Lecture 8 - Cancer Flashcards
1
Q
Cancer
A
- Selection should favor cells that can outreproduce other cells
- Impetus for cancer
- Cells that differentiate lose the ability to proliferate
- Creates a trade-off between specialization and proliferation
- Found in all multi-cellular organisms
2
Q
Cancer Prevention in Organisms
(TAC)
A
- Undifferentiated cells have ability to clone
- Differentiated cells do not reproduce
- Transient amplifying cells: partially differentiated that increase proliferation of stem cells
- Each TAC stage doubles descendant cells
- Metabolically expensive
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3
Q
Mathmatical simulations for TAC
A
- Stem cells exactly replicate themselves
- But how low proliferation potential
- TAC do not replicate but high proliferation
- Self-renewal/proliferation required for selection
- DNA must replicate itself and anything that promotes reproduction should be favored
- Implication: What if there are differentiated cells capable of proliferation?
4
Q
Insulin cells of pancreas
A
- Pancreatic islet cells are differentiated and capable of replication
- Pancreatic cancer is very rare
- Cells at risk of cancer development and cells at risk may be seen as cancerous
- Potential mechanism: Because they replicate, immune system may view this organ as suseptible to cancer
- Maybe this explains Type 1 Diabetes?
- When growth is rapid, immune system kills islet cells
- Immune system may be more susceptible to cancerous cells during reproductive years, thus low risk of pancreatic cancer during this time.
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5
Q
Type 1 Diabetes
and Type 2
A
- Type 1 usually in juveniles and especially those with type 1
- Relative of T2 risk highest when diabetes duration lower
- In cases where diabetes has a long duration, risk of cancer is lower so therefore T2 likely not caused by cancer.
- If pancreatic cancer has a relationship to T2, its a negative association
- Since pancreatic cancer is pretty lethal, not likely to have a long duration of T2
- Unclear if T2 causes cancer or cancer causes T2
6
Q
Warburgh Effect
(And math)
A
- Aerobic glycolysis produces ATP faster
- Cancer uses this
- Therefore, if we deprive cells of oxygen, more likely to become cancerous
- Fermentation (non-aerobic) outcompetes when lots of glucose is available
- Fermentation population decreases over time though
- Because it’s faster, but less efficient (makes less atp/glucose)
7
Q
Oxygen and Cancer
(and strategic usefulness of oxygen for cancer)
A
- Cancer cells can grow without oxygen
- Some types of cancer cells need oxygen though and have reduced ability to produce ATP from glycolysis (fermentation)
- Glycolysis can support higher growth rates for cancer cells
- Does not produce oxygen radical so oxidative stress not a part of this and the cell won’t be damaged by it.
- Because it doesn’t, an important trigger for cell death (apotosis) doesn’t occur so these cells can keep surviving
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8
Q
Poff et al (2013) - Experiment
A
- Restrict access of cancer cells to glucose
- Give protein or fat
- Artificially increase levels of oxygen
- To increase oxidative stress and help body target cells for destruction
- Control was given a standard diet, condition groups given low carb (kerotogen) diet, low carb with more oxygen, standard diet with oxygen
- Standard diet + oxygen rats died sooner
- Low carb high oxygen and low carb survived the longest
- Kerotgen diet also significantly reduced weight
- Lots of evidence suggests that underfeeding reduces cancer development
9
Q
Cachexia
(plus hypothesis)
A
- Loss of appetite, weight/muscle
- POSITIVE risk factor for death in cancer
- Viewed as a negative symptom
- Pathological symptom of cancer
- Loss of body tissue fuels the cancer
- But why loss of appetite?
- Body trying to take control of the cancer by reducing energy intake
- Adaptive response to cancer
