Editing Tubular reabsorption & secretion
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==Tubular reabsorption and secretion== | ==Tubular reabsorption and secretion== | ||
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*Recall that reabsorption of glucose occurs in the proximal tubule via SGLT (active) and then GLUT (passive). | *Recall that reabsorption of glucose occurs in the proximal tubule via SGLT (active) and then GLUT (passive). | ||
*Because not all the glucose can be reabsorbed at these high levels, there is increased osmotic pressure in the filtrate and less water is reabsorbed causing '''polyuria'''. | *Because not all the glucose can be reabsorbed at these high levels, there is increased osmotic pressure in the filtrate and less water is reabsorbed causing '''polyuria'''. | ||
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===Micropuncture and microperfusion of nephrons ''in vivo''=== | ===Micropuncture and microperfusion of nephrons ''in vivo''=== | ||
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- | *We can also measure | + | *We can also measure the tubular fluid and the plasma. |
- | **The ratio of the tubular fluid | + | Are these volumes or concentrations or what? |
- | + | **The ratio of the tubular fluid to plasma is a function of the length of the nephron: the farther along the nephron, the higher the tubular fluid concentration. | |
- | + | ? | |
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===Proximal tubule fluid is essentially iso-osmotic to plasma=== | ===Proximal tubule fluid is essentially iso-osmotic to plasma=== | ||
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**When urea, glucose, saline, and mannitol are given, the osmolarity of urine rises more rapidly than plasma (causing the U / P ratio to increase); this indicates the ability of the kidney to concentrate urine. | **When urea, glucose, saline, and mannitol are given, the osmolarity of urine rises more rapidly than plasma (causing the U / P ratio to increase); this indicates the ability of the kidney to concentrate urine. | ||
**The highest urine osmolarity to plasma osmolarity (U / P ratio) is seen when rats are dehydrated. | **The highest urine osmolarity to plasma osmolarity (U / P ratio) is seen when rats are dehydrated. | ||
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===Perfusion of isolated tubules can teach us about the PCT=== | ===Perfusion of isolated tubules can teach us about the PCT=== | ||
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***This means that water is reabsorbed in the PCT. | ***This means that water is reabsorbed in the PCT. | ||
***This provides a measure of how much water is reabsorbed. | ***This provides a measure of how much water is reabsorbed. | ||
- | ** | + | **Organic ions (like PAH) are secreted. |
***Recall that PAH is secreted "so vigorously" that nearly all of it is removed from the blood in a single pass. | ***Recall that PAH is secreted "so vigorously" that nearly all of it is removed from the blood in a single pass. | ||
***Because nearly all PAH is removed in a single pass, '''PAH is a good indicator of renal plasma flow''' (when Hct is taken into account). | ***Because nearly all PAH is removed in a single pass, '''PAH is a good indicator of renal plasma flow''' (when Hct is taken into account). | ||
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*Recall that most of the oxygen used by the kidneys goes to generating ATP for the Na / K ATPase. | *Recall that most of the oxygen used by the kidneys goes to generating ATP for the Na / K ATPase. | ||
**The consistent, large Na gradient allows tubule cells to couple transport of many molecules to Na. | **The consistent, large Na gradient allows tubule cells to couple transport of many molecules to Na. | ||
- | *'''Na reabsorption is the main driving force for reabsorption of solutes | + | *'''Na reabsorption is the main driving force for reabsorption of solutes and water.''' |
**Recall that the epithelium of the PCT is leaky, so as solutes are moved via Na gradient, H20 can and will follow. | **Recall that the epithelium of the PCT is leaky, so as solutes are moved via Na gradient, H20 can and will follow. | ||
**Recall that glucose is moved via the Na-Glucose symporter SGLT on the apical surface of the tubule cells and then via the passive GLUT transporter on the basal membrane. | **Recall that glucose is moved via the Na-Glucose symporter SGLT on the apical surface of the tubule cells and then via the passive GLUT transporter on the basal membrane. | ||
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===Reabsorption: from tubular cell to blood=== | ===Reabsorption: from tubular cell to blood=== | ||
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*Mostly passive movement of solutes and water down their concentration gradients moves them from the tubular cell into the interstitial fluid between the tubular cells and the endothelial cells of the peritubular capillaries. | *Mostly passive movement of solutes and water down their concentration gradients moves them from the tubular cell into the interstitial fluid between the tubular cells and the endothelial cells of the peritubular capillaries. | ||
