Receptor Tyrosine Kinases

Question 1

Receptor Tyrosine Kinases (RTK) Structure and Overview

Answer 1

• RTKs are critical for mediating signalling from ligands (growth factors, mitogenic factors, and factors important in survival like insulin)
• extracellular/cytoplasmic ligand-binding domain with intrinsic (built-in) tyrosine kinase binding activity which is stimulated by ligand binding due to Receptor Dimerization (two receptors binding together). Now adaptor proteins are recruited.
• exterior ligand-binding region + single transmembrane alpha-helix + cytoplasmic protein tyrosine kinase with activation loop
• Ras (small monomeric G protein) acts as a GTPase switch protein to signal further downstream kinases
• aberrant signalling in any part of this pathway is the root for cancers
• these receptors actually phosphorylate themselves (their cytoplasmic domain has the ability to phosphorylate itself and other proteins directly through transcription factors, and can also activate G proteins which activate kinases in a series of kinases.)

Question 2

Activation of RTKs for Signal Trasnduction

Answer 2

1. Dimerization: Ligand binding to ligand-binding region of RTK changes shape of receptor, which causes the two receptors to come together and dimerize (so you have two receptors and 2 ligands)
2. Phosphorylation: dimerization allows for trans-autophosphorylation of BOTH cytoplasmic domains (=the tyrosine kinases– specifically their Activation Loop. aka, ATP–>ADP)
3. Phosphorylation of additional tyrosine residues(AAs)==>
   Phosphotyrosines (has lots of Ps on domain). Serve as docking sites for downstream signal-transduction proteins containing SH2 (src homology 2) domains (adaptor domain)
   - you now have activated RTK
   - the recruited adapter proteins contain unique domains that recognize specific sequences

Question 3

Discovery of first oncogene

Answer 3

• Noticed that if we were to inject a tumour cell extract from unhealthy chicken sarcoma tissues into healthy chicken, this chicken would develop tumours and get cancer. Therefore transmissible agent was determined to be a retrovirus (Rous Sarcoma Virus)
• They were able to sequence the genome of that virus, and find a gene that encodes a tyrosine kinase (src)
  (so there was a kinase domain plus more domains labelled SH3 and SH2 in the genome– which is highly conserved and found in humans)
  -Normal version of virus = c-Src = cellular src which is inhibited by phosphorylation
• Viral version (v-Src) which is turned on all the time, which leads to it promoting tumours

Question 4

Ras, a GTPase switch protein

Answer 4

= monomeric G protein, GTPase superfamily, lipid-anchored protein
= downstream effector of RTK signalling
- similar to Galpha but smaller
- its activity is not directly linked to cell-surface receptors.
Doesn’t have intrinsic GTPase activity (aka, can’t activate itself, needs middle men to regulate its activity)
- so uses GAP to help speed up GTP hydrolysis (INACTIVATES)
- and GEF to turn GDP–> GTP (ACTIVATES)

Question 5

How could Ras produce cancer?

Answer 5

Ras binds GTP but no hydrolysis (so it’s constitutively on) because there’s been a mutation of glycine-12 which prevents binding of GAP

Question 6

FGF-Induced Ras Activation Step 1

Answer 6

• Ras is inactive and anchored to membrane by prenylation
• FGF (hormone) binds FGF receptor monomers (FGFR)
• binding of FGF causes receptor dimerization, kinase activation, and phosphorylation of cytosolic receptor tyrosine residues —> active FGF receptor dimer
• this sets up a docking scaffold for adapter proteins containing SH2 and SH3 domains
  
  • SH2 is critical for recognizing and binding to the tyrosines on the activated receptor tyrosine kinase
• example of adaptor protein recruited: GRB = Growth factor Receptor Bound protein = adapter protein with no enzymatic activity

