BIOS 20175 Lecture Notes - Lecture 15: Cytosol, Patch Clamp, Membrane Potential

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lemonhedgehog555

25 Jul 2020

School

University of Chicago

Department

Biological Sciences

Course

BIOS 20175

Professor

Cheesecake

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Because k+ ions are charged, and charge separation is unfavorable: a lipid bilayer is an insulator, and therefore can act as a capacitor. A more accurate measure of membrane potential is provided by taking into account the permeability of the plasma membrane to different ions. In this case the membrane potential switches polarity and becomes positive inside. Repolarization of nerve cells: soon after they open, sodium channels close again due to inactivation. K+ efflux then begins to repolarize the cell: eventually the system returns to its initial (resting) state, this entire action potential lasts only a few milliseconds. During a single action potential, only a tiny fraction of the na+ and k+ ions cross the membrane, so the gradients remain intact. Molecular description of channel behavior: individual channels can be studied by patch clamping. It turns out that a given channel switches back and forth between an open and a closed state.

Related Questions

We mentioned in class that biological systems are ... We mentioned in class that biological systems are always in a state of osmotic equilibrium due to a combination of solute diffusion in some cases and osmosis in others. In this experiment, what substance is moving across the red blood cell plasma membrane to achieve osmotic equilibrium, Na+ and Cl- or water? Explain why based on your understanding of the permeability characteristics of biological membrane. Always use scientific language. HERE IS AN INTRO TO THE LAB EXPERIMENT Intro: We have known for a very long time that the mammalian red blood cell plasma membrane is very permeable to water. Even the introductory biology student understands that if you put mammalian red blood cells in water, they will rapidly swell and break open (hemolyze) due to the rapid osmosis of water into the cell. The experimental question we are asking in today's lab experiment is "Is the high water permability of mammalian red blood cell plasma membrane due solely to the lipid bilayer, or are there water channels present in the membrane?" Experimental Design: It has been shown by several investigators that water movement through water channels can be blocked by the known K+ channel blocker, tetraethylammonium chloride (TEAC). Brooks, Regan and Yool (2000) showed that TEAC reduces the water permeability of human water channels expressed in the plasma membranes of frog ocytes. After preincubation of the oocytes for 15 min with 100 microM TEAC, the water permeability of frog oocyte plasma membrane containing human water channels was reduced 20 to 40%. The investigators concluded that treatment of cells with TEAC can be useful in determining the presence of aquaporins in membranes.The specific objective of today's experiment is to uncover the presence of water channels in mammalian red blood cell plasma membrane by determining the effect of tetraethylammonium chloride on the water permeability of mammalian RBC plasma membran

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BIOS 20175 Lecture Notes - Lecture 15: Cytosol, Patch Clamp, Membrane Potential

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