**Recall that there are two sets of capillaries in the kidney: glomerular and peritubular. | **Recall that there are two sets of capillaries in the kidney: glomerular and peritubular. | ||
- | *'''Movement of these reabsorbed solutes and water molecules from the ICF ( | + | *'''Movement of these reabsorbed solutes and water molecules from the ICF (intercellular fluid) to the blood is (of course) determined by the four Starling forces''': |
**Hydrostatic pressure of the blood and colloid osmotic pressure of the ICF force solutes to stay in the ICF. | **Hydrostatic pressure of the blood and colloid osmotic pressure of the ICF force solutes to stay in the ICF. | ||
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**Hydrostatic pressure of the ICF and colloid osmotic pressure of the blood force solutes to move into the blood. | **Hydrostatic pressure of the ICF and colloid osmotic pressure of the blood force solutes to move into the blood. | ||
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===PCT and secretion of organic ions=== | ===PCT and secretion of organic ions=== | ||
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*'''Anions must be accompanied by carrier proteins''' as they cross the tubular cells (from basal to apical surface). | *'''Anions must be accompanied by carrier proteins''' as they cross the tubular cells (from basal to apical surface). | ||
**This is one reason for '''drug interactions: when one drug (anion) preferentially binds the carrier protein, another drug (anion) may be not be secreted as fast, causing an elevated effect at a normal dosage.''' | **This is one reason for '''drug interactions: when one drug (anion) preferentially binds the carrier protein, another drug (anion) may be not be secreted as fast, causing an elevated effect at a normal dosage.''' | ||
- | *OAT1 | + | *OAT1 and OCT are two important transport proteins for ions and are found on the basal membrane of the tubular cells. |
**OAT1 is the transporter that so effectively secretes PAH. | **OAT1 is the transporter that so effectively secretes PAH. | ||
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**PAH (used for measurement of renal plasma flow) | **PAH (used for measurement of renal plasma flow) | ||
**Penicillin (an antibiotic) | **Penicillin (an antibiotic) | ||
- | **Probenecid = benemid (inhibits | + | **Probenecid = benemid (inhibits penecillini secretion, inhibits uric acid reabsorption) |
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**Furosemide = lasix (a loop diuretic drug) | **Furosemide = lasix (a loop diuretic drug) | ||
***"Loop diuretics act on the Na+-K+-2Cl- symporter (cotransporter) in the thick ascending limb of the loop of Henle to inhibit sodium and chloride reabsorption. This is achieved by competing for the Cl- binding site." per [http://en.wikipedia.org/wiki/Loop_diuretic wikipedia] | ***"Loop diuretics act on the Na+-K+-2Cl- symporter (cotransporter) in the thick ascending limb of the loop of Henle to inhibit sodium and chloride reabsorption. This is achieved by competing for the Cl- binding site." per [http://en.wikipedia.org/wiki/Loop_diuretic wikipedia] | ||
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*Lipid soluble organics get into the filtrate through non-ionic diffusion through the tubular cell membranes. | *Lipid soluble organics get into the filtrate through non-ionic diffusion through the tubular cell membranes. | ||
*The lipid soluble molecules would simply diffuse back out if they are not trapped in the filtrate. | *The lipid soluble molecules would simply diffuse back out if they are not trapped in the filtrate. | ||
- | *The tubule cells pump hydrogen (H+) into the filtrate in order to trap these lipid soluble molecules in the filtrate. | + | *The tubule cells pump hydrogen (H+) and ammonia into the filtrate in order to trap these lipid soluble molecules in the filtrate. |
- | + | Are both H+ and NH3 secreted? If so, what does each do? | |
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**H+ reacts with acids to neutralize and reabsorb them into the blood. | **H+ reacts with acids to neutralize and reabsorb them into the blood. | ||
+ | **H+ reacts with ammonia to trap it in the filtrate. | ||
+ | **Ammonia reacts with H | ||
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**In order to neutralize phenobarbital when you no longer want your patient sedated, you give NaHCO3-. | **In order to neutralize phenobarbital when you no longer want your patient sedated, you give NaHCO3-. | ||
**NaHCO3- dissociates into Na and HCO3- and increases the HCO3- concentration of the blood. | **NaHCO3- dissociates into Na and HCO3- and increases the HCO3- concentration of the blood. | ||
- | **Increased plasma HCO3- will result in less reabsorption of HCO3- in the proximal tubule and thus an increased | + | **Increased plasma HCO3- will result in less reabsorption of HCO3- in the proximal tubule and thus an increased alkalinization of urine |
