Fraumeni syndrome

Question 54

How may we damage/lose the TP53 gene?

Answer 54

The TP53 gene can be damaged in cells by mutagens (chemicals, radiation, or viruses), increasing the likelihood that the cell will begin decontrolled division.
Loss of the TP53 gene (due to mutations or deletion) occurs in >50% of human cancers (almost 100% of high grade serous ovarian cancers)

Question 55

What is the role of DNA repair genes?

Answer 55

DNA repair genes code for proteins whose normal function is to correct errors that arise when cells duplicate their DNA prior to cell division.

Question 56

What does the rate of DNA repair depend on?

Answer 56

cell type, the age of the cell, and the extracellular environment.

Question 57

With a cell with too much DNA damage, what are its 3 options?

Answer 57

• an irreversible state of dormancy
  
  • cell suicide, also known as apoptosis or programmed cell death
• unregulated cell division, which can lead to the formation of a tumor that is cancerous

Question 58

What can a mutation in DNA repair genes lead to?

Answer 58

failure in repair, which in turn allows subsequent mutations to accumulate.

Question 59

What are the 2 types of cancer viruses?

Answer 59

DNA and RNA viruses

Question 60

What is the principle of cancer viruses?

Answer 60

Several viruses have been linked to certain cancers in humans

Question 61

How do some viruses cause cancer?

Answer 61

DNA of the virus mixed with the human cell DNA causing it to grow and multiply

Question 62

What is an example of virus cancer?

Answer 62

Cervical cancer, 99,9% is caused by human papilloma virus