1. Chapter 11 notes Cell Communication

2. The Cellular Internet Trillions of cells in a multicellular organism must communicate together to enable growth, survival, and reproduction The same cell-signaling mechanisms tend to show up again and again

3. Concept 11.1 Yeast cells use cell signaling to identify mates - two sexes, type a and type  - cells secrete a chemical signal that binds to receptors on the opposite cell - causes the two cells to grow toward each other so they can fuse and mate

4. Concept 11.1 Signal transduction pathway: process by which a signal on a cell’s surface is converted into a specific cellular response

5. Concept 11.1 Receptor  factor a factor a   a Exchange of mating factors Yeast cell, mating type a Yeast cell, mating type  Mating New a/  cell a/  1 2 3

6. Concept 11.1 Some cells communicate through direct contact - use of cell junctions - animal cells use membrane-bound cell surface molecules

7. Concept 11.1 Plasma membranes Gap junctions between animal cells (a) Cell junctions Plasmodesmata between plant cells (b) Cell-cell recognition

8. Concept 11.1 Some molecules only travel a short distance - local regulators (ex. growth factors) Synaptic signaling is found in the nervous system - electrical signal triggers the release of neurotransmitters across a synapse

9. Concept 11.1 Hormones are used for long-distance signaling - specialized cells release hormones into the circulatory system to travel to other parts of the body

10. Concept 11.1 Local signaling Target cell Secreting cell Secretory vesicle Local regulator diffuses through extracellular fluid (a) Paracrine signaling(b) Synaptic signaling Target cell is stimulated Neurotransmitter diffuses across synapse Electrical signal along nerve cell triggers release of neurotransmitter Long-distance signaling Endocrine cell Blood vessel Hormone travels in bloodstream to target cells Target cell (c) Hormonal signaling

11. Concept 11.1 The receiving end of a signal can be organized into three stages: Reception - a chemical signal is bound to a receptor protein at the cell’s surface Transduction - converts the signal to a form that can produce a cellular response

12. Concept 11.1 Response - any cellular activity that the cell is directed to accomplish

13. Concept 11.1

16. Concept 11.2 Reception - the receptor protein on a target cell allows the cell to “hear” the message from a signal - the signal is complementary in shape and attaches to the protein - the receptor protein changes shape, and thus is activated

17. Concept 11.2 Receptors can be intracellular or plasma membrane bound To reach the intracellular receptors, messengers must be able to pass through the plasma membrane (either small or hydrophobic) - ex. steroid hormones or NO (nitric oxide)

18. Concept 11.2 Most water soluble molecules are going to bind to plasma membrane receptors - receptor transmits information from the outside environment to the inside of the cell

19. Concept 11.2 G protein-coupled receptor Plasma membrane Enzyme G protein (inactive) GDP CYTOPLASM Activated enzyme GTP Cellular response GDP P i Activated receptor GDP GTP Signaling molecule Inactive enzyme 1 2 3 4

20. Concept 11.3 Transduction - usually a multi-step process - benefit in that it greatly amplifies a signal Protein kinase: an enzyme that transfers phosphate groups from ATP to a protein

21. Concept 11.3 Signaling molecule Recepto r Activated relay molecule Inactive protein kinase 1 Active protein kinase 1 Inactive protein kinase 2 ATP ADP Active protein kinase 2 P P PP Inactive protein kinase 3 ATP ADP Active protein kinase 3 P P PP i ATP ADP P Active protein PP P i Inactive protein Cellular respons e Phosphorylation cascade i

22. Concept 11.3 Many signaling pathways also involve small, nonprotein molecules called second messengers - ex. cyclic AMP (cAMP) carries a signal initiated by epinephrine from the plasma membrane of a liver cell into the cell’s interior

23. Concept 11.3 - the binding of epinephrine to a liver cell activates adenlyl cyclase, which in turn can synthesize many molecules of cAMP

24. Concept 11.3 First messenger G protein Adenylyl cyclase GTP ATP cAMP Second messenger Protein kinase A G protein-coupled receptor Cellular responses

25. Concept 11.4 Response In the liver cells, the final step activates the enzyme that catalyzes the breakdown of glycogen into glucose Many other signaling pathways regulate the synthesis of an enzyme by turning genes on and off

26. Concept 11.4 Signal Amplification - at each step in the cascade, the number of activated products is much greater than the preceding steps - b/c the proteins persist in an active form long enough to process numerous molecules

27. Concept 11.4 Specificity of Cell Signaling - ex. heart cells vs. liver cells - respond to some signals but ignore others - different responses to the same signal (ex. epinephrine)