Case 3- Water and ion Reabsorbtion

Question 1

Starling forces in the proximal tubule

Answer 1

The efferent arteries and peritubular capillaries have a higher oncotic pressure as the proteins remain in the blood after ultrafiltration. The PCT and interstitium have a lower oncotic pressure as they don’t contain any proteins. Water moves down the oncotic gradient from the interstitium to the peritubular capillaries. Ions can be taken up via solvent drag. The fluid moves by osmosis

Question 2

Glomerulus starling forces

Answer 2

The hydrostatic pressure is less then in the Bowmans capsule so fluid is pushed in

Question 3

Peritubular capillaries starling forces

Answer 3

The interstitium has a high hydrostatic pressure driven by reabsorption of fluid and electrolytes via active transport. The peritubular capillaries have a low hydrostatic pressure due to the small amount of fluid in the efferent arteriole. Fluid is reabsorbed into the peritubular capillaries from the interstitium down the hydrostatic gradient

Question 4

Water reabsorption in the proximal tubule

Answer 4

1) The microvilli in the apical surface move ions from the tubular lumen into the interstitium and then the capillaries down their concentration gradient.
2) The microvilli also increase the surface area.
3) Water follows the solutes through aqua porins, this is obligatory water reabsorbtion.
4) The epithelium is leaky so water absorption can be passive and transcelular.
5) It goes from the tubular lumen through the apical surface into the brush border cells and then through the basolateral surface and into the interstitium

Question 5

Mechanisms in which Na+ is absorbed in the proximal tubule

Answer 5

1) Na/solute cotransport
2) Na/HCO3 transport
3) Passive Na/Cl absorption

Question 6

Proximal tubule- Na/solute cotransport

Answer 6

Uses the the movement of Na down its concentration to move solutes like glucose against their concentration gradient. They move in cotransporters via secondary active transport. Glucose and sodium move from the tubular lumen to the brush border cells via an Na+/ glucose cotransporter. Glucose then diffuses into the interstitium via GLUT1 and Glut2 and passively diffuses into the peritubular capillary. The N+/K+ removes Na+ from the brush border cells into the interstitium and then passively absorbs into the capillary

Question 7

Proximal tubule- paracellular transport of sodium

Answer 7

A leaky tight junction allows the paracellular transport of sodium from the tubular lumen to the interstitium. Moves due to difference in hydrostatic gradient, the water carries the Na+ on solvent drag. It then diffuses into the peritubular capillary. It’s negative in the early PT due to chloride. So, the NA+ gets attracted back into the tubular lumen by paracellular backflow

Question 8

Early Proximal tubule- Na/HCO3 transport

Answer 8

In the tubular lumen HCO3 reacts with the H+ brought in by the Na/H+ exchanger on the apical membrane of the tubular lumen: HCO3 + H+ ↔ H2CO3 ↔CO2 + H2O. The reaction is catalysed by carbonic anhydrase. H2CO3 crosses into the renal proximal tubule cells inside the reverse reaction occurs and HCO3 and H+ are produced. The gain of Na from Na/H exchange results in the net movement of Na and HCO3 (bicarbonate) from the tubular lumen to the proximal tubular cell interior. HCO3 exits the cell via NA/HCO3 transporter on basolateral membrane into the peritubular capillary, Na is pumped out by Na/K-ATPase.

Question 9

Proximal tubule- Na+/ HCO3 with Glutamine

Answer 9

The Na/HCO3 cotransporter is also used by Glutamine. It gets broken down into ammonium (NH4) and HCO3-. The ammonium is moved into the tubular lumen for excretion. And the Na+/HCO3- cotransporter moves sodium and bicarbonate into the peritubular capillary.

