Clinical cancer genetics

Question 1

What are the two types of mutations that occur in cancer ?

Answer 1

Constitutional (germline) mutations - in all body cells, present at birth, present in fertilised egg (from sperm/egg)

Somatic mutations - tumour-only mutations. genetic change occurs in cell, copying errors during cell division, DNA mutation within cell. mosaic. don’t give info about inherited risk, but about molecular pathways for targeted drug therapy.

Question 2

What are germline mutations ?

Answer 2

Hereditary
Informs future cancer risk
Informs treatment decisions
Provides information for other family members
Inherited cancer is due to constitutional germline mutations

Question 3

What are somatic mutations?

Answer 3

These are acquired
Informs treatment decisions
Provides reassurance for family and future children
-Sporadic cancer is due to tumour-only somatic mutations
-due to errors in DNA replication, repair, cell division processes

Question 4

What are the three types of cancer patients ?

Answer 4

• Sporadic cancer
• Familial cancer - not 1 high-risk genetic factor but multiple low-risk genetic variants/factors. Most common inherited susceptibility to cancer. Multifactorial polygenic risk.
• High risk cancer susceptibility/predisposition gene - 1 genetic change which significantly increases cancer risk

Question 5

What is the multifactorial/polygenic familial risk?

Answer 5

Larger proportion of familial cancers than high risk cancer predisposition genes

No single high risk gene identified

Disease Risk conferred through multiple lower risk genetic factors +/- environmental factors

No current testing available but is on the horizon

Use Family history as a proxy of polygenic familial risk. Family members share variants.

Increased screening is available for some cancer types in at risk individuals (e.g. breast, colorectal)
Identify multifactorial familial risk for screening, prevention + early detection + management pathways

Question 6

High risk cancer predisposition genes are rare + dependent on cancer type?

Answer 6

Breast cancer 5-10%

Colon 5-10%

Prostate 5-10%

Ovarian 10-15%

Melanoma 10%

Pancreatic 10%

Medullary thyroid 25% - RET gene mutation drives the cancer

Retinoblastoma 40% - childhood cancer

Question 7

Why do we try to identify patients with increased genetic disposition to cancer ?

Answer 7

1. Provides reason for why developed cancer
2. Informs medical management and surgical options - provide diff targeted therapies according to specific molecular mechanisms driving the cancer. e.g. opt for bilateral mastectomy bc high risk of second cancer. helps patient decide suitable treatment.
3. Informs patients about future cancer risks - preventative methods after treat this cancer
4. Informs relatives about cancer risk - access to screening/risk reducing surgery, preventing + early detection of cancer.

Question 8

How can we identify patients with increased genetic predisposition to cancer ?

Answer 8

Family history
Syndromic features - e.g. in tumour that indicate it’s due to a high-risk gene? Pathology of Cancer histology/type?
Tumour testing - look for genetic changes within tumour - sporadic (tumour-only)/mutation in a known cancer predisposition gene = we can then check that it isn’t in patient’s germline
Pathology of cancer

Question 9

Outline family history assessment

Answer 9

Three generational family history .
Bilateral cancer/ multiple cancer in same individual

Age of onset

Multiple cancer diagnosis of same type .

Closely related individual

Multiple cancer diagnosis or cancer related to specific CPG in closely related individuals (caused by same underlying genetic defect)

Question 10

What are polygenetic risk scores?

Answer 10

Single value estimate of an individual’s genetic liability to a trait or disease.
Target to look for specific changes using SNP from GWAS that are known to be associated w certain cancer types
Is any SNP base subs more common in cancer cases than in controls? Then test for that using SNP chip for polygenic risk score.

Question 11

What are syndromic features?

Answer 11

Very rare cancer predisposition genes
Flags on clinical examination

• Trichielomma - Cowden Syndrome - cancer predisposition syndrome caused by PTEN gene
• Mucocutaneous pigmentation - rare cancer predisposition syndrome Peutz-Jagher’s syndrome - STK11 gene mutations

Clinical signs indicating inheritied cancer susceptibility

Question 12

What is stratified prevention ?

Answer 12

All women are offered screening from age of 47-50.
This is the categorization of the population into risk groups, each of whom would be offered a different intervention

Individuals with a family high risk can be offered further screening

Identify those w increased cancer risk to offer increased screening program - cost-effective.
Using family history as a proxy for increased familial risk

Stratified screening based on genetic risk, using family history as a proxy for genetic risk

Question 13

What is Tamoxifen?

Answer 13

Tamoxifen = anti-oestrogen drug which has been shown to reduce the risk of women developing breast cancer from families with increased genetic susceptibility to breast cancer - Chemo prevention = use medication to reduce breast cancer risk

Question 14

Give a summary of multifactorial /polygenic risk assessment

Answer 14

Larger proportion of familial cancers than high risk cancer predisposition genes

No routine genetic testing

Multiple lower risk genetic factors

Family history as a proxy of risk

Screening, prevention and early detection (SPED)

• Mammograms
• Colonoscopies
• Chemoprevention

Question 15

When is genetic testing offered to patients for high risk cancer predisposition genes ?

Answer 15

Where there is a likelihood of finding a pathogenic variant >10%

Question 16

What are the caveats of cancer predisposition genes ?

Answer 16

Even if a disease causing change is found , the risk of cancer is not 100%

Large range which may have other influences

The age of the patient , type of pathogenic variant and risk penetrance must be taken into account.

