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Signaling by Tyrosine Phosphorylation in the Nervous System

Signaling by Tyrosine Phosphorylation in the Nervous System. Introduction. Protein phosphorylation represents the most common form of posttranslational modification in nature Protein function altered by addition of a negatively charged phosphate group to a Ser, Thr , or Tyr residue:

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Signaling by Tyrosine Phosphorylation in the Nervous System

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  1. Signaling by Tyrosine Phosphorylationin the Nervous System

  2. Introduction • Protein phosphorylation represents the most common form of posttranslational modification in nature • Protein function altered by addition of a negatively charged phosphate group to a Ser, Thr, or Tyr residue: • Binding properties • Enzymatic activity if a catalytic protein

  3. Introduction • Cell surface receptors recruit activity of protein kinases in two general ways: • Non-receptor tyrosine kinases: Receptors lacking self-contained kinase function recruit activities of intracellular protein kinases to the plasma membrane • Receptor tyrosine kinases: Possess an intrinsic tyrosine kinase activity that is part of the receptor protein. Examples include receptors for growth factors (PDGF, EGF, insulin, etc.)

  4. Receptor tyrosine kinases • Introduction: • Protein phosphorylation • Recruitment of kinases in signalling pathways • Consequences of protein phosphorylation • RTK family: • Classification and structure/function • RTK ligands • Receptor dimerization and autotransphosphorylation

  5. RTK family classification and structure/function • Four common structural features shared among RTKs: • Extracellular ligand-binding domain • Single transmembrane domain • Cytoplasmic tyrosine kinasedomain(s) • Regulatory domains

  6. Seven subfamilies of receptor tyrosine kinases

  7. RTK family classification and structure/function • Implicated in diverse cellular responses: • Cell division • Differentiation • Motility • At least 50 RTKs identified: • Subdivided into 10 subclasses based on differences within extracellular, ligand-binding domain of receptor • “Oncogenic” RTK mutants exist: • erbB gene encodes an N-terminal truncated, constitutively active form of EGF receptor

  8. Receptor tyrosine kinases • RTK-mediated pathways: • Ras-Raf-MAPkinase pathway, use of dominant negative mutants to map pathway • R7 photoreceptor development pathway inDrosophila

  9. RTK structure/function Regulatory domains

  10. RTKLigands • Typically small soluble proteins • Work in autocrine and paracrine manner • Dimerize (may aid in receptor dimerization) • Some RTK ligands membrane-bound

  11. RTKAutotransphosphorylation

  12. ReceptorDimerization and Autotransphosphorylation • Ligand-induced RTK activation induces receptor dimerization, leading to activation of catalytic domains. • Receptor autotransphosphorylation: • Further stimulates kinase activity • Leads to phosphorylation of additional proteins involved in receptor signalling pathway • Provides “docking sites” for downstream signalling proteins (Grb2, PI3-kinase, phospholipase Cg, etc.)

  13. Src homology (SH)2 and SH3 domains Supposed Purpose: Joins, combines, targets kinases and phosphatases (see below) with activated (ligand-bound) growth factor receptors. SH2 and SH3 refer to domains that bind specific peptides containing a phosphorylatedtyr or pro-rich sequence, respectively.

  14. Src homology (SH)2 and SH3 domains • Tyr phosphorylation allows recruitment of proteins that possess domains that bind to specific peptide sequences that encompass a phosphorylatedtyr and which  activating a variety of signalling pathways. • Such domains include SH2 and SH3 and P-tyr binding (PTB) domains. • These domains bind to the GF receptor only when it is phosphorylated on tyr residues. • SH2 domains: bind P-Tyr-containing sequences. • SH3 domains: bind to pro-rich (PxxP) sequences. • The proteins that contain SH2 domains belong to several categories: PLCγ, PI-3K, Grb2, SHP-2, Src(next slide):

  15. SH2 and SH3 domains

  16. RTK-mediated pathways: one pathway with two very different functions • Ras-Raf-MAPkinasepathway. • R7 photoreceptor development inDrosophila.

  17. RTK Signaling: Ras Pathway

  18. The regulation of Ras activity, a famous downstream molecule of RTK responsible for cancer development

  19. Three ways in which signaling proteins can cross-link receptor chains 1. dimer, 2. monomer but brought together by proteoglycan, 3. cluster on membrane

  20. The importance of receptor oligomerization

  21. The docking of signaling molecules at RTK

  22. The activation of Ras by RTK signaling

  23. The MAP-kinase regulated by Ras

  24. GDP GTP DNA The Ras-Raf-MAPkinase pathway SH2 domain SH3 domains Proline-rich regions (-PXXP-) Tyr-P Raf SOS Grb2 Ras (inactive) Ras (active) Pi Nucleus P MEK P P fos jun P P P P MAP kinase MAP kinase Increase gene expression

  25. Use of oncogenic and dominant negative mutants to map pathways • OncogenicRas (V12Ras): defective GTPase function. Always turned “on” (always GTP-bound) • Dominant negative Ras (N17Ras): can interact with its immediate upstream partner (SOS), but cannot become activated to transduce a downstream signal (i.e., to Raf). Effect is to “sequester” SOS to prevent it from activating endogenous Ras.

