Week 12

Question 1

Tubular reabsorption

Answer 1

• The kidneys control reabsorption of each substance separately to regulate excretion
• Transport occurs across tubular epithelium into interstitial space then across peritubular capillaries into blood

Question 2

Paracellular path of reabsorption

Answer 2

Path between cells

Question 3

Transcellular path of reabsorption

Answer 3

Path through cells

Question 4

Reabsorption transport mechanism for sodium

Answer 4

• Primary active transport through ATPase
• Some through leaky junctions

Question 5

Why does the bulk flow in the peritubular capillaries favor reabsorption

Answer 5

• Much lower capillary pressure because its the second capillary bed
• Interstitial pressure higher because tubule pushing out

Question 6

Reabsorption in the proximal tubule

Answer 6

• Majority of filtered sodium, chloride and water reabsorbed
• High transport capacity due to brush boarder, transport proteins and mitochondria, and cell junctions are leaky
• High water permeability allows osmosis to keep pace with sodium and chloride
• Nutrients and bicarbonate rapidly absorbed
• Secretion of organic acids and bases occurs

Question 7

Proximal Tubule Transport Mechanisms for amino acids and glucose

Answer 7

• Sodium-glucose co-transporter (SGLT): Uses Na to pull glucose into cell through secondary active transport against concentration gradient - amino acids transported into tubular cells
• Amino acids transfuse out of cell
• Glucose transporter (GLUT) transports glucose out of cell

Question 8

Proximal tubule transport mechanisms for calcium

Answer 8

• Moved through paracellular pathway pulled by water moving by osmosis causing solutes to be pulled through bulk flow
• move down gradient into cell and then uses primary active transport to transport out of the cell

Question 9

Solute and water transport in the loop of henle

Answer 9

• Descending segment is highly permeable to H2O, but does not transport ions
• Ascending segments are H2O impermeable, but thick segment actively reabsorbs ions (25% of filtered Na and Cl)

Question 10

Transport in distal tubule and cortical collecting duct

Answer 10

• early distal tubule is similar to thick ascending loop (reabsorbs 5% of filtered Na and Cl)
• Late distal tubule and cortical collecting duct have similar characteristics - reabsorb Na and secrete K and secrete or reabsorb H+, HCO3- and K+

Question 11

What are the two distinct cell types that the late distal tubule and cortical collecting duct are composed of and what are their functions?

Answer 11

Principle Cells: reabsorb Na+ and secrete K+
Intercalated Cells: secrete or reabsorb H+, HCO3- and K+

Question 12

Secretion Mechanisms in intercalated cells

Answer 12

Two types with opposite functions, which are regulated based on K+ needs and pH homeostasis
Type A:
- Secrete H+ and reabsorb K+
- CO2 flows into cell and reacts with water, HCO3- is reabsorbed using secondary transport with Cl- and H+ is secreted using active transport
- Cl- excreted through diffusion
Type B:
- Secrete K+ and Bicarbonate
- Opposite direction of mechanisms occurs

Question 13

Medullary Collecting Duct

Answer 13

• Reabsorbs 5% of filtered water, sodium and chloride
• Water permeability is regulated to determine the final urine volume and concentration
• Some urea is reabsorbed into the interstitium via urea transporters to help raise the osmolarity of the medulla

Question 14

Glomerulotubular Balance

Answer 14

The proximal tubule and think ascending loop of Henle have intrinsic ability to increase reabsorption in response to increases in glomerular filtration rate (partially in response to mechanical forces on tubule)

Question 15

Aldosterone (Site of action and effect)

Answer 15

• Collecting tubule and duct
• NaCl, H2O reabsorption, K+ secretion and H+ secretion

Question 16

Angiotension II (Site of action and effect)

Answer 16

• Proximal tubule, thick ascending loop of henle, distal tubule and collecting tubule
• NaCl and H2O reabsorption, H+ secrretion
• Activates NHE causing secondary transport of Na by moving H+ out of cell, uses active transport to move into interstitial fluid

Question 17

Antidiuretic Hormone (Site of action and effect)

Answer 17

• Distal tubule/collecting tubule and duct
• H2O reabsorption
• Aquaporin II activation

Question 18

Atrial natriuretic Peptide (Site of action and effect)

Answer 18

• Distal tubule/collecting tubule and duct
• less NaCl reabsorption

Question 19

Parathyroid Hormone (Site of action and effect)

Answer 19

• Proximal tubule, thick ascending loop of henle, distal tubule
• less PO4- reabsorption nad more Ca++ reabsorption

Question 20

How does loss of functional nephrons affect renal excretion of water and solutes?

