L10 Potassium homeostasis: renal contributions

Question 1

Cell functions K+ is Critical for?

Answer 1

regulation of cell volume

regulation of intracellular pH

maintaining potential difference across cell membrane

Question 2

Hyperkalemia’s Effect on ECG?

Answer 2

Increases T Waves

Further increases prolong PR interval, depress ST segment, and lengthen QRS

As plasma [K+] approaches 10 mEq/L, P wave disappears, QRS interval broadens, the ECG appears as a sine wave(ventricular fibrillation)

Question 3

Hypokalemia’s Effect on ECG?

Answer 3

prolongs the QT interval

Inverts the T wave

Lowers the ST segment

Question 4

Factors that Alter Plasma [K+]

Answer 4

• Food intake
• Acid-Base Balance (Metabolic Acidosis (increased [H+]) => movement of H+ into cells and reciprocal movement of K+ out of cells ( Increased Plasma [K+])
• Plasma Osmolality
• Cell Lysis and Exercise (Increase Plasma [K+])

Question 5

Kidney is primarily responsible for maintaining total body K+ content (takes hours). As such K+ concentration is initially buffered by the movement of K+ into/out of _________________

Internal K+ Balance is regulated by:

• ________________________
• ________________________
• ________________________

Answer 5

Kidney is primarily responsible for maintaining total body K+ content (takes hours). As such K+ concentration is initially buffered by the movement of K+ into/out of skeletal muscle

Internal K+ Balance is regulated by:

• Catecholamines (epinephrine): activates adrenergic (alpha= release K+, Beta = uptake) receptors on target cells (Minutes)
• Insulin: Stimulates uptake of K+ into cells (Minutes)
• Aldosterone: Stimulates uptake of K+ into cells and urinary K+ secretion (~1hr)

Question 6

Excretion of K by the kidneys is regulated by?

• ________________________
• ________________________
• ________________________

Answer 6

Excretion of K by the kidneys is regulated by:

1. Plasma [K]
2. Aldosterone (Steroid hormone) passes through the membrane of principal cells & binds mineralocorticoid receptors=> bound receptor acts as transcription factor increasing: Na/K+ ATPase on the basolateral surface, Increased K+ channels on APical relative to basolateral => driving secretion of K+ from body
3. ADH: Net K secretion is not affected

Question 7

What cells are primarily responsible for regulating K+ excretion?

Answer 7

Regulation of K+ excretion is achieved mainly by alterations in K +secretion by principal cells of late distal tubule and collecting duct cells

Question 8

The proximal tubule reabsorbs _____% of the filtered K+

K+ reabsorption in PCT is primarily due to _________ via solvent drag but also due to a shift in __________________

Answer 8

The proximal tubule reabsorbs ~67% of the filtered K+

K+ reabsorption in PCT is primarily due to paracellular movement via solvent drag but also due to a shift in transepithelial voltage

Question 9

The TAL reabsorbs about ____% of filtered K+

K+ reabsorption in TAL due to both transcellular movement via ___________ and paracellular movement due to _____________ generated by apical K+ channels

Thick ascending limb DOES NOT REABSORB WATER, so no _________

Answer 9

The TAL reabsorbs about 20% of filtered K+

K+ reabsorption in TAL due to both transcellular movement (by NKCC2) and paracellular movement due to the lumen positive voltage generated by apical K+ channels

Thick ascending limb DOES NOT REABSORB WATER, so no solvent drag

Question 10

The DCT and Ccollecting duct can reabsorb K+ (_____________) or secrete K+ (____________)

• ____________cells reabsorb K+ via H+/K+ ATPase transporter
• ____________cells secrete K+ via K+ channels (ROMK channels)

Principle Cell

• _____________ is present throughout DCT and Collecting Duct
• _____________ begins in the DCT2 w/ combined presence of ROMK (K+ channel), ENaC, and Aldosterone Sensitivity.

