1 / 38

Lecture #9. July 13,2001 Cell signaling: Receptor tyrosine kinases NO and NYC. Chapter 15 .

Lecture #9. July 13,2001 Cell signaling: Receptor tyrosine kinases NO and NYC. Chapter 15 . Axiom #9: Multitasking is essential for success. The Nobel Prize in Physiology or Medicine 1994. "for their discovery of G-proteins and the role of these proteins in signal transduction in cells".

ajay
Download Presentation

Lecture #9. July 13,2001 Cell signaling: Receptor tyrosine kinases NO and NYC. Chapter 15 .

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Lecture #9. July 13,2001 Cell signaling: Receptor tyrosine kinasesNO and NYC.Chapter 15. Axiom #9: Multitasking is essential for success

  2. The Nobel Prize in Physiology or Medicine 1994 "for their discovery of G-proteins and the role of these proteins in signal transduction in cells" Alfred G. Gilman Martin Rodbell USA USA University of Texas, Southwestern Medical Center Dallas, TX, USA National Institute of Environmental Health Sciences Research Triangle Park, NC, USA 1941 - 1925 - 1998 The importance of G-proteins

  3. The Nobel Prize in Physiology or Medicine 2000 "signal transduction in the nervous system" Arvid Carlsson Paul Greengard Eric R Kandel Sweden USA USA Göteborg University Göteborg, Sweden Rockefeller University New York, NY, USA Columbia University New York, NY, USA 1923 - 1925 - 1929 - The significance of “signal transduction in the nervous system"

  4. The Nobel Prize in Physiology or Medicine 1999 "for the discovery that proteins have intrinsic signals that govern their transport and localization in the cell" Günter Blobel USA Rockefeller University New York, NY, USA and National Institute of Environmental Health Sciences Research Triangle Park, NC, USA 1936 - Peptide signaling

  5. How do cells regulate [Ca2+]?Sequester in ER, bind to proteins! • Calmodulin binds 4 Ca2+ ions • In most cases, CM +Ca2+ binds to an effector • Accordingly, CM –Ca2+ dissociates from target • CM/kinase

  6. Signaling by Tyrosine Kinases

  7. Protein Tyrosine Kinases (PTK) 5 classes in the superfamily • AGC group: PKA, PKG, PKC, Rac, G-protein kinases • CaMK group: kinases regulated by Ca2+/CaM • CMGC group: cyclin-dependent kinases ERK, MAP, Casein kinase • PTK group: conventional protein tyrosine kinases Src, Abl, Fak, PDGF, IR 5. OPK: Other Protein Kinases

  8. Tyrosine kinases can be cytosolic or integral membrane receptors . Substrate Single Membrane spanning Hydrophobic domain. How many does the GPCR have? No membrane-spanning domain

  9. What are the substrates for TKs?Src, is a non-receptor tyrosine kinase Src, is the product of the first proto-oncogene to be characterized. Fariba Fana

  10. Src and other proteins that have Src-homology domains can bind to RTKs! Even though Src is a cytoplasmic Tyrosine Kinase, Src homology domains: (SH)

  11. Other proteins have homologies to Src domainsSH Src-homology regions • SH1 domain: Catalytic domain of the protein: kinase activity • SH2 and SH3 domains: mediate protein-protein interactions in cellular signaling cascades: very common in proteins outside the Src family. • SH2: binds peptides with consensus: (PTyr-Met/Val-X-Met) • SH3: b-barrel. Interacts with proline-rich peptide targets • SH4 domain: myristylation and membrane-localization signal

  12. The Src homology 2 (SH2) domain has been found in a number of signal transduction pathways. Its primary function is to bind phosphotyrosines and in doing so localizing different proteins necessary to transmitt the proper function Pawson, 1997. Elegant experiments using a combinatorial approach showed that specificity for a particular protein is encoded in the amino acids following the phosphotyrosine Songyang, 1993. Monday, April 20 1998 08:26 SH2 Domains

