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Sodium–potassium pump

January 01, 1970

The sodium–potassium pump (sodiumpotassium adenosine triphosphatase, also known as Na+/K+-ATPase, Na+/K+ pump, or sodium–potassium ATPase) is an enzyme (an electrogenic transmembrane ATPase) found in the membrane of all animal cells. It performs several functions in cell physiology.

Na+/K+-ATPase pump
Sodium–potassium pump, E2-Pi state. Calculated hydrocarbon boundaries of the lipid bilayer are shown as blue (intracellular) and red (extracellular) planes
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The Na+/K+-ATPase enzyme is active (i.e. it uses energy from ATP). For every ATP molecule that the pump uses, three sodium ions are exported and two potassium ions are imported.[1] Thus, there is a net export of a single positive charge per pump cycle. The net effect is an extracellular concentration of sodium ions which is 5 times the intracellular concentration, and an intracellular concentration of potassium ions which is 30 times the extracellular concentration.[1]

The sodium–potassium pump was discovered in 1957 by the Danish scientist Jens Christian Skou, who was awarded a Nobel Prize for his work in 1997. Its discovery marked an important step forward in the understanding of how ions get into and out of cells, and it has particular significance for excitable cells such as nerve cells, which depend on this pump to respond to stimuli and transmit impulses.

All mammals have four different sodium pump sub-types, or isoforms. Each has unique properties and tissue expression patterns.[2] This enzyme belongs to the family of P-type ATPases.

Function edit

The Na+/K+-ATPase helps maintain resting potential, affects transport, and regulates cellular volume.[3] It also functions as a signal transducer/integrator to regulate the MAPK pathway, reactive oxygen species (ROS), as well as intracellular calcium. In fact, all cells expend a large fraction of the ATP they produce (typically 30% and up to 70% in nerve cells) to maintain their required cytosolic Na and K concentrations.[4] For neurons, the Na+/K+-ATPase can be responsible for up to 3/4 of the cell's energy expenditure.[5] In many types of tissue, ATP consumption by the Na+/K+-ATPases have been related to glycolysis. This was first discovered in red blood cells (Schrier, 1966), but has later been evidenced in renal cells,[6] smooth muscles surrounding the blood vessels,[7] and cardiac purkinje cells.[8] Recently, glycolysis has also been shown to be of particular importance for Na+/K+-ATPase in skeletal muscles, where inhibition of glycogen breakdown (a substrate for glycolysis) leads to reduced Na+/K+-ATPase activity and lower force production.[9][10][11]

Resting potential edit

 
The Na+/K+-ATPase, as well as effects of diffusion of the involved ions maintain the resting potential across the membranes.
See also: Resting potential

In order to maintain the cell membrane potential, cells keep a low concentration of sodium ions and high levels of potassium ions within the cell (intracellular). The sodium–potassium pump mechanism moves 3 sodium ions out and moves 2 potassium ions in, thus, in total, removing one positive charge carrier from the intracellular space (see § Mechanism for details). In addition, there is a short-circuit channel (i.e. a highly K-permeable ion channel) for potassium in the membrane, thus the voltage across the plasma membrane is close to the Nernst potential of potassium.

Reversal potential edit

Even if both K+ and Na+ ions have the same charge, they can still have very different equilibrium potentials for both outside and/or inside concentrations. The sodium-potassium pump moves toward a nonequilibrium state with the relative concentrations of Na+ and K+ for both inside and outside of cell. For instance, the concentration of K+ in cytosol is 100 mM, whereas the concentration of Na+ is 10 mM. On the other hand, in extracellular space, the usual concentration range of K+ is about 3.5-5 mM, whereas the concentration of Na+ is about 135-145 mM.[citation needed]

Transport edit

Export of sodium ions from the cell provides the driving force for several secondary active transporters such as membrane transport proteins, which import glucose, amino acids and other nutrients into the cell by use of the sodium ion gradient.

Another important task of the Na+-K+ pump is to provide a Na+ gradient that is used by certain carrier processes. In the gut, for example, sodium is transported out of the reabsorbing cell on the blood (interstitial fluid) side via the Na+-K+ pump, whereas, on the reabsorbing (lumenal) side, the Na+-glucose symporter uses the created Na+ gradient as a source of energy to import both Na+ and glucose, which is far more efficient than simple diffusion. Similar processes are located in the renal tubular system.

Controlling cell volume edit

Failure of the Na+-K+ pumps can result in swelling of the cell. A cell's osmolarity is the sum of the concentrations of the various ion species and many proteins and other organic compounds inside the cell. When this is higher than the osmolarity outside of the cell, water flows into the cell through osmosis. This can cause the cell to swell up and lyse. The Na+-K+ pump helps to maintain the right concentrations of ions. Furthermore, when the cell begins to swell, this automatically activates the Na+-K+ pump because it changes the internal concentrations of Na+-K+ to which the pump is sensitive.[12]

Functioning as signal transducer edit

Within the last decade[when?], many independent labs have demonstrated that, in addition to the classical ion transporting, this membrane protein can also relay extracellular ouabain-binding signalling into the cell through regulation of protein tyrosine phosphorylation. For instance, a study investigated the function of Na+/K+-ATPase in foot muscle and hepatopancreas in land snail Otala lactea by comparing the active and estivating states.[13] They concluded that reversible phosphorylation can control the same means of coordinating ATP use by this ion pump with the rates of the ATP generation by catabolic pathways in estivating O. lactea. The downstream signals through ouabain-triggered protein phosphorylation events include activation of the mitogen-activated protein kinase (MAPK) signal cascades, mitochondrial reactive oxygen species (ROS) production, as well as activation of phospholipase C (PLC) and inositol triphosphate (IP3) receptor (IP3R) in different intracellular compartments.[14]

