Regulation of fluid and electrolyte balance

Question 1

What must overall salt and water balance equal?

What regulates ECF osmolality?

Answer 1

Input must equal output

Kidneys regulate ECF osmolality

Question 2

What control systems regulate the volume and osmolality of the ECF? How do they regulate?

Answer 2

Effective Circulating Volume (~ ECF volume)
Regulated by monitoring arterial volume/pressure and regulating the total body content of Na

Extracellular osmolality
Regulated by monitoring and adjusting total body
water content

both have same actions on the kidneys, but use different mechanisms

Question 3

How is the ECV determined?

Answer 3

by total body sodium content

Question 4

How is the sodium concentration and osmolality of the ECF determined?

Answer 4

determined by water balance

Question 5

What happens if the ECF osmolarity changes?

Answer 5

ECF osmolality and intracellular osmolality must be equal.

if ECF osmolality changes. then the ECF may become hypo or hyper tonic. causing cells to shrink or swell

Question 6

What is the ECV? What is the ECV connected to?

When is it disconnected?

Answer 6

that part of the ECF volume that is in the arterial system and effectively perfusing tissues

connected to ECF, disconnected in disease states

Question 7

What is ECV and ECF proportional to? How is long term regulation of fluid balance occurs?

Answer 7

proportional to total body Na+ content*

Na+ loading typically leads to volume expansion
and Na+ loss can lead to volume depletion (where salt goes water goes)

Long term regulation of fluid balance occurs
by regulating the rate of urinary Na+ excretion

Question 8

Why are patients with HTN are told to watch there salt intake?

Answer 8

Where salt goes, water goes. its an increase in volume. which increases HTN

Question 9

How does the kidneys respond to a change of ECF?

Answer 9

total body Na content (not concentration) is directly related to ECV

ECF volume increase
-> Kidneys Na excretion increases

ECF volume decreases-> kidneys retains Na

Question 10

What are the sensors, efferent pathways (long term and short term) Effector(short term and long term and short term), and what is affected(short term and long term)?

Answer 10

ECV(Na content)->

sensed by (Baroreceptors in : carotid sinus, aortic arch, renal afferent arteriole, atria) ->

efferent pathway (RAAS, sympathetic nervous system, ANP, ADH) ->

Effector (Short term:  heart, blood vessels
Long term:  kidney)
->  
affected:
Short term:  blood pressure
Long term:  Na+ excretion

Question 11

What are the pathways activated that act on the kidney in response to low ECV ?
What are the sensors?

Answer 11

RAAS
Sensor = afferent arteriole -> renin

Sympathetic NS

Posterior pituitary (ADH)
Sensors:  carotid art., aortic arch

ANP secretion by the heart/atria
Sensor = atrial myocytes

Question 12

How does the kidney respond in response of decreased ECV?

Answer 12

decrease sodium excretion by

increasing tubular reabsorption or by decreasing renal blood flow, GFR

Question 13

What stimulates renin secretion?

Answer 13

Low pressure in afferent arteriole

Increased sympathetic tone(hypovolemia)

Low [NaCl] in tubule at macula dense (usually due to decreased GFR)

Question 14

Where is renin found?

Answer 14

JG cells that line the afferent ateriole

Question 15

What is going to decrease renin release?

Answer 15

Increase afferent arteriole pressure

Decreased sympathetic tone (hypervolemia)

Increased [NaCl] at macula densa (often due to increased GFR)

Question 16

What is theRenin-Angiotensin-Aldosterone

System (RAAS)?

Answer 16

Angiotensinogen is a protein that is constitutively secreted from the liver and always circulating in the blood; inactive

Renin cleaves off a decapeptide from angiotensinogen to make angiotensin I (Ang I); little/no physiological activity

Ang I circulates through out the body, acted on by angiotensin converting enzyme, ACE. ACE is found on the lumenal membranes of capillary endothelial cells, particularly in the lung [note – ACE is not “in the lung”]

ACE cleaves off two a.a. to make the octapeptide angiotensin II. This is the primary physiologically active form.

While Ang II can act on multiple sites, one of its main targets is the adrenal cortex, where it stimulates aldosterone secretion.

Question 17

Where does ANGII act?

Answer 17

Systemically
kidney
Aldosterone release

Question 18

What are ANGII systemic effects?

Answer 18

Vasoconstriction (including afferent and efferent arterioles)

Potentiate release of NOR from postganglionic
sympathetic neurons

Induce thirst and 
ADH secretion (renal effects)

Question 19

What are ANG II effects on the kidney?

Answer 19

Stimulates tubular Na+ reabsorption (PCT and eDT)

Impacts renal blood flow and GFR

Question 20

How does ANG II act on PCT? (which receptors)

What is the effect?

Answer 20

AngII receptors* are found
on both the apical and
basolateral membranes
of the early PCT

Acts to stimulate Na+ 
reabsorption via the 
apical NHE3 and 
basolateral Na-HCO3
co-transporter and 
Na/K ATPase

Sodium reabsorption pulls water along with it, so water reabsorption increases proportionally

Question 21

Which on on the receptors does ANGII act on on the eDCT?

Answer 21

NCC

ENAC

Question 22

What is the effects on Aldosterone?

Answer 22

Regulates the reabsorption of the last 2-3% of the filtered Na+ load

Na reabsorption promotes
K+ secretion (vice versa) in principle cells of ICT, CCD, OMCD

H+ secretion from intercalated cells

Question 23

What stimulates aldosterone release?

Answer 23

ANGII

Hyperkalemia

Question 24

Which transporters does aldosterone stimulate the transcription of in the principal cells?

