Cell growth and differentiation

Question 1

What are the basic mechanisms responsible for turning a zygote into a mature multicellular organism?

Answer 1

Cell growth and differentiation.

Cell growth precedes differentiation, but with some overlap

Cells divide, lose potency. Cells become more specialised and eventually exit cell cycle and cell differentiation begins

Question 2

What are the three groups of diseases related to cell growth and differentiation?

Answer 2

Developmental conditions, can be related to defects in cell growth or differentiation e.g spina bifida

Neoplasia (and metaplasia)e.g cancer, tumours

Others e.g cardiac hypertrophy

Question 3

What are the two main forms of cell growth?
And what is cell growth balanced by?

Answer 3

Hypertrophy (bigger cells)
Hyperplasia (more cells) - most common form of cell growth in humans

Cell growth is balanced by cell death - apoptosis and necrosis

Question 4

What is hypertrophy?

Answer 4

Cells growing bigger. Caused by cells making more macromolecules, more proteins, more membrane.
Elevated protein synthesis is driver of increased cell size e.g heart.

Question 5

What is hyperplasia?

Answer 5

More cells, caused by cell division or proliferation - the cell cycle

Question 6

What is common between cell growth and differentiation?

Answer 6

The mechanisms governing them.

Cell growth and differentiation are governed by integration of multiple signals

Intra (e.g checks on health and physiology of cell, energy levels, sufficient nutrients for differentiation) and extravascular signals (checks on cellular physiology, growth and inhibitory factors, cell adhesion (on outside of cell) etc.)

Promoters act as “co-incidence detectors” - when there’s the right combo of signals being received by promoter, it makes binary decision

Decision to express genes YES/NO? Governs how much is made

Question 7

What do promoters do with signals?

Answer 7

Signals are integrated and converge on the promoters of key genes.

Promoters act as “co-incidence detectors” - when there’s the right combo of signals being received by promoter, it makes binary decision

Decision to express genes YES/NO? Governs how much is made

Question 8

What do extracellular signals follow?
What are the three broad classes

Answer 8

Ligand receptor binding - followed by intracellular cascade.

Paracrine: produced locally to stimulate proliferation of a different cell type that has the appropriate cell surface receptor

Autocrine: produced by a cell that also expresses the appropriate cell surface receptor

Endocrine: like conventional hormones, released systemically for distant effects

Question 9

What do the proteins that act as extracellular signals in cell growth and differentiation do?

Answer 9

Stimulate proliferation and survival – referred to as mitogens E.g growth factors and interleukins EGF, FGF, NGF, PDGF, IGF1, IL2, IL4

Induce differentiation and inhibit proliferation e.g TGFB

Can do either, promote cell growth or inhibit cell growth e.g Wnt ligands

Other signals act to induce apoptosis e.g TNFa and other members of TNF family, bind to receptor and elicit cascades causing death

Question 10

What is the m phase of the cell cycle?

Answer 10

Mitosis. Cell divides into 2 daughter cells.

Cell leaves mitosis and enters interphases. Grows in size throughout interphase as macromolecules are synthesised.

Question 11

What is the s phase?

Answer 11

Synthesis. Genome is copied.

Question 12

What is G1 and G2?

Answer 12

Gap phases.

G1 is between M phase and S phase.

G2 is between S phase going back to M phase.

Question 13

What cells are in G0?
How long are cells in G0?

Answer 13

Cells that have left the cell cycle are quiescent cells and are in G0.

In G0 indefinitely, metabolism takes over. Or can rejoin cell cycle as some stimulus makes them proliferate again.

Or they begin to differentiate., change shape and adopt a new function. Ultimately terminally differentiated and considered post mitotic cells.

Question 14

How can you tell if cells are in mitosis and are G0 and G1 cells or if they are G2 cells/going into mitosis?

Answer 14

Measure amount of cells in cell cycle.
Cells that have just been through mitosis and are G0 and G1 cells will have diploid genome.

Cells in G2/going into mitosis will have tetraploid genome 4N. As in DNA replication after mitosis chromosomes double.

Cells in synthesis will be somewhere in between as they’re in process of replicating.

Question 15

What does the FAC machine measure?

Answer 15

Measures the DNA content of every cell in a population by measuring the strength of the staining.

Question 16

How does increasing amount of DNA show on a FAC analysis?

Answer 16

DNA amount increases = Bigger peak with many cells.
Corresponds to diploid population, G1 and G0 cells.

Question 17

What does a second peak on the FAC analysis plot correspond to?

Answer 17

As amount of DNA increases again you get second peak, tetraploid cells G2 and mitosis

Question 18

What does the area between two peaks on a FAC analysis correspond to?

image is trace for population of cells with low rate of division

Answer 18

Cells in S phase, between 2 and 4 copies of chromosomes.