Protein-protein interactions play a very important role in Na+-K+ pump-mediated signal transduction. For example, the Na+-K+ pump interacts directly with Src, a non-receptor tyrosine kinase, to form a signaling receptor complex.[15] Src is initially inhibited by the Na+-K+ pump. However, upon subsequent ouabain binding, the Src kinase domain is released and then activated. Based on this scenario, NaKtide, a peptide Src inhibitor derived from the Na+-K+ pump, was developed as a functional ouabain–Na+-K+ pump-mediated signal transduction.[16] Na+-K+ pump also interacts with ankyrin, IP3R, PI3K, PLCgamma1 and cofilin.[17]

Controlling neuron activity states edit

The Na+-K+ pump has been shown to control and set the intrinsic activity mode of cerebellar Purkinje neurons,[18] accessory olfactory bulb mitral cells[19] and probably other neuron types.[20] This suggests that the pump might not simply be a homeostatic, "housekeeping" molecule for ionic gradients, but could be a computation element in the cerebellum and the brain.[21] Indeed, a mutation in the Na+-K+ pump causes rapid onset dystonia-parkinsonism, which has symptoms to indicate that it is a pathology of cerebellar computation.[22] Furthermore, an ouabain block of Na+-K+ pumps in the cerebellum of a live mouse results in it displaying ataxia and dystonia.[23] Alcohol inhibits sodium–potassium pumps in the cerebellum and this is likely how it corrupts cerebellar computation and body coordination.[24][25] The distribution of the Na+-K+ pump on myelinated axons in the human brain has been demonstrated to be along the internodal axolemma, and not within the nodal axolemma as previously thought.[26] The Na+-K+ pump disfunction has been tied to various diseases, including epilepsy and brain malformations.[27]

Mechanism edit

 
The sodium–potassium pump is found in many cell (plasma) membranes. Powered by ATP, the pump moves sodium and potassium ions in opposite directions, each against its concentration gradient. In a single cycle of the pump, three sodium ions are extruded from and two potassium ions are imported into the cell.

Looking at the process starting from the interior of the cell:

  • The pump has a higher affinity for Na+ ions than K+ ions, thus after binding ATP, binds 3 intracellular Na+ ions.[3]
  • ATP is hydrolyzed, leading to phosphorylation of the pump at a highly conserved aspartate residue and subsequent release of ADP. This process leads to a conformational change in the pump.
  • The conformational change exposes the Na+ ions to the extracellular region. The phosphorylated form of the pump has a low affinity for Na+ ions, so they are released; by contrast it has high affinity for the K+ ions.
  • The pump binds 2 extracellular K+ ions, which induces dephosphorylation of the pump, reverting it to its previous conformational state, thus releasing the K+ ions into the cell.
  • The unphosphorylated form of the pump has a higher affinity for Na+ ions. ATP binds, and the process starts again.

Regulation edit

Endogenous edit

The Na+/K+-ATPase is upregulated by cAMP.[28] Thus, substances causing an increase in cAMP upregulate the Na+/K+-ATPase. These include the ligands of the Gs-coupled GPCRs. In contrast, substances causing a decrease in cAMP downregulate the Na+/K+-ATPase. These include the ligands of the Gi-coupled GPCRs. Note: Early studies indicated the opposite effect, but these were later found to be inaccurate due to additional complicating factors. [citation needed]

The Na+/K+-ATPase is endogenously negatively regulated by the inositol pyrophosphate 5-InsP7, an intracellular signaling molecule generated by IP6K1, which relieves an autoinhibitory domain of PI3K p85α to drive endocytosis and degradation.[29]

The Na+/K+-ATPase is also regulated by reversible phosphorylation. Research has shown that in estivating animals, the Na+/K+-ATPase is in the phosphorylated and low activity form. Dephosphorylation of Na+/K+-ATPase can recover it to the high activity form.[13]

Exogenous edit

The Na+/K+-ATPase can be pharmacologically modified by administering drugs exogenously. Its expression can also be modified through hormones such as triiodothyronine, a thyroid hormone.[13][30]

For instance, Na+/K+-ATPase found in the membrane of heart cells is an important target of cardiac glycosides (for example digoxin and ouabain), inotropic drugs used to improve heart performance by increasing its force of contraction.

Muscle contraction is dependent on a 100- to 10,000-times-higher-than-resting intracellular Ca2+ concentration, which is caused by Ca2+ release from the muscle cells' sarcoplasmic reticulum. Immediately after muscle contraction, intracellular Ca2+ is quickly returned to its normal concentration by a carrier enzyme in the plasma membrane, and a calcium pump in sarcoplasmic reticulum, causing the muscle to relax.