**At higher alkalinity (that is, fewer H+), phenobarbital will remain as an acid (and not bind H+) in the filtrate and thus be secreted (instead of binding H+, neutralizing, and being reabsorbed). | **At higher alkalinity (that is, fewer H+), phenobarbital will remain as an acid (and not bind H+) in the filtrate and thus be secreted (instead of binding H+, neutralizing, and being reabsorbed). | ||
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*Dilution occurs because the ascending loop is impermeable to water (that is, water from the filtrate cannot be reabsorbed) yet there is active reabsorption of solutes like Na and Cl. | *Dilution occurs because the ascending loop is impermeable to water (that is, water from the filtrate cannot be reabsorbed) yet there is active reabsorption of solutes like Na and Cl. | ||
**Thus, as the epithelial cells remove solutes but leave behind the water that would like to follow, '''the filtrate becomes more dilute'''. | **Thus, as the epithelial cells remove solutes but leave behind the water that would like to follow, '''the filtrate becomes more dilute'''. | ||
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*The loop of Henle is where '''loop diuretics''' work. | *The loop of Henle is where '''loop diuretics''' work. | ||
**Loop diuretics cause a loss of water and are therefore useful in treating hypertension (by decreasing the extracellular fluid compartment). | **Loop diuretics cause a loss of water and are therefore useful in treating hypertension (by decreasing the extracellular fluid compartment). | ||
**Loop diuretics include furosemide, bumetanide, etc. | **Loop diuretics include furosemide, bumetanide, etc. | ||
- | **'''Loop diuretics inhibit the Na / K / | + | **'''Loop diuretics inhibit the Na / K / Cl cotransporter of the ascending limb''' that moves Na, K, and Cl from the filtrate to the interstitial fluid. |
**One might think that this means water will not follow, but recall that the ascending limb is nearly impermeable to water anyhow. | **One might think that this means water will not follow, but recall that the ascending limb is nearly impermeable to water anyhow. | ||
**Thought loop diuretics have their pharmacological effect on the channels and cells of the ascending loop, '''loop diuretics have their physiological affect on the collecting duct'''. | **Thought loop diuretics have their pharmacological effect on the channels and cells of the ascending loop, '''loop diuretics have their physiological affect on the collecting duct'''. | ||
- | **When loop diuretics decrease the Na / K / | + | **When loop diuretics decrease the Na / K / Cl content of the interstitial fluid between the (parallel) ascending loop and collecting duct, water reabsorption is decreased at the collecting duct because there is less osmotic force pulling water from the filtrate to the interstitial fluid. |
===Distal terminology=== | ===Distal terminology=== | ||
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**Principle cells reabsorb Na and water while excreting K. | **Principle cells reabsorb Na and water while excreting K. | ||
**K secretion make sense because the Na / K ATPase on the basal surface of the principal epithelial cell generates a flow of Na into the blood (reabsorption, which H20 follows) and a flow of K out into the filtrate. | **K secretion make sense because the Na / K ATPase on the basal surface of the principal epithelial cell generates a flow of Na into the blood (reabsorption, which H20 follows) and a flow of K out into the filtrate. | ||
- | + | "K+ secretion is increased when urine flow increased due to diuretic action (problem of K+ wasting)." | |
- | + | What is causing the diuretic action? | |
- | ** | + | Why is K+ secretion increased? |
- | * | + | **Note: the more concentrated the urine, the more K+ lost. |
+ | ***This makes sense because concentrated urine occurs when Na reabsorption is high and when Na reabsorption is high, we know that lots of K+ is being exchanged for Na+. | ||
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**Alpha cells (think "a for aaaahh! too much acid") secrete H+ and reabsorb HCO3-, thus raising the pH of the blood. | **Alpha cells (think "a for aaaahh! too much acid") secrete H+ and reabsorb HCO3-, thus raising the pH of the blood. | ||
***Alpha cells secrete H+ via an apical H+ATPase and an apical H+/K+ ATPase. | ***Alpha cells secrete H+ via an apical H+ATPase and an apical H+/K+ ATPase. | ||
- | ***'''AE1 is the protein of alpha cells that | + | ***'''AE1 is the protein of alpha cells that...''' |
***Note that H+ secretion is an active process taking place on the apical surface of alpha intercalated cells of the collecting duct. | ***Note that H+ secretion is an active process taking place on the apical surface of alpha intercalated cells of the collecting duct. | ||
**Beta cells secrete HCO3- and reabsorb H+, thus decreasing the pH of the blood. | **Beta cells secrete HCO3- and reabsorb H+, thus decreasing the pH of the blood. | ||
- | ***'''Pendrin is the protein of the beta cells that | + | ***'''Pendrin is the protein of the beta cells that...''' |
