Tumour Angiogenesis, Invasion, and Metastasis

Question 1

What are the characteristics of malignant tumours?

Answer 1

• Growth: unlimited growth; not self-limited as in benign tumours - as long as adequate blood supply is available.
• Invasiveness: Migration of tumour cells into the surrounding stroma where they are free to disseminate via vascular or lymphatic channels to distant organs.
• Metastasis: Spread of tumour cells from the primary site to form secondary tumours at other sites in the body.

Question 2

Describe the sequential process of metastasis

Answer 2

1. Transformation: The cell starts to proliferate until it reaches a certain size
2. Angiogenesis: New blood vessels start to form around the tumour.
3. Motility and Invasion: Then, the tumour escapes through blood vessels and lymphatics. It forms multi-cell aggregates.
4. Embolism: It embolises in the lungs primarily, and other organs where it then metastasis.
5. Arrest and Adherence: It arrests to form micrometastases and arrests in the capillary bed.
6. Extravasation into organ parenchyma
7. In response to the microenvironment, the tumour will undergo further cell proliferation and angiogenesis.
8. Then forms further metastases.

Question 3

Summarise the key steps in cancer progression

Answer 3

1. There are extensive mutagenic and epigenetic changes followed by clonal expansion.
2. Then, the cell undergoes angiogenesis to overcome the limitations that hypoxia proposes.
3. There is the transformation from epithelial to mesenchymal allowing for intravasation and extravasation.
4. Then, the colonization of target organs which will allow the expansion of the micrometastases.
5. Finally, the release of the metastatic cells that have required the ability to colonise.

Question 4

What is angiogenesis?

Answer 4

Angiogenesis is the formation of new blood vessels from pre-existing vessels.

Question 5

What is vasculogenesis?

Answer 5

Vasculogenesis is the formation of new blood vessels from progenitors.

Question 6

What are the three types of angiogenesis and what sort of growth do they form/used in?

Answer 6

• Developmental/vasculogenesis which leads to organ growth.
• Normal angiogenesis occurs in wound repair, the placenta during pregnancy and cycling ovary, and other physiological processes.
• Pathological angiogenesis occurs in tumours, ocular and inflammatory disorders (affect macular degeneration). This is when you do not want new blood vessel growth.

Question 7

Difference between breast cancer in situ and invasive human breast cancer

Answer 7

In situ breast cancer is not well vascularised therefore it is unable to grow beyond a certain size without its own blood supply (tumours aren’t able to grow beyond about 1-2mm(3) without their own blood supply). However, in invasive human breast cancer; there are lots of cell types so there is a loss of rigid structures. This will increase the blood vessel network.

Question 8

Describe the process of tumour angiogenesis

Answer 8

1. Tumours become hypoxia as they move away from the nearby capillary.
2. When they become too big, they do not have enough oxygen or nutrients so an angiogenic switch occurs. The tumour secretes factors that promote the growth of vessels.
3. Angiogenic factors such as vascular endothelial growth factor (VEGF) is secreted from the tumour. This is a cytokine that diffuses and initiates the endothelial cell near the capillary to migrate and proliferate.
4. When enough proliferation occurs, a vessel network will form around the tumour = blood vessel network.
5. Depending on the genomic instability, the tumour cell can be heterogenic which causes changes in the oncogene causing other cells to mutate so there are lots of offshoots.
6. A cell can escape the primary tumour through the vascular network leading to metastatic spread.

Question 9

How is hypoxia a stimulus for tumour angiogenesis?

Answer 9

As the distance between the tumour and the capillary increases, there is lower oxygen tension. Therefore areas of the tumour will have a reduction in oxygen and become hypoxic. Hypoxia activates transcription of genes involved in angiogenesis, tumour cell migration and metastasis. Such as GF being released e.g. VGEF.