According to the Blaustein-hypothesis,[31] this carrier enzyme (Na+/Ca2+ exchanger, NCX) uses the Na gradient generated by the Na+-K+ pump to remove Ca2+ from the intracellular space, hence slowing down the Na+-K+ pump results in a permanently elevated Ca2+ level in the muscle, which may be the mechanism of the long-term inotropic effect of cardiac glycosides such as digoxin. The problem with this hypothesis is that at pharmacological concentrations of digitalis, less than 5% of Na/K-ATPase molecules – specifically the α2 isoform in heart and arterial smooth muscle (Kd = 32 nM) – are inhibited, not enough to affect the intracellular concentration of Na+. However, apart from the population of Na/K-ATPase in the plasma membrane, responsible for ion transport, there is another population in the caveolae which acts as digitalis receptor and stimulates the EGF receptor.[32][33][34][35]

Pharmacological regulation edit

In certain conditions such as in the case of cardiac disease, the Na+/K+-ATPase may need to be inhibited via pharmacological means. A commonly used inhibitor used in the treatment of cardiac disease is digoxin (a cardiac glycoside) which essentially binds "to the extracellular part of enzyme i.e. that binds potassium, when it is in a phosphorylated state, to transfer potassium inside the cell"[36] After this essential binding occurs, a dephosphorylation of the alpha subunit occurs which reduces the effect of cardiac disease. It is via the inhibiting of the Na+/K+-ATPase that sodium levels will begin to increase within the cell which ultimately increases the concentration of intracellular calcium via the sodium-calcium exchanger. This increased presence of calcium is what allows for the force of contraction to be increased. In the case of patients where the heart is not pumping hard enough to provide what is needed for the body, use of digoxin helps to temporarily overcome this.

Discovery edit

Na+/K+-ATPase was proposed by Jens Christian Skou in 1957 while working as assistant professor at the Department of Physiology, University of Aarhus, Denmark. He published his work that year.[37]

In 1997, he received one-half of the Nobel Prize in Chemistry "for the first discovery of an ion-transporting enzyme, Na+,K+-ATPase."[38]

Genes edit

  • Alpha: ATP1A1ATP1A1, ATP1A2ATP1A2, ATP1A3ATP1A3, ATP1A4ATP1A4. ATP1A1 is expressed ubiquitously in vertebrates, and ATP1A3 in neural tissue. ATP1A2 is also known as "alpha(+)". ATP1A4 is specific to mammals.
  • Beta: ATP1B1ATP1B1, ATP1B2, ATP1B3ATP1B3, ATP1B4

The parallel evolution of resistance to cardiotonic steroids in many vertebrates edit

Several studies have detailed the evolution of cardiotonic steroid resistance of the alpha-subunit gene family of Na/K-ATPase (ATP1A) in vertebrates via amino acid substitutions most often located in the first extracellular loop domain.[39][40][41][42][43][44][45] Amino acid substitutions conferring cardiotonic steroid resistance have evolved independently many times in all major groups of tetrapods.[43] ATP1A1 has been duplicated in some groups of frogs and neofunctionlised duplicates carry the same cardiotonic steroid resistance substitutions (Q111R and N122D) found in mice, rats and other muroids.[46][39][40][41]

In insects edit

In Drosophila melanogaster, the alpha-subunit of Na+/K+-ATPase has two paralogs, ATPα (ATPα1) and JYalpha (ATPα2), resulting from an ancient duplication in insects.[47] In Drosophila, ATPα1 is ubiquitously and highly expressed, whereas ATPα2 is most highly expressed in male testes and is essential for male fertility. Insects have at least one copy of both genes, and occasionally duplications. Low expression of ATPα2 has also been noted in other insects. Duplications and neofunctionalization of ATPα1 have been observed in insects that are adapted to cardiotonic steroid toxins such as cardenolides and bufadienolides.[47][48][49] Insects adapted to cardiotonic steroids typically have a number of amino acid substitutions, most often in the first extra-cellular loop of ATPα1, that confer resistance to cardiotonic steroid inhibition.[50][51]

See also edit

References edit

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  49. ^ Petschenka Georg, Vera Wagschal, Michael von Tschirnhaus, Alexander Donath, Susanne Dobler 2017 Petschenka, G.; Wagschal, V.; von Tschirnhaus, M.; Donath, A.; Dobler, S. (2017). "Convergently Evolved Toxic Secondary Metabolites in Plants Drive the Parallel Molecular Evolution of Insect Resistance". The American Naturalist. 190 (S1): S29–S43. doi:10.1086/691711. PMID 28731826. S2CID 3908073.
  50. ^ Labeyrie E, Dobler S (2004). "Molecular adaptation of Chrysochus leaf beetles to toxic compounds in their food plants". Molecular Biology and Evolution. 21 (2): 218–21. doi:10.1093/molbev/msg240. PMID 12949136.
  51. ^ Dobler, Susanne; Dalla, Safaa; Wagschal, Vera; Agrawal, Anurag A. (2012). "Community-wide convergent evolution in insect adaptation to toxic cardenolides by substitutions in the Na,K-ATPase". Proceedings of the National Academy of Sciences. 109 (32): 13040–13045. doi:10.1073/pnas.1202111109. PMC 3420205. PMID 22826239.

