Na+-K+ channel pumps: Difference between revisions
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The [[Sodium|Na<sup>+</sup>]]/[[Potassium|K<sup>+</sup>]] pumps are found in the neuronal plasma membrane and are a type of primary active transporter. | The [[Sodium|Na<sup>+</sup>]]/[[Potassium|K<sup>+</sup>]] pumps are found in the neuronal plasma membrane and are a type of primary active transporter<ref>Siegel GJ, Agranoff BW, Albers RW, et al. Basic Neurochemistry: Molecular, Cellular and Medical Aspects-Chapter 5-Membrane Transtport.6th edition. Philadelphia: Lippincott-Raven; 1999.</ref>. The role of the Na<sup>+</sup>/K<sup>+</sup> pump is to maintain the electrochemical gradient of Na<sup>+</sup> and K<sup>+. </sup>The Na<sup>+</sup>/K<sup>+</sup> pumps are a type of [[ATPase|ATPase]] they use the energy produced from the spliting of the [[ATP|ATP]] via [[Hydrolysis|hydrolysis]] to actively transport Na<sup>+</sup> out of the [[Axon|axon]] and pump K+ into the axon. The Na<sup>+</sup>/K<sup>+</sup> pump is a carrier protein, thus requires a change in conformation in order to move the [[Ions|ions]] across the membrane, for every 3 Na<sup>+</sup> pumped out there are 2 K<sup>+</sup> that have been pumped in. The Na/K+ pumps establish a [[Resting potential|resting potential]] of -70mv, this is a negative [[Voltage|voltage]] as the outside of the cell is more positive than commpared with the inside of the cell. The Na+/K+ pump is described as being electrogenic as it creates a change in electrical potential within the cell. _2<sup></sup> | ||
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How An Na+/K+ Pump Works | == How An Na+/K+ Pump Works == | ||
The Na+/K+ pump has two different conformational states known as E1 and E2. Three Na+ bind to the intracllular binding site, the phosphorlyation of the pump using the ATP causes the conformational change within the pump. The pump is now in conformational state E2, the 3 Na+ are released outside of the cell._3 The binding of the 2 K+ to the extracellular surface results in the dephosphorylation of the pump returning the configuration back to E1, once in the E1 conformation the 2K+ are released into the cell. | The Na+/K+ pump has two different conformational states known as E1 and E2. Three Na+ bind to the intracllular binding site, the phosphorlyation of the pump using the ATP causes the conformational change within the pump. The pump is now in conformational state E2, the 3 Na+ are released outside of the cell._3 The binding of the 2 K+ to the extracellular surface results in the dephosphorylation of the pump returning the configuration back to E1, once in the E1 conformation the 2K+ are released into the cell. | ||
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=== Reference === | |||
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Revision as of 00:11, 5 December 2016
The Na+/K+ pumps are found in the neuronal plasma membrane and are a type of primary active transporter[1]. The role of the Na+/K+ pump is to maintain the electrochemical gradient of Na+ and K+. The Na+/K+ pumps are a type of ATPase they use the energy produced from the spliting of the ATP via hydrolysis to actively transport Na+ out of the axon and pump K+ into the axon. The Na+/K+ pump is a carrier protein, thus requires a change in conformation in order to move the ions across the membrane, for every 3 Na+ pumped out there are 2 K+ that have been pumped in. The Na/K+ pumps establish a resting potential of -70mv, this is a negative voltage as the outside of the cell is more positive than commpared with the inside of the cell. The Na+/K+ pump is described as being electrogenic as it creates a change in electrical potential within the cell. _2
How An Na+/K+ Pump Works
The Na+/K+ pump has two different conformational states known as E1 and E2. Three Na+ bind to the intracllular binding site, the phosphorlyation of the pump using the ATP causes the conformational change within the pump. The pump is now in conformational state E2, the 3 Na+ are released outside of the cell._3 The binding of the 2 K+ to the extracellular surface results in the dephosphorylation of the pump returning the configuration back to E1, once in the E1 conformation the 2K+ are released into the cell.
Reference
- ↑ Siegel GJ, Agranoff BW, Albers RW, et al. Basic Neurochemistry: Molecular, Cellular and Medical Aspects-Chapter 5-Membrane Transtport.6th edition. Philadelphia: Lippincott-Raven; 1999.