Answer 20

• Feedback mechanism compensates and upregulates function of remaining nephrons
• 90-95% loss and still maintain Na levels - regulated primarily by reabsorption
• only need to loss 25% to see an increase in waste products - impaired filtration

Question 21

Osmolarity homeostatic loop

Answer 21

Sensor: Osmoreceptor (Hypothalamus)
Control Center: Brain (Hypothalamus)
Signal to effector: ADH
Effectors: Kidneys, thirst (water input)

Question 22

Osmoreceptor-ADH Feedback System

Answer 22

1. Specialized neurons in the anterior hypothalamus act as osmoreceptors in the homeostatic regulation of extracellular osmolarity
2. Hypertonic conditions lead to shrinkage of osmoreceptor cells, leading to increased frequency of AP
3. Osmoreceptors synapse with integrating neurons in the supraoptic and paraventricular nuclei, which project axons to the posterior pituitary
4. When activated, these integrating neurons release ADH into the circulation to favor water reabsorption
   - Baroreceptors also synapse with the integrating neurons in the supraoptic and paraventricular nuclei, sensing decreases in blood pressure as a result of decreased blood volume

Question 23

Does the osmoreceptor-ADH feedback loop respond more to changes in osmolarity or blood pressure

Answer 23

Much greater release of ADH with changes in osmolarity

Question 24

Countercurrent Multiplier Mechanism

Answer 24

1. As fluid moves through loop, Ions are pumped out of the ALoH into interstitium, increasing its osmolarity
2. water diffuses out of the DLoH making it more concentrated
3. fluid continues to flow forward
4. Steps 1 and 2 are repeated
   Constant flow of lower concentrated filtrate out and higher concentrated filtrate in increases the concentration of the filtrate to a max, allowing for highly concentrated urine

Question 25

What two factors create hyperosmotic medullary interstitium?

Answer 25

1. Active transport of ions out of the thick ascending loop of Henle
2. Low water permeability of the descending loop of Henle

Question 26

How does ADH levels affect water permeability and urine concentration?

Answer 26

WHEN ADH LEVELS ARE LOW
- Permeability of distal tubule and collecting duct is low
- High volumes of diluted urine produced

WHEN ADH LEVELS ARE HIGH
- water permeability increases and reabsorption is high - more in cortical collecting duct where largest osmotic gradient exists
- low volumes of concentrated urine is produced

Question 27

How does ADH act to increase water reabsorption (physiologically)

Answer 27

1. ADH binds to tubular cell
2. activates cAMP which acts on protien kinase leading to protien phosphorylation
3. Activates intracellular vesicles to move to membrane, increasing concentration of aquaporin-2 on membrane and facilitating movement of water

Question 28

ADH effect on urea concentration

Answer 28

• Tubule normally has low permeability to urea
• ADH activates urea transporters in the inner medullary collecting ducts, enabling urea diffusion into medullary interstitium
• Urea diffuses back into the tubule in earlier regions where its concentration is lower
• This increases osmolarity and amplifies water reabsorption

Question 29

How is the medulla kept hyperosmotic? why isn’t the solute simply carried away in the blood, since there is a net absorption of fluid from interstitium into peritubular capillaries?

Answer 29

• Capillaries follow same path
• Constant equilibrium with extracellular fluid

Question 30

Osmoreceptors Control of Thirst

Answer 30

• Hypothalamus contains osmoreceptors that control thirst (Thirst Centre)
• Stimuli that increase water reabsorption in the kidneys will also stimulate thirst
• Other stimuli, like a dry mouth, will also stimulate thirst without effecting ADH and reabsorption