External links edit

January 01, 1970
sodium, potassium, pump, sodium, potassium, pump, sodium, potassium, adenosine, triphosphatase, also, known, atpase, pump, sodium, potassium, atpase, enzyme, electrogenic, transmembrane, atpase, found, membrane, animal, cells, performs, several, functions, cel. The sodium potassium pump sodium potassium adenosine triphosphatase also known as Na K ATPase Na K pump or sodium potassium ATPase is an enzyme an electrogenic transmembrane ATPase found in the membrane of all animal cells It performs several functions in cell physiology Na K ATPase pumpSodium potassium pump E2 Pi state Calculated hydrocarbon boundaries of the lipid bilayer are shown as blue intracellular and red extracellular planesIdentifiersEC no 7 2 2 13DatabasesIntEnzIntEnz viewBRENDABRENDA entryExPASyNiceZyme viewKEGGKEGG entryMetaCycmetabolic pathwayPRIAMprofilePDB structuresRCSB PDB PDBe PDBsumSearchPMCarticlesPubMedarticlesNCBIproteins Flow of ions Alpha and beta units The Na K ATPase enzyme is active i e it uses energy from ATP For every ATP molecule that the pump uses three sodium ions are exported and two potassium ions are imported 1 Thus there is a net export of a single positive charge per pump cycle The net effect is an extracellular concentration of sodium ions which is 5 times the intracellular concentration and an intracellular concentration of potassium ions which is 30 times the extracellular concentration 1 The sodium potassium pump was discovered in 1957 by the Danish scientist Jens Christian Skou who was awarded a Nobel Prize for his work in 1997 Its discovery marked an important step forward in the understanding of how ions get into and out of cells and it has particular significance for excitable cells such as nerve cells which depend on this pump to respond to stimuli and transmit impulses All mammals have four different sodium pump sub types or isoforms Each has unique properties and tissue expression patterns 2 This enzyme belongs to the family of P type ATPases Contents 1 Function 1 1 Resting potential 1 2 Reversal potential 1 3 Transport 1 4 Controlling cell volume 1 5 Functioning as signal transducer 1 6 Controlling neuron activity states 2 Mechanism 3 Regulation 3 1 Endogenous 3 2 Exogenous 3 3 Pharmacological regulation 4 Discovery 5 Genes 6 The parallel evolution of resistance to cardiotonic steroids in many vertebrates 7 In insects 8 See also 9 References 10 External linksFunction editThe Na K ATPase helps maintain resting potential affects transport and regulates cellular volume 3 It also functions as a signal transducer integrator to regulate the MAPK pathway reactive oxygen species ROS as well as intracellular calcium In fact all cells expend a large fraction of the ATP they produce typically 30 and up to 70 in nerve cells to maintain their required cytosolic Na and K concentrations 4 For neurons the Na K ATPase can be responsible for up to 3 4 of the cell s energy expenditure 5 In many types of tissue ATP consumption by the Na K ATPases have been related to glycolysis This was first discovered in red blood cells Schrier 1966 but has later been evidenced in renal cells 6 smooth muscles surrounding the blood vessels 7 and cardiac purkinje cells 8 Recently glycolysis has also been shown to be of particular importance for Na K ATPase in skeletal muscles where inhibition of glycogen breakdown a substrate for glycolysis leads to reduced Na K ATPase activity and lower force production 9 10 11 Resting potential edit nbsp The Na K ATPase as well as effects of diffusion of the involved ions maintain the resting potential across the membranes See also Resting potential In order to maintain the cell membrane potential cells keep a low concentration of sodium ions and high levels of potassium ions within the cell intracellular The sodium potassium pump mechanism moves 3 sodium ions out and moves 2 potassium ions in thus in total removing one positive charge carrier from the intracellular space see Mechanism for details In addition there is a short circuit channel i e a highly K permeable ion channel for potassium in the membrane thus the voltage across the plasma membrane is close to the Nernst potential of potassium Reversal potential edit Even if both K and Na ions have the same charge they can still have very different equilibrium potentials for both outside and or inside concentrations The sodium potassium pump moves toward a nonequilibrium state with the relative concentrations of Na and K for both inside and outside of cell For instance the concentration of K in cytosol is 100 mM whereas the concentration of Na is 10 mM On the other hand in extracellular space the usual concentration range of K is about 3 5 5 mM whereas the concentration of Na is about 135 145 mM citation needed Transport edit Export of sodium ions from the cell provides the driving force for several secondary active transporters such as membrane transport proteins which import glucose amino acids and other nutrients into the cell by use of the sodium ion gradient Another important task of the Na K pump is to provide a Na gradient that is used by certain carrier processes In the gut for example sodium is transported out of the reabsorbing cell on the blood interstitial fluid side via the Na K pump whereas on the reabsorbing lumenal side the Na glucose symporter uses the created Na gradient as a source of energy to import both Na and glucose which is far more efficient than simple diffusion Similar processes are located in the renal tubular system Controlling cell volume edit Failure of the Na K pumps can result in swelling of the cell A cell s osmolarity is the sum of the concentrations