Question 10

Give examples of angiogenic factors secreted by tumour cells to stimulate directional growth of endothelial cells

Answer 10

• Vascular Endothelial Growth Factor (VGEF)
• Fibroblast Growth Factor-2 (FGF-2)
• Transforming Growth Factor-Beta (TGF-Beta)
• Hepatocyte growth factor/scatter factor (HGF/SF)

Question 11

What ways are angiogenic factors released?

Answer 11

• Secreted by tumour cells

- Stored bound to components of the extracellular matrix and may be released by enzymes called matrix metalloproteinases

Question 12

What is the function of matrix metalloproteinases (MMPs) enzymes?

Answer 12

Facilitate invasion and give the enzymatic capacity to spread the tumour.

Question 13

How is the VGEF signalling cascade activated?

Answer 13

1. VGEF binds to the tyrosine kinase receptor causing dimerization.
2. It activates the pathways that stimulate cell growth, gene expression, etc. Ras, MAPK, PkB, and PkC
3. These are all in operation in the endothelial cell following VEGF binding. It allows for cell proliferation and vasopermeability, Angiogenesis, Cell Survival, and Gene expression.

Question 14

What are the mechanisms the tumour cell adopts for motility and invasion?

Answer 14

• Increased mechanical pressure caused by rapid cellular proliferation
• Increased motility of the malignant cells (epithelial to mesenchymal transition) - switches to a different cell and becomes de-differentiated - fibroblast cells.
• Increased production of degradative enzymes by both tumour cells and stromal cells.

Question 15

How does the epithelial-mesenchymal transition occur?

Answer 15

1. The epithelial-like cells express cell-cell adhesion molecules and other cell apparatus so it keeps the epithelial features.
2. The genes that make them epithelial cells become downregulated e.g. adhesion molecules and actins
3. There is an upregulation of cell pathways to change into a mesenchymal cell such as P13K (targeted by a lot of therapies at the moment). This drives the expression of genes e.g. fibronectin.

Question 16

What is lost during the epithelial-mesenchymal transition?

Answer 16

• Epithelial shape and cell polarity
• Cytokeratin intermediate filament expression e.g. actins
• Epithelial adherens junction protein (E-cadherin) - cell to cell adhesion molecules.

Question 17

What is acquired during the epithelial-mesenchymal transition?

Answer 17

• Fibroblast-like shape and motility
• Invasiveness
• Vimentin intermediate filament expression
• Mesenchymal gene expression (fibronectin, PDGF receptor, avbeta6 integrin) - integrin binds to the cellular matrix rather than cell to cell
• Protease secretion (MMP-2, MMP-9)

Question 18

Characteristics of E-cadherins

Answer 18

• Homotypic adhesion molecule (adhesion of cells with the same cadherin)
• Calcium-dependent
• Inhibits invasiveness
• Binds beta-catenin
• E-cadherins are important for contact inhibition

Question 19

What is the contact inhibition of E-cadherins?

Answer 19

1. Recognize that there is another cell nearby and the cell starts proliferating due to cell-cell adhesion molecules called E-cadherins (facilitate cell-cell contact)
2. E-cadherin will contact and bind to an E-cadherin on another cell. They recognize each other, maintain polarity, and stop proliferation.
3. There is a loss of E-cadherin meaning proliferation doesn’t stop and the cells start to grow on top of each other. These are cancer cells.

Question 20

Characteristics of Integrins

Answer 20

• Heterodimers (alpha and beta subunits)
• Heterotypic adhesion molecule
• Adhesion to the extracellular matrix (via collagen, fibronectin, laminin)
• Cell migration

Question 21

How do integrins allow for the cell to gain the ability to bind to the extracellular matrix?

Answer 21

1. Whilst losing contact inhibition, cancer cells gain the ability to bind to the extracellular matrix.
2. They do this through integrins. They are able to dimerize and acquire invasive properties.
   The integrins have lots of different binding partners.

