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Membrane Protein Pumps

Membrane Protein Pumps. Learning objectives. You should be able to understand & discuss: Active transport-Na + /K + ATPase ABC transporters Metabolite transport by lactose permease. Ion pumps: ATP-driven.

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Membrane Protein Pumps

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  1. Membrane Protein Pumps

  2. Learning objectives You should be able to understand & discuss: • Active transport-Na+/K+ ATPase • ABC transporters • Metabolite transport by lactose permease

  3. Ion pumps: ATP-driven • Ion-pumps are energy transducers in that they convert one form of free energy into another. • Two types of ATP-driven pumps: (1) P-type ATPases and (2) the ATP-binding cassette (ABC) transporters that undergo conformational changes on ATP binding & hydrolysis and cause a bound ion to be transported across the membrane.

  4. Ion pumps: gradient driven • A different mechanism of active transport used the gradient of one ion to drive the active transport of another. An example of such a secondary transporter is the E.coli lactose transporter. • Many transporters of this class are present in the membranes of our cells. The expression of these transporters determines which cell metabolites a cell can import from the environment. Transporter expression is therefore a primary means of controlling metabolism.

  5. Expression & metabolic activity • e.g. glucose metabolism. Which tissues can make use of glycose is largely governed by the expression of different members of a family of homologous glucose transporters called GLUT1 through GLUT5 in different cell types. GLUT3 binds glucose tightly so these cells have first call on glucose when it is present at low concentrations.

  6. Free Energy & Transport (a) Free energy in transporting uncharged solute across a membrane (b) Singly charged solute to the side having the same charge. A transport process must be active when DG is positive, whereas it can be passive when DG is negative.

  7. The Free Energy Stored in Concentration Gradient For an uncharged solute molecule: DG = RTln(c2/c1) = 2.303RTlog10(c2/c1) R is the gas constant (8.315x10-3 kJ/mol) T is temperature in Kelvin Concentration on side 1 of the membrane c1 Concentration on side 2 of the membrane c2

  8. The Free Energy Stored in Concentration Gradient For a charged solute molecule: DG = RTln(c2/c1) + ZFDV = 2.303RTlog10(c2/c1) + ZFDV where Z is the charge of the solute DV is the potential across the membrane F is the Faraday constant (96.5 kJ/V/mol)

  9. Two families of membrane proteins use ATP hydrolysis to pump ions and molecules across membranes • The extracellular fluid of animal cells has a salt concentration similar to seawater (ca 140 mM). However cells must maintain their intracellular salt concentrations (ca 14 mM). • Most animal cells have high K+ and low Na+ relative to the external medium.

  10. Na+-K+ ATPase • These ionic gradients are generated by the Na+-K+ ATPase. It transports 3 Na+ out and 2 K+ into the cell for each ATP hydrolysed. • ATP hydrolysis provides the energy needed to pump Na+ out of the cell and K+ into the cell generating the gradients. • Subsequent purification of other pumps reveals a large family (evolutionarily related) in bacteria, archaea, and eukaryotes including the Ca2+ ATPase and the H+-K+ ATPase.

  11. Pump action – simple in principle but more complex in detail

  12. Calcium pump structureSR Ca2+ ATPase, or SERCA P-type ATPase – forms phosphorylaspartate (E1: Ca2+ bound state) Pumps calcium into the SR of muscle cells (1.5mM in SR compared to 1.0mM in cytoplasm) Important for muscle contraction N – binds nucleotide; P – accepts the phosphoryl group (Asp 351); A is the actuator domain

  13. E2: Calcium free state Ca2+ can access from cytoplasmic side

  14. Mechanism of P –type ATPases (>70 in the human genome)

  15. Digitalis inhibits the Na+ -K+ pump by blocking dephosphorylation of E2-P • Foxglove (Digitalis purpurea) is the source of digitalis • Digitoxigenin is used to treat congestive heart failure. It increases the force of muscle contraction Ki = 10 nM

  16. How inhibition of the sodium-potassium pump leads to stronger contraction of the heart • Inhibition of the Na+-K+ pump by digitalis leads to a higher level of Na+ inside the cell. The reduced Na+ gradient results in slower extrusion of calcium by the sodium-calcium exchanger. The increase in calcium enhances the ability of the cardiac muscle to contract.

  17. ABC transporters - multidrug resistance • The onset of MDR in cultured tumour cells (& presumably tumours in patients) was found to correlate with expression & activity of a membrane protein of 170 kD. This is an ATP-dependant pump that extrudes a wide range of small molecules from the cells that express it. • There are ABC transporters containing two transmembrane domains and two ATP-binding domains (cassettes).

  18. ABC transporters

  19. Vibrio cholerae lipid transporter – an ABC transporter Dimer of 62 kDa chains; N – transmembrane C – ATP binding cassette (>150 ABC transporter genes in the human genome)

  20. Eukaryotic ABC transporters generally transport molecules out of the cell

  21. Lactose permease • Archetype secondary transporter • The thermodynamically unfavourable flow of one species of ion or molecule up a concentration gradient is driven by the favourable flow of a different species down a concentration gradient.

  22. Lactose permease • This symporter uses the H+ gradient across the E.coli membrane (outside H+ has higher concentration) generated by the oxidation of fuel molecules to drive the uptake of lactose and other sugars against a concentration gradient.

  23. Lactose permease

  24. Glu 269 is the likely proton acceptor Many features similar to ABC transporter (NO ATP!)

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