of the various ion species and many proteins and other organic compounds inside the cell When this is higher than the osmolarity outside of the cell water flows into the cell through osmosis This can cause the cell to swell up and lyse The Na K pump helps to maintain the right concentrations of ions Furthermore when the cell begins to swell this automatically activates the Na K pump because it changes the internal concentrations of Na K to which the pump is sensitive 12 Functioning as signal transducer edit Within the last decade when many independent labs have demonstrated that in addition to the classical ion transporting this membrane protein can also relay extracellular ouabain binding signalling into the cell through regulation of protein tyrosine phosphorylation For instance a study investigated the function of Na K ATPase in foot muscle and hepatopancreas in land snail Otala lactea by comparing the active and estivating states 13 They concluded that reversible phosphorylation can control the same means of coordinating ATP use by this ion pump with the rates of the ATP generation by catabolic pathways in estivating O lactea The downstream signals through ouabain triggered protein phosphorylation events include activation of the mitogen activated protein kinase MAPK signal cascades mitochondrial reactive oxygen species ROS production as well as activation of phospholipase C PLC and inositol triphosphate IP3 receptor IP3R in different intracellular compartments 14 Protein protein interactions play a very important role in Na K pump mediated signal transduction For example the Na K pump interacts directly with Src a non receptor tyrosine kinase to form a signaling receptor complex 15 Src is initially inhibited by the Na K pump However upon subsequent ouabain binding the Src kinase domain is released and then activated Based on this scenario NaKtide a peptide Src inhibitor derived from the Na K pump was developed as a functional ouabain Na K pump mediated signal transduction 16 Na K pump also interacts with ankyrin IP3R PI3K PLCgamma1 and cofilin 17 Controlling neuron activity states edit The Na K pump has been shown to control and set the intrinsic activity mode of cerebellar Purkinje neurons 18 accessory olfactory bulb mitral cells 19 and probably other neuron types 20 This suggests that the pump might not simply be a homeostatic housekeeping molecule for ionic gradients but could be a computation element in the cerebellum and the brain 21 Indeed a mutation in the Na K pump causes rapid onset dystonia parkinsonism which has symptoms to indicate that it is a pathology of cerebellar computation 22 Furthermore an ouabain block of Na K pumps in the cerebellum of a live mouse results in it displaying ataxia and dystonia 23 Alcohol inhibits sodium potassium pumps in the cerebellum and this is likely how it corrupts cerebellar computation and body coordination 24 25 The distribution of the Na K pump on myelinated axons in the human brain has been demonstrated to be along the internodal axolemma and not within the nodal axolemma as previously thought 26 The Na K pump disfunction has been tied to various diseases including epilepsy and brain malformations 27 Mechanism edit nbsp The sodium potassium pump is found in many cell plasma membranes Powered by ATP the pump moves sodium and potassium ions in opposite directions each against its concentration gradient In a single cycle of the pump three sodium ions are extruded from and two potassium ions are imported into the cell Looking at the process starting from the interior of the cell The pump has a higher affinity for Na ions than K ions thus after binding ATP binds 3 intracellular Na ions 3 ATP is hydrolyzed leading to phosphorylation of the pump at a highly conserved aspartate residue and subsequent release of ADP This process leads to a conformational change in the pump The conformational change exposes the Na ions to the extracellular region The phosphorylated form of the pump has a low affinity for Na ions so they are released by contrast it has high affinity for the K ions The pump binds 2 extracellular K ions which induces dephosphorylation of the pump reverting it to its previous conformational state thus releasing the K ions into the cell The unphosphorylated form of the pump has a higher affinity for Na ions ATP binds and the process starts again Regulation editEndogenous edit The Na K ATPase is upregulated by cAMP 28 Thus substances causing an increase in cAMP upregulate the Na K ATPase These include the ligands of the Gs coupled GPCRs In contrast substances causing a decrease in cAMP downregulate the Na K ATPase These include the ligands of the Gi coupled GPCRs Note Early studies indicated the opposite effect but these were later found to be inaccurate due to additional complicating factors citation needed The Na K ATPase is endogenously negatively regulated by the inositol pyrophosphate 5 InsP7 an intracellular signaling molecule generated by IP6K1 which relieves an autoinhibitory domain of PI3K p85a to drive endocytosis and degradation 29 The Na K ATPase is also regulated by reversible phosphorylation Research has shown that in estivating animals the Na K ATPase is in the phosphorylated and low activity form Dephosphorylation of Na K ATPase can recover it to the high activity form 13 Exogenous edit The Na K ATPase can be pharmacologically modified by administering drugs exogenously Its expression can also be modified through hormones such as triiodothyronine a thyroid hormone 13 30 For instance Na K ATPase found in the membrane of heart cells is an important target of cardiac glycosides for example digoxin