  13. SH3 b-barrel of 5-6 anti-parallel b-strands. Binds a polyproline helix The loss of binding can lead to a constitutively active Src molecule and cancer Williams, 1998

  14. Receptor tyrosine kinasesAll are single membrane-spanning proteins • General Relevance • Tyrosine phosphorylation is frequently an EARLY event in signaling. • Amplification by downstream signaling elements greatly amplifies the effects of low levels of tyrosine phosphorylation that are most directly induced by extracellular triggers. Example: PLC and PI3K • Activation of multiple kinases (kinase cascades) including ser/thr as well as tyrosine kinases, is a frequent consequence of these early events. Example: MAP Kinase • There is often cross-talk between tyrosine kinase-induced pathways and other, e.g. G protein, signaling pathways.

  15. You know that I’m going to ask you why you should care about receptor tyrosine kinases! Activation of receptor tyrosine kinases ultimately leads to cell division or differentiation, for example, during embryonic development. Other functions • Growth control • Cell-cell recognition • Cell cycle control • Immune responses • Development • Differentiation Are these processes important? What happens if a check point looses function?

  16. Tyrosine Kinases and associated genes and proteins are implicated in developmental defects and cancer. • Excessive activation of receptor tyrosine kinases can lead to uncontrolled growth and malignant transformation. • Many defective or viral forms of tyrosine kinases and associated proteins are oncogenic: • v-src • abl • erbB

  17. Classes of Receptor Tyrosine kinases • EGFreceptor, NEU/HER2,HER3 • Insulin receptor • PDGF • FGF • VEGF • Eph

  18. What makes a RTK active? a) Conformational change: Insulin Receptor Kinase (IRK) Binds insulin Autophosphorylates Activates substrates including IRS-1 (insulin receptor substrate 1) by tyrosine phosphorylation b) Dimerization: • PDGF Receptor: Binds platelet derived growth factor (PDGF) Monomeric integral membrane protein Autophosphorylates Activates enzymes including PI3 kinase, Phospholipase Cg and GAP (GTPase activating protein) by tyrosine phosphorylation 2. EGF Receptor Monomeric integral membrane protein 3. Eph Receptor family: Erythropoietin producing hepatocellular carcinoma cell line Binds to Ephrins (ligand) Role in neurogenesis (neuronal pathfinding)

  19. Response of the insulin receptor kinase (IRK) to ligand bindingFig. 15.20 • Heterotetramer (2a, 2b) • Insulin binding leads to change in structure (different from other RTKs) • Conformation change activates b-subunit TK activity • b subunit phosphorylates Tyr residues on cytoplasmic domains as well as downstream substrates (IRS)

  20. Three-dimensional structures of the insulin receptor tyrosine kinase (IRK) IRK conformational change upon activation loop phosphorylation. The N-terminal lobe of IRK is colored white and the C-terminal lobe is colored dark grey. The activation loop (green) contains autophosphorylation sites Y1158, Y1162 and Y1163, and the catalytic loop (orange) contains the putative catalytic base, D1132. Also shown are the unbound/bound ATP analog and tyrosine-containing substrate peptide (pink). [Hubbard, EMBO J. 16, 5572 (1997)]

  21. Once Tyr-Phosphorylated, the IRK activity trigerrs a number of signaling pathways. • Phosphatidylinositol 3-hydroxy kinase, makes PIP2,PIP3 • Grb2, Sos, activates Ras • Activation of PI-PLC

  22. Unlike IRK, most RTKs are present as a monomer in the resting cell membrane

  23. Receptor Tyrosine Kinases Receptor protein-tyrosine kinases transmit signals across the plasma membrane, from the cell exterior to the cytoplasm.