Question 10

Late Proximal tubule- passive NaCl absorbtion

Answer 10

As water gets reabsorbed the concentration of chlorine in the proximal tubule increases. Cl moves from the lumen of the tubule down its electrochemical gradient passively and paracellularly back into the bloodstream. This results in net Cl reabsorption. As Cl carries a negative charge, movement of Cl from the lumen generates a positive charge in the lumen. Generation of a +ve transepithelial potential creates a transepithelial driving force for the passive paracellular reabsorption of Na+ as it moves down its concentration gradient away from the lumen.

Question 11

Sodium reabsorption in the thin limb of the loop of Henle

Answer 11

Sodium movies passively into the interstitium through shallow tight junctions, down the concentration gradient. A type of paracellular transport through the squamous epithelia cells. Ascending limb of the loop of Henle

Question 12

Sodium reabsorption in the thick limb of the loop of Henle

Answer 12

In the ascending limb of the loop of Henle. On the apical surface we have a Na/K/2Cl cotransporter which move potassium and sodium into the cuboid cells surrounding the tubular lumen. This is a form of secondary active transport, so when the sodium moves down its concentration gradient it provides the energy to move the chlorine and Potassium. The Na+/K+ ATPase then moves 3 sodium into the interstitium and pumps two Potassium ions out of it and into the cuboidal cells.

Question 13

Na+ reabsorption in the early distal convoluted tubule

Answer 13

Sodium moves down its concentration gradient into the tubular cells using secondary active transport with a Na/Cl cotransporter. As sodium moves down its concentration gradient it provides the energy to move chlorine across. Sodium moves out of the tubular cells into the interstitium using an Na+/K+ ATPase pump. In the early DCT Na+ reabsorptions is load depended meaning that when there is more Na more can be reabsorbed.

Question 14

Na+ reabsorption in the late DCT and collecting

Answer 14

Na moves down its concentration into the principal cells (surrounds tubular lumen in late DCT and collecting duct) through an ENaC (epithelial Na channel). This is controlled by Aldosterone which promotes the excretion of sodium. The Na+/K+ ATPase pump moves sodium out of the principal cells and into the interstitium

Question 15

Permeability of loop of Henle

Answer 15

In the descending loop of Henle, it is water permeable and has a low permeability for ions, water passively move by osmosis through the aquaporins into the interstitium. In the ascending limb it is impermeable to water as there are no aquaporins but its permeable to ions

Question 16

How water is reabsorbed in the loop of Henle

Answer 16

The filtrate in the nephron increases in osmolarity as you go down the loop of Henle. This is known as the cortico-papillary Hyperosmotic gradient. The further down the fluid goes in the loop of Henle the more water leaves into the interstitium. The same thing happens in the collecting duct. The hyperosmolar environment is due to the build up of NaCl and urea in the medulla due to selective transport of water and salt in different nephron segments.

Question 17

The osmolarity of the loop of Henle compared to the interstitium

Answer 17

The descending loop of Henle is hyposmotic compared to the interstitium, it increases in osmolarity and becomes more hypersmotic as water leaves. The bottom of the loop of Henle is isosmotic with the interstitium. As it does up the ascending limb the fluid in the loop of Henle is more hyperosmotic then the interstitium so ions move down the concentration gradient into the interstitium. The filtrate starts to dilute in thick ascending limb until it is isosmotic with the interstitium. In order to make the interstitium saltier sodium is actively pumped out. The filtrate at the end of the PCT is Hyposmotic compared to the filtrate at the start and the interstitium.

Question 18

How is the corticopapillary gradient establishes (small)

Answer 18

It is established through Counter current multiplication (bringing electrolytes into the interstitium) and urea recycling (bringing urea to the interstitium). It is maintained by the counter current exchanger mechanism of the Vasa Recta. Aims to create a difference of 200mOsm/L between the fluid that enters and the fluid that leaves.