and ouabain inotropic drugs used to improve heart performance by increasing its force of contraction Muscle contraction is dependent on a 100 to 10 000 times higher than resting intracellular Ca2 concentration which is caused by Ca2 release from the muscle cells sarcoplasmic reticulum Immediately after muscle contraction intracellular Ca2 is quickly returned to its normal concentration by a carrier enzyme in the plasma membrane and a calcium pump in sarcoplasmic reticulum causing the muscle to relax According to the Blaustein hypothesis 31 this carrier enzyme Na Ca2 exchanger NCX uses the Na gradient generated by the Na K pump to remove Ca2 from the intracellular space hence slowing down the Na K pump results in a permanently elevated Ca2 level in the muscle which may be the mechanism of the long term inotropic effect of cardiac glycosides such as digoxin The problem with this hypothesis is that at pharmacological concentrations of digitalis less than 5 of Na K ATPase molecules specifically the a2 isoform in heart and arterial smooth muscle Kd 32 nM are inhibited not enough to affect the intracellular concentration of Na However apart from the population of Na K ATPase in the plasma membrane responsible for ion transport there is another population in the caveolae which acts as digitalis receptor and stimulates the EGF receptor 32 33 34 35 Pharmacological regulation edit In certain conditions such as in the case of cardiac disease the Na K ATPase may need to be inhibited via pharmacological means A commonly used inhibitor used in the treatment of cardiac disease is digoxin a cardiac glycoside which essentially binds to the extracellular part of enzyme i e that binds potassium when it is in a phosphorylated state to transfer potassium inside the cell 36 After this essential binding occurs a dephosphorylation of the alpha subunit occurs which reduces the effect of cardiac disease It is via the inhibiting of the Na K ATPase that sodium levels will begin to increase within the cell which ultimately increases the concentration of intracellular calcium via the sodium calcium exchanger This increased presence of calcium is what allows for the force of contraction to be increased In the case of patients where the heart is not pumping hard enough to provide what is needed for the body use of digoxin helps to temporarily overcome this Discovery editNa K ATPase was proposed by Jens Christian Skou in 1957 while working as assistant professor at the Department of Physiology University of Aarhus Denmark He published his work that year 37 In 1997 he received one half of the Nobel Prize in Chemistry for the first discovery of an ion transporting enzyme Na K ATPase 38 Genes editAlpha ATP1A1ATP1A1 ATP1A2ATP1A2 ATP1A3ATP1A3 ATP1A4ATP1A4 ATP1A1 is expressed ubiquitously in vertebrates and ATP1A3 in neural tissue ATP1A2 is also known as alpha ATP1A4 is specific to mammals Beta ATP1B1ATP1B1 ATP1B2 ATP1B3ATP1B3 ATP1B4The parallel evolution of resistance to cardiotonic steroids in many vertebrates editSeveral studies have detailed the evolution of cardiotonic steroid resistance of the alpha subunit gene family of Na K ATPase ATP1A in vertebrates via amino acid substitutions most often located in the first extracellular loop domain 39 40 41 42 43 44 45 Amino acid substitutions conferring cardiotonic steroid resistance have evolved independently many times in all major groups of tetrapods 43 ATP1A1 has been duplicated in some groups of frogs and neofunctionlised duplicates carry the same cardiotonic steroid resistance substitutions Q111R and N122D found in mice rats and other muroids 46 39 40 41 In insects editIn Drosophila melanogaster the alpha subunit of Na K ATPase has two paralogs ATPa ATPa1 and JYalpha ATPa2 resulting from an ancient duplication in insects 47 In Drosophila ATPa1 is ubiquitously and highly expressed whereas ATPa2 is most highly expressed in male testes and is essential for male fertility Insects have at least one copy of both genes and occasionally duplications Low expression of ATPa2 has also been noted in other insects Duplications and neofunctionalization of ATPa1 have been observed in insects that are adapted to cardiotonic steroid toxins such as cardenolides and bufadienolides 47 48 49 Insects adapted to cardiotonic steroids typically have a number of amino acid substitutions most often in the first extra cellular loop of ATPa1 that confer resistance to cardiotonic steroid inhibition 50 51 See also editSodium calcium exchanger Thyroid hormone V ATPaseReferences edit a b Gagnon KB Delpire E 2021 Sodium Transporters in Human Health and Disease Figure 2 Frontiers in Physiology 11 588664 doi 10 3389 fphys 2020 588664 PMC 7947867 PMID 33716756 Clausen MV Hilbers F Poulsen H June 2017 The Structure and Function of the Na K ATPase Isoforms in Health and Disease Frontiers in Physiology 8 371 doi 10 3389 fphys 2017 00371 PMC 5459889 PMID 28634454 a b Hall JE Guyton AC 2006 Textbook of medical physiology St Louis Mo Elsevier Saunders ISBN 978 0 7216 0240 0 Voet D Voet JG December 2010 Section 20 3 ATP Driven Active Transport Biochemistry 4th ed John Wiley amp Sons p 759 ISBN 978 0 470 57095 1 Howarth C Gleeson P Attwell D July 2012 Updated energy budgets for neural computation in the neocortex and cerebellum Journal of Cerebral Blood Flow and Metabolism 32 7 1222 32 doi 10 1038 jcbfm 2012 35 PMC 3390818 PMID 22434069 Sanders MJ Simon LM Misfeldt DS March 1983 Transepithelial transport in cell culture bioenergetics of Na D glucose coupled transport Journal of Cellular Physiology 114 3 263 6 doi 10 1002 jcp 1041140303 PMID 6833401 S2CID 22543559 Lynch RM Paul RJ March 1987 Compartmentation