Angiogenesis

Question 1

Describe and explain the change in oxygen flux from the arterial to the Venus end of a capillary

Answer 1

Oxygen flux decreases from arterial to Venus end
As blood flows through, the [O2] decreases along the capillary as it diffuses out the capillary to areas of lower [O2], therefore slowing the flow of O2

Question 2

What is oxygen flux?

Answer 2

The flow of oxygen

Question 3

Why must cancer cells be close to a blood vessel?

Answer 3

It has high requirements for O2, glucose, amino acids etc.

The diffusion distance of O2 is limited

Question 4

What does the Krogh cylinder show?

Answer 4

Where cells can function based on O2 levels and closeness to blood supply

Question 5

If blood flow is low, what happens to the length of Krogh cylinder?

Answer 5

Length of cylinder is low

Question 6

If metabolic rate is high, what is the effect on the Krogh cylinder?

Answer 6

The diameter is small

Question 7

What does oxygen tension depend on?

Answer 7

Closeness to capillary

Closeness to arteriole end of capillary

Question 8

What are hypoxic cells?

Answer 8

Cells that don’t have enough oxygen to function, beyond critical oxygen tension level

Question 9

What is the oxygen diffusion distances under normal metabolism rate at:
Arterial end?
Venus end?

Answer 9

Arterial: 70 µM
Venus: 10 µM

Question 10

What is the diffusion distance in highly metabolic environments at the:
Arterial end?
Venus end?

Answer 10

Arterial: 150 µM

Venus end: 70 µM

Question 11

What are the 6 ways cancers can stay oxygenated?

Answer 11

1. Increase blood flow
2. Cause new vessels to grow in
3. Split existing blood vessels
4. Metabolism anaerobically
5. Grow along blood vessels
   [6. Develop new vessels de novo]

Question 12

What does VEGF stand for?

Answer 12

vascular endothelial growth factor

Question 13

Describe VEGF-A’s structure

Answer 13

A dimer with 2 identical polypeptides

Question 14

Describe how VEGF can result in the formation of new vessels

Answer 14

• VEGF produced and secreted into surrounding stroma
• VEGF binds to VEGF-Receptors and activates Ca2+ & other signalling pathways
• Increases permeability of blood vessels (becomes leaky)
• Enables breakdown of extracellular matrix by MMPs
• Pericytes withdraw
• Sprouts form
• Endothelial cells migrate to source of VEGF
• Cell division occurs behind migrating sprout to push it out
• Lumen formed in new endothelial
• Sprouts connect when they reach other sprouts, lumens connect, and blood can flow through

Question 15

What does HIF1 protein do?

Answer 15

Detected change in oxygen tension

Question 16

What happens in the cell when decreased oxygen tension is sensed by HIF1?

Answer 16

HIF1 upregulates and moves to nucleus where it can increase transcription of VEGF gene to VEGF protein
VEGF released, …

Question 17

What does hypoxia upregulate?

Answer 17

VEGF and HIF1a

Question 18

How can we tell that VEGF is upregulated by hypoxia?

Answer 18

VEGF is present at 5% [O2] but not 20% [O2] (normoxia)

Question 19

How do we know that HIF1a induces the expression of VEGF?

Answer 19

When the promoter region for the VEGF gene is mutated in the areas of HIF1a binding sites, no VEGF is expressed

Question 20

How does HIF1-a induce VEGF expression?

Answer 20

• HIF1a is ways being expressed under all conditions
• Under normoxia, HIF1a is degraded and cannot work
• Under hypoxia, HIF1a is not degraded and is able to build up
• HIF1a binds to VEGF-b, forming a stable complex which can pass through to the nucleus
• The complex can recognise and bind to the DNA sequence of the VEGF promoter region
• It helps to recruit transcription proteins, which can transcribe the VEGF gene into VEGF protein

Question 21

Describe the experiment used to measure vascular permeability

Answer 21

Cannulate blood vessel and inject solution with few RBCS.
Perfuse vessel and record pressure driving the solution.
Use the RBCs as markers of flow and count them
Work out permeability using fluid velocity and pressure

Question 22

What happens to vascular permeability if VEGF is addd but Ca2+ channels are blocked?

Answer 22

Vascular permeability does not change

Question 23

What is oedema?

Answer 23

A fluid common in many cancers caused by the increase in vascular permeability

Question 24

What happens to pericytes if VEGF is present?

Answer 24

They migrate away from. The blood vessel, allowing fluid to move out and flow through tissue easier

Question 25

What is intussusseption angiogenesis?

Answer 25

Blood vessel splits in two

Question 26

What are 2 differences between sprouting and intussuseption angiogenesis?

Answer 26

Sprouting requires an increase in vascular permeability

Sprouting produces a new vessel rather than splitting one into two

Question 27

What is an endothelial tip cell?

Answer 27

The cells that have filopodia and search for other growing endothelial tissues. They migrate towards source of VEGF

Question 28

What are endothelial stalk cells?

Answer 28

Dividing cells that push tip cells out towards source of VEGF

Question 29

What happens if tip cells meet?

Answer 29

They change from angiogenic to quiescent
Lumen is formed
Blood is able to flow through new vessels

Question 30

What is the role of Angiopoietin 1?

Answer 30

Stabilizes vessels

Enables epithelial cells to resist proliferation

Question 31

What is the role of Angiopoietin 2?

Answer 31

Destabilizes vessels,

Encourages growth and proliferation

Question 32

What is the role of PDGF?

Answer 32

Platelet derived growth factor
Recruits pericytes
Enables communication

Question 33

How are antibodies used to treat cancer?

Answer 33

They bin to circulating VEGF to stop them from binding to VEGF-R.

Question 34

What type of treatment is Avastin?

Answer 34

An antibody used to bind to VEGF to stop it from binding to VEGF-R

Question 35

How do VEGF-R blockers work?

Answer 35

inhibit tyrosine kinase

Proteins aren’t released so basement membrane is not degraded

Question 36

How do soluble receptors work as a treatment against VEGF?

Answer 36

Copies of VEGF-R modified to compete with VEGF-R by binding to VEGF
‘VEGF trap’

Question 37

How does VEGF get past the extracellular matrix?

Answer 37

• macrophages and mast cells are recruited from stoma to release MMPs
• MMPs degrade the ECM
• VEGF binds to VEGF-R
• Permeability of membrane increases, more MMPs leak out so more ECM is degraded (positive feedback)