Question 19

Steps in maintaining the corticopapillary gradient (first half)

Answer 19

• Step 1- Assume the loop of Henle is filled with a 300mOsm/L concentration
• Step 2- The solutes in the ascending limb are pumped out, the osmolarity in the tubule fluid will decrease.
• Step 3- H2O will leave the descending limb to equilibrate the osmolarity, till the descending limb is isosmotic to the interstitium. The osmolarity of the interstitium does not change due to the removal of water in the Vasa recta.

Question 20

Steps in maintaining the corticopapillary gradient (second half)

Answer 20

• Step 4- Additional fluid flows from the PCT into the loop of Henle, the hyperosmotic fluid previously produced in the descending limb will flow into the ascending limb.
• Step 5- additional ions are pumped into the interstitium from the ascending limb till a gradient of 200mOsm/L is established.
• Step 6- again the fluid in the descending limb come to equilibrium with the hyperosmotic interstitial medullary fluid. As the hyperosmotic tubular fluid is pushed into the ascending limb from the descending limb the more solutes are drained out.
• Step 7- these steps are repeated over and over producing a gradient of osmolarity down the tubule and increasing the osmolarity at the bottom to 1200 mOsm/L.

Question 21

How does the corticocapillary gradient allow for dilute and concentrated urine

Answer 21

The filtrate is now very dilute at 375mOsm/L allowing for dilute urine but the interstitium is very concentrated so if the collecting duct becomes permeable the urine can become concentrated as water moves out.

Question 22

Counter current Exchanger- Vasa Recta

Answer 22

Maintaince the cortical pupillary hyperosmotic gradient. The Vasa Recta loops around the loop of Henley. As the vasa recta goes down the ascending loop of Henle water is secreted, and solutes are re-absorbed down their concentration gradient. The osmolarity of the Vasa recta at the bottom of the loop of Henle is equal to the interstitium. As it goes up the descending limb water is reabsorbed, and solutes are secreted down their concentration gradient. The gradient is maintained and is not washed away by the blood supply as both water and solutes are secreted and absorbed at the same rate. Only a small amount of solutes are lost to the blood and this is dependent on blood flow.

Question 23

Counter current exchanger- urea recycling in loop of Henle

Answer 23

There is more urea at the bottom of the loop of Henle then at the top. As the fluid goes down the descending limb of the loop of Henle urea moves down its concentration gradient into the loop of Henle and is reabsorbed. Increasing the concentration of the urea in the filtrate. The rest of the nephron is impermeable to urea so it cant leave.

Question 24

Counter current exchanger- urea recycling in late DCT and collecting duct

Answer 24

ADH incorporates urea transporter UT1 in the late collecting duct which passively moves urea to maintain the urea in the interstitial fluid. As when the water moves out due to ADH the interstitial fluid is diluted so the urea tops up the solutes and helps maintain the concentration gradient. Urea is recycled back into the tubular filtrate, constantly topping up the cortical papillary gradient.

Question 25

How much fluid is absorbed in the PCT

Answer 25

70% both concentrated and dilute urine

Question 26

How much fluid is absorbed in the loop of henle

Answer 26

20% both concentrated and dilute urine

Question 27

How much fluid is absorbed in the in the DCT

Answer 27

3-5% only cocncentrated urine

Question 28

How much fluid is absorbed in the CD

Answer 28

0-5% only concentrated urine

Question 29

How ADH is released- osmolar control

Answer 29

Increase in osmolarity is detected by osmoreceptors in the anterior hypothalamus, within the supraoptic nuclei. If the fluid within the osmoreceptor has a lower osmolarity then in the blood, water will leave the neuron and enter blood via osmosis through the AQP4 channels in their apical surface. This causes the neuron to shrink, triggering an action potential., The action potential triggers a thirst response and causes the posterior pituitary to release ADH

Question 30

How ADH is released- non osmolar control

Answer 30

When you are dehydrated your blood volume decreases, this is sensed by baroreceptors which are stretched less and trigger less action potentials. The firing pattern is sent to the Medulla Oblongata who passes the signals to the Hypothalamus. This triggers a thirst response and release of ADH

Question 31

How ADH is released- Granular Juxtaglomerular cells

Answer 31

The granular Juxtaglomerular cells detects a low blood volume and the low stretch of the arteries. Renin is secreted which converts Angiotensin to Angiotensin 1 which is converted using the Angiotensin converting enzyme to angiotensin 2 on the membrane. This goes to the hypothalamus to trigger the thirst response and release of ADH to reabsorb more fluid in the nephrons.