of carbohydrate metabolism in vascular smooth muscle The American Journal of Physiology 252 3 Pt 1 C328 34 doi 10 1152 ajpcell 1987 252 3 c328 PMID 3030131 Glitsch HG Tappe A January 1993 The Na K pump of cardiac Purkinje cells is preferentially fuelled by glycolytic ATP production Pflugers Archiv 422 4 380 5 doi 10 1007 bf00374294 PMID 8382364 S2CID 25076348 Dutka TL Lamb GD September 2007 Na K pumps in the transverse tubular system of skeletal muscle fibers preferentially use ATP from glycolysis American Journal of Physiology Cell Physiology 293 3 C967 77 doi 10 1152 ajpcell 00132 2007 PMID 17553934 S2CID 2291836 Watanabe D Wada M December 2019 Effects of reduced muscle glycogen on excitation contraction coupling in rat fast twitch muscle a glycogen removal study Journal of Muscle Research and Cell Motility 40 3 4 353 364 doi 10 1007 s10974 019 09524 y PMID 31236763 S2CID 195329741 Jensen R Nielsen J Ortenblad N February 2020 Inhibition of glycogenolysis prolongs action potential repriming period and impairs muscle function in rat skeletal muscle The Journal of Physiology 598 4 789 803 doi 10 1113 JP278543 PMID 31823376 S2CID 209317559 Armstrong CM May 2003 The Na K pump Cl ion and osmotic stabilization of cells Proceedings of the National Academy of Sciences of the United States of America 100 10 6257 62 Bibcode 2003PNAS 100 6257A doi 10 1073 pnas 0931278100 PMC 156359 PMID 12730376 a b c Ramnanan CJ Storey KB February 2006 Suppression of Na K ATPase activity during estivation in the land snail Otala lactea The Journal of Experimental Biology 209 Pt 4 677 88 doi 10 1242 jeb 02052 PMID 16449562 S2CID 39271006 Yuan Z Cai T Tian J Ivanov AV Giovannucci DR Xie Z September 2005 Na K ATPase tethers phospholipase C and IP3 receptor into a calcium regulatory complex Molecular Biology of the Cell 16 9 4034 45 doi 10 1091 mbc E05 04 0295 PMC 1196317 PMID 15975899 Tian J Cai T Yuan Z Wang H Liu L Haas M et al January 2006 Binding of Src to Na K ATPase forms a functional signaling complex Molecular Biology of the Cell 17 1 317 26 doi 10 1091 mbc E05 08 0735 PMC 1345669 PMID 16267270 Li Z Cai T Tian J Xie JX Zhao X Liu L et al July 2009 NaKtide a Na K ATPase derived peptide Src inhibitor antagonizes ouabain activated signal transduction in cultured cells The Journal of Biological Chemistry 284 31 21066 76 doi 10 1074 jbc M109 013821 PMC 2742871 PMID 19506077 Lee K Jung J Kim M Guidotti G January 2001 Interaction of the alpha subunit of Na K ATPase with cofilin The Biochemical Journal 353 Pt 2 377 85 doi 10 1042 0264 6021 3530377 PMC 1221581 PMID 11139403 Forrest MD Wall MJ Press DA Feng J December 2012 The sodium potassium pump controls the intrinsic firing of the cerebellar Purkinje neuron PLOS ONE 7 12 e51169 Bibcode 2012PLoSO 751169F doi 10 1371 journal pone 0051169 PMC 3527461 PMID 23284664 Zylbertal A Kahan A Ben Shaul Y Yarom Y Wagner S December 2015 Prolonged Intracellular Na Dynamics Govern Electrical Activity in Accessory Olfactory Bulb Mitral Cells PLOS Biology 13 12 e1002319 doi 10 1371 journal pbio 1002319 PMC 4684409 PMID 26674618 Zylbertal A Yarom Y Wagner S 2017 The Slow Dynamics of Intracellular Sodium Concentration Increase the Time Window of Neuronal Integration A Simulation Study Frontiers in Computational Neuroscience 11 85 doi 10 3389 fncom 2017 00085 PMC 5609115 PMID 28970791 Forrest MD December 2014 The sodium potassium pump is an information processing element in brain computation Frontiers in Physiology 5 472 472 doi 10 3389 fphys 2014 00472 PMC 4274886 PMID 25566080 Cannon SC July 2004 Paying the price at the pump dystonia from mutations in a Na K ATPase Neuron 43 2 153 4 doi 10 1016 j neuron 2004 07 002 PMID 15260948 Calderon DP Fremont R Kraenzlin F Khodakhah K March 2011 The neural substrates of rapid onset Dystonia Parkinsonism Nature Neuroscience 14 3 357 65 doi 10 1038 nn 2753 PMC 3430603 PMID 21297628 Forrest MD April 2015 Simulation of alcohol action upon a detailed Purkinje neuron model and a simpler surrogate model that runs gt 400 times faster BMC Neuroscience 16 27 27 doi 10 1186 s12868 015 0162 6 PMC 4417229 PMID 25928094 Forrest M 4 April 2015 The Neuroscience Reason We Fall Over When Drunk Science 2 0 Retrieved 30 May 2018 Young EA Fowler CD Kidd GJ Chang A Rudick R Fisher E Trapp BD April 2008 Imaging correlates of decreased axonal Na K ATPase in chronic multiple sclerosis lesions Annals of Neurology 63 4 428 35 doi 10 1002 ana 21381 PMID 18438950 S2CID 14658965 Smith RS Florio M Akula SK Neil JE Wang Y Hill RS et al June 2021 Early role for a Na K ATPase ATP1A3 in brain development Proceedings of the National Academy of Sciences of the United States of America 118 25 e2023333118 Bibcode 2021PNAS 11823333S doi 10 1073 pnas 2023333118 PMC 8237684 PMID 34161264 Burnier M 2008 Sodium In Health And Disease CRC Press p 15 ISBN 978 0 8493 3978 3 Chin AC Gao Z Riley AM Furkert D Wittwer C Dutta A et al October 2020 The inositol pyrophosphate 5 InsP7 drives sodium potassium pump degradation by relieving an autoinhibitory domain of PI3K p85a Science Advances 6 44 eabb8542 Bibcode 2020SciA 6 8542C doi 10 1126 sciadv abb8542 PMC 7608788 PMID 33115740 S2CID 226036261 Lin HH Tang MJ January 1997 Thyroid hormone upregulates Na K ATPase a and b mRNA in primary cultures of proximal tubule cells Life Sciences 60 6 375 382 doi 10 1016 S0024 3205 96 00661 3 PMID 9031683 Blaustein MP May 1977 Sodium ions calcium ions blood pressure regulation and hypertension a reassessment and a hypothesis The American Journal of Physiology 232 5 C165 73 doi 10 1152 ajpcell 1977 232 5 C165 PMID 324293 S2CID 9814212 Schoner W Scheiner Bobis G September 2008 Role of endogenous