  26. GDP DNA Dominant negative Ras (N17Ras) sequesters SOS and blocks pathway from Ras on down SH2 domain SH3 domains Proline-rich regions (-PXXP-) GDP Tyr-P Raf Sos Grb2 N17Ras Ras (inactive) Nucleus jun MEK fos MAP kinase gene expression blocked

  27. GDP DNA Combine oncogenic and DN mutants to map position of pathway components SH2 domain SH3 domains Proline-rich regions (-PXXP-) GDP Tyr-P Raf Ras (inactive) Sos Grb2 N17Ras Nucleus P Oncogenic Raf MEK P P fos jun P P P P MAP kinase MAP kinase Increased gene expression

  28. R7 photoreceptor development • Fruitfly (Drosophila melanogaster) • Compound eye (800 ommatidia) • Each ommatidium has 8 photoreceptor cells; each detects a different wavelength of light

  29. R7 photoreceptor development • Photoreceptor cells “recruited” as an undifferentiated precursor from epithelial sheet of cells • Each photoreceptor develops in a specific order beginning with R8 and ending with R7 (responds to ultraviolet light)

  30. The R7 Photoreceptor Developmental Pathway is a RTK-MAPKinase Cascade

  31. RTK Signaling: • PI 3-Kinase Pathway

  32. The inositol phospholipids generated by PI3K

  33. The recruitment of signaling molecules with PH domains to the plasma membrane during B cell activation One PI3K pathway PH domain: pleckstrin homology domain

  34. Another PI3K pathway to regulate cell survival

  35. Intracellular Signaling Pathways activated by RTKs and GPCRs

  36. RTKs – Some Additional Important Points • See next slide: • Low-abundance proteins, their activation exerts major effects due to simultaneous activation of several signaling pathways that are often synergistic and  enhanced survival and growth. • This is an important function of growth factors when they are located on dendritic spines or shafts or on nerve terminals. • Ser/Thrkinases can alter gene expression. • RTKs can/must be regulated (attenuated) – if not, perhaps because of some mutation, such signaling intermediates escape such control  cancer. • Include mechanisms, such as desensitization, degradation, and dephosphorylation of tyrs.

  37. RTK Activation Lead to the Activation of Several Ser/ThrKinases with a wide Variety of Substrates: CREB – end-point of several signaling pathways

  38. Non-receptor Tyrosine Kinases • Heterogeneous group of enzymes that share a common conserved tyr cat domain and a lack of extracellular ligand-bindiing domain. • At least 32 known non-receptor tyrkinases in humans distributed into 10 families. • Diverse functions

  39. JAK/STAT-Cytokine receptors complex resemble RTKs in their ability to transduce signals in response to direct activation by extracellular signals/ligands. • Cytokine receptors are a receptor for CNTF and for leptin.

  40. Examples of Non-receptor Tyr Kinases • Conserved catalytic domains – black • Note that in JAKs, only the C-term tyrkinase domain is catalytically active.

  41. Activation Mechanism of a Cytokine Receptor coupled to JAK tyrKinases and of STAT Cytokine, hormone… Receptor Out In JAK tyr kinase P P STAT STAT STAT P P P P STAT P P STAT STAT P P STAT STAT Transcription P P Nucleus STAT-regulated genes

  42. Activation of c-Src Myristic acid at N-term allows Covalent attachment to membrane Myristoylation enriches Src kinases in membrane rafts • Two modes of intrinsic inhibition • by interactions between: • SH2 domain and • phosphorylated Y527; • (2) SH3 domain and • Polyproline region.

  43. Regulation of Src Family of Kinases • These kinases are attached to the membrane through an N-terminal myristic acid. • Maintained in an inactive state by intramolecular interactions that can be alleviated as indicated. • Note the unusual situation in which a tyrphosphatase can activate a tyrphosphorylation pathway. • Another way of activating Src is displacement of its SH2 domain from the C-terminal phos’dtyr by a competing phosphopeptide.

  44. Protein Tyrosine Phosphatases (PTPs) • Overall, the various types of PTPs are rather dissimilar (lacking sequence homology). • 2 Types: Receptor-like (RPTP)s and Non-receptor-like PTPs. • Among the RPTPs, there is a highly conserved cys residue in the conserved catalytic domains (some PTPs have 2 catalytic domains, although the C-term one has little-to-no catalytic activity). • Although PTPs tend to oppose tyrkinasesignalling, in some cases, they can activate specific tyrkinases(above, Src).

  45. Inactivation of MAP kinases (ERK) by threonine or tyrosine dephosphorylation

  46. Role of Protein Tyr Phosphorylation During Development of the Nervous System • Growth factors signaling. • Synaptogenesis. - NMJ – MusK (a tyrkinase, see preceding slide) and agrinAchR clustering. • Eph receptors (see slide 6) and their ligands, ephrins, participate in bidirectional signaling between cells in the travelling growth cone.

  47. Role of Tyr Phosphorylation in the Regulation of Ion Channels and Receptors NMDAR NMDAR P Tyr P-Tyr EphB2 Src Ca2+ PYK2/Cakβ TrkB ? PKC

  48. Role of Tyr Phosphorylation in Synaptic Plasticity • LTP. • Synaptogenesis: Ephrins and their receptors: In hipp cultures, Eph2 interacts with syndecan-2 (cell surface glycoprotein) to induce dendritic spine formation assoc with NMDAR clustering and synapse formation. EphB activation increases NMDAR tyrphosphorylation and glu-induced Ca2+ currents through phosphorylation by Srckinases. However, EphB2-/- appear/act normally underscoring the redundancy of multiple phos pathways in plasticity and development.

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