Question 19

How does the typical trace differ in a population of cells with a high rate of division?

Answer 19

Proportion of cells in G1/G0 have decreased, from 60% to 40%

Population in S phase has increased

G2/M doesn’t change much because it is time limited part of cell cycle

Question 20

What do check points ensure?

Answer 20

Ensures DNA synthesis and mitosis are separated, mitosis only happens when cells have right number of chormosomes. Synthesis only happens once cells have cleared mitosis and are ready.

Question 21

What are the three checkpoints in the cell cycle?

Answer 21

Restriction point. Dependent on factors e.g checks for DNA damage, if cell size big enough to be divided into two. Checks metabolite/nutrient stores are enough to get through process of synthesis and mitosis.

Second checkpoint, G2 M phase checkpoint. When cell commits to enter mitosis. Another check for DNA damage and that replication is complete, when cells divides it can guarantee there is enough chromosomal DNA for the two daughter cells

Final check point in mitosis, distinct doesn’t involve checks in DNA. Checks physical positioning of chromosomes on mitotic spindle, ensures when it separates the chromosomes are pulled apart. Ensures right number of chromosomes goes to each cell.

Question 22

What does CDK form a complex with?

Answer 22

Cyclins. Complex is an active kinase complex that can bind to and phosphorylate specific substrates

Question 23

How is Cyclin-CDK activity regulated?

Answer 23

• Cycles of synthesis (gene expression) and destruction (by proteasome)
• Post translational modification by phosphorylation
  
  • May result in activation (increase in kinase activation), inhibition or destruction (increased targeting to proteasome)
• Regulation by dephosphorylation
• Binding of cyclin-dependent kinase inhibitors (CDKis) able to bind to complexes and inhibit them

Question 24

What is retinoblastoma protein a substrate of?

Answer 24

G1 and G1/S cyclin-dependent kinases.

In presence of cyclin D-CDK4 and E-CDK2 it is phosphorylated, discociates from E2F.

E2F no long suppressed and binds to promoters of its target genes, including DNA pol + proteins involved in S phase.

Allows DNA replication to start, stimulates S phase.

Question 25

How does E2F cause a positive feed forward loop when it is freed from RB?

Answer 25

E2F binds to promoter Cyclin E, becoming partially active. Drives expression of more Cyclin E, creating positive forward loop.

Question 26

What triggers cell cycle arrest or apoptosis?

Answer 26

DNA damage, cell cycle stops, driven by expression of cyclin dependent kinase inhibtors e.g CHEK2.

Cell attempts to repair DNA using repair mechanisms - nucleotide or base exicision enzymes, mismatch repair etc

if repaired cell re-enters cell cycle, if not there is apoptosis

Question 27

What is TP53?

Answer 27

Tumour protein 53, tumour suppressor gene. Normally destroyed by proteasome.

In response to DNA damage by mutagen, TP53 is picked up by processes, leads to activation of protein kinases (including DNA dependent protein kinase), phosphorylates TP53.

TP53 can’t be destroyed by proteasome.

Question 28

What happens if TP53 accumulates?

Answer 28

• Drives expression of CDKI, causing cell cycle arrest
• Activation of DNA repair, DNA can be repaired and can return back to cell cycle. However, sometimes damage is too bad and TP53 will activate cell death.

Question 29

What mutations are frequent in cancer?

Answer 29

TP53 loss of function mutations.

Prevent cell cycle arrest – cells grow faster

Prevent apoptosis – cells do not die

Prevent DNA repair – more mutations, causes more heterogeneity, more chance of tumour mass adapting to its environment, drives cancer progression

Question 30

What are some S-phase drugs?

Answer 30

S phase drugs cause DNA damage

5-fluorouracil (prevents synthesis of thymidine), which is required for making more DNA

Cisplatin (binds to DNA causing damage and blocking repair)

Question 31

Examples of M-phase drugs

Answer 31

M-phase drugs target mitotic spindle

• Vinca alkaloids
  
  • Bind to free (monomeric) tubulin and stabilise it
  • Prevent microtubule polymerisation, can’t form a mitotic spindle
  • Arrests cells in mitosis
• Paclitaxel (Taxol)
  
  • Stabilises microtubules by binding to polymerised microtubules
  • Prevents de-polymerisation
  • Arrests cell in mitosis

Question 32

What is colchine used for?

Answer 32

Not just cancer: colchicine (similar mode of action to vinca alkaloids) is used for immune suppression

If you lose TP53, you lose lots of ways the cells response to these drugs e.g DNA synthesis inhibiting drugs