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Molecular Cell Biology
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20. Cell-to-Cell Signaling: Hormones and Receptors

2. CYTOKINES: Soluble factors required for hematopoietic Cell growth and differentiation
gp130
IL-6
!L-11
LIF
CNTF
IFN family
IFNα/β
IFNγ
IL-10
gp 140
IL-3
IL-5
GM-CSF
γc chain
IL-2
IL-4
IL-7
IL-9
IL-15

4. Figure 20-5. Common intracellular signaling proteins
Figure Common intracellular signaling proteins. (a) GTP-binding proteins with GTPase activity function as molecular switches. When bound to GTP they are active; when bound to GDP, they are inactive. They fall into two categories, trimeric G proteins and Ras-like proteins(b) Protein kinases modulate the activity or the binding properties of substrate proteins by phosphorylating serine, threonine, or tyrosine residues. The phosphorylated form of some proteins is active, whereas the dephosphorylated form of other proteins is active. The combined action of kinases and phosphatases, which dephosphorylate specific substrates, can cycle proteins between active and inactive states. (c) Adapter proteins contain various protein-binding motifs that promote the formation of multiprotein signaling complexes.

5. Figure Schematic overview of common signaling pathways downstream from G protein – coupled receptors (GPCRs) and receptor tyrosine kinases (RTKs).
SM=Second messenger

6. Figure Identification and isolation of a cDNA encoding a desired cell-surface receptor by plasmid expression cloning. All mRNA is extracted from cells that normally express the receptor and reverse-transcribed into double-stranded cDNA which is then introduced in non-expr. cells eg COS
Fluorescence-activated cell sorter (FACS).

7. Figure 15-47. Six subfamilies of receptor tyrosine kinases
Figure Six subfamilies of receptor tyrosine kinases. Only one or two members of each subfamily are indicated. Note that the tyrosine kinase domain is interrupted by a "kinase insert region" in some of the subfamilies. The functional significance of the cysteine-rich and immunoglobulinlike domains is unknown.

8. Figure General structure and activation of receptor tyrosine kinases (RTKs). The ligands for some RTKs, such as the receptor for EGF depicted here, are monomeric; ligand binding induces a conformational change in receptor monomers that promotes their dimerization. The ligands for other RTKs are dimeric; their binding brings two receptor monomers together directly (see Figure 20-4d). In either case, the kinase activity of each subunit of the dimeric receptor initially phosphorylates tyrosine residues near the catalytic site in the other subunit. Subsequently, tyrosine residues in other parts of the cytosolic domain are autophosphorylated. See text for discussion. [See G. Panayotou and W. D. Waterfield, 1993, Bioessays 15:171; M. Mohammadi et al., 1996, Cell 86:577

9. Figure 15-57. Some of the protein kinases discussed in this chapter
Figure Some of the protein kinases discussed in this chapter. The tyrosine kinases shown are bound to the plasma membrane, whereas most of the serine/threonine kinases are in the cytosol.

10. Cytokines in the Immune system

11. STATs and SMADs: Linking receptors to transcription.
Pawson T and Nash P (2000). Genes Dev.,1027

12. STAT= Signal Transducer and Activator of Transcription

14. Three examples of signaling in the JAK-STAT pathway
Three examples of signaling in the JAK-STAT pathway. Specific ligand-receptor interactions generate active transcription complexes composed of distinct STAT proteins. GAS= gamma activated sequence

18. Variations in STAT activation mechanisms

24. Structural features of Src-kinases, JAKs and SOCS/CIS/JAB protein family proteins.