cardiotonic steroids in sodium homeostasis Nephrology Dialysis Transplantation 23 9 2723 9 doi 10 1093 ndt gfn325 PMID 18556748 Blaustein MP Hamlyn JM December 2010 Signaling mechanisms that link salt retention to hypertension endogenous ouabain the Na pump the Na Ca2 exchanger and TRPC proteins Biochimica et Biophysica Acta BBA Molecular Basis of Disease 1802 12 1219 29 doi 10 1016 j bbadis 2010 02 011 PMC 2909369 PMID 20211726 Fuerstenwerth H 2014 On the differences between ouabain and digitalis glycosides American Journal of Therapeutics 21 1 35 42 doi 10 1097 MJT 0b013e318217a609 PMID 21642827 S2CID 20180376 Pavlovic D 2014 The role of cardiotonic steroids in the pathogenesis of cardiomyopathy in chronic kidney disease Nephron Clinical Practice 128 1 2 11 21 doi 10 1159 000363301 PMID 25341357 S2CID 2066801 Na K ATPase and inhibitors Digoxin Pharmacorama Archived from the original on 2020 09 28 Retrieved 2019 11 08 Skou JC February 1957 The influence of some cations on an adenosine triphosphatase from peripheral nerves Biochimica et Biophysica Acta 23 2 394 401 doi 10 1016 0006 3002 57 90343 8 PMID 13412736 S2CID 32516710 The Nobel Prize in Chemistry 1997 NobelPrize org Nobel Media AB 15 October 1997 a b Moore David J Halliday Damien C T Rowell David M Robinson Anthony J Keogh J Scott 2009 08 23 Positive Darwinian selection results in resistance to cardioactive toxins in true toads Anura Bufonidae Biology Letters 5 4 513 516 doi 10 1098 rsbl 2009 0281 ISSN 1744 9561 PMC 2781935 PMID 19465576 a b Hernandez Poveda M 2022 Convergent evolution of neo functionalized duplications of ATP1A1 in dendrobatid and grass frogs MS Thesis Dissertation Universidad de los Andes a b Mohammadi Shabnam Yang Lu Harpak Arbel Herrera Alvarez Santiago Rodriguez Ordonez Maria del Pilar Peng Julie Zhang Karen Storz Jay F Dobler Susanne Crawford Andrew J Andolfatto Peter 2021 06 21 Concerted evolution reveals co adapted amino acid substitutions in frogs that prey on toxic toads Current Biology 31 12 2530 2538 e10 doi 10 1016 j cub 2021 03 089 ISSN 0960 9822 PMC 8281379 PMID 33887183 Mohammadi Shabnam Brodie Edmund D Neuman Lee Lorin A Savitzky Alan H 2016 05 01 Mutations to the cardiotonic steroid binding site of Na K ATPase are associated with high level of resistance to gamabufotalin in a natricine snake Toxicon 114 13 15 doi 10 1016 j toxicon 2016 02 019 ISSN 0041 0101 PMID 26905927 a b Mohammadi Shabnam Herrera Alvarez Santiago Yang Lu Rodriguez Ordonez Maria del Pilar Zhang Karen Storz Jay F Dobler Susanne Crawford Andrew J Andolfatto Peter 2022 08 16 Constraints on the evolution of toxin resistant Na K ATPases have limited dependence on sequence divergence PLOS Genetics 18 8 e1010323 doi 10 1371 journal pgen 1010323 ISSN 1553 7390 PMC 9462791 PMID 35972957 Mohammadi Shabnam Ozdemir Halil Ibrahim Ozbek Pemra Sumbul Fidan Stiller Josefin Deng Yuan Crawford Andrew J Rowland Hannah M Storz Jay F Andolfatto Peter Dobler Susanne 2022 12 06 Epistatic Effects Between Amino Acid Insertions and Substitutions Mediate Toxin resistance of Vertebrate Na K ATPases Molecular Biology and Evolution 39 12 msac258 doi 10 1093 molbev msac258 ISSN 0737 4038 PMC 9778839 PMID 36472530 Ujvari Beata Mun Hee chang Conigrave Arthur D Bray Alessandra Osterkamp Jens Halling Petter Madsen Thomas January 2013 Isolation Breeds Naivety Island Living Robs Australian Varanid Lizards of Toad Toxin Immunity Via Four Base Pair Mutation Evolution 67 1 289 294 doi 10 1111 j 1558 5646 2012 01751 x PMID 23289579 Price Elmer M Lingrel Jerry B 1988 11 01 Structure function relationships in the sodium potassium ATPase alpha subunit site directed mutagenesis of glutamine 111 to arginine and asparagine 122 to aspartic acid generates a ouabain resistant enzyme Biochemistry 27 22 8400 8408 doi 10 1021 bi00422a016 ISSN 0006 2960 PMID 2853965 a b Zhen Ying Aardema Matthew L Medina Edgar M Schumer Molly Andolfatto Peter 2012 09 28 Parallel Molecular Evolution in an Herbivore Community Science 337 6102 1634 1637 Bibcode 2012Sci 337 1634Z doi 10 1126 science 1226630 ISSN 0036 8075 PMC 3770729 PMID 23019645 Yang L Ravikanthachari N Marino Perez R Deshmukh R Wu M Rosenstein A Kunte K Song H Andolfatto P 2019 Predictability in the evolution of Orthopteran cardenolide insensitivity Philosophical Transactions of the Royal Society of London Series B 374 1777 20180246 doi 10 1098 rstb 2018 0246 PMC 6560278 PMID 31154978 Petschenka Georg Vera Wagschal Michael von Tschirnhaus Alexander Donath Susanne Dobler 2017 Petschenka G Wagschal V von Tschirnhaus M Donath A Dobler S 2017 Convergently Evolved Toxic Secondary Metabolites in Plants Drive the Parallel Molecular Evolution of Insect Resistance The American Naturalist 190 S1 S29 S43 doi 10 1086 691711 PMID 28731826 S2CID 3908073 Labeyrie E Dobler S 2004 Molecular adaptation of Chrysochus leaf beetles to toxic compounds in their food plants Molecular Biology and Evolution 21 2 218 21 doi 10 1093 molbev msg240 PMID 12949136 Dobler Susanne Dalla Safaa Wagschal Vera Agrawal Anurag A 2012 Community wide convergent evolution in insect adaptation to toxic cardenolides by substitutions in the Na K ATPase Proceedings of the National Academy of Sciences 109 32 13040 13045 doi 10 1073 pnas 1202111109 PMC 3420205 PMID 22826239 External links editSodium Potassium ATPase at the U S National Library of Medicine Medical Subject Headings MeSH RCSB Protein Data Bank Sodium Potassium Pump A video by Khan Academy Portal nbsp Biology Retrieved from https en wikipedia org w index php title Sodium potassium pump amp oldid 1223401347, wikipedia, wiki, book, books, library,

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