Question 32

How ADH is release

Answer 32

The anterior hypothalamus triggers an action potential which is received at the Paraventricular nuclei which contains the Herring bodies. When the action potential is received the Herring bodies are degranulated and ADH is released into the capillary bed of the posterior pituitary gland. The posterior pituitary then puts ADH into the systemic circulation which goes to the kidneys.

Question 33

ADH’s effect at the kidney

Answer 33

• In the peritubular capillary ADH binds to V2 receptors on the basolateral surface of principal cells.
• Actives the conversion of a G-coupled protein.
• This promotes conversion of ATP to cAMP via adenylate cyclase
• Which activates protein Kinase A, setting up a signalling cascade which promotes the fusion of aquaporin 2 into the apical luminal membrane enhancing permeability to H2O
• Increasing the water permeability in DC and CD results in more concentrated urine. This increases blood volume so it can return to a normal osmolality and blood volume. ADH is also a potent vasoconstrictor

Question 34

Positive Na+ balance

Answer 34

When Na+ input exceeds Na+ output. Urinary excretion of Na+ lags behind a sudden increase in dietary Na+ or IV saline. Eventually the positive balance will be corrected, more sodium causes an increase in effective circulatory volume. The increase in blood volume will be detected by baroreceptors which suppress ADH and aldosterone. This will increase the amount of urinary excretion of sodium and ECV will decease

Question 35

Negative Na+ balance

Answer 35

Occurs when Na+ output exceeds Na+ input. Urinary excretion of Na+ lags behind a sudden removal of Na+ from the diet. Less Na+ is reabsorbed so more Na+ and water is excreted. The decrease in ECF volume signals Na+ conservation and thus decreased Na+ excretion. As the decrease in ECV is detected by baroreceptors which increase ADH and aldosterone secretion. In the compensatory mechanism Na+ conservation and reabsorption leads to water reabsorption and an increase effective circulating volume.

Question 36

Initial signals to trigger RAAS (renin-angiotensin-aldosterone axis)

Answer 36

• Drop in perfusion pressure sensed by renal baroreceptors: The afferent arteriole acts as a high-pressure baroreceptor (in the Juxtaglomerular cells). If blood flow to the kidney is reduced, the drop in perfusion pressure is sensed in the afferent arteriole resulting in stimulation of renin secretion.
• Increased Sympathetic nerve activity; Activation of the sympathetic nerve fibres which innervate the afferent arteriole results in increased renin secretion, with reduced ECF.
• GFR feeback - A drop in NaCl delivery to the macula densa results in the release of renin from the JGA.

Question 37

Effects of Renin

Answer 37

Renin cleaves the circulating polypeptide Angiotensin to create Angiotensin 1, angiotensin is produced by the liver. In the circulation Angiotensin I is cleaved by Angiotensin Converting Enzyme (ACE) to produce an 8 amino acid peptide; Angiotensin II.

Question 38

What does Angiotensin 2 stimulate

Answer 38

1) The release of the steroid hormone Aldosterone from the adrenal cortex.
2) Arteriolar vasoconstriction, stimulation of ADH secretion and the thirst response and stimulation of Na absorption in proximal tubule.
3) Angiotensin 2 increases the Na+/H+ exchanger rate.
4) Reduces blood flow in vasa recta so less urea washout and more urea in the interstitium. This increases the gradient for passive NaCL reabsorption at the ascending thin loop of Henle.

