1. Cell Communication Chapter 11

2. An overview of Cell Signaling

3. Signal-transduction pathway Process by which a signal on a cell’s surface is converted into a specific cellular response is a series of steps called signal- transduction pathway

4. Evolutionary connection Scientists think that signaling mechanisms evolved in ancient prokaryotes and single celled eukaryotes They were adopted for new uses by multicellular descendents

5. Local regulator – a substance that influences cells in its vicinity Transmitting cells can secrete molecules of a local regulator to communicate with nearby cells

6. Paracrine signaling Paracrine signaling is a type of local signaling in animals in which numerous cells can simultaneously receive and respond to the signal of a single cell in their vicinity

7. Examples of local regulators that uses paracrine signaling Growth factors in animal cells are compounds that stimulate nearby target cells to grow and multiply

8. Synaptic Signaling Specialized type of local signaling that occurs in animal nervous systems An electrical signal that is transmitted the length of a nerve cell to its target cell without touching the target cell

9. Example of synaptic signaling Nerve cells produce a chemical signal called a neurotransmitter that diffuses to a single target cell that is almost touching the signaling cell

11. Long distance signaling Plants and animals use chemicals called hormones for signaling

12. In animals – hormonal signaling is called endocrine signaling – Hormone molecules are released into vessels of the circulatory system and travel to other parts of the body

13. In plants – sometimes they move through vessels – More often they are diffused through the air as a gas Example: plant hormone ethylene is a gas that helps promote fruit ripening

14. Direct Contact Both plants and animals have cell junctions that promote the direct contact between 2 cells Signaling substances dissolve in the cytosol and can pass freely between adjacent cells Animal cells can communicate directly between the molecules on their cell surfaces

15. Three stages of cell signaling Earl W. Sutherland discovered how the hormone epinephrine acts on cells Sutherland suggested that cells receiving signals went through three processes: – Reception – Transduction – Response

16. Reception First step when the target cell detects a signal coming from outside the cell Chemical signals are detected when they bind to a cellular protein in the cell membrane of the target cell

17. Transduction In this stage the signal is converted into a form that can bring about a specific cellular response Transduction can occur in a single step or multiple steps of the signal- transduction pathway. Molecules involved in the pathway are often called relay molecules

18. Response Transduced signal triggers a specific cellular response Cellular response can be anything from activation of certain genes in the nucleus to catalysis by an enzyme

19. Signal Reception and the Initiation of Transduction

20. Signal molecule binds to a receptor protein causing the protein to change shape Signal molecules are complementary in shape to a specific site on the receptor and attaches there Like a lock and key

21. Signal molecule behaves as a ligand A ligand is a small molecule that specifically binds to a larger one Sometimes causes receptor protein to change shape For some, this shape change activates the receptor

22. Signal receptors Most signal are water soluble molecules that are too large to pass freely through the cell membrane They must utilize a signal receptor protein embedded in the cell membrane to transmit information from the extracellular environment to the inside of the cell

23. 3 major types of membrane receptors G-protein-linked receptors Tyrosine-kinase receptors Ion-channel receptors

24. G-protein-linked receptors Large family of receptor proteins that all have 7 transmembrane helices

25. G-proteins Act as an on/off switch If GDP (guanosine diphosphate) is bound – the G-protein is inactive If GTP (guanosine triphosphate) is bound – it is active

27. G-protein receptor systems are diverse in function They can be shutdown quickly when the signal molecule is no longer present

28. Tyrosine-Kinase Receptors These receptors are commonly used for growth factors Characterized by having enzymatic activity Tyrosine kinase is an enzyme that catalyzes the transfer of phosphate groups from ATP to the amino acid tyrosine on a substrate protein

30. Different from G-protein receptors Binding of a signal molecule does not cause the shape of the receptor to change like in the G- protein receptors Can activate more than 1 cellular response (unlike G-proteins)

31. How it works The ligand binding causes phosphate groups from ATP (adenosine triphosphate) to aggregate (combine) with the tyrosines forming a phosphorylated dimer (a protein consisting of 2 polypeptides)

32. This aggregation activates the tyrosine-kinase receptor to bind to specific intracellular relay proteins The activation of the relay proteins initiates a signal-transduction pathway leading to a variety of specific cellular responses

34. Ligand gated ion-channel receptors Protein pores that open or close in response to a chemical signal Important in the nervous system

35. Intracellular Receptors Some receptors are proteins in the cytosol or on the nucleus of a cell In order for these to work, the signal must be able to pass through the cell membrane Many of these signals are hydrophobic so they can pass through easily Examples include steroid and thyroid hormones

36. Protein phosphorylation Most proteins are activated by adding one or more phosphate groups to it – this is called phosphorylation Protein kinase is the enzyme that commonly transfers phosphate groups from ATP to a protein

37. Phosphorylation cascade Protein kinases are often the relay molecules in the signal- transduction pathway They often act on each other to trigger another protein to be phosphylated This can occur numerous times until finally triggering the target protein to elicit a cellular response