Answer 24

ENaC
ROMK
SGK1 (regulatory kinase)
Na/K pump
TCA cycle 
enzymes

Question 25

What are the receptors that Aldosterone binds to?

Answer 25

Minneralcorticoids receptors (MR)

Question 26

What other hormone does MR bind?

Answer 26

Cortisol has similar effects to aldosterone

Question 27

Which has a greater binding affinity for MR?

Answer 27

Cortisol

Question 28

How does aldosterone receptive cells bind aldosterone instead of cortisol?

Answer 28

11b-HSD inactivates cortisol to cortisone

Question 29

What blocks the effects of 11b-HSD?

Answer 29

Black licorice contains glycyrrhizic acid which blocks the action of 11β-HSD and people who consume too much licorice have symptoms that mimic hyperaldosteronism that may lead to excess Na+ retention, hypervolemia and hypertension and hypokalemia.

Question 30

What activates the sympathetic NS to act on the kidneys?

Answer 30

are large changes in effective circulating volume or Na+ content, i.e., with hemorrhage or when some one is on a chronic low Na+ diet

Question 31

What does the sympathetic NS activates on the kidneys?

Answer 31

the JGA

the nephron (PCT)

afferent and efferent arterioles

Question 32

Which receptors does the SNS act on on the JGA and PCT?

Answer 32

Norepinephrine

JGA-B1
PCT- alpha1

Question 33

What is the effects of the stimulation of B1 receptors on jGA?

Answer 33

renin secretion and (indirectly) increasing aldosterone-mediated Na+ reabsorption

Question 34

What is the effects of the stimulation of a1 receptors on pct?

Answer 34

stimulation of apical NHE3 and basolateral Na/K ATPase

activity

Question 35

What does the excessive volume loss trigger?

Answer 35

ADH secretion from posterior pituitary

Question 36

What are the effects of ADH secretion from the posterior pituitary?

Answer 36

Excessive volume loss enhances ADH secretion

TALH, ICT and CCT, stimulates Na+ reabsorption

vasoconstriction (through V1 receptors. )

Question 37

Which transporters does ADH stimulate in the TALH,, ICT, CCT?

Answer 37

NKCC-TALH

ENAC-in principal cells of ICT, CCT

Question 38

What is the effect of ANP?

Answer 38

Promotes urinary Na+ excretion (natriuresis) by increasing GFR and filtered load of Na

direct actions decreasing tubular Na+ reabs

Question 39

From where is ANP secreted?

Answer 39

atrial myocytes in response to stretch

Question 40

Where does ANP act?

Answer 40

on the early early distal tubule and the CCD to inhibit Na+ reabsorption

Question 41

Which channels does ANP act on in the DCT?

Answer 41

Inhibits NCC in the eDCT

Question 42

Which channels does ANP act on on the CD?

Answer 42

ENaC in CD

Acts directly (cGMP mediated phosphorylation of ENaC) and indirectly (decrease renin secretion)

Question 43

What decreases the secretion of ANP? What is the effect?

Answer 43

effective circulating volume, less ANP is secreted, decreasing the stimulation for Na+ excretion (in other words, a decreased effective circulating volume downregulates ANP so more Na+ is retained, reducing Na+ excretion)

Question 44

What will happen in a reduction of ANP?

Answer 44

allow more ADH (vasopressin) to be secreted,

lead to a decrease in GFR and

an increase in renin secretion, and

would remove the inhibitory effects of ANP on tubular Na
reabsorption directly and indirectly by allowing

aldosterone secretion (ie, allow an increase in

aldosterone secretion).

Question 45

What are the summary effects of decreasing ECV?

Answer 45

decrease stretch on renal afferent arteriole
increase renin secretion-> increase ang II -> increase-> increase aldo -> increase Na+ R
PT (NHE3) CCD (ENaC)

Decrease stretch on carotid artery/aorta ->
increase sympathetic NS (nor) -> increase renin, increase-> Na+ R
ADH secretion Na+/water R in TALH/CD

decresae stretch on atria myocytes
decrease ANP* secretion-> increase Na+ R in DCT,
CCD, IMCD ( decrease Na+ excretion)

Question 46

What is the sequence that is effected when ECF osmolatity (total body water) is changed?

Answer 46

sensors- hypothalmic osmoreceptors

Efferent pathways - ADH/ thirst

Effector- short term kidney/long term brain:drinking behavior

What is affected- short term urine flow rate/long term water intake

Question 47

What senses change in ECF osmolality?

Answer 47

hypothalmic osmoreceptors

Question 48

What is ADH secretion based on when regulating osmolality?

Answer 48

Under normal conditions, little/no ADH is secreted if ECF
osmolality < 280 mOsm (red line)

But the actual threshold and sensitivity is variable and based on effective circulating volume
Above the threshold, ADH secretion is sensitive to even small changes in osmolality

Question 49

What is the primary stimulus for ADH secretion?

Answer 49

ECF osmolality (1) is primary stimulus 
for AVP secretion

Question 50

what is a change in ECF osmolality detected by?

Answer 50

OVLT and SFO in the hypothalmus

Question 51

What are the stimulus for increase of ECF osmolality?

Answer 51

1) OVLT and SFO in hypothalmus
2) decrease in circulating volume
3) decrease in arterilapressre at the carotid sinus

4angiotensin II also binds to receptors near the hypothalamus to stimulate ADH/AVP secretion

Question 52

What does ADH stimulate and where?

Answer 52

ADH/AVP binds to V2 receptor on basolateral membrane
V2 = GPCR
cAMP PKA

Phosphorylation cascade leads to insertion of AQP2 containing vesicles to apical membr