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Where would you find active transport? interface with the environment…. maintain cell volume control internal environment signaling….Ca ++ gradient Lecture.

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Presentation on theme: "Where would you find active transport? interface with the environment…. maintain cell volume control internal environment signaling….Ca ++ gradient Lecture."— Presentation transcript:

1 Where would you find active transport? interface with the environment…. maintain cell volume control internal environment signaling….Ca ++ gradient Lecture 16 Membrane Transport Active transport

2 Characteristics of a Transporter Saturability…characterized by K M and V max Stereospecificity..or specificity unrelared to biophysical characteristics Higher rate than expected from oil/water partition coef.

3 GLUT = sugar transporters GLUT1-GLUT12

4 Michaelis-Menten equation for enzyme/transport reactions is very similar to the Langmuir isotherm [s], mM 010203040 50 0 0.2 0.4 0.6 0.8 1 K m = 1 mM K m = 10 mM V max A “simple explanation” says that the rate of reaction should be proportional to the occupancy of the binding site as long as V max is constant.

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6 Bacterial Lac permease (lacY): Lactose-proton co-transporter from Abramson et al. 2003

7 The Lac permease functional cycle, an example of coupled transport Note: the proton is always taken up first, but is released at last, which ensures strict coupling of transport without H + leakage

8 energy in gradient: Example: Na + -glucose symport: stoichiometry of 2:1 at equilibrium: Δμ glu = -2Δμ Na

9 Aspartate Transporter: Na + - dependent transport of aspartate (from Boudker et al., Nature 2007)

10 apical basolateral Tight junction Na-K ATPase = the primary active transport, generates concentration gradients of Na + and K + utilizing ATP Na-Glucose co-transporter, utilizes Na + gradient as a secondary energy source Glucose diffusion facilitator (no energy consumed, passive transport) H2OH2O GLUT

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12 ATPases that couple splitting of ATP with ion motion across the membrane pump only protons ATP synthase (works in reverse)

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14 During contraction of the striated and cardiac muscle, Ca 2+ is released into the cytoplasm, but during the relaxation phase it is actively pumped back into SR. Ca 2+ ATPae (SERCA) constitutes >80% of total integral protein in SR.

15 High-affinity state open inside Low-affinity state open outside Muscle Ca 2+ pump (SERCA)

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17 The activity of SERCA, especially in the heart is regulated by Phospholamban, a small (single-pass) transmembrane protein. Phosphorylation of phospholamban by PkA removes its inhibitory action and increases the activity of SERCA by an order of magnitude. The activity of plasma membrane Ca 2+ pump (p-class) is regulated by calmodulin, which acts as a sensor of Ca concentration. Elevated Ca 2+ binds to calmodulin, which in turn causes allosteric activation of the Ca 2+ pump.

18 Post-Alberts Cycle for the Na+/K+ ATPase

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20 at equilibrium: Vacuilar or Lysosomal V-type ATPases work in conjunction with Cl - channels

21 BtuCD ATPase pumps vitamin B12 (ABC transporter)

22 Many ABC transporters work as flppases or pump lipid-soluble substances (MDR) MDR1 flippase

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