Question 39

What does Aldosterone stimulate

Answer 39

It is synthesised by the Zona Glomerulosa of the adrenal gland. Constricts the efferent and afferent arteriole, constrict efferent more. Decreases peritbuluar hydrostatic pressure and increases oncotic pressure (Starling forces), causes more Na+ reabsorption through solvent drag

Question 40

Mechanism of Aldosterone action

Answer 40

Aldosterone passes through the membrane, of principle cells in the collecting duct and attaches to mineralocorticoid receptors in the cytoplasm. The receptor then travels to the nucleus and binds to specific DNA response elements. Aldosterone switches on protein synthesis of mRNA. mRNA enters the cytoplasm and binds to a ribosome. Aldosterone stimulates production of Na channels (ENaC) which are inserted into the apical membrane of the Principal cells. Aldosterone stimulates production of Na ATPase which are inserted into the basolateral membrane of the Principal cells. Na/ATPase removes Na from Principal Cells into blood. To get from the tubular fluid to the blood Na+ moves through ENaC and Na+/K+ ATPase pumps. SGK1 inhibits the enzymes which destroy these channels, so they can stay active for longer.

Question 41

Overall role of Aldosterone

Answer 41

Increase Na permeability of the collecting duct so that more Na is reabsorbed.

Question 42

How increased sympathetic nerve activation effects GFR

Answer 42

Baroreceptors detect a decrease in blood volume which will be sent to the Hypothalamus which will increase sympathetic activity. This will cause afferent arteriole vasoconstriction causing a decrease in GFR and RBF, there will be a decrease in the rate at which Na is filtered. Which will result in an increased retention of Na within the blood and therefore an increase in blood volume. A decrease in Sympathetic output will have the opposite effect. Will promote renin secretion. Can release adrenaline which will act on alpha adrenergic receptors to increase PCT Na+ reabsorption.

Question 43

How Atrial Naturetic peptide (ANP) effects GFR

Answer 43

ANP is released from the atria in response to atrial stretch, due to increased water and Na+. ANP acts as a vasodilator on both the afferent and efferent arterioles in the glomerulus. The net effect is an increase in the rate of GFR and an increase in the filtered load of Na. It also inhibits renin and aldosterone. It increases blood flow through the vasa recta, increasing the washout of solutes in the interstitium.

Question 44

The 2 types of GFR regulatory mechanisms

Answer 44

Spontaneous GFR control mechanism (modulates GFR to prevent effects from postural changes in blood pressure). As well as compensatory GFR control mechanisms (modulates GFR to combat excess dietary sodium intake, in order to reduce ECV).

Question 45

How starling forces can regulate GFR

Answer 45

Changes in fluid and small molecule reabsorption due to changes in Starling’s Forces. As more fluid and small molecules are filtered and reabsorbed in the proximal tubule, the hydrostatic pressure in the interstitium increases driving fluid and solute reabsorption from the tubule into the blood stream. If the % of H2O and small molecules being filtered increases then the colloid osmotic pressure in the peritubular capillaries would increase and this would increase fluid and small molecule absorption from the interstium of the tubule.

Question 46

Natriuresis

Answer 46

Sodium excretion

Question 47

Anti- natriuresis

Answer 47

Decrease in sodium excretion

Question 48

Inhibitors which target the RAAS system

Answer 48

Renin inhibitors block the conversion of angiotensin into angiotensin 1, meaning no angiotensin 2 can be formed. Ace inhibitors block the conversion of angiotensin 1 to angiotensin 2. ARB antagonists block the effects of angiotensin 2. Less sodium and water will be reabsorbed

Question 49

Potassium balance within the body

Answer 49

Most of our potassium is within cells (140mM), 4.5mM is extracellular.