Intercollated Type A

• No ______________ on basolateral side! Energy required for transport derived from _________________________________________

Answer 10

The DCT and Ccollecting duct can reabsorb K+ (Type A Intercalated Cells) or secrete K+ (_Principal cells)

• Intercalated cells reabsorb K+ via H+/K+ ATPase transporter
• Principal cells secrete K+ via K+ channels (aka ROMK channels)

Principle Cell

• Electroneutral K+/Cl- co-transport is present throughout DCT and Collecting Duct
• Electrogenic-Mediated K+ transport begins in the DCT2 w/ combined presence of ROMK (K+ channel), ENaC, and Aldosterone Sensitivity.

Intercollated Type A

• No Na+/K+ ATPase pumps on basolateral side!! Energy required for transport derived from H+ gradient generated by H+ ATPases on the apical side

Question 11

__________ is responsible for K+ secretion in the initial collecting duct and cortical collecting duct

Answer 11

Principal cell is responsible for K+ secretion in initial collecting duct and cortical collecting duct

Question 12

Factors that influence K+ secretion by the cortical collecting ducts?

Answer 12

1. Plasma [K]
2. Aldosterone
3. Antidiuretic hormone (Minor Response- Cancels Out): ADH increases K secretion which compensates for the decreased tubular fluid flow rates they cause

Question 13

Thresholds of Hyperkalemia/Hypokalemia?

ECF [K+] > ______ mEq/L constitutes hyperkalemia

ECF [K+] < _____ mEq/L constitutes hypokalemia

Answer 13

ECF [K+] > 5.0 mEq/L constitutes hyperkalemia

ECF [K+] < 3.5 mEq/L constitutes hypokalemia

Question 14

Role of Plasma [K+] in K+ secretion? (5 Mechanisms)

Answer 14

ECF [K+] > 5.0 mEq/L constitutes hyperkalemia and stimulates secretion of K+ within minutes via several mechanisms:

• Stimulates Na+-K+-ATPase resulting in increased K+ uptake across the basolateral membrane => increases the electrochemical driving force for exit of K+ across the apical membrane
• Increases permeability of the apical membrane to K+
• Increases secretion of aldosterone by adrenal glands
• Increases flow rate of tubular fluid which stimulates secretion of K+

An ECF [K+] < 3.5 mEq/L constitutes hypokalemia and results in opposite effects to those outlined above

Question 15

MOA/Indication for Spironolactone?

Answer 15

The action of aldosterone blocked by Spironolactone, a potassium-sparing diuretic (water pill), used to treat and/or prevent oedema and hypokalemia

Question 16

Effects/MOA of Aldosterone on K+ Secretion?

Answer 16

Hyperkalemia => Aldosterone release from Zona Glomerulosa of Adrenal Cortex=> Aldosterone (Steroid hormone) passes through the membrane of PRINCIPAL Cells & binds mineralocorticoid receptors => acts as a transcription factor leading to:

i. Increased Basolateral Na+/K+-ATPase: Increases K+ levels in cell thus increasing the electrochemical driving force for the exit of K+ across the apical membrane

ii. Increased Apical ENaC: increases the electronegativity of the lumen, thereby increasing the electrical gradient favoring K+ secretion

iii. Elevated SGK1 Levels: results in further increased ENaC expression in apical membrane and K+ channel activation

iv.Increased Apical K+ Channels: (> than basolateral) driving excretion of K+ from cell

Question 17

Effect of Tubular Flow Rate on Secretion of K+ by Principal Cells?

Answer 17

Increased Tubular Fluid Flow Rate => Bends Cilia of Principal cells=> Bending activates PKD1/PKD2 and Ca+ entry => Increased Ca+ Activated K+ channels

A rise in the flow of tubular fluid stimulates K+ secretion within minutes, whereas a fall reduces K+ secretion

Question 18

Effects of ADH on K+ secretion?

Answer 18

Opposing effects of ADH enable urinary K+ excretion to remain constant despite wide fluctuations in water excretion;

• ADH increases the electrochemical driving force for secretion of K+ across apical membrane of Principal Cells by stimulating uptake of Na+ (via ENaC) across the apical membrane => interior of the cell becomes less negatively charged => increased K+ secretion
• ADH reduces flow rate of tubular fluid => reduced K+ secretion