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How does Ras act in our body, in vivo ? Why would constitutively active Ras lead to cancer ? From cell culture to model organisms.

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Presentation on theme: "How does Ras act in our body, in vivo ? Why would constitutively active Ras lead to cancer ? From cell culture to model organisms."— Presentation transcript:

1 How does Ras act in our body, in vivo ? Why would constitutively active Ras lead to cancer ? From cell culture to model organisms

2 Model organisms teach us about ourselves Drosophila melanogaster Caenorhabditis elegans Xenopus laevis Mus musculus Californias governorus

3 5 Key Signal transduction pathways Critical for development and homeostasis All are involved in Cancer

4 5 Key Signal transduction pathways RTK- Ras (me) Critical for development and homeostasis All are involved in Cancer Wnt (you) TGF-ß (you) Hedgehog (you) Notch (not this time)

5 Signal transduction pathways RTK Receptor tyrosine kinases SrcRTKs

6 In the absence of Ligand RTKs are monomers with an inactive kinase

7 Ligand binding activates RTKs by dimerization Lodish et al. Fig. 20-21

8 RTKs are their own substrates-- i.e., they autophosphorylate

9 Remember SH2 domains? What did they bind??

10 SH2 domains allow “effector” proteins to bind activated receptors

11 One adaptor with an SH2 domains is Grb2 It also has SH3 domains--what do they bind?

12 One adaptor with an SH2 domains is Grb2 It also has SH3 domains--what do they bind?

13 Step by step--think dominos

14 Remember-Ras is anchored to the membrane through a lipid

15 And SOS is a GEF--remember them??

16 Figure 15-60 Molecular Biology of the Cell (© Garland Science 2008) Each activated protein activates the next

17 Figure 15-60 Molecular Biology of the Cell (© Garland Science 2008) MAPK/ERK enters nucleus Each activated protein activates the next

18 Figure 15-60 Molecular Biology of the Cell (© Garland Science 2008) MAPK/ERK enters nucleus Each activated protein activates the next

19 Figure 15-60 Molecular Biology of the Cell (© Garland Science 2008) Each activated protein activates the next MAPK/ERK enters nucleus

20 The RTK pathway

21 We made it to the 90s 10 years-old Britney Spears Kurt Cobain A new graduate from Harvard Travolta is still dancing

22 Model organisms teach us about ourselves Drosophila melanogaster Caenorhabditis elegans Xenopus laevis Mus musculus Californias governorus

23 The eye of a fly: One Key to learning how Ras and RTKs work Lodish et al. Fig. 20-24

24 Did you say flies?

25 Did you say flies?

26 This is all I need to know

27 But wait--flies Helped us Understand The single Most important Human oncogene Lodish et al. Fig. 20-24

28 I told you the RTK pathway is key in MANY developmental decisions

29 Each ommatidium contains the cells needed to see the world

30 These cells choose fate one by one, each telling the next what fate to adopt

31 Wild-typesevenless mutant sevenless mutants lack an R7 photoreceptor

32 Sevenless encodes an RTK Lodish et al. Fig. 20-25

33 To get a cellular response, There is a threshold level of pathway activity Gian Garriga sev pathway activity wild type sev - sev ts sev ts sev ts ; enh*/+ 22.7 o C 24.3 o C 22.7 o C sev threshhold R7 present R7 absent

34 Scientists figured out how to tune RTK activity using a temperature sensitive mutant Gian Garriga sev pathway activity wild type sev - sev ts sev ts sev ts ; enh*/+ 22.7 o C 24.3 o C 22.7 o C sev threshhold R7 present R7 absent

35 They then looked for mutants In other genes that would drop Pathway activity below the threshold Gian Garriga sev pathway activity wild type sev - sev ts sev ts sev ts ; enh*/+ 22.7 o C 24.3 o C 22.7 o C sev threshhold R7 present R7 absent