  24. Receptor tyrosine kinases The interaction of the external domain of a receptor tyrosine kinase with the ligand, often a growth factor, up-regulates the enzymatic activity of the intracellular catalytic domain, which causes tyrosine phosphorylation of cytoplasmic signaling molecules. Fig. 15.23

  25. Fibroblast Growth Factor Receptor Tyrosine Kinase • During the metastasis of tumor cells, the adhesion between normal cells and cancerous cells must be broken. Many molecules involved in this process have been identified, and most are implicated in either heritable human diseases or cancer. For instance, members of the fibroblast growth factor receptor (FGFR) family have been linked widely to the development of cancer and disease. • Dimeric assembly of 2 FGF2:FGFR1 complexes. FGF2 is colored orange, Ig-like domain 2 of FGFR1 is colored green, and Ig-like domain 3 of FGFR1 is colored cyan. [Plotnikov et al., Cell 98, 641 (1999)]

  26. N-CAM modulates tumor-cell adhesion to matrix by inducing FGF-receptor signalingUGO CAVALLARO, JOACHIM NIEDERMEYER, MARTIN FUXA, Nature Cell Biology3, 650-657 (July 2001)

  27. Eph receptor kinase • Erythropoietin producing hepatocellular carcinoma cell line • Putative signaling effectors are in light shading. • Proteins with known SH2 domains are depicted as oval shapes

  28. RTKs can activate the Ras pathway of cellular signaling • Ras is a small G-protein (monomeric 21-kD) • Mutant Ras proteins are unable to dissociate GTP, so they are stuck in the ON or proliferative state: ras (gene) mutations found in 30% of human cancers. • Do you think mutations in Ras-GAPs can lead to disease? Oui!

  29. Steps in the activation of Ras by RTKs. Fig. 15.24 Raf is a PK that triggers MAP-K pathway Raf SH2 binds RTK, SH3 binds SOS c-fos, c-jun Cell proliferation Ras-GEF

  30. The Nobel Prize in Physiology or Medicine 1998 "for their discoveries concerning nitric oxide as a signalling molecule in the cardiovascular system" Robert F. Furchgott Louis J. Ignarro Ferid Murad USA USA USA SUNY Health Science Center Brooklyn, NY, USA UCLA School of Medicine Los Angeles, CA, USA University of Texas, Health Science Center Dallas, TX, USA 1916 - 1941 - 1936 - NO signaling

  31. Nitric oxide is a free radical • It contains an unpaired electron • .N=O • Role in macrophage killing of pathogens • NO also acts as a second messenger that causes relaxation of smooth muscle

  32. Signal transduction pathway mediated by NO and cGMP. PDE5 136252

  33. Nitric oxide (NO) is a small membrane-permeating free radical. It is synthesized as needed, since it cannot be stored in vesicles. Consequently, regulation of its synthesis is crucial. • Nitric oxide synthase (NOS) converts arginine to NO and citrulline • NOS is activated by Ca2+/calmodulin • NOS is inactivated by phosphorylation • NOS is located only in neurons in CNS (2% of all cells)

  34. Nitric Oxide Synthase Complexed with Dystrophin and Absent from Skeletal Muscle Sarcolemma In Duchenne Muscular Dystrophy • J. E. Brenman , D. S. Chao , H. Xia , K. Aldape , and D. S. Bredt 1 • 1 Department of Physiology, University of California, San Francisco School of Medicine 94143-0444, USA NOS is a dystrophin-binding protein

  35. Pfizer web site • VIAGRA enables many men with erectile dysfunction to respond to sexual stimulation. When a man is sexually excited, VIAGRA helps the penis fill with enough blood to cause an erection. After sex is over, the erection goes away.

  36. How does Viagra work? • Enlivens the male “wunder horn” with fresh sound? • Sildenafil inhibits PDE5 (phosphodiesterase 5) • cGMP build up in the cell • Enhances the effects of NO • Not for patients using nitrates (nitroglycerine)

  37. Summary Be able to outline pathways for: • GPCR (Fig. 15.13) • IRK activation and downstream effectors • RTK and activation of Ras • Compare and contrast activation events mediated by Ca2+, cAMP and NO.

  38. Finito • For Monday • Read Chapter 16, the Biology of Cancer

More Related