Question 50

Potassium intake and absorbtion

Answer 50

We have GI intake of 70mMol of K+ every day, this is in meat, fruit and fruit juice. It enters the gut and 10mMol are lost as faeces, The rest is absorbed in the intestines (65 mMol) and forms part of our extracellular fluid. The kidneys filter the excess K+ about 810mMol/day, and we secrete 50mMol/day. 60mMol/day of K+ is excreted in the urine. The rest of the K+ is reabsorbed in the extracellular fluid. This is external balance. K+ is buffered by our muscles, liver, bone and red blood cells. This is internal balance, uptake is stimulated by insulin, aldosterone and adrenaline.

Question 51

Factors affecting K+ balance

Answer 51

• Acid base balance- to increase the pH in acidosis the H+ is taken out of the cell in exchange for K+ using the K+/H+ exchanger. This results in Hyperkalaemia as more potassium in the blood. Acidosis causes Hyperkalaemia
• Changes in osmolality- cells gain K+ in response to cell shrinkage, so that water will move in.
• Cell Lysis- burns or chemotherapy treatment
• Exercise- increase in muscle contraction

Question 52

How does increases K+ levels increase K+ excretion

Answer 52

This mechanism will get saturated at high concentrations. So, when the [K+] increases the Na+/K+ ATPase pump moves K+ into the cell and K+ gradient across the apical membrane becomes steeper. K+ will then move into the lumen down its concentration gradient so it can be excreted.

Question 53

How does aldosterone cause increased K+ excretion

Answer 53

As plasma [K+] increases the zona glomerulus is depolarised which causes direct stimulation of Aldosterone release, due to calcium entering the cell. Not due to RAAS. Aldosterone inserts more Na/K ATPase channels into the basolateral membrane. It also inserts more Na+ channels into the apical membrane. The increase in Na+ reabsorption generate an electrochemical gradient, by leaving a negative charge in the lumen. The increase in Na/K ATPase generates a steeper K+ concentration gradient. So K+ moves into the lumen

Question 54

How does increased urine cause increased K+ excretion

Answer 54

As urine flow rate increases so does Potassium secretion, this is because the more urine flow there is the steeper the gradient for K+. As the K+ is being washed away. Increased [K+] also stimulate more urine flow.

Question 55

How does acid-base balance lead to increased K+ excretion

Answer 55

In alkalosis we have increased K+ renal secretion, in acidosis we have decreased K+ secretion. In alkalosis the low [H+] stimulates the Na+/K+ ATPase on the basolateral membrane increasing the K+ gradient in the cell. Also increases the number of K+ channels and their opening time. More K+ enters the tubular lumen. Acidosis does the opposite.

Question 56

Different sites of K+ absorption

Answer 56

Regardless of diet, 80% of K+ is reabsorbed in the proximal tubule and 10% in the loop of Henle. In a low K+ diet, the remaining K+ is reabsorbed in the distal tubule and collecting duct.

Question 57

How is K+ absorbed in the late proximal tubule

Answer 57

K+ is absorbed paracellularly, it’s driven by the membranes potential difference. The tubular fluid is more positive then the extracellular fluid, so the potassium moves down this concentration gradient.

Question 58

How K+ is absorbed in the ascending limb of the loop of Henle

Answer 58

K+ is reabsorbed via the Na-K-2Cl cotransporter. The lumen is still more positive then the extracellular fluid so the K+ can be reabsorbed paracellularly due to the difference in potential difference.

Question 59

How K+ is handled in the distal tubule and collecting duct

Answer 59

The first mechanism involves the principal cells. As sodium moves out of the collecting duct, the lumen becomes more negative, so Potassium enters the urine due to this difference in potential difference. Only happens when we have high K+ levels in our blood. The relative levels of Na+ and K+ can be maintained by the Na+/K+ pump.
The other mechanism involves the alpha intercalated cells of the collecting duct. This reabsorbs K+ in exchange for protons due to the action of the K+/H+ ATPase pump. When we have too much K+ more will secreted by the principal cells, when we have too little more will be absorbed by the alpha-intercalated cells