1. 1QQ # 7: Answer one. 1.For A-D list the four types of Glial Cells of the CNS and their functions: A) B) C) D). E) Which type of neuron has its cell body in the PNS and an axon that enters the CNS? 2.These questions concern Menopause: A) Which hormones are found in excess in this condition? B) Which hormones are found deficient in this condition? C) If a woman elects to receive HRT, what hormone is being replaced? D) What are the risks associated with HRT? E) What are the risks of not replacing the hormone?

2. Fig. 06.03 S 12 Orthograde = anterograde retrograde

3. Axonal Transport Orthograde = Anterograde = from soma to terminals –slow……1-2 mm/day –fast …..200-400 mm/day (kinesin) Retrograde = from terminals to soma –fast….200-400 mm/day (dynein) What gets transported and why? Axonal transport is too slow for rapid signaling, so… S 13

4. Who Cares?

5. Alayna Davis October 1992 Age 5 October 31, 1992 October 1998

7. Regeneration in CNS? So how can PNS axon regenerate and what prevents CNS axons from regenerating?

9. Bioelectricity is chemistry + physics Membrane potentials Ohm’s law Resting Membrane Potential The Nernst Equation The Goldman Equation

10. Who Cares?

11. Cortical vesicle exocytosis during fertilization leads to envelope elevationA, prior to fertilization (left), the proteinaceous vitelline coat of the sea urchin egg of Lytechinus pictus is not visible in this differential interference contrast image. Zimmerberg J et al. J Physiol 1999;520:15-21 ©1999 by The Physiological Society

12. Virtues of Squid Giant Axon Big questions: 1)How do cells generate a resting membrane potential? 2)What causes changes in the membrane potential? 3)How do cells use these potentials? i.e. What is their purpose?

13. Fig. 06.09

14. Fig. 06.10a There is a concentration gradient favoring the diffusion of Na+ and K+ through the selectively permeable membrane which has ion channels only for potassium. At the start, is there an electrical driving force?

15. Fig. 06.10b With K+ channels open, K+ diffuses down its concentraiton gradient, leaving behind CL- ions which are not permeable through the membrane. As more and more K+ move to the left, the compartment they leave becomes more and more negatively charged. Is there an electrical driving force?

16. Fig. 06.10c

17. Fig. 06.10d Soon, the accumulation of negative charges seriously impeded the diffusion of K+ as the electrostatic force builds up in opposition to the concentration driving force.

18. Fig. 06.10e Equilibrium potential = Nernst potential = diffusion potential Eventually, the electrostatic force that impedes diffusion of K+ is exactly equal to the driving force favoring diffusion based on a concentration gradient. When these two driving forces are equal and opposite, the membrane potential reaches an equilibrium at which the voltage is called So which compartment corresponds to intracellular fluid? E ion+ = 61/Z log ([conc outside]/ [conc inside]) E K+ = 61/1 log (5/150) E K+ = -90 mV

19. The Nernst Equation If the membrane is permeable to ONLY ONE ion species and you know the concentrations on both sides of the membrane, use the Nernst Equation to calculate the membrane potential. Nernst potential for X = 61/Z log [Outside ] / [Inside] S 2

20. Fig. 06.10e Equilibrium potential = Nernst potential = diffusion potential E ion+ = 61/Z log ([conc outside]/ [conc inside]) E K+ = 61/1 log (5/150) E K+ = -90 mV 150 mM5 mM K+ 50 mM Predict the change in membrane potential if K+ were added to the extracellular fluid. S 1 What hormone regulates the levels of Na+ and K+ in extracellular fluid?

21. Fig. 06.11a S 3 Now consider a situation in which only Na+ is permeable.

22. Fig. 06.11b S 4

23. Fig. 06.11c S 5

24. Fig. 06.11d S 6

25. Fig. 06.11e Equilibrium potential for Na+ E Na+ = 61/1 log (145/15) E Na + = +60 mV 145 mM 15 mM Extracellular Intracellular So, given these concentrations of Na+ and a membrane permeable only to Na+, use Nernst equation to calculate what the membrane potential would be. At the equilibrium potential, no net movement of Na+ because driving forces (concentration and electrical) are exactly equal and opposite. S 7

26. Electrical and concentration gradient driving forces for Sodium and Potassium How does the membrane potential change if 1) permeability to sodium increases 2) Permeability to potassium increases Why is resting membrane potential closer to E K than E Na ? What would happen to membrane potential if suddenly P Na became very great? Size and Direction of Arrows show driving forces! The G-H-K Equation! S 8