Question 22

Describe how stromal cells contribute to tumour progression

Answer 22

1. Factors are released by stromal cells (macrophages, mast cells, fibroblasts) include angiogenic factors, growth factors, cytokines, proteases which affect the cancer cells. They release an inactive precursor.
2. These bind to the uPA (urokinase-type plasminogen activator) receptor which is activated by tumour cells.
3. This results in plasmin production. This activates matrix metalloproteinases (MMPs) which permit invasion by degrading extracellular matrix (ECM) thus releasing matrix-bound angiogenic factors. This assists cancer cells in becoming invasive.

Question 23

What is plasmin?

Answer 23

A potent proteolytic enzyme important in fibrin dissolution also mediates cell migration. It does this by activating pro-MMPs to MMPs. It also activates latent GF in the extracellular matrix.

Question 24

What are the steps involved in cancer dissemination?

Answer 24

1. Primary tumour formation
2. Localised invasion
3. Intravasation: interaction with platelets, lymphocytes, and other blood components.
4. Transport through circulation
5. Arrest in microvessels of various organs
6. Extravasation
7. Formation of a micrometastasis
8. Colonisation - formation of a macrometastasis

Question 25

Which parts of cancer dissemination are inefficient?

Answer 25

• Formation of a micrometastasis
• Colonisation - formation of a macrometastasis
  They are very inefficient (<0.02% of cells actually form micrometastases.

Question 26

What are the sites of tumour metastasis?

Answer 26

• Breast cancer: go to the brain, bone, lung, and liver
• Colorectal cancer: go to the liver and lung
• Gastric cancer: go to the liver, oesophagus, and lungs
• Lung (Non-Small Cell) cancer: go to the brain, bone, kidney and liver.
• Pancreatic cancer: go to the lung and liver.
• Prostate cancer: go to the bone

Question 27

What are the two hypotheses that determine the pattern of tumour spread?

Answer 27

1. Mechanical Hypothesis: what is close by that cancer spreads to.
2. Seed and Soil Hypothesis: climate within a distant site is desirable for specific molecules

Question 28

What is the mechanical hypothesis?

Answer 28

Anatomical considerations: Blood and lymphatic systems, entrapment in capillary beds (20 - 30 um carcinoma cell, about 8 um capillary)

Question 29

What is the seed and soil hypothesis?

Answer 29

Specific adhesions between tumour cells and endothelial cells in the target organ, creating a favourable environment in the target organ for colonisation.
Genetic alterations acquired during progression allow tumour cells to metastasize.

Question 30

What has been seen to inhibit cancer by targeting tumour angiogenesis?

Answer 30

Success with targeted therapy to angiogenic factors like vascular endothelial growth factor.

Question 31

What success has there been with targeting cell motility?

Answer 31

No success with targeting cell-cell adhesion molecules or integrins.

Question 32

What success has there been in targeting invasion of tumour cells?

Answer 32

All clinical trials with matrix metalloproteinases have been unsuccessful in reducing tumour burden.

Question 33

Which 3 areas have been the forefront of decades of research?

Answer 33

• Tumour angiogenesis
• Cell motility
• Invasion

Question 34

What hypothesis did Judah Folkman introduce?

Answer 34

• Introduced the angiogenesis hypothesis.
• Tumour growth is dependent on new blood vessel growth.
• Paradigm shift in cancer therapy: both the tumour and microvascular compartment are valid therapeutic targets. Targetting the microvascular compartments of cancer.

Question 35

Give an example of pathological angiogenesis

Answer 35

Kidney cancer/renal cell carcinoma is a highly angiogenic and metastatic tumour. This can be treated with anti-angiogenic drugs.

Question 36

What is avastin?

Answer 36

The first specific anti-angiogenesis drug in 2013 was the second biggest-selling oncology product. It was approved for colorectal, lung, kidney and ovarian cancers and eye diseases.

• Monoclonal antibody
• Binds to VGEF
• Prevents VGEF binding to VGEF receptors on endothelial cells

Question 37

What is the mechanism of action of Avastin/bevacizumab?

Answer 37

1. The antibody binds to VGEF and stops it binding to receptors.
2. Receptors do not dimerize so downregulation of cell signalling pathways.