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How the eye sees Last time Anatomy of the eye Rods and cones Visual receptors Color Vision

How the eye sees Last time Anatomy of the eye Rods and cones Visual receptors Color Vision This time Visual transduction Eye to brain. 1. Rods and cones have different visual receptors The visual receptors are G protein-coupled receptors. seven transmembrane regions

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How the eye sees Last time Anatomy of the eye Rods and cones Visual receptors Color Vision

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  1. How the eye sees Last time Anatomy of the eye Rods and cones Visual receptors Color Vision This time Visual transduction Eye to brain 1

  2. Rods and cones have different visual receptorsThe visual receptors are G protein-coupled receptors • seven transmembrane regions • hydrophobic/ hydrophilic domains • conserved motifs • chromophore stably attached to receptor (Schiff’s base Lys296 in TM7) • thermostable Nomenclature for visual receptors Receptor == GPCR, opsin Ligand == chromophore, retinal, pigment Receptor bound to ligand == rhodopsin 2

  3. Light hyperpolarizes the cell 3

  4. The visual cascade is a G protein-coupled cascade Rhodopsin Gtransducin phosophodiesterase cGMP to GMP close cGMP channels 4

  5. Signal transduction in the dark 5

  6. Signal transduction in the light 6

  7. Negative regulation of phototransduction Rhodopsin Gtransducin phosophodiesterase cGMP to GMP close cGMP channels Closing cGMP channels causes a decrease in Ca2+ Decrease in Ca2+ activates • Rhodopsin kinase === deactivate receptor • Guanylate cyclase === converts GTP to cGMP === opens cGMP channels Ca2+ independent deactivation also occurs 1. GTPase activating protein 7

  8. Turning off rhodopsin Ca-dependent 8

  9. Turning ON Guanylate Cyclase Ca-dependent, Decrease in Ca activates GC ENZYME REACTION ACTION on CHANNELS ACTIVATED BY Guanylate cyclase GTP--- cGMP opens cGMP channels GCAP (less Ca) Phosphodiesterase cGMP--- GMP closes cGMPchannels transducin 9

  10. Turning off the G protein 10

  11. Mice without GAP cannot turn off light response quickly no GAP with GAP (wild-type) 11

  12. Rods respond to a single photon of light 12

  13. Single photon response is very reproducible 13

  14. Dark noise is very low 1 rhodopsin/minute 108 rhodopins/ photoreceptor 1000 years for all rhodopsins to turn over 14

  15. High amplification increases signal size and reliability Rhodopsin Gtransducin phosophodiesterase cGMP to GMP close cGMP channels 1 100 100 100,000 ~1000 15

  16. Properties of phototransduction • responds to 1 photon of light • responses are extremely reliable • high amplification of signaling • low dark noise • 1000s of discs maximize surface area of light detection • high concentration and thermostability of rhodopsin means high detection, low noise Photoreceptors are highly specialized to detect light! 16

  17. Phototransduction: Differences between rods and cones RodsCones Very sensitive to light 30x less sensitive to light each rhodopsin activates 30x less G proteins 17

  18. Drosophila mutants with abnormal light responses 18

  19. The signaling pathway for Drosophila phototransduction Fastest GPCR cascade measured No amplification 19

  20. Connectivity in the retina The Basic Retinal Circuit Back of eye 6. Pigment cells 1. Receptor Cells (rods and cones) 2. Bipolar Cells 3. Ganglion Cells 4. Horozontal Cells 5. Amacrine Cells Structure of the eye Front of eye 20

  21. View of the retina Ramon y Cajal, Nobel 1906 21

  22. Flow of visual information in the retina Vertical Connections Back of eye Front of eye back of eye Photoreceptor Cell---Bipolar Cell---Retinal Ganglion Cell---Brain Horozontal Connections Horozontal Cells- connect photoreceptors and bipolar cells Amacrine Cells- connect bipolar cells and retinal ganglion cells light 22

  23. What happens if all rods and cones are killed? 23

  24. Unusual retinal gangion cells 24

  25. Retinal ganglion cells express melanopsin, are sensitive to light and project to the suprachiasmatic nucleus 25

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