Question 17

Describe cancer predisposition inheritance

Answer 17

Most inherited cancer predisposition genes are inherited in autosomal dominant fashion therefore 50% chance of passing it on to child
Heterozygous increases cancer risk

Question 18

Outline autosomal recessive cancer predisposition inheritance

Answer 18

Sometimes ,autosomal recessive predisposition to cancer can occur with healthy carriers but when a child inherits 2 pathogenic variants.
MUTYH gene -colon polyps and cancer

Several autosomal dominant cancer predisposition genes are linked to rare autosomal recessive conditions (childhood onset cancer syndromes) when biallelic pathogenic variants are inherited e.g.BRCA2 is a Fanconi anemia gene

Question 19

What are the different genetic tests which are offered ?

Answer 19

Single gene

NGS panel
(Next generation sequencing) - breast cancer, bowel cancer, multiple genes cause the cancer

WES
(Whole exome sequencing)

WGS
(Whole genome sequencing) - paired both tumour + germline

Question 20

What are the outcomes of diagnostic genetic testing for high-risk cancer predisposition gene?

Answer 20

1.No disease causing variant is identified
-manage on basis of family history and personal diagnosis
=more likely to be polygenic multifactorial risk = still need ↑ screening even if not high-risk gene

2. Disease causing (pathogenic) variant identified
   - manage as per gene specific protocol
   - Can offer cascade screening to relatives
3. Variant of uncertain significance identified
   - Analyze variant with scientists
   - Manage on basis of personal and family history
   - Try to get information to help classify variant
   - Majority of rare changes within a gene are not disease-causing
   - Variants never seen before

Question 21

What would happen if an actionable pathogenic variant is identified?

Answer 21

Screening, Prevention and Early detection

• Non invasive imaging -more frequent from a young age
• Invasive-more frequent
• Chemoprevention
• Risk reducing surgeries

Question 22

What is predictive testing ?

Answer 22

This is a test in a well person to predict future risk
Protected against discrimination

If pathogenic variant not present can manage as population risk

If pathogenic variant us present, manage as per gene specific protocol

Question 23

What are the genes which are most frequent monogenic causes for hereditary breast cancer ?

Answer 23

BRCA1 / BRCA2 genes = monogenic cause of hereditary breast cancers
-They account for 20% of familial breast cancer
Contribution to overall breast cancer
-Involved in DNA repair (homologous recombination repair) and regulation of transcription
-Disease causing variants result in an increased risk to develop certain cancers
-Founder mutations common in specific populations e.g Polish, Jewish

Question 24

What is the carrier management ?

Answer 24

Offer women who carriers of BRCA mutations:
Screening - MRI scans of breast + Annual Mammograms
Risk-reducing surgery - uterine tubes, ovaries
Chemoprevention for BRCA2 carriers
More BRCA2 carriers recommended to have annual PSA test

Question 25

What is Lynch syndrome ?

Answer 25

This is a familial colorectal, endometrial and ovarian cancer which is 1-3% of all cancers.
Caused by mismatch repair in (mutations )
MLH1,MSH2,MSH6 and pMS2.
High in young uterus cancers

Question 26

How are patients checked for Lynch syndrome ?

Answer 26

A tumour test is offered to find four proteins produced by the genes .

Test on tumour to look for the 4 proteins produced by the 4 genes. Immunohistochemistry staining. Missing proteins suggest Lynch. Further tests - blood tests

The cancer risks are dependent on the gene and gender of the patient

Question 27

What is some further lynch syndrome carrier management

Answer 27

Screening:

• colorectal
• gastric (H. pylori)
• symptom awareness

Risk reducing surgery - Hyseterectomy +/- BSO

Chemoprevention - Low does aspirin - 1/2 developing cancer risk when one has Lynch syndrome

Research
Cancer management
Family matters

Question 28

• 5-10% high-risk cancer predisposition genes -

- Multifactorial

Answer 28

• 5-10% high-risk cancer predisposition genes - v. rare, high effect size
• Multifactorial - common variants, low effect size, but add up with other variants to increase overall cancer risk

Question 29

Women w increased familial risk are given

Answer 29

yearly mammography screening program bc have increased risk of younger, more aggressive cancers = increased screening for women at increased risk 40-49yrs

Question 30

Population women breast cancer risk
Moderate breast cancer risk
Moderate-high breast cancer risk

Answer 30

Population women breast cancer risk - 12-17%
Moderate breast cancer risk - 17-30% = category B1 surveillance
Moderate-high breast cancer risk - >30% = category B2 surveillance

see slide

Question 31

Moderate-high breast cancer risk - >30%

Answer 31

has been a genetic test in family but no high risk gene but instead multiple polygenic risk factors in the family which are more significant than the moderate risk breast cancer risk (12-17%) families
-offer these annual mammograms ages 40-59yrs + 3-yearly mammogram after

Question 32

Which gene mutations significantly increase breast cancer + ovarian cancer risk?

Answer 32

BRCA1

BRCA2 - also prostate cancer + pancreatic cancer

Question 33

Having breast cancer = ……… risk of developing a second contralateral breast cancer

Answer 33

<50%

Question 34

Why not chemoprevention for BRCA1 carriers?

Answer 34

BRCA1 carriers = Oestrogen-negative tumours