36 The mutations identified were candidates To encode things in the RTK pathway

37 Wow--Ras, an adapter and a GEF are in the RTK pathway! Sos Ras Grb2

38 Further, Ras acts downstream of the RTK Sevenless Lodish et al. Fig. 20-25

39 The signal transduction pathway should look familiar Grb2 Alberts et al. Fig. 15-53

40 Because that’s how we figured it out! Grb2 Alberts et al. Fig. 15-53

41 Caenorhabditis elegans Flies were bad enough, but worms!?

42 Caenorhabditis elegans Luckily the Nobel Committee thinks they are cool

43 lineage and programmed cell death Bob Horvitz John Sulston Sydney Brenner Physiology and Medicine 2002 RNAi Physiology and Medicine 2006 Andy Fire Craig Mello GFP Chemistry 2008 Marty Chalfie Nobel Prize

44 A simple model for organogenesis Formation of the vulva in C. elegans (“ask Gidi what he did in graduate school?”) vulva Only 22 cells! sperm oocytes embryos early oocytes

45 The Key Players One gonadal anchor cell (AC) 6 vulval precursor cells (VPCs) The anchor cell induces vulval fates Sherwood and Sternberg (2003) Dev Cell

46 Cell Induction The AC signals the VPCs to adopt vulval fates Only 3 VPCs will actually form the vulva

47 How can we figure out how to build a vulva? GENETICS!

48 No vulva induction wild type multivulvae (Muv) vulvaless (Vul) Mutants with no vulval signaling Mutants with too much vulval signaling

49 multivulvae (Muv) vulvaless (Vul) Loss of function mutants in the signaling pathway Gain of function mutants in the signaling pathway

50 some examples A Screen for Vul and Muv mutants Vul Muv let-23 lin-3 lin-15 let-60 Next step: cloning and sequencing the genes Bob Horvitz physiology and medicine 2002 Nobel Prize

51 The first two vul mutations identify the anchor cell signal and its receptor

52 let-23 is an EGFR homologue = RTK Alberts et al. 21-44 lin-3 is an EGF homologue Where do they function? Lin-3 is expressed in the AC Let-23 is expressed in all the VPCs Vul lin-3 let-23

53 - lin-15 was found to be an inhibitor of vulval induction (loss of function mutation) Muv lin-15 let-60 lin-15 - let-60 was found to promote vulval induction (gain of function mutation)

54 Next step: clone the let-60 gene First evidence: Ras has an in vivo role as part of the RTK pathway

55 The gain-of-function mutation = Glycine 13 Glutamine All the VPCs make vulvae G13Q Constitutively active Ras

56 Suppressor and enhancer screens [suppressors (or enhancers) of the mutated phenotype] Other mutations of ras lin-15 How can we find the rest of the proteins in the pathway? ? ?

57 Vul = “bag of worms” Muv Normal vulva” For example, second mutations that turn Muv mutants into normal Vul worms

58 lin-15 This worked GREAT!

59 lin-15 This worked GREAT!

60 The fly and worm work allowed cell biologists and biochemists to return to mammalian cells to identify the ways these new proteins worked as machines

61 The RTK-Ras pathway also offers drug targets for cancer treatment Alberts et al. Fig. 21-44

62 The RTK-Ras pathway offers drug targets for cancer treatment e.g., the Raf kinase inhibitor sorafenib (also inhibits the RTKs VEGFR, PDGFR, and Kit)

63 The RTK-Ras pathway offers drug targets for cancer treatment e.g., the Raf kinase inhibitor sorafenib (also inhibits the RTKs VEGFR, PDGFR, and Kit) Approved for treatment of advanced renal cell carcinoma (Jan. 2006) Increased survival in Phase III liver cancer trial and approved for inoperable form (Nov. 2007) In clinical trials for melanoma and lung cancer

64 Summary - Cellular oncogenes = viral oncogenes

65 Summary - Cellular oncogenes = viral oncogenes - Ras, as one of these genes, encodes a small GTPase, acting as a molecular switch

66 Summary - Cellular oncogenes = viral oncogenes - Ras, as one of these genes, encodes a small GTPase, acting as a molecular switch - Ras is a major component of the RTK pathway

67 Summary - Cellular oncogenes = viral oncogenes - Ras, as one of these genes, encodes a small GTPase, acting as a molecular switch - Ras is a major component of the RTK pathway -Basic and Clinical Science provide a VERY powerful partnership

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