**Movement of H+ (in either direction: secretion or reabsorption) is achieved by antiporting with K+. | **Movement of H+ (in either direction: secretion or reabsorption) is achieved by antiporting with K+. | ||
***Alpha cells secrete H+ into the filtrate and thus reabsorb K+ (because to move H+ into the filtrate we have move K+ into the blood). | ***Alpha cells secrete H+ into the filtrate and thus reabsorb K+ (because to move H+ into the filtrate we have move K+ into the blood). | ||
***Therefore '''alpha intercalated cells are activated when dietary K+ is low such that K+ reabsorption becomes a high priority'''. | ***Therefore '''alpha intercalated cells are activated when dietary K+ is low such that K+ reabsorption becomes a high priority'''. | ||
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**Note that '''via intercalated cells of the collecting duct, the kidney can help regulate blood pH'''. | **Note that '''via intercalated cells of the collecting duct, the kidney can help regulate blood pH'''. | ||
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*Aldosterone acts on the intercalated cells of the collecting dcut of the nephron to decrease blood pH. | *Aldosterone acts on the intercalated cells of the collecting dcut of the nephron to decrease blood pH. | ||
**Aldosterone increases alpha intercalated cell activity which causes increased secretion of HCO3- into the blood and H+ into the filtrate. | **Aldosterone increases alpha intercalated cell activity which causes increased secretion of HCO3- into the blood and H+ into the filtrate. | ||
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===ADH's effects on the kidney=== | ===ADH's effects on the kidney=== | ||
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**Note that '''potassium-sparing diuretics act on cells of the collecting tubule and have their physiological effect at the collecting tubule'''. | **Note that '''potassium-sparing diuretics act on cells of the collecting tubule and have their physiological effect at the collecting tubule'''. | ||
- | ===Comparison of PCT and | + | ===Comparison of PCT and DCT=== |
*The PCT and DCT differ in their inherent water permeability, precision of reabsorption control, transport capacity, and transepithelial gradients. | *The PCT and DCT differ in their inherent water permeability, precision of reabsorption control, transport capacity, and transepithelial gradients. | ||
*Inherent water permeability: | *Inherent water permeability: | ||
- | **The PCT's inherent water permeability is high while the | + | **The PCT's inherent water permeability is high while the DCT's is low. |
**Recall that the PCT reabsorbs most of the solutes and water of the filtrate. | **Recall that the PCT reabsorbs most of the solutes and water of the filtrate. | ||
*Transport capacity: | *Transport capacity: | ||
- | **The PCT has a very high transport capacity while the | + | **The PCT has a very high transport capacity while the DCT's transport capacity is smaller. |
**Recall that the PCT reabsorbs most of the solutes and water of the filtrate. | **Recall that the PCT reabsorbs most of the solutes and water of the filtrate. | ||
*Precision of reabsorption control: | *Precision of reabsorption control: | ||
- | **The PCT's control is course while the | + | **The PCT's control is course while the DCT's control is fine. |
- | **Recall that diuretics, ADH, and aldosterone all work at the | + | **Recall that diuretics, ADH, and aldosterone all work at the DCT (or at least the latter parts of the nephron). |
*Transepithelial gradient | *Transepithelial gradient | ||
- | **The PCT has a low transepithelial gradient while the | + | **The PCT has a low transepithelial gradient while the DCT has a high transepithelial gradent. |
**Recall that the DCT generates a high transepithelial gradient so the collecting duct can reabsorb lots of water. | **Recall that the DCT generates a high transepithelial gradient so the collecting duct can reabsorb lots of water. | ||
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**Cystinuria (amino acid transporter) | **Cystinuria (amino acid transporter) | ||
***A faulty amino acid transporter would caused decreased aa reabsorption, increased filtrate osmolarity, and decreased water reabsorption, thus causing increased urination and water loss. | ***A faulty amino acid transporter would caused decreased aa reabsorption, increased filtrate osmolarity, and decreased water reabsorption, thus causing increased urination and water loss. | ||
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**Bartter syndrome (Na / K / 2Cl cotransporter) | **Bartter syndrome (Na / K / 2Cl cotransporter) | ||
***...see above | ***...see above | ||
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***...see above | ***...see above | ||
**Liddle syndrome (ENaC) | **Liddle syndrome (ENaC) | ||
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***...see above | ***...see above | ||
**Nephrogenic diabetes insipidus (V2 receptor or AQP2) | **Nephrogenic diabetes insipidus (V2 receptor or AQP2) |