Question 7

FGF-Induced Ras Activation Step 2

Answer 7

• assembly of a multiprotein complex at the cytosolic face of the plasma membrane == GRB2 has SH2 domain that binds Phosphotyrosine (on receptor), and two SH3 domains bind Proline in Sos
• Sos connects to Ras
• the binding of GRB2 acts as a middle man btwn kinase (receptor) and Sos
• Ras is still inactive, but is now primed

Question 8

FGF-Induced Ras Activation Step 3

Answer 8

• Sos is a GEF— it promotes dissociation of GDP from Ras; GTP binds and active Ras dissociates from Sos
• Ras-GTP is now active and triggers the downstream kinase cascade
  (Ras-GTP –> Raf –> MEK–>MAPK= mitogen-activated protein kinase

Question 9

Ras/MAP kinase pathway

Answer 9

1. Ras (lipid-anchored to membrane on cytosolic face) activated by exchange of GDP to GTP
2. Active Ras recruits, binds at Raf’s N-terminal regulatory domain, and activates Raf
   (inactive Raf is in cytosol bound to inhibitory protein 14-3-3)
3. GTP hydrolysis leads to dissociation of Ras from Raf (now Ras is inactive again)
4. Raf activates MEK by phosphorylation
5. MEK activates MAPK by dephosphorylating itself and phosphorylating MAPK (2Ps)
6. Active MAP kinase translocates to nucleus; activates many transcription factors, which go and alter genes controlling cell-cycle, cell growth, cell differentiation
   - MAPK aka, ERK= extracellular signal-regulated kinase

Question 10

RTK/RAS/MAP kinase pathway components that are frequently mutated in cancer

Answer 10

• everything in the pathway is a proto-oncogene (=disregulation is biased to being turned on, which makes cell likely to grow in uncontrollable manner) except for NF1 which is a tumour-suppressor gene
• Usually NF1 binds to activated RAS and helps hydrolyze GTP to turn RAS off. But recessive loss-of-function mutation in GTPase activating protein (NF1) leads to constitutive (permanent) activation of RAS.
• loss of GAP (because of glycine-12 mutation) leads to sustained RAS activation of down stream signal transducing proteins

Question 11

Oncogenic receptors promote proliferation in absence of ligand
(2 examples)

Answer 11

EGF receptor is a type of RTK.
- an oncogenic mutation (Val->Gln) in Her2 receptor (a type of EGF receptor) causes dimerization and activation of receptor in absence of ligand (==>Neu oncoprotein -neuroblastoma) –> uncontrolled cell growth in brain

• deletion (oncogenic mutation) that causes loss of extracellular ligand binding domain in EGF receptor leads to spontaneous dimerization and thus constitutive activation of cytoplasmic kinase domain (==>ErbB oncoprotein)

Question 12

The 4 types of Human Epidermal Growth Factor Receptors (HERs)

Answer 12

• part of epidermal growth factor (EGF) family
• 4 RTKs: HER1 to HER4
• HER2 doesn’t bind a ligand directly, but can form heterodimers (aka, HER1 and HER2, etc.)
• this dimerization is essential for transmitting the signal
• all 4 can bind EGF

Question 13

HER2 Amplification in Breast Cancer

Answer 13

• 25% of breast cancer patients have increased HER2 expression (>100 fold) due to HER2 gene amplification
• the cells are stimulated by very low concentration of EGF
• HER2 is targeted by a monoclonal antibody called Herceptin
• a cancer cell will also have many more receptors for Herceptin to bind onto because the gene has been amplified.

Question 14

Herceptin Mode of Action

Answer 14

• HER2 therapy designed to bind to HER2 and tumour cells to flag them for destruction by immune system (using antibody-dependent cytotoxicity and increased endocytosis of HER2)
• also blocks downstream HER2 signalling to inhibit proliferation of cells by physically blocking either homodimerization of heterodimerization

Question 15

What leads to constitutive activation of ErbB oncoprotein’s kinase activity?

Answer 15

a deletion that causes the loss of